Gene
KWMTBOMO05696 Validated by peptides from experiments
Annotation
PREDICTED:_LOW_QUALITY_PROTEIN:_notch-like_protein_isoform_X1_[Bombyx_mori]
Full name
Fibrillin-1
+ More
Fibrillin-2
Neurogenic locus notch homolog protein 1
Neurogenic locus Notch protein
Neurogenic locus notch homolog protein 2
Neurogenic locus notch homolog protein 3
Latent-transforming growth factor beta-binding protein 2
Fibrillin-3
Protein eyes shut homolog
Latent-transforming growth factor beta-binding protein 4
Latent-transforming growth factor beta-binding protein 1
Neurogenic locus notch homolog protein 4
Fibropellin-1
Latent-transforming growth factor beta-binding protein 3
Fibulin-2
Transmembrane cell adhesion receptor mua-3
Adhesion G protein-coupled receptor E1
Adhesion G protein-coupled receptor E2
Fibulin-1
Protein jagged-1a
Protein jagged-1b
Protein jagged-1
Sushi, nidogen and EGF-like domain-containing protein 1
Mucin-like protein
Multiple epidermal growth factor-like domains protein 6
Protein kinase C-binding protein NELL1
Protein jagged-2
Signal peptide, CUB and EGF-like domain-containing protein 3
Protein serrate
Hemicentin-1
Protein crumbs homolog 1
Signal peptide, CUB and EGF-like domain-containing protein 1
Protein crumbs
Signal peptide, CUB and EGF-like domain-containing protein 2
Protein lin-12
Protein crumbs homolog 2
Fibrillin-2
Neurogenic locus notch homolog protein 1
Neurogenic locus Notch protein
Neurogenic locus notch homolog protein 2
Neurogenic locus notch homolog protein 3
Latent-transforming growth factor beta-binding protein 2
Fibrillin-3
Protein eyes shut homolog
Latent-transforming growth factor beta-binding protein 4
Latent-transforming growth factor beta-binding protein 1
Neurogenic locus notch homolog protein 4
Fibropellin-1
Latent-transforming growth factor beta-binding protein 3
Fibulin-2
Transmembrane cell adhesion receptor mua-3
Adhesion G protein-coupled receptor E1
Adhesion G protein-coupled receptor E2
Fibulin-1
Protein jagged-1a
Protein jagged-1b
Protein jagged-1
Sushi, nidogen and EGF-like domain-containing protein 1
Mucin-like protein
Multiple epidermal growth factor-like domains protein 6
Protein kinase C-binding protein NELL1
Protein jagged-2
Signal peptide, CUB and EGF-like domain-containing protein 3
Protein serrate
Hemicentin-1
Protein crumbs homolog 1
Signal peptide, CUB and EGF-like domain-containing protein 1
Protein crumbs
Signal peptide, CUB and EGF-like domain-containing protein 2
Protein lin-12
Protein crumbs homolog 2
Alternative Name
MP340
Motch B
Motch A
mT14
p300
Translocation-associated notch protein TAN-1
Transforming growth factor beta-1-binding protein 1
Epidermal growth factor-related protein 1
Fibropellin-I
SpEGF I
UEGF-1
Transforming growth factor beta-1-masking protein large subunit
Muscle attachment abnormal protein 3
Cell surface glycoprotein F4/80
EGF-like module receptor 1
EGF-like module-containing mucin-like hormone receptor-like 1
EMR1 hormone receptor
Jagged3
Epidermal growth factor-like protein 10
Epidermal growth factor-like protein 11
Protein spacemaker homolog
Insulin-responsive sequence DNA-binding protein 1
Epidermal growth factor-like protein 3
NEL-like protein 1
Nel-related protein 1
Protein beaded
Fibulin-6
Secreted protein SST-3
Stromal nidogen extracellular matrix protein
Basement-membrane protein 90
95F
Protein CEGP1
Scube/You
Abnormal cell lineage protein 12
Protein You
Crumbs-like protein 2
Motch B
Motch A
mT14
p300
Translocation-associated notch protein TAN-1
Transforming growth factor beta-1-binding protein 1
Epidermal growth factor-related protein 1
Fibropellin-I
SpEGF I
UEGF-1
Transforming growth factor beta-1-masking protein large subunit
Muscle attachment abnormal protein 3
Cell surface glycoprotein F4/80
EGF-like module receptor 1
EGF-like module-containing mucin-like hormone receptor-like 1
EMR1 hormone receptor
Jagged3
Epidermal growth factor-like protein 10
Epidermal growth factor-like protein 11
Protein spacemaker homolog
Insulin-responsive sequence DNA-binding protein 1
Epidermal growth factor-like protein 3
NEL-like protein 1
Nel-related protein 1
Protein beaded
Fibulin-6
Secreted protein SST-3
Stromal nidogen extracellular matrix protein
Basement-membrane protein 90
95F
Protein CEGP1
Scube/You
Abnormal cell lineage protein 12
Protein You
Crumbs-like protein 2
Location in the cell
Extracellular Reliability : 2.967
Sequence
CDS
ATGTATATAGACAGTCTACCGCTCGTGGTTTGGACGCTCTTAGTCACAACGACACATGTAGCGACACAAAGCCAGTATGGAATAGGCTTAGGAATAAAACGAGAAGTATTTTTCTTAAATTTAGAAGACGGCTACTTTGGTTGTCAAGTTAACGAATCAACACAAATTTTGCAATTATATGAACTATCGAAACTATGCGACGGTGTTACGGATTGTTACAAAGGCTCTGATGAGTTGAAGTCGGAGTTAAAATGTTCAGACGATTGTACCAAAGAAGATGGCGCCCAGTGTGTGAACGGTGCCTGTCTAAACGGTGTGTGCCATTGTAATGACGGTTTCGGCGGCTGCAACTGCCAAGACCCCGATATAAATGAATGCAAAGACAGGCCCTGTGATGTTTTTGCACACTGTACAAACACCGTCGGCAGTTTTCAATGTTCTTGCTTTCCCGGTTATGAGGGCGACGGTTTTACTTGCAGAGATATAAACGAATGTGAAGACCCGGCTATAGCATCTCGTTGTGTTGAAAACGCGGAATGCTGTAATCTGCCAGCTCACTTTATCTGCAAATGCAACCGTGGCTTTGAAGGCGACGGCGAAGAAGAATGCAGAGATATCGATGAATGTCGTCGACCTGGTGCTTGTGGAACGCATGCAATTTGTCGTAATTATCCTGGAAACTACACGTGCTCATGTCAAGCCGGCTACACTGGGAATCCATTCGATGGTTGCGTTGATGTTGATGAATGCATCAATGAATCAACGTGTGGCGAAGTGGCCATTTGTCGCAACATAGACGGCGGCTACGAGTGCAGCTGTCCACCTGGCTACGAAGGCGATCCACGAGTCGCATGTCATGATCATGACGAGTGCGCTCGCGCTGCCTGCGGTCGCGGTGCTTTGTGTGAAAATCTTCCGGGAGCATACCGCTGCGTCTGCCCGCCAGGTTTTGATGGAAACCCCGATGTTCTCTGTTCCGACGTGGATGAATGTAAGAGTAGCGAGACTGTGTGCGGTGCACATGCTGTCTGCACGAACACGGCAGGCAGCTATGTGTGCACTTGCGCGCCTGAATACACCGGAGACGCATACGCGCAAGATGGTTGCCTGGACTTGGACGAATGTCAGACGCTAGAGAAGCCGTGTGGAACAAATGCTATTTGTGAAAACTCTGCGCCAGGCTACAATTGCGTCTGTCCTCAAGGATTCGCAGCACAACCAGACCCTCAAATTGCATGTGAACAGGTTGACGTCAATATTCTGTGCAAATCAAACTTTGATTGCACTAATAATGCCGAGTGTATTGATCATCAATGTTTCTGCAAGGAAGGCTTCAATGCCAAGGGCTCCATCTGCGAAGACGTTGATGAGTGTTCAAATAATAAATCAGTATGCGGTGAAAATGCTTTATGTATTAATATTCCCGGGGGCTACAATTGCCAATGTGCTGCGGGATTTGTTGGATCTCCGCCAAAGATTGGATGTCGTGCCCCTTGTGAAGATGTTAAATGTGGAAAACATGCTTATTGTAAGCCTGATGGAATGGAGGCGTATTGTGTTTGTGAAGATGGATGGACATTTAATCCCCATGATATAGCAGCTGGTTGTATTGATTTAGACGAATGCGACATATCACTGGGTCCAGTAGGCCGCTGTGGAAAAAATGCCATTTGCTCAAACACTCCTGGAAGTTTTTCATGTAATTGTCCCGAAGGATATACTGGTGATGCATACAAACAGTGTTCAGATATTGATGAATGTCAATTAGAAGGAGCATGTGGCTTAGGAGCCGATTGTTTGAATCGAGATGGATCTTATAGTTGCGAATGTCCCGACGGTACTATACCAGATCCAGACCCACACATACGATGCGCTGAAATTCTTGCTTGCAAAGGAGACAAGGACTGTCCTGGAAATGCAGTATGTGATTCTAATGCTAGGTGTTTGTGCCCCGAGCCCAATATCGGAAATGATTGCCGACATCCTTGTGAATCTCTGCAATGTGGCACTAATTCAGAGTGCTTATTAAGTGATCAAGAAGCCCAATGTACTTGCAAGAGTGGATTCACAGGTGATCCATCTTCACTACTAGGGTGTCAGGATATGAATGAGTGTGATGAAAAACCATGCGGCGTAGGTGCTGTCTGTAAAAATCTACCAGGACGTTTTCAATGTGAATGTCCTGCGACGTTCACTGGAAATCCATACGTTGAAGGATGTAATCCTGGTAAAATACTAAGCGAGTGTAGCAACTTAAATCCTTGTCCAGAAGGTGAACAATGTATTTTACATGATGGTGGAAATGTTTGTATTTGCCCTCAAGGATTCACACGTAATTCTGAAACTGGATTATGTGAAGATATTAACGAATGTGTTCAACACGGACGTTCTCCATGTGGTTTAAATGCTATTTGTAAAAATCTACCTGGAAGCTATGAATGTAAATGTCCTCAGGATTATAGTGGTAACCCATATAAAATTTGCGAGCTTTGTGATGACATTTCATGCCAGTGTCAACCACCATATAAAATGATAGACGGAAGCTGTGTTCTTTCTGGTTGCGGTAAAGATAATAAATGTGGTACAGGCGCAGAATGCATTGTAATTTCTGATGAAGTTAGTTATTGTGCATGTCCAGCCGGTTACACGCAGACCAGTGACAGTACTTGTGAAGACATTAATGAATGCACCTCAGGCACACCTGTATGTGGATTTGGGGCAGAATGTATAAATACCGTGGGCTCTTTTGAATGTAAATGTCCTCCCGGATATAGTAAAGACAAGATCGAAGGACACTGTTCATTAAACCAAAAACGATGCATTAGTGATTCCGATTGTTTCCCTAACGAAAAATGCGTTCAACCAGGTAAATGTATGTGCCCTCCGCCGTTTTATTTAGATGTCACAGATGGGCAAAAGTGCAAAAGTCCTTGCGAACGTTTTACTTGTGGTATTAACGCTAAATGCACTCCAAGTGATCCACCGCGTTGCATGTGTATGGCTGGTTATGAAGGCGATCCTTACACCGGTTGCACGAAAAGAAACGAATGTCACAGTTCTCCTTGCGCATACGGAGCTATTTGTCATGATCAAAAAGGGGGTTATAAATGCGATTGTCCACCGAATATGATCGGAGATCCATACAGGAGTGGATGCGTATTTGAAGAGGAACCAACACAAAAACATTTATGTAGCTCTGATGATCAATGCCCTAATACATTAGCATGCTTAAATCATACATGCATCTCACCATGTGCCACCATTTCTTGTGGACCAAATGCATTTTGTGAAGTTGAAAATCATGCAGCATGGTGTCGATGCGATCCAGGTTACACCAAACCTGAAGGTGGAAAATGTATTTCAGCATGTGACACATATAATTGTGCCCCAGGAGCTCAGTGTATTATTTCGAAAACGGGACCGACATGTGTTTGCGTTGAGGGCTTTGTAGGAAATCCGTTTCCTGGTGGTTCGTGCAGTAGAGACCAGTGTGGACCAGGGATTCCATGTGAAGATCCTTTGACCTGTGTGGCTGGACGTTGCAGACAACGATGTGAGGGAGTTCTTTGTGGTGTTGGCGCGACTTGTGACTCTCAAACCGGTAGATGTGTTTGTAATCCATTCTTCATTGGAAATCCGGATTTGTTGTGCATGCCACCTGTCTCTCCACCAGCTTGTGAACCCAATTGTGGAACCAATGCACATTGCGTATATGGAAAAGACAACATTTGCAAATGCAATAAAGGTTTCACAGGAAATCCGTATAAAAAGTGTTTATCACGTAAACAAATAACATGCGCCACAGCCTCCTGCGGTCGAAATGCTGTGTGTCAACAAACGAAATCTTCCATAGAATGTTTATGTCCACCAGGTTATGTAGGGAATCCTAATATTCAATGTAAAGATATAGATGAATGTGGTACAAATCCATGTGGTGAGAACGCACTTTGTATTAATACGCCAGGAAGTTTTAGTTGTATATGTAGGAGCAGATACGTCGGTAACCCATATGAATTGTGCTCACAAGTTTCAGTTGCAAAATGCACTGATGGCGCTGTGTGTACTTGTTCACATAATACTACATGCCCTCATGGATTTGTTTGTGACAAATCTAAGTGTGTTGATCTTTGCGAGAAACTTGCGTGCGGACCTAAATCTGTTTGCGAAGAAGGCGTATGTCACTGTTTACCAAGTCATACTGGAGATCCTAATGACCTACGAAAAGGCTGCGTACCCGATGATAGCTGCCTAGTTGACGGAGATTGCAAAGATTCGGAAATCTGTTTTCAAGTAGCAAAAAACACTCGCAAGTGTGTTGACTCATGTAGTAAATTACAATGTGGACCAAATTCACTTTGTATTGGTGCCAACCATCAAGCCCATTGCATTTGTGCAGATGGATACATTGGAAAACCCACAGACGTTAAGGTTGGCTGTCATTTAGAACAAAGAGAGCCAAATGAATTCGAATGTAATGACAATAGCGATTGCAATGAGCCTTTTGTTTGTATGTCACTAGAAGGATCTACGAAAAGATGCATAGACTTATGTACCACCATAGCTTGTAGTGCAAATGAAGTTTGCAGAGTAGTTGCGGAAAGCGCTCGTTGTGAGTGTGATAATGGTTTTCTATGGAATCCTGTTACCTCGAATTGCGAACAACCTTCAACGCCAAATTGTCAAGAAGATGATGATTGCGATGATAATAAATCGTGTAATAAAGATGTTCTAGGTGTCAAAAAATGTGAGGATAGCTGCTCTGTTTTCAATTGTCCTGAAAATTCTAAATGTGTAACAAAAAATCATAAAAGTAAATGTGAATGTATTAATGGATTTATCGGAAATCCTAATGATCGTGATGGCTGTTTAGCGATAGATAAAAACGAGTGCTCAGATGACGCACAGTGCAGAGAAAGCGAAGTGTGTAGGACCTTTGGTGGTAATAAAAAGTGTGTATCGGCATGTCAAAACGTCGTGTGTGGTCCTAATGCTTTTTGTATTACTAAAAATCATATTGCCAGATGCCAATGTCCGTCTGGACCATTTACTGGAAGTCCTGATGATTTAGAAAAAGGATGCCAATCTGTACCATGTGTACATAATGATGATTGCTTGTCGCACCAATTGTGTAACCGTATGACATACACATGCATCAATGCTTGTACTGTAAATTCTTGTGGTGATAATGCAGTGTGTATAGCAGAAAATCATAAAATTATTTGCCAATGTCCTAATGGTTACAGTCCCGATCCGAAGCCTGAAGTAAGCTGCCAAAAAGACGATGCTTGTAATTCAAATCCTTGTCACCCGTCAGCGATTTGCGAGTCCAGCTTCTCTTCCTTTAGTTGTCAGTGTCCTAATGGATATGTAGGTGATCCAATCAAAGACGGCTGTCGAAAACAAGATATTTGTCTCAGAGATGGTGACTGTCCCAGAGAAGCTGTCTGTGTTGAAAATCGCTGCGTCAATACTTGTGATGGAGCATGCGGGCTCAATTCATTATGTCAAATTATCAATAGAAAGGCCGTTTGTATGTGTCCAGAGGGATATGAAAAAATACAAGACAATGCATGTAAAAAGAAGTTGTTGGCATGCTCGAGTGAAAAAGATTGCGGCGGAGACATTTGTAACAATGGCCAATGTTTTACGGCTTGTAAAAACTCAAGCCAGTGTGAATTTGGAGATATATGCAAAAATAACCTTTGTGTTGCTCAATGTAATAAGCATACACAATGTGGACATGGCCAGGCATGCATTGGCGGACAGTGTTTAATTGGTTGCAGAAATAATGAAGATTGTTTTTCCGAAGAAGCATGTGTAAACAACAAGTGTGTGAATCCCTGTCTGACAACAAAACCATGTGGTCCAAACGCTATTTGTTCCAGAATAAACCACAGTACAAATTGTGAATGCCCTCTAGGTTTTCAAGGTGCACCGACACCTCAACAAGGCTGCGTCCGAAAACCAAGTGTCTGTGATAGAACATCTGATTGCCCACCGGATCATATGTGCATAGGGTTTTTGTGTCAAGTACCATGCAAAGACAGTACTGGTTGTGCTATTGGAGAAAAATGTAGTGACAATAAATGTTTAAGAATTTGTCATTCGAGTACTAATTGCTTACACGGGGAACATTGCGATGCGGGCGTATGTGTACCGGGATGTAAATCAGATTTAGATTGCCTGAACAATCTAGTGTGCAATAACATGAAATGTCAATGTACTGCTGGATTCGAACTACGGAACGAAGAATGTACTAATTTAAACGAATGTTTGGAATATCCATGTCATCCATCAGCTCAATGTGTTGATACTCCAGGATCTTATAAATGTGTCTGCTCAGTAGGAGCTGCTGGTGATCCTTACAGAAGCGGTTGTTTACTGCCTAATCAATGCAGAAATGATGAACAGTGTGACAATTCATTAGCTTGTATACAAGGAAAATGTTCAAATCCCTGTCAAAACAACACTTGCGGCACAAATGCAGAATGTTCTGTTATGAATCATAATGTAATGTGTGCTTGCAAAAAAGGATATCTCGGAAATCCATTTGACAAAAACATAGGATGCTTTAAGGTGGAATGCGTGGATGATTCAGACTGCAATACTGAAAAATATTGTGATTTAAAATTCAATAAATGTTCAGACGTATGCGAACCGTCAATCTGCGATGGTGGCAACTGCAAAATAGAGAATCATAAAATGCTGTGTACCTGTCCAACAGGATATTTGTTCAAAGATAAAAAATGCGTAGACTTAAATGAATGTCTTAGCAGCCCATGTCCGCTTAATTCGAAGTGTTTTAATACACTCGGATCTTACAAATGCGAATGTGTAAATGGAACAGTACAAGATACAATCACGGGCAGCTGTAAGCTTCCAGGAGATTGTGTTACCGATGACGATTGTACTCAAGTAACAAAATGCTTCAACAACCATTGTGTCAATCCTTGCGAAAAATTGTCACCTTGTGGCGAAAATGCTAATTGTTTTGTAACAAAACATAAAGCTGAGTGTGAGTGTCCGTCTGATAGTCAAGGTGATCCCTACAAGAAATGCATTAAGTTTGAATGCACAAAAGACAACCACTGCCCACAAGAGGAGGCGTGTGTTAATAACAAATGCAAAAATGCATGCAGTTTGCCAAGGGCATGTGGCCGGAATGCGGATTGTTTCTCCAAAAGTCACGTTGGGAACTGTATCTGCTCGCCTGGTTATACCGGGGATCCTGTTCTTGGCTGTGTTCCAATTCAATACTGTACCACTGATGACAGATGCTCTTCAGGAACAAAATGCGTGGATAATTTATGCGTTGGCCTGTGTAAAAACTCCAGAGACTGTTTGAACAACCAAGTTTGTATAAAAAATACATGTCGAGTAAGTTGCAGTCTCAACGATACTTGTCCAGAATTTCAATATTGTTTAAATAGTATATGTACCAAAGAAGTTCAGTGCATATCTAACGATGATTGTCTGGATGACGAAAAGTGTTCGACGGGGAAAAATGGAATACCTCAATGTATTAAAGTTTGCGATAAACATCCATGCGGCCGACAGGCTGAATGTCTTGGAAAAAATCATCAACCAACTTGTTCTTGCGCTTTAGGATTCTTCGGTGATCCGTTGGAAGGATGCCAACGAAAAGAATGCGACACGGACACAGAATGCTCTGAAGATAAAGTATGTGATCGTAACATGTGTAAAATAGCCTGTCTAGTTAAAAACGAATGCCGCGAAAATTCTATTTGTTCATCAGAGAAGCATAAAAATGTATGCTATTGTCAACCTGGCTATACCGGTGATCCAATAAAAGGATGTACTGAAATAAATTGGTGTAAATTAAGCCCTTGTGCAAATGGAGCGGAATGTAAAAGTGCGCGAGACCGGGCAGAATGTACATGTCCAGCAAATACTGTGGGAAATCCGTACGAAGAAGGATGTCGGAAGGCTGAAGAGTGTAGGTTTAACCGAGATTGTCCAACTGCTGCACGTTGTACCGTTATCGATGGTACAAGGAAGTGTACAGATGCCTGTGAAAATGTAAAATGTGGATTAAATGCAGAATGTTTCGCTTCGAGACATAGCGCTCAGTGCAGATGTAAAACTGGATTCATAGGAAACGCTAATAGTGAGAAAGGATGTCACCTACGTGAAATATCGTGTACTTCTAAATCGAACTGTCCCGATGATCAGTATTGCCACAAGGGAATTTGCAAAGCTTTATGCCTCCTGGACGAAGAATGTGCATCCAACGAGAAATGCTTCGGCGGACAGTGCCTTAATCCATGTCAGTTAGAAAAAACTTGTGGCTTAAATGCTATATGTCGGACTGATAACCACATTGTTCAATGCAGCTGTCCTCAAAGTTTTACAGGAAATCAAGACATGGAATGCATTCGAATTCCGAGATTGTGCGGTTCAGCTGGTGATTGTGAAAATGGCCACATGTGCAAAGATTCCATGTGCATTCCTCGATGTAATATCGATGAAGAATGTGCTTTGAACGAAAGGTGCACGAAAGGTGGATGTTTATTGACTTGTCGGGTTGATAATGATTGTTTCCCAGGACACATTTGTCTAGAACAAAGTTGTCAATATGGCTGTAGATACGACGATGATTGTGGGCCTGAAGAATTTTGCAAGAATGATGTTTGCAAAAATCCTTGTGATAGTGATGTGAATCCTTGTGGACCAAATGCTGTATGTTCAGTCTTGGAGAGAATAGCACATTGTTCGTGTATTGAGGGCTTGATACCGAATCCAACGCCAAATATTGGTTGTATCCGTGCTCCGTCATCAGAATGTCGTCAAAACACTGATTGTACAGATGGATGGACATGTGAGGACAGCCGATGCAGACCTGCATGCACAGCCGATGGCTCACAATGCTTGCAAGGAGAAAGGTGCGACGAAGGTGTCTGTCGTTATGCGTGTACCTCAGATGAACATTGTTCCGATGATGAAATATGTGACGGACGCTCATGCACCATAGGGTGCAGGTCGAATTCACATTGTTCAAGTAAATTAGCTTGTATATCAGGACAGTGTCGGGACCCATGCACCGAACCGGCAAGTTGTGGAATTAATGCGATCTGTGCCACGAAAGATCATCAACCTGTTTGTACATGTCCACGAAAGTTAGCAGGTGACCCTAAGTTAGTGTGCTCGCGAGTCACCACTTCTTGTGGTTCTAACCAAAACTGTCCAGATGGTTTTAGTTGTTATGGAGATACATGCCATCCGTCCTGCAGGAGCGATAATGTCTGTTTGTCTAACGAAAAATGTATACGAGGTATCTGCAGAACAATTTGTAATAGTGACACTGCCTGTAGTGAGGGTTACATTTGCGAGAATCGGATTTGTAAGCAGGGCTGTCGCGATGATAATGCTTGCGAAGAAACACATGCATGTGTCAAAGGACAATGCAAAGATCCATGTAGTCAAGGTGCATGTGGAATTTGTTCGGAATGTAAAGTTCAGAATCATCGTCCTCAGTGCAGCTGTGCCAGCAACTATACAGGCAACCCCCTTGTAGAGTGCCGAAGGAAAAAGACTTTGTGTGATGGTTTTTGTCCGTGCGATCAGAGTGGTTATTGTATTTCGTTATGCGATGAGAACTCGGACTGCCCTTGCGGTGATAAATGTATCGAAGGAGGATGCCTGACTCGATGCTCTCCTAGAAATAAATGTCCAGAGAGACAAATTTGTCAGCAAGGCGTTTGTACTCCTGGTTGTAACAACGACAAAGATTGCAGCGATGATATGTTTTGTTCTTCAAATTTATGCGTGAATGCATGCCAAGAGGAGTCTTGCGGCATAAATGCTCTTTGCCTTACTACAAGACATCGTGCTGTCTGCAGCTGTCCAAGTGGATATTCCGGTGATCCTTTAAAAGAATGTAATCAATTCGAATGCCAGAATAACGAAGACTGTGGCACCGATGAGGAGTGTTATACCGACGGCAAATGTAAAAATGTGTGTTCGGGGGCTTGTGGGCTCAATGCTTTATGTCGTTCAGTCGACCGATCACCTCAGTGTTCATGTCCACCTAATTATCAAGGTAACCCACAAATTGAGTGTACTAAACCAACAACAGGCAGTTGTCTACGTAATCCGTGCGGCGTAAATGCAAGATGTCGCGACCTGGACGACGGTAGTTATGAATGTACATGTCCACCGAATTGTGCTGGAAATCCACAGAGACAGTGTTTTTGTGGCAAAATGGAGCCGTGTGCATACAAACCGTGCGGTACTAATGCGCAATGTCGAGTGAATCGTATCGGCGAAGCACAATGCTATTGTCCCCGTAACTATCCAAATGGAGATCCCAATATTGAATGTGCCCAAGAACGCAGTGTGATTGATTGTCGAACTACGGGCTGTGGTATTAATGGTGAATGTTTAAGGGAAGGTGCGGAATTTGTGTGTCGCTGCGTACCTGGAACCGAAGGTCAAGCCGATATCGAATGTCATACTAGTATCGAATGCACGAGTGACGTGGAATGCCCTGTCGATAAAGTGTGTCTGAGCTTACACTGTGTGGACCCGTGCACGCTGCGAGGCGCCTGTGGGGAAGATGCTCTTTGTGCACCACTGATGCACATGGCTCAATGCTCGTGTCCGCAATGTTATGTCGGCCAGCCAAGGATCTCTTGTAGACTCGATCCCAACTGCAAACCGACAACAGACTACAACTCAACATTCAGTTGTTCCGAAGATAAACCTTGTCCACCAAAACTAGCCTGTGATCTCAACAGTAATCAATGCCGAAATCCTTGTCTCGGTTATCAAAATTGTAAGCTAAATCAAAAATGTGAAGTAAGAGATCATAAGCCCGTATGTGTATGTCGTAATGGATTCGCCCTAAATGAAAAAGGTGAGCTAACATGTGCCCCAGAGCACGCAGAATGTACAAGAGATGACCAATGTCCATCAAATGCGGCCTGCCGTGATTACAAATGTGTGAATCCTTGTTTGACATCAAAAGAACCAATTTGTCCAAAAGGGAAACAGTGCGAAGTACTTGATCATCGTGCCATGTGTTTATGTGTACAAGACTGTAATCCATCCGTATCGATATGTCGGACAGACAAAGGGTGTCCAAACAATTTAGCTTGCAGAGATTATCAATGCAAGGATCCATGTAATGGTGCTTGCGGAGGTGCTCCGTGCACTGTAGAAGACCACCACCCTGTATGCAAGTTCTGTCCACATGGGTTCACACATGACGAAAAACATGGCTGTATCAAAGCTGTAGAATGCAGCGATCACGAGCAGTGTCCCAGCAATATGGCGTGCATGGCTGATCGTTGCGCCGACCCTTGTTCTCAAGGTGGACCTTGCACTCCCGGGCAGTCTTGCACTGTTTTAAATCATCAGCCAGTATGTTCTAAAGTTTGTCAGTGTCAAACCTCATCGGATTGTGTCAGCTATTCAAATTCTGTCTGCGACGGCTGTAATTGTGTTCTGGGCGATAAACCAAAGACGAACTGCGCTCATTGCAGACCAGGTGTTCCTTGCGATCCCTTCTCTGGAGCTTGTATGGAAAATGATCAACCTAAAAATGTCCCACTAACTGATGTCACAAGTACTACAACGAGCGAAGACACCGAAACCTCTACAAAAGATGATTCTTTAAATTATCTTACGTACTCGACTAATATTGACGACGAACAAATTGATACGACATCATCCGACTTAAAACTGTCTACGGACTATCACAATATTATTACTGAAAAACCATCTACATTACATATTGACGATATAGCAACCAAAAGTACACTCGCCGATGATTTATCTACAACGGATTCGTTTGATGAAACTTATCTCACAAAAAGTATAACACGGTCAGGATTAAACGCTACGGCTGATACTAACATTTCCTTATTCAATTACACATCCACAAAGTTCCATACTACTGATAGTTTGTTAACTGACATCTACGATTTTCAAAATGTTACCGAAGCTGATCAAAAGAGCTACGCAACAATACCAATAAATACCGAAAAAATATACGACAGTGAAAAACCTGCGTTTACTACACAAAAATATATAGACACTACAATTAATGAGAAAACAACAATATTCTCCTCTTTAGTTAAAGAGCCAATTAGTAAACCACTTTATTTAGATAAAAGTGATGAACCTGTACAGAGTAGCAGTACAATTCATGAAGAAAGTACCCTTAAACCCAACGTTAAACAGACAACACAAGTTGCTGAAAAACCAATATCAATTGAAAATAAGAACACTAAAACTCCTGAAAATCAAAGAAAACTGAATGGTAATTACACAAACATTGCCGATGGATACGGTCCTGTATCACACTCGGTTAATGAGAAATCAGCAACGAAAATGACAACTCCACTACCAAAAACTAAGCCAACAAATCCATCGGAAATACCATTAACGGCTTCTGAAATTACGATCAATTATTATACAACAGAAGGTAGCAGCGTTGAGAGTACTCTTAGTGAAGAAATTACGTTGACAAATCAAGACACTGCAGCTACAAGTATGAAAACATTAACTTCAGGTATAGAAATGGATACAGGTGTCAATGCGGAAGAGAATAATAAAAGTACTAATTTTTATACTAGCACAATACAATATAGTACTCAAAATGACATGTCTGATAGCCATGAAACTGTTTCAACTGACTTTAAAGTTGCTACCACAACATCACCTACAGTTCACATCATTGACAATCAATCAGATCAGATCAATTATTCAGAAAAAAATGCCTATCAGACAACAAAAAACGCACCTAGCTTAAACCCAACTACAACAAACTATTATCATACTGTCATTACAATGGAAGAAAAATGGGATAGTTCGGAAAATGATTTAATTGAAACTACTACAGAAGCTCAGCTTAAACAAACAAATTATGAATTTAAATTAACAGACACAAATGACTTAAACAAACAAAACGATACTACAACAATACCTACCGGAGGTATAGTAGAATTTTTAACACATAAAGCAACAAAATCAGATGATACTATTGTTACTATTTCAACTGAACCCTATACAATATTCAATTCTAATGAAGAAACAACACATAAACCTGTTCAACCACTAAACAAACAGAAACCCACTCAATTTATAAAATATGAGACGACTACTGAATTTACGCAATCATCAAATGATGATATCAAACAGCTTTCTGAATATCCTAAAGAACAGTTTAATATTTTAAATGAAAGAATAACTACTGGTAGTTCACTGGCTTCTCAAACAGACGCCGAAGGTGTTGAGATTACTTCTTCACTAACGACAATGTCGAAATCAACAATATCAACTCTTGATATACATGAAACAATACCCAATTTAGGTCTATCTACACAATCTGGAAGCTATGAATTCACTTCATCAATACCACAAGTTTTCTCGACAACGAACTCTGACGTCATTTTAGATCAGGATAATTTATTTTTACACCCCAATATAGCCACAATCAACTATAAGGCGACTGATAAAAATGATAATCAAGAGACGACCTCACAATACAATGACAACGAAAACGAATTTCCTCTAACCTCTACGGTTACATATGACAATACTGGAAAATCAGAACCGGCAGAATCACAACATATGCACAGTTCGGATATTAATAAAGTCACGAATGGCAATGAAAATAATTTACTTTCAACCACCTATAGAGATGTCACTACGTCACAGTATGACAGCGAAACTGAGGATTCCAATTCAGAGTCACAAAGTATGCAGAGTGCAACCACTGACCAACCCATTAACATACAAACAAATGAAAATGAAAATAAATTACCATCAACCACATCTATCACTACGTCACATTATGACAGTGAAACTGAGGATTCCAATTCAAAATCACAAAGTACGCAGAGTGCAACCACTGACCAACTCACTAGCGTACAAATGAATGACAACGACAATAAATTACCATCAACCGTCTCTGTCACTACGTCACGTTATGACGGCGAAACTGAGAATTCCGTTTCAGAGTCACAAAGTGGGCAAAGTACAAACGTTAACCGAGCCACCAGCATGTATGCCAATGACAATGAAAATAATTTACCATCAACCACCTCTATCACTAGGTCACATTATGACAGCGAAACTGAGGATTCCAACTCAGAGTTACAAATAACACAAAGTACAACTACTACCCAAGCCACTAGCATACAACCTAATGACAATGAAAATAAATTACCATCAACCACTTTTATCACTACATCACATGATGACAGTGAAACTGAGGATTCTGATTCAGAATCACAAACAACACACAGCAGAACCACTAACCAAGCCACTAGCATGTATGCCAATGACAATGAAAACAAGTTACCATCAACCGCCTCTGTCACTACGGTACATTATGGCACTGAAACGGAGGATTATAATTCAGAATCACAAACTACGCAGAGTACAATCACTAACCAAGCCACTGGCATACAAACTAATGATAATGTAAACAAATTACCATCAACCGCTTATGGTACTACGTCACATTATGACAGTGAAACTGAGGATTCTATTTCAGAATCACAAAGTACTCAAAGTACAATCACTAACCAAGCCTCTAGCATTTATGCTAATGACAATAAAAATAAATTACCATCAACCGCCTCTGTCACTAAATCACATTATGATAGTGAAACCGAGGATTCTGATTCAGAATCACAAACAACGCACAGGAGAACCACTAACCAAGCCACTAGAATGTATGCCAATGACAATGAAAACAAATTACCATCAACCGCCTCTCCTACTACGTCATATTATGACACTGAAACGCAGGATTATAATTCGGAATCACAAAGTACACACAACGTAACCACTGATCAAGCCACTAGCATATATGCTAATGAAAACGAAAACAAGTTACCATCAACTGCCTCTATCGCTACGTCACACTATGACAGTGAAACTGAGGATTTCAATTTAGAATCACAAACTCCGCAAAGTACAATCACTAAACAAGCCACTAACACATATGCTAATGACAATGAAAATAAATTACCATCAACCGCCTCTGTCACTACATCACATTATGACAGTGAAACCGAGGAGTCTGATTCAGAATCACAAACAACGCACAGCAGAACCACTAACCAAGCCACTAGCATGTATGCCAATGACAATGAAAACAAATTACCATCAACCGCCTCTCCTACTACGTCACATTATGACACTGAAACGCAGGATTATAATTCGGAATCACAAAGTACACACAGCGTAACCACTGATCAAGCCACTAGCATATATGCTAATGAAAACGAAAACAAATTACCATCAACTGCCTCTATCGCTACGTCCCATTATGAAAGTGAAACTGAGGATTCCAATTTAGAATCACAAACTCCGCAAAGTACAATCACTAACCAAGCCACTAACACATATGCTAATGACAATGAAAATAATTTAACATCAACCGCCTCTGTCAATACGTCACATTATGACAGTGAAACTGACGATTCCAATTCAGAATCAAAAAGTACGCAACGTACAATCACTAATCAAGTGACTAGTATATATGCCAATGACAATGAAAACAAATTACCATCAACCGCCTCTGTCACTACGGTACATTATGACACTGAAACGCAAGACTATAATTCAGAATCACAAACTACGCAGAGTACAATCACTAACCAAGCCACTAGCATACAAACTAATGACAATGAAAACAAATTACCATCAACCGCCTCTGTCACTACGGTACATTATGACACTGAAACGCAGGATTATAATTCGAAATCACAAACTACGCAGAGTACAATCACTAACCAAGCCACTAGCATATATGCTAATGACAATGAAAATAATTTACCATCAACCGCCTTTGTCACTGCGTCACATTATGATAGTGAAACTGAGGATTCCAATTCAGAATCACAAACTACGCAACGTACAATCTCTAACCAAGTCACTAACATACATGCTAATGACAATGAAAACATATTAGCATCAACCGCTTCTGGTACTACGTCACATTATAACAGTGAAACTGAGGATTCTATTTCAGAATCACAAACTACGCAGAGTACAATCGCTAACCAAGCCACAAGCATACAAACTAATGACAATGAAAACAAATTACCATCAACCGCCTCTGTCACTACGGTACATTATGACACTGAAACGCAGGATTATAATTCGAAATCACAAACTACGCAGAGTACAATCACTAACCAAGCCACTAGCATATATGCTAATGACAATGAAAATAATTTACCATCAACCGCCTTTGTCACTGCGTCACATTATGATAGTGAAACTGAGGATTCCAATTCAGAATCACAAACTACGCAACGTACAATCTCTAACCAAGTCACTAACATACATGCTAATGACAATGAAAACATATTAGCATCAACCGCTTCTGGTACTACGTCACATTATAACAGTGAAACTGAGGATTCTATTTCAGAATCAAAAAGTACTCAAAGTACAATCACTAACCAAGCCACTAGCACTTATGCTAATGACAATGAAAATAAATTACTATCAACTGCCTCTGTCACTGCGTCACATTATGACAGTGAAACTGACGATTCTAATTCAGAATCACAAAGTACTCAAAGTAGAAACATTAACCGAGCCACTACCATATATGCTAATGAAAATGAAAATAATTTACCATCAACCGCCTTTGTCACTGCGTCACATTATGACAGTGAAACTGAGGATTCCATTTCAGAATCACAAACTCCGCAAAGTACAATCACTAACCAAGCCACTAGTGTACAAACTAATGACAATGAAAACATATTACCATCAACCGCCTCTGTCACTACGGTACATTATGACACTGAAACGCAAGACTATAATTCAGAATCAAAAAGTACTCAAAGTACAATCACTAACCAAGCCACTAGCATACAAACTAATGACAATGAAAACAAATTACCATCAACCGCCTCTGTCACTACGGTACATTATGACACTGAAACGCAAGACTATAATTCAGAATCACAAAGTACTCAAAGTACAATCACTAACCAAGCCACTAGCATATATGCTAATGACAATGAAAATAATTTACCATCAACCGCCTTTGTCACTGCGTCACATTATGACAGTGAAACTGAGGATTCCAATTCAGAATCACAAACTCCGCAAAGTACAATCACTAACCAAGCCACTAGCGTACAAACTAATGACAATGAAAACATATTACCATCAACCGCCTCTGTCACTACGGTACATTATGACACTGAAACGCAAGACTATAATTCAGAATCACAAAGTACTCAAAGTACAATCACTAACCAAGCCACTAGCATACAAACTAATGACAATGAAAACAAATTACCATCAACCGCCTCTGTCACCACGGTACATTATGACAGTGAAACTGACGATTCTAATTCAGAATCACAAACTCCGCAAAGTACAATCACTAACCAAGCCACTAGCATATATGCTAATGACAATGAAAATAATTTACCATCAACCGCCTTTGTCACTGCGTCACATTATGATAGTGAAACTGAGGATTCCAATTCAGAATCACAAACTACGCAACGTACAATCTCTAACCAAGTCACTAACATACATGCTAATGACAATGAAAACATATTACCATCAGCCGCCTCTGTCACTACGGTACATTATGACACTGAATCGCAAAATTCTAATTCAGAATCACAAACTACGCAAGTTACAATCACTAAACAAGCCACTAGCATACAAACTAATGACAATGAAAACAAATTACCATCAACCGCCTCTATCACTGCGTCATATTATGACAATGAAACTGAGAATTCCAATTTAGAATCACAAACTCCGCAAAATACAATCACTAACCAAGCCACTAGCACATATGCTAATGACAATGAAAACAAATTACCATCAACCGCATCTGTCACTACGGTACCTTATAACAATGAATCTGATGAGTTTAAAACAGGATCACAAAGTATCCATAGTACAGCTGCGAATCAACATTCAAGCATACAAACTAATGAAACTAGAATACCATTGACCACCCCGATCGTTGAGTCGTACCACAACACCGAAATTAAAGGTTCCCAAAGAGAATCACATAATACACAAAGTACTGATACAACGTATACAGAATCATATGACAGTAAATATGAATTGCCATTGACTACTGCTTTCACCACGTTATATTATAACAGCGAATCTGACCTTTCCCGGACAGAGTCTTTAGCTACGCAAAGAATAGCTACTGGAAAAGACACAAATATAGAATCTAATCAGGATCATTATCAGACAACAGTTGATGCTACAGAATCATTATCAACAGAAAACGTTGTTGATTCATTCACATCTACTGCAGTAACAAATTTAGCCACTTTGATCGACGAAAACGTTAACAAGTTTTCGGAGAGTCAACATTCTACAACTATATTAACAGCACAAGATGAAACCACCTTTAAACCGTATTCTGAAGTCGATTTCACTACAGTGTTTCATAATATTAAGACAGTTGAAAATGACTTTAATGCAGATAAAGATGATGATTATTTAACACAGGAAATATCTACTACAACAGAACCGTCAACGATTGATTACCTGAACAACCCATGTGATTTGCCTGAGATGAAGTGTGCCCAGAATACTTCCTGTAAAGTTGTCAACCACGCTGCTGTTTGTGTTTGTGACTCAGCTGGAAACAACTGTGTAAGAGAATCATCTGGAACGCCAAAAGTACCAGAGCCGTGTCATTCCGATCGAGATTGTATAGAAATTGAAGCCTGTTTTATGGGACTATGTCAAGATCCATGTGAGTTTGATAATGTTTGTGGAATACAAGCAAACTGCCAGCGCGTAAAACACAGGCCTATGTGTTCCTGCCCTGCGGGCTACGATGGAGACCCTGCAATTAAATGTTCACCTAAAATATTTGGATGCACGCGAAACGACGACTGTCAATCTACAGAGGCTTGTATAAATAATGCATGTCAACACCCTTGTGCCATACACAACCCATGCGCACCTAATGCTGTATGTATAAACACAAACCATGGATCTGACTGTAGCTGTGTGGAAGGTTTTCAAGGCAACGGATACGTTGGTTGTGTACCAGTTGTGGAATCTACATCAGTATGTCAATATAACGAGGATTGTCCACCTGAATTACTATGCGATAGATTAAATAGAAAATGCATTAATCCTTGTGCAATTAACAAATGTGGAGATAATGCTGAATGTTTACCTTCAAATCATGGTATACAATGTAAATGTGCCCCTGGTTTTACTGGTAATGCCTTCCTGGAATGCTATCAAGTTCAAGGCTGTCGTTCAGATAACGAGTGTGCCAATTCTGAAGCGTGTATAAATGGTAAATGTGGTTCTCCATGCCGTTGTGGTATAAACGCTGTCTGTGATGTAATTAACCATCGAGCATCTTGTAAATGTCTACAAGGATATACCGGTAATCCACAAATTGGTTGTGAACCACCAACAAATCCATGTAGTCCGAACCCTTGTGGAATAAATGCATTATGTGAAATCGACAACGGAAATCCAATTTGTTACTGTCCGAAAGGCTTAACCGGAAATCCTTTCAAGAATTGCATCCCAGAAGGAAACGAATGTGAACCAAATCCATGTGGACCAAACTCAGGATGTCGACTAATAGATGATAAACCAGCCTGTTTCTGTCTACCAAATTACGAAGGGAGTCCGCCAAGAATGCCATGCAAATTACCAAACAATCCCTGTAATCCATCACCTTGCGGTCCTAACACTCAATGTACAGTACTGTCTAATGGATTTTCAAAGTGTTCTTGTTTACCTGGTTATGTCGAAAGCCCGAATACTGTTCGTGGATGTATTGAAGCACGAAACCCTTGCGAACCGAGTCCCTGCGGAGTCGGCGCTCGATGTGATCCAAACAAAACTCCATCTTGTTTCTGTCCAGAAAATACTGTTGGAAATCCATACAAATCATGCGACAGTAACCGTGGATATCTTCCACCAGTTGCGAATGTTCTCTGTCAGCCAGGACCATGTGGACCAAATGCGGATTGTTTTGTTAGTAGCAATAGAGAAGTGTGCTATTGCAAAACTGGTTTTAGTGGTGACCCATATCTGGGTTGCCAAAATCAAATAAGTCCTTGTGCTCCCAACGCTTGTGGACCACGAGCAATCTGTCAAGTAAAGTTTGATGGACAAGCCTTCTGTGTGTGTCCTGAAGGAAGTGTGGGTGATGCTTACAGCATTGAAGGCTGTATTTTACGGGAATGTGAGGTCGATGATGGCTGTCCCACAAATAAAGCATGTATTGGATATAGTTGCCAAGATCCCTGTCCTGGAGTATGTGGGTTGAATACCAAATGTCACGTAGAGGCTCATCGACCAGTATGTTTCTGTGAAGAAGGTTTCATCGGAAATCCATTAATATGTTGTCTTCCACCCGAAGATCAGAAATCAATATCACCATGTAACAAAATACAATGTGGTATTAACGCAATCTGTCAAGAAGTCGGAGATAGAGCCGTTTGCTCTTGTCCACTTGATTTCATTGGTGATCCAACAATAGAATGTAAGCCTGAATGTATGATGAACTCCGATTGTTCCTCGAACGAAGCTTGCATTAACAAAAAATGTATTGATCCTTGTGCATCTGCCAACATCTGTGGAATAAATGCTGTTTGCCTATGTTCAGATCATACTGTTTCTTGTCTGTGTCCCGATGGTTATATAGGAGATCCGTTAACTCAATGTATATACAAACCTATAATAATTGTACCAGATAATTCTACAGCGCAGCCTTGTTCACCAAATCCATGCGATCAAAATGCGCCTTGTGATACTTATGGTAACCAGTTTGCAATTTGCGACGCATGTGTTGGACTGAATTCTTTAAATAACCCATCGTGTAGACCGGAGTGCGTTTTGAATTCGGATTGTAGTTTTGATAAATCTTGCTTAAGAAACAAGTGCTTGAATCCTTGCCCTGGTTCTTGTGGTATAAATGCAGAGTGCACAGTTTATAATCACGATCCAGTTTGCCAGTGCGTTAATGGTTTCGAAGGGAATCCATACGAACATTGTAAACCAAGTGTCCGGCCTATCACACATGAAACTTGCAACAATGTGCAATGCGGTGCAAATGCAATTTGTAGAGACTTCAATGGTGCTTTAGCTTGCCATTGTCTGCCCGACTTTTATGGAAATCCTTATATTTCGTGCCGACCGCAATGTGTTGTTAACAGCGACTGTTCACCGGAATTGGCTTGTTTCCACAATAAATGCGAAGACCCTTGTACAAATGTGTGTGGCATAGGAGCTTTGTGTAAAACAGTCAATCATCATGCCGTGTGCTATTGTGAATCTGGACAAATTGGAGATCCTTATGTTAGATGCCAAAACGCACCAGCGTTGCCTCCTTCTTTATCTGTATGTGATCCATCTCCTTGTGGGCCTTACAGTCGTTGTCTTGTTTCATCTAACGGTTTTGCAATGTGTTCCTGTTTACCAGGACATAAAGGGATAGCCCCTATGTGTCAACCAGAATGTGTCAGTAATGCAGATTGTCAACAGATGGAAACATGTGTTAATCAACGATGCATAAACCCTTGCCTCGGTAGTTGTGGTGTTAACGCTGACTGTGTTGTTGTTAATCACAACCCAATATGTACCTGTAGTCGAGGAAAATCTGGTGACCCCTTTGTAGCCTGTACTGATATAACAGAAGTGGTGCCTTCCGAAAGAAATCCATGTGTACCTTCTCCATGTGGGCCGAACTCCGTTTGTGAAATTAAGTCGAATCACCCAGTATGTTCATGTCGACCTAACTACTCTGGTACTCCACCGTACTGTAGACCTGAGTGTGTCATAAGTCAAGAATGTCCTTCTAACAAAGCTTGCATCAATGAAAAATGTTTAGACCCATGTACAGGGGCTTGTGGTAATAATGCCAAATGTGTTGTAATTAATCACACGCCGTTATGTAGCTGTTTAGATGGATATAAAGGCGATGCATTCGTAGGATGCAATGCAATTTCAAACGACGATACCGAGACTCTTTGTAATCCTTCACCATGCGGAGAGAACACAATCTGCAATGTAATAAACAATATTGCGCGCTGCTCATGTATTCCGCCCAACATAGGAAACCCGTATGCGGGGGGATGTCGACCAGAGTGTTCATTAAACTCAGATTGTCCGAATCATTTGGCTTGTCTGTCAAACCACTGCAGGGATCCATGTAAGGATCTATGTGGTGTTAATGCGGAATGTATAGTGACTAATCATGTACCTGTATGTACATGCTTTAGAGGTCACGAAGGAGACCCTTTTATTGCATGCAATCGTCAAGAACAAAAACCACGAAATCCAGAGAGTCCTTGTGAGCCTTCTCCGTGCGGAGCGAACAGTGACTGCCATATAGTGAGCGGTCGAGCGGCATGTTCTTGTCGTCCGGGCTACTTGGGCGCGCCACCAGCGTGTCGTCCTGAGTGTGCGGTCAACTCAGATTGTCCTGCTACTAGAGCGTGTATTAATCACAAATGCAAAGATCCATGCATAAATAGTTGCGGTATTGACGCTCGTTGCCATGTTGTTGGACACAATCCTATTTGTACGTGTCCCGAAAATCTCTCGGAAGGTGATCCATTCATTAAGTGCACCAGAAAAACCATTATGCCGACACATACTGATCCGTGCTTAATGTCACCGTGTGGACCTTACGCAACATGTAGAAATGAAGATGGACGTGCCATATGCGCATGTGAACCTGGAACTCTTGGAGCACCACCATCTTGCCGGCCACAATGTGTTATTAACCAAGATTGTCCTTTAGCGCTGGCTTGCCTCGGCGGTAATTGTGTAAATCCGTGCATTGGTTCATGCGGATTTAATGCCCGATGTTCTGTGCAAAATCATCGTCCAGTGTGTTCATGCGACGACGGATTCTCTGGTGACCCATTCGCTGGATGCAACCCAATTGAAATTTCTAAAGAAGCACCTCGTCAACCTTGTCATCCTTCACCTTGCGGTGCTAATGCGATATGTCGAGAAAAGGATGGTGCTGGTTCTTGTACATGCTTAGATGATTTTTACGGTGACCCATATAGTGGTTGTCGCCCTGAGTGCCTTATGAATACAGACTGTGCTAGGGAAAAATCTTGTTTTAATAACAGATGTATAGACCCTTGTTCTGGGACTTGTGGACAAAACACTCAATGTAGAGTTGTAAATCATGCTCCTTCATGTTACTGCTTATCTGGATTTACGGGAAATCCTCTTCACGCATGTGTTCCTGTTAAACCTTTTCCGGATAATCTGGATCCTTGTCACCCTTCGCCCTGTGGACCATATAGTAAATGCCGAATATCAAACGGTCATGCTGTATGCACATGTCTTGACATGTGTATCGGTTCTCCGCCTAATTGTCATCCGGAATGTATTGTTAGTTCTGATTGCCGCTCAGATAAAGCTTGTATAAATCAGAAATGTCAGGACCCTTGTTCTGGCATTTGTGGCATTAACGCGAAATGCCAAGTGGTGAATCACAATCCAATTTGCAGTTGCTTAAGTGATTATACTGGCGATCCGTTTGTCCGGTGTTATATTGATGACCGCCAAATGACGCCGATAAATAATTGTGTTCCAAGCCCTTGTGGTCCAAATTCACAATGTAAGGAAGTAGACGGAGTAGCAGTTTGCTCATGCATTGAAAATTATGTGGGTCGTCCCCCTAATTGTAGACCAGAATGCGTCATGAATGTTGAGTGCTCGGGGAATTTAGCATGTATAGCGGAAAGATGCAGCGATCCTTGTCCTGGTTCTTGTGGGTTCCATGCGATTTGTACTGTTGTGAATCATGTGCCGACGTGTACTTGTGATCATGGGTACACAGGTGACCCCTTCTCTGGATGTTCATCTATTCCTTCAATAGAACCTCAACCACAAAGTCTTTGTTCTCGTTCGCCGTGTGGAGCTAACGCAATATGTAAGGAAAGGAACGGAGTTGGATCATGTTCATGTTTACCTGATTATTACGGAGACCCATATATTGAATGTCGCCCTGAGTGTGTTTTGAACTCAGACTGTACTAAAGACAAGGCTTGTATTAACAACAAGTGTAAAGATCCATGCCCTGGTGTTTGTGGTATGAACGCCGAATGTCGCGTAAATAATCACGCGCCTTCATGTGCATGTCTACCTGGGTACGAAGGAAACCCATTTTCTTCATGTTACATAAGTACCTTCGAAGATCCAGTAAATCCTTGTGTACCGTCACCTTGTGGTCCTTACAGTTTATGTCGTGAAAATAACGGACACGCAATATGCTCTTGTCAGGAACATTACTTTGGTTCACCGCCTTTTTGCCGCCCCGAATGTATGGTCAGCAGCGATTGTATGCCAAATAAAGCTTGCATTAATAAAAAATGCGTGGATCCATGCTCAGGTGCATGTGGCAACAACGCTAAATGTACAGTCGTAAATCATAATCCGTTATGTAGCTGCCCAAAAGATTATACAGGCGATCCGTTTGTACACTGTTCTTATGAAACAAGACCAGAACCAAAACCGTCAGGAAATCCGTGTATTCCTTCCCCTTGCGGACCTCACTCGCAATGTCGTGTAATAGGAGAGACGGCCGCTTGTTCTTGCCAACTCGGATTTATTGGTCGTGCTCCTAACTGTCGGCCTGAATGTATATTCGATGAAGAATGTCCTAGTAATCTAGCGTGTATCCGAGAAAAGTGTGCTAACCCTTGCGAAGGTTCATGTGGGTCAAACACTAATTGTGTTGTCATCAACCATAAAGCAGTCTGTCATTGTCGTGAGAGCTATACTGGCGATCCTTTCAGTGGATGTTACTTTATAGTAACCGTACCGAGTGAAGAAGAAACAAATCCATGTAATCCGTCACCATGTGGTCCAAACGCTCTATGTAAAGAACGAAATTCTGCTGGATCATGTACTTGTATACCTGATTACTTTGGAGATCCGTACTTAGGATGTAGACCCGAATGTGTCACAAATAACGACTGCACCTTCGACAAAGCCTGTTCGAATAACAAGTGCGTAGACCCGTGTCAAGGAGCTTGTGGCATAAACTCGCAATGTACAGTAGCACACCATAATCCAGTTTGTCTTTGCGTAGATGGTTATGAAGGCAATCCTGCGGTATCTTGTCATCCACAGCGTAAACCTCCACTTGCGGATACAAATCCTTGCATACCTTCGCCTTGTGGACCTTATAGTCATTGTAAAGTGGTCGATGACCACGGAGTGTGTTCATGCCAAGAGGGATATATTGGATCGCCTCCTGCATGTAGACCGGAGTGTGTAACAAGTACAGATTGTCCGCAAAATCAGGCATGCATTCGACAAAAGTGTAAGGATCCATGTCCTGGAACTTGCGGCACAAATGCACGATGCTTAGTGATAAACCATAATCCAATTTGTACGTGCAAACCTGGTTTTACTGGAGATCCGTTCAATTTCTGTCAATTAGAACAAAAACCTATCATAGAGGGGCCTAAAGGAAACCCATGCATTCCTTCGCCATGCGGTCCATATTCTCAATGTAAAATAATCGCAGATGCGCCTGCATGTTCATGCTTGCCCAATTATCTTGGTGTTGCACCAAACTGTAGACCTGAATGCTCGATAAATGCTGAATGTCCGGGTAGTCTTGCATGTCAAAATGAAAAATGTGTGGACCCATGTCCTGGGTCTTGTGGTTTTAACGCTGAATGCTCCGTAGCAAATCACGTAGCATTATGTAACTGTATACCCGGATACTCTGGTGATCCATTCAGTGGATGTTCATTATTTCAACATATACCAGAACCCCCACCCAATCCATGCAGTCCTTCTCCATGTGGAGCTAATGCTATTTGCAAGGAAAGGAATGGAGTAGGCTCTTGTACTTGTTTACCAGAATATTTCGGAGATCCATACACTGGTTGTCGTCCAGAATGTGTTTCTAATTCTGACTGCGACCGTAATAAGGCTTGTTCAAATAACAGATGTAAAGATCCTTGCCCTGGTACTTGTGGTATTAACGCTGAATGTAGAACAGTAAACCATTCTCCAACCTGCTCTTGCTTAACGGGATACACCGGAGATCCTTTAGTGAAGTGTGACTTTGAAACTATAACGGAAAAGAATGAACCAGTTCAGAATCCATGCAAACCATCGCCTTGCGGCCCCAACAGTCTTTGCAAAGTTGTGAACGGTCATAGCGTTTGCACTTGTGATACTGGTTATATTGGCACACCACCCTCTTGTCGTCCAGAATGTCTTGTGAGTGTGGAATGTTCCCAAGATAAAGCATGTATAGGGAAAAAATGTCTGGATCCGTGTCCCAATACCTGTGGCCTCAATGCTCGTTGTCAAGTAATCAATCACAATCCTGTATGCAGCTGTACGCCTGGATTTACGGGAGATCCGTTCACTAAGTGTAATCCTGAAGAACGAATGGTACAATCAAATCCATGTCAACCATCACCATGCGGACCGAACGCAGAATGTCGAGTAATCGGTGATCAAGCAGCTTGTTCTTGTTTACCGAATTATATTGGAAGAGTACCAAACTGTAGACCTGAATGTACGATAGATGCTGAATGTCCTAGCAACGCGGCTTGTATCAATGAGCGTTGTAAAGATCCTTGCGAGCGTGCATGTGGTGTAAATGCCATGTGCTTAACTGTAAATCACAAACCGATTTGTTCTTGCCAGCAAGGTTTTACAGGTGACGCATCTATAAGTTGTGATCAACTTATCATATCATCAACCGAAATGACGCCGACATCAAGTCCATGTACTCCATCACCCTGCGGGCCTAATGCTGAATGCAGAGAACATAACGGAGCCGGAGCATGTGTTTGCTCCGAGGGCTATGAAGGAGATCCGTATAGTCCACAAGGATGTCGAAGGGAATGCGAGAGTAATGATGAATGTGCACCTAATCTAGCTTGCACCCGATATAAGTGCATTGACCCATGTCCAAGAACATGTGGACAGTTGGCGCAATGTATAGTAGAAAATCATGCACCAGTTTGCAGTTGTCCTCGTGGTTATACTGGAGATCCATTCTTCCAGTGCAAACAAATATTAATGGACCCATCCCCTCCGAAGAACCCTTGTGAACCAACACCTTGCGGCCCCAACAGTCAATGTAGACAAGTAAACATGCAAGCTGTATGTTCTTGTCTTCCAAATTATATTGGATCTCCACCATCATGCAGACCACAATGTGTTGTAAACAGCGAATGTGACACATCGAAAGCTTGCATTAATCAAAAGTGTGACGATCCCTGTCCAAACACGTGCGGACTTAGAGCTCATTGTTTGGTTAAAAACCACAATCCGATATGTACTTGTCCAGTGGGAATGACAGGGGATCCATTTACACAATGTTATCAGATTCCGCCTACAACTGAACGACCTCCAACATGTACTCCATCTCCATGCGGACCACATTCTCGATGTCAGTTGCTAGCCAGTGGACCAGCCTGCTCTTGTTTACCAGGATATGTGGGTTCACCACCTTCGTGTCGTCCCGAATGTACAATTAATTCTGAATGTCCTGCTTCATTAGCTTGTGTGCGTCAGAAATGTGAAGATCCATGCCCTGGCTCATGTGGAGTAGATGCAAATTGCCATGTTCTAAATCACGTTGCCATATGTGTTTGCAATGAAGGTTTCACCGGTGATCCATTTTCAAGATGTCTACCAATAAGTGGAACACCTACAACGCCAGAACCATCAGATCCATGTAATCCCTCACCATGCGGGCCAAATGCTCGTTGTGATAACGGATTCTGTACATGTTTACCAGACTATAGTGGAAACCCTTATGAATCATGCCGACCTGAATGTACCGGCAGTCAAGAATGTCCTAGGGATAAGGCCTGCTTTAGAAACAAATGTCGGGACCCCTGCCCTGGAGTGTGCGGGCTTAATGCTAAATGTGATGTTATAAACCACATTCCGACTTGTTCATGTATATCAGACTTTACTGGAAATCCATTTACACACTGTAACAGAATAGAAGGAAAACAAACTGATAAACCAAGAGACCCCTGCCATCCTTCGCCTTGTGGACCGAACAGTGTCTGTAAAACTGTTGATAACGCTGCAGTGTGCGCCTGTTTAGAATCTTTCCAAGGAACACCGCCAGCTTGTAGACCTGAATGTATTGTTAGTTCAGAATGTCCATCAACCAAAGCTTGTGTTAATCAAAAATGTATAAATCCCTGTATAAACGCTTGCGGCGTGTCAGCACGCTGTGAAGTTATAAATCATAGCCCTATATGCAGTTGCAGTCCTGAACAAACAGGAGATCCTTTCAAGAGCTGTTACGATGTTGTAAATACACCACCTGAACCAATCGATGCATGTAATCCTTCTCCTTGCGGACCAAATGCTCAGTGCATCCAACGTAACGAAAAAGCCAATTGTAGATGTTTGGAGAATTACATTGGCCAGCCTCCTAATTGTAGACCCGAATGTGTTATCAATCCTGACTGTCCATCTAATCAAGCATGCGTAAGAAATAAATGCATTGACCCGTGTCCAGGTTCTTGTGGTATTAATGCTGATTGTGTGATAGTAAGTCACACAGTTTCATGTATCTGTAGAGAAAAATATACTGGAAATCCCTTTATGCAATGTGTTCCACAAGAAGAAATTGTCACGAAGCCTTGCGATCCCTCACCTTGTGGTGCTAATGCTCTGTGTACCCAAAGAGAAGGAGCTGGTTCCTGTTCATGTTTGGAAGGCTATCAAGGAAATCCTTACGAAGGCTGCCGTCCCGAGTGTGTGCTCAGCTCAGATTGTCCAGCTGATAAATCATGTATTAGAAATAAGTGTGCAGACCCATGCCCAGGAATTTGTGGTACTAATGCAGAATGTAACGTCATCAATCATGTACCAAGCTGCGCATGTCTTAAAGGATACTCTGGAAATCCATTTACCCAATGCTCTAAAGATGAACCTATAGAATTTAGTCGACCATGTCAACCATCACCATGTGGGCCTAATAGTGTCTGCAGAGAAAATGGAGGATTAGCATCTTGTGAATGTCTACCAGAATATATTGGTGCACCTCCAGACTGTCGACCAGAATGTACCGTTAGTAATGAATGTCCATCAGATCGCGCATGTCATAAACTGAAATGTGCGGATCCTTGCAGAGGTACATGCGGTATAGGTGCACATTGTCAAGTTGTTAATCATAGTCCATTATGCAGCTGCCCAGCTGGTACTTCTGGTGATCCCTTCAAGAGATGCTTTGAAACTGTACTTTATGAACCAGGACAGCCGGTGCAACCATGTCAACCAAATCCTTGTGGCCCATACAGTGAATGTCGTGCTCTTAATGAAAATCCATCATGCTCTTGTATGCAAGGATACGCAGGTGTACCTCCAAACTGTCACCCGGAATGTCTTGTGAATACGGACTGTCCTTCTCATCAAGCGTGCATCGCTGAAAAGTGCACAAATCCTTGTGAAGGATCATGTGGATTTAAAGCAGAATGCCGAGTGCAAGACCATATTCCGATTTGTAGTTGCCCAGTTGGATATTCCGGTGATCCATTCATCCAATGTTCTGAAGTTATAATTACACCAACACCTTCCCCAGAGCCTTGCAACCCATCACCTTGCGGAAGTAATGCTTTATGTAATGCTGGTCTCTGTACATGTGCACATGGTTATTTCGGAGATCCATACGTCGGTTGTAGGCTTGAATGCTCGACCAATGGTGAATGTTCACCTACGCGTACTTGTCAAGGAGGAAAATGTGTTGATCCATGCCCGGGAGCTTGCGGTACTAATGCTATCTGCTCAATCAACAATCATATCCCGTCTTGTACTTGCCCACCGAATACTTTCGGAGACCCGTTCACTTTCTGTACTGAAGTCGTTCACCAAGATACACCTACTTCGGCGTGTTCTCCTTCGCCATGTGGTCCATACAGTGAATGTTCCGTAAGCGCAAACGGTGCCGCTGCCTGCTCCTGTAAATCAGGTCATGTTGGGTCGCCTCCATCTTGTAGACCTGAATGCCTCGTTAGTGCGGAATGCAAACTTCAACAAGCTTGTATAGATCGCCGTTGCCGTGACCCTTGTGAAGGTGCTTGTGGCCGTGGTGCGCGCTGCCAAGTAATCGCACATTCCCCGATATGTACCTGTAATGATGGTTTTACCGGAGACCCATTCTCATATTGTTACCCGGCACCAGCCACCCCACCCACACCTATTGACCCTTGCCAACCATCACCATGTGGACCAAATTCGATGTGCGTTAATTCTGGTGAAACACCTGCGTGCAGTTGTCATCCAGGATTTATAGGAACGCCTCCAAACTGTCGACCTGAGTGTACAATTAGTGCAGAATGCCCTGCCACTCTGGCGTGTGTTGGACAAAAATGTAAAAACCCGTGTGAACAAGCTTGCGGTCCACGTGCTCTCTGTTCGGTGGTTGATCATCGTGCAACCTGCGCTTGTGAACCCGGATTAGAAGGTGACCCATTCCAGGGTTGTTCTCCAGCACGAGCTCCGCCAAAGATTGAATATTTAAATCCTTGTGAACCTTCGCCTTGTGGCGCGAATGCAGTGTGTAAAATCCAAGGAAATGCCGGTTCGTGCACTTGTTTGCCTGAATATTTTGGTGATCCATATCAAGGATGTAGACCAGAATGCTTAACAGATTCTGATTGTCCACTGGTATCATCTTGCAGCAGAAACAAATGCATAAATCCTTGTCTCGGTGCATGTGGTGTTAATACTGAATGTTTCGTTAACAACCACAAGCCGATGTGCAACTGTAAGAGTGGTTTCACAGGAAATCCAATGACTATATGTTCCGCACTAAGAGAAAATGATGTTTACATTGAAAATGTTTGTAATCCTTCACCGTGCGGTAACAATGCAATTTGTAAAAATATAAACGAACAGCCTGTGTGTTCCTGTTTGGCGAATTTCATTGGATCTCCGCCAAATTGTCGACCAGAATGTATTGTTAATTCGGAATGCAAACCTAGTAAAGCTTGTATAAATCAGAGGTGCATCAATCCGTGTCCAAAACCGTGCGGAAAGAACAGTGAATGTAAGGTAATCAACCACAGTCCCATATGCAGCTGCCGCCAAGGCTACAGTGGGAACCCATTCACAATGTGCAACCTAGTTCTTCAGACCTTACCAAGTGTAGTTGAAACGTCCAATCCATGCTCACCGTCGCCATGCGGCCCATACTCTGAATGCCGTAACAACAATGGATTAGCAAGCTGTTCTTGCTTATCAACCTACATTGGGTCTCCACCGTTTTGCAAACCAGAATGTGTTGTTAACTCGGATTGTCCGAGTAACTTGGGATGCATTTCAGAAAAATGTAGAGATCCTTGTGAGGGCTCATGCGGCTTATTTGCGAAATGCTTCGTAAATAACCACGTACCGGTTTGTTTATGCCCGGAAGGTTTTACGGGAGATCCATTCAGTCAATGTGTGGAAAAGCCTGTGAAAGAAATAACTCCAACTCTTCAATTAGACCCATGTCAACCAAGCCCTTGTGGACCTAATACTGAGTGTAGGAATGGCGTTTGTTCGTGTATAAATGGGTATCACGGAGATCCTAATTTAGGTTGCCGACCTGAATGCGTCTATAATGCCGACTGCCCCTCCGATAAAGGTTGCCAGAAAAATAAATGTATCAATCCATGTATTGGCACCTGCGGAGTGAATGCTATTTGTGATGTGATGAACCATATTCCAATGTGCTCTTGCCCCAAAGGAATGGTCGGAAATGCATTTGTGGAGTGTAGAGCTGTTGCAGTGACAGCTACAAGCCCGTGTAGTCCATCTCCTTGTGGACCTAATAGTCAATGTCAGCAAAGTAATGGACAAGCAGTATGTTCATGTGTACCTGGATATAAAGGCAGTCCGCCTACTTGTAGACCTGAATGCGTAGTCAGCCTGGAATGTCCTCTTAATCAAGCTTGCAACAACCAAAAATGTCTTAATCCTTGCATTGGAGCTTGTGGCGCTGGAGCTGTTTGTGATGTAATTAATCACAACCCAATATGCACCTGTCCTCCTTCGTTTACTGGAGACCCATTTGTTAGATGTTCAGTCATAGTTGCGGTAGAACCAACGGTAAACCCGTGTGAGCCGTCACCTTGTGGTCCTAACTCTATTTGTAAAATAAGTGGAGAGAATCCAATTTGTGCTTGTTTACAAGATTACAAAGGGACTCCTCCAAATTGTCGTCCAGAGTGTATCAGTAACAGTGAATGCGAGTATCATCTAGCCTGTCAAAATAAAAAATGCATTGATCCGTGTCTTGGTACCTGCGGGTCTAACGCAGAATGTAGAGTAGTTAGTCATGCCCCAAATTGTATCTGTCAAGTAGGATATACTGGAGACCCTTTTGCTTACTGTAGTATGTTAGCAGTAATGGATTACACAGAAATTCTGACACCGTGCAGTCCTAGTCCCTGTGGCGCTAACGCTATTTGTAGAGAACAAAAAGGAGTTGGATCATGTCAATGTTTGGACGGTTATTCGGGCAATCCCTATGAAGGTTGTCGACCAGAATGTGTCGTCAATTCCGATTGTCCTCTTAATAAAGCTTGTTCGAGGATGAAGTGCGTCGATCCTTGTCCAGGAGTATGTGGTTCAAATGCTTTATGCCTAGTTAACAATCATATGCCAACATGCATTTGTCAGCCGGGATATACCGGAAATCCGTTCGGATATTGTACTATTATGCAAGAACCTCAAGTATTGGAAACAAATCCTTGTAACCCTACGCCCTGTGGTGCCAACAGTCAGTGAAAGAAATAAATGGACAAGCTGTATGTTCCTGTTTACCTTCATTTAGTGGTTCCCCACCGAACTGCCGACCAGAATGTGTTGTAAGCTCGGAATGCCCACCGGATTTGTCTTGCAGTTCACAAAAATGCATTAATCCCTGCGAAGGCGCATGTGGAGAAAACGCTCGCTGTAATGTTATTAATCACAGTCCTATTTGTGTATGCAAGCAAGGATTAACTGGAAATCCTTTCACAAGATGCTATCCAATAACAGGTTCTAAACCGCCTCAAAATATACCAATACAAGATCCGTGCATCTCTTCGCCATGTGGACCATACGCAGAATGTAGAAATATAGAACATGCTCCATCTTGCGCTTGTAAATTGAATTATGTTGGAACTCCACCTAACTGTAGACCGGAGTGCACTATAAACTCTGAATGCTCTAGTAACCAAGCGTGTATTAATGAAAAGTGCCGCGACCCGTGTCTTGGTGCCTGTGGAATTAATGCTCAATGCTCTGTATTTAATCATGTCGCACAGTGTAGTTGCATTGAACAACACACTGGAGATCCTTTTACTCGTTGCTCACCTGCAATAGAACAAGACGAATTCTCGGAACCTGACCCATGCAACCCGTCGCCCTGTGGAGGAAACGCAGAATGCAATAATGGAATTTGTACATGTTTGCCTGATTACCAAGGTGACCCGTATTTTGGATGCAGGCCTGAATGTTTGCTCAACAACGACTGTCCTCAAGAAAAGGCTTGTGTGAAGAAAAAATGTGTGGACCCATGCTTTAATACGTGTGGCACAGACGCAATTTGCAACGTGTATAATCACTTGCCAATGTGCTCGTGTCCAAATGGATTTACAGGAAATGCTTTTCTACAATGTCGACCTATAAAGAATATTGAAGAAATAAACCCATGTAGTCCTTCGCCTTGTGGTCCAAATAGTCAGTGCCGAGAAGTTAACGGACAAGCGATTTGCTCCTGTTTCCCCGGATTTTTCGGAGCTCCTCCAACTTGCAGACCAGAATGCATATCGAGTGCTGAATGTGCATTGAACAAAGCTTGTTCTAATCAACGTTGTATTGATCCTTGCAAAGGAAATTGTGGTACAGCGGCCATATGTCAAGTTATTAACCACAATCCTATATGCTCTTGTCCACAACGATTCACCGGCGATCCATTTTCGAGATGTTCTGTTCAAGAAGAAGAAATACCTCAATATGTAAATCCTTGTGAGCCATCACCTTGTGGACCGAACTCAATTTGCAAAGAAGTTGGTAACTCGCCATCTTGCGCATGCTTGGAAACATACTTAGGCCATCCACCAAATTGTCGACCAGAATGTATCGCAAATTCAGAATGTCCCAATAGTATGGCATGTATGAATCAAAAATGCAAGGATCCATGCCCCGGTTCTTGCGGATCTAATGCAGAATGTAAGGTTGTGAGTCACGCGCCGCAGTGTATTTGTTCCCCTGGTTATACAGGAGACCCATTCATAGCTTGTTTAGTGCAAGACATACCTTTGACGCCATGTCAACCTTCACCTTGTGGTCCGAATGCAATATGTAAGCAGCAAGGAAATGCCGGCGCTTGTGTATGTTTACCAGAATATTTAGGAAATCCATACGAGGGCTGTCGTCCAGAATGTATAGTTAATTCTGACTGTGCAACCAATCTAGCATGTATTCAAAACAAATGTAAAAATCCATGTAACAGCGCTTGTGGCCTCAACGCGATATGTAATGTCATAAATCATTCACCAAAATGTGAGTGTTTGCCGGGATTAACTGGAAATCCATACCAAAACTGCTATGAGCAAAGCGCAGATACTCCTTCGGTTACGAAAAATCCTTGTACGCCTTCGCGGTGTGGTCCCAACAGTATATGCAAGATTAATAATGAACAGGCTGTGTGCACTTGTCAACAAGATTTCATTGGAACACCACCATCATGCAAACCCGAATGCGTGGTCAGCTCTGAATGCTCGCAACAACAAGCTTGTATTAAAAAAAAATGCAGAAATCCTTGTGAAGGTGTTTGCGGACAGAACTCTGAGTGCAAAGTTATCAATCATAGTCCCATTTGCACATGTCGTGTACATTACACCGGCGATCCATTTAATGGTTGTTCTAAAATTGTTGCTGCTGAGATTATTCCTCTGCCAACAAATCCATGTCTACCATCTCCGTGTGGTCCATTTGCACAATGTCGTGATATAGGTGGATCGCCTTCATGTTCTTGTTTACCTCTTTATATTGGCCAACCTCCAAATTGTAGACCAGAATGTACTATCAACACCGATTGTCCTAGCGATAAATCGTGCATCAATGAAAGATGCATAGATCCGTGCCCTGGGTCGTGTGGAATCTACGCAGAATGCAGAGTTCAAAATCACGTTTCAATCTGCACATGTCTTGAGGGTTACACAGGAGATCCCTTTAATGCATGTATACTGAAACCACAAAAAGACCCTGTTCCTTCTGATCTTTGTAATCCATCACCTTGTGGACCAAATGCCATTTGCAATGACGGGATATGTTCTTGTCTACCTGAATTCCAAGGTGACCCGTACTTTGAATGTCGTCCAGAGTGCACGATAAGTTCAGAATGTCCGATGAATAAAGCTTGTGTTAAAAATCATTGCGTGGATCCATGTCCGAATACATGTGGTACTAATGCCATTTGTCAAGCAATAAATCACATGGCAGTGTGTACATGTCCGGCAGGGATGTCTGGCAACGCATTTATACAATGCAACCCTATAAAAGAATTTTCCATTGTAAACCCATGTCAACCAAGCCCGTGTGGAGCAAATAGTCAATGCCGAGAATTAAATGGTCAAGCAATATGTACATGTTTACCGGGATATCGCGGAACTGCGCCTTATTGTCGCCCAGAATGTGTGGCAAGCTCTGAATGCCCATCGGACAAAGCCTGTAGCAATCAGAAATGTATTAACCCATGCCAGGGAACTTGTGGTGTTGCAGCCCAATGTCAAGTAATACATCATAACCCCATTTGTACGTGTTCTACAGGTTTTACGGGAGATCCATTTACACGATGTACTGCTACGCCTCTCGAGTTACCTACGGCCCCTATAAATCCTTGTCAACCATCACCGTGTGGTCCTAATTCAATTTGTCAAGAAAACGGCAGCCAAATACCTTCTTGTCAGTGTATGCCCGAATACATTGGTGCACCGCCGAATTGTCGTCCTGAATGTCTCGCAAACAGTGAATGTGCTCCTCATTTAGCCTGTATCAATAAAAAATGCCAAAATCCATGTGAAAAAGCATGTGGTACAAACGCTGAGTGTCGAGTTGTGAGTCATACAGCGGTCTGCATTTGTCCAGAAGGATATAGCGGTGATGCAGCAATTCAGTGTTCACAAAATGCTGTTGTTCCATTCGAAACACTTTCAGCTTGTGAACCTTCGCCCTGTGGAGCAAACGCAGAGTGTATAGAACGGGCTAGTGCAGGTGCTTGCATTTGCCGAAAAGGATATATCGGAAATCCATATGATGGCTGTCATCCAGAATGTGTTGTAAGTTCGGACTGTCCGAGTAACAAGGCTTGCACAAGAAATAAGTGTATAGATCCATGTCCTGGTACATGTGCATCGAACGCTAATTGCCAAGTTGTTAACCATTCGCCTCTTTGTACATGTAAAACGGGATACATTGGAGATCCATTCACCGCATGCAAACTCGAACCTCAACTCGATTTACCAGTTAATCCGTGTCAGCCATCTCCTTGTGGACCAAACAGTCAATGCAAGGTTTCGAATGGCCTGAGCATTTGCTCATGTTTACCAGAGTACAGCGGATCGCCTCCAAATTGTAGACCAGAATGTGTTGTGAGCGCAGAATGTCCTTCAGAAAAAACATGCAGAAACAAAAAATGTGTGTCACCATGTCCCGACCCTTGCGGTCAAAACACGAACTGCAAAGTTATTAATCACAGTCCAATATGCTCTTGCCAAAGCGGATACACTGGAGACCCATTCTCACGTTGTTACCGTGTAACTATCACGGAACTTCCACCTCAACAACAAAGAGACCCTTGTGTGCCTTCCCCTTGTGGGCCGAACTCCTATTGTCAAGACCTAAGAGGTATTCCCTCGTGTTCTTGTTTACCCAACTTCGAAGGGAATCCGCCTAACTGCAGACCTGAGTGTACTATCAATGAAGACTGTGCCAGTAATTTAGCGTGCATAAATCAAAAATGTAAAGATCCATGCCCTGGTTCATGTGGTATTAATGCTAACTGTCAGACTCAAAATCATATAGCGATCTGTTCATGTATCGAAAGCTTTACCGGAGATGCTTTCACGCAATGCAAACCAATACCATTTATAGAAGAAAGTGATCCCTGTAATCCATCTCCATGTGGTATAAATGCTGAGTGCTCAAACGGAAAATGTACCTGCTTTGAGGAGTACCAAGGTGACCCATACACTGGTTGCCGACCGGAGTGCTTGGAAAGTTCAGAATGTGAACGGGATAAAGCTTGCATTAAAAATAAATGTAAAGATCCGTGTCCAGGAACCTGCGCGTCGAATGCTGAATGTAATGTCATCAATCACATACCTATGTGTAGCTGTCCTGAACGAATGACTGGCAATGCATTTGTAGAGTGCCGTCCAATAATAGAAGCAGTTATAACGAATCCTTGTGAACCATCACCTTGCGGGCCTAATAGTCGCTGCAGAGATGTGAATAATCAAGCTGTTTGTTCATGTGCACCAAATAACATAGGTTCTCCGCCGTCATGTCGTCCTGAATGTACAATTAGTTCTGAATGTCCTCTCAATCAGGCCTGCAGTAATCAACGTTGTGTGGATCCTTGCATCGGTTCATGTGGTGTTAATGCAGAATGCAAAGTTGTAAATCATAATCCAATTTGTTCGTGTCCAACATTTTACACAGGAGACCCATTCTCAAGATGTATGAGGCAACCTGAACGTCTTCCTGAGCCAACGAATCCGTGCGCACCATCACCATGTGGTCCAAACTCGGTTTGTCGAGAAGTAAACGGGGCGCCATCGTGTATTTGTTTAGAAGGATTCAAGGGTCAACCTCCCTATTGCAAGCCCGAATGTAGTAGTAATGAAGAATGTTCTCCACACTTGTCTTGTATTCGCAATAAATGTAAAAATCCCTGTGAAAACGTATGCGCTGTAAACGCTGAATGTAAAGTTGTGAGCCATTCGCCGGTTTGCGTGTGCCAATATGGTTTTACTGGGGACCCATTCTTCGAATGTATTCAAGAACCCTTATATACAGAACCTATCACATCTCCCTGTTCGCCATCACCTTGTGGAGCTAATGCTATCTGTAAAGAACGTGACAACGCAGGGTCCTGTTCATGTATCGATGGTTACATGGGTAATCCATATGAAGGATGTAGACCTGAATGTGTAGTTAATACTGATTGCCCGTCAAACAGAGCCTGTGTTAATTATAAATGCAATGATCCGTGTCCAGGAAGTTGTGGTACCAATGCGGAATGTCAGACTGTTAATCATGTGCCCTTATGTACTTGTATTAATGGCTATACTGGTGATCCATTTAGATACTGTGTTTATCAAGATTCTCCAGTACTAGCTCCGGTTGACGTATGTAACCCTTCGCCGTGTGGACCTAACAGCCAATGTAGAACTATTAACGGCCAAGCTGTGTGTTCCTGTTTGATAGAATATGTTGGATCTCCACCTAATTGTCGGCCAGAATGCATAGTCAGCTCTGAGTGTTCGCACGACAAAGCATGCGTCAACAATAAGTGTGTAAATCCTTGTCCTAAACCATGCGGAGTCAATGCTGACTGTAAAATGATTAATCACAGTCCAATTTGTTCATGTAAAAATGCTTACACTGGAGATCCATTTACTGTTTGCACCGCAATAAAACATGAACCTGTACCAGATACGAGCGATCCTTGCGTACCCTCCCCATGTGGACCATATTCGCAGTGTCGAAACATTGGAAACAATCCGTCATGTTCTTGTCTTCCAACGTATACAGGCAGTCCACCTAACTGTAGACCAGAATGTATTATACATTCTGATTGCCCTGGTGATCGAGCATGTATTGGTTCCAAATGTCTAGATCCTTGTCCAGGATCATGTGGTATTTCAGCTACCTGTAACGTTCAAAATCACATACCAATTTGTACGTGCATTGAGGGATACATAGGTGATCCATTCACCGATTGTAAACCTAAACCCTTAGAAGTTGAACCAAGTGTGACAGATGCTTGTACAAACATAAGATGCGGTTCCAATGCTGAATGCATTAACGGTCAATGTCAATGCTTCCCGGAATACCACGGTGATCCTTACTTTAGTTGTCGACCAGAATGTGTGTTTAGTAGCGACTGTGATGAAACCAAAGCCTGTATACTAAAGAAATGTGTGGATCCTTGCATTGGAGCTTGCGGACAGAATGCTATTTGTCAAGTTTTCAATCACATTCCGATGTGTAGTTGTAATAATGGCTTCACTGGTAATGCGTTTGTCAGGTGCAATGCAGTCAGAGAACCGACTATCAAACATCCTTGCAGTACAGCGGTATGTGGTCCAAATAGCCAATGCCGAGAGGTACACGATCAAGCAGTTTGTTCTTGTTTACCATCGTATTTGGGCACACCGCCCGCTTGCAGACCCGAATGTGTAGTTAACGCTGAATGCCCACAAAATCAAGCTTGTATGAAACAAAAATGTATTAACCCATGCGCTGGTACATGCGGTTCGAGAGCATCGTGCGATGTCATCAATCATAACCCCATTTGTACTTGTCCTGCTGGTTATTCTGGGGATCCATTTGTAGAATGCAAAGTTTTATACAATACACCGCCTGTTGTTATTGACCCATGTCAACCATCACCCTGCGGACCTAATTCTATTTGTGAAGTCAAAAATAACAATCCATCCTGTACATGCAAAGAAGAATACAATGGACAACCTCCATACTGTAAACCAGAATGTATAAGTAACAGCGAATGTGCACCACATCTTGCATGCATCAAACAAAAATGTAGAGATCCTTGTATAAAAGCGTGCGGAACAAACGCAGAGTGTCGTGTTGTCAGCCATTCGGCTATGTGTATTTGCCCACAAGGATATTTAGGTGACCCCTTCATTCAGTGTTCTGTTAAAATTGAAGATGAAATTCTTCCTCCATGTTCTCCATCACCTTGTGGACCTAATGCGATTTGCCGTGAACATCACAACATTGGTGCGTGCATTTGCAATGACGGCTACTTCGGTAATCCTTATGAAGGATGTCGTCCTGAATGTATTTCTAACTCCGACTGCCCAGGCGACAGAGCTTGTATCGGTAACAAATGTCAAGATCCATGTCCAGGAACGTGTGGTATTAACTCTGAATGCACAACAGTATATCATTCACCAACTTGCACATGTATTCAGGGTTACACTGGAGATGCTCTCCGTCGCTGCAATCCTATTTTGCCTCAAGAAAATATTCAAGAAAACCTTTGTATTCCAAATCCATGTGGAGCACATAGTCAGTGTCGAGAAATTAACGATTGTAACTCAAACAAGGCCTGCGTTAATCATAAATGTATTAATCCTTGTCCGGGACCATGTGGCGAAAAAGCTGAATGCAAAGTGTTTAATCATAATCCTATCTGCAGCTGTCATTCAGGTTTCACAGGAGATCCTTTCACGCGATGCTATCCAAAACCAGTAATACAAACCATATACGAGGAAAGAAACGACCCATGCGTACCTTCGCCTTGTGGTCCACTCTCAATATGTAGAAATGTCGGTGATCAACCTTCCTGTTCCTGTGCTCCCGGCTACATCGGTAGTCCTCCAAATTGTCGCCCTGAATGTGTTACAAATCAAGAATGTCAAAGTTCACTGGCTTGCATCAACGAAAAGTGCAAAGATCCTTGTCCAGGTTCTTGTGGTCAAAATGCGAAATGTTCAGTTATAGAACACGTATCTATTTGCACCTGTCTGGAAGGCTATAAGGGTGATCCGTTTACTTCGTGTGCACCGCAACCAATACAAGACCTGGTTCCAGCTGATCTTTGTAATCCATCTCCTTGCGGATCAAATGCCGAATGCAATAACGGGGAATGCTCATGTTTACCCGATTACAGAGGTGATCCCTATCTGGGATGTCGACCTGAATGCACGATCAGTTCAGATTGTCAAAAGAATCAAATATGTGCTAAAAAGAAGTGTTTCAATCCGTGTCCTGACACGTGTGGTCAGAATGCTATTTGTGAAGTCATTAATCACGTGCCTATGTGCAGTTGCCCTGCAGGATTTACTGGAAACTCTTTTGTTACTTGCAATGCTATTCAAGTACCCATAGCGATTAACCCTTGCAATCCAAGTCCTTGTGGACCGAACAGCCAGTGCAAAGAAATTAAGAATGTCGCTGTATGCTCTTGTATACCAGGCTTTTCAGGAAACCCACCTACTTGCAGGCCTGAGTGTACCACAAGTGCAGAGTGCTCTTTAGATAAAGCTTGCAATAACTATAAATGCATCAACCCATGTAATGGTGCTTGTGGCATTGGAGCATTTTGTCAAGTGGTAAATCACAATCCAATATGTTCGTGTCCAAACGAATATACGGGAGATCCATTTACTAGATGTGTACTGAAACCTGCAGAAATACAACCGCAAGTTAATCCGTGCTCACCTTCGCCTTGTGGACCAAACTCAATATGCCAAAATAATAATGATTCTCCCTCATGTTCCTGCCTACCGGAATATACTGGAGTACCCCCGAATTGCCGTCCGGAATGTACAAGTAATAGTGAATGTGGAAACCATTTGGCGTGTATCAACAATAAATGTGGAGACCCTTGTGTCGGCGCTTGTGGACAAAATGCTGAATGCCGAGTAGTCAGCCACACGCCGAACTGTGTCTGCCCGTCAGGCTTTATTGGAGATCCATTTATACAATGTTCAATACAACAAATTTTACATGAAAATATCACTCCGTGTGTCCCGTCGCCTTGTGGAAGCAATGCTTTATGTAAAGAACGTAACAATGCTGGTTCGTGTGTTTGCTTACCTGGATATTTCGGGAATCCATATGAAGGATGCAGACCCGAATGCATAGTAAATACTGACTGTCCTTCGAATAGAATTTGTCAACAAAATAAATGTCAAGATCCATGTCCAGGAACATGCGCTGCAAATGCTCAGTGCAACACAGTGAACCACGCTCCGATATGCACTTGTTTACCTGGCTTCACTGGAAATCCTTTCCAAAGCTGTCTTATCATTCAAAACATTGAAATTGAAACGAACCCTTGCTCACCAAATCCGTGCGGACCAAATAGTATATGTAAAGAAGTAAACGAACAAGCAGTTTGCACATGTTTGGCAGATTATCGCGGCGCTCCTCCAAATTGTAGGCCAGAATGTGTAGTCAGTGCTGAATGTCCAACAAATAAAGCTTGTGTCTCCTTGAAATGTCAAGATCCATGCATAGGACAGTGTGGTCTTAACACGAAATGTCAAGTTATAAATCATAGTCCTATATGTTCATGTATAGAAAGGTTTACAGGTGATCCTTTTAGCCGATGTTTTGCTTTAGTATCTAGCCCACCTACGCACGAGGAACAACCAAAGAATCCATGCTTACCATCGCCTTGTGGACCATTTAGTGAATGCAGAGATATCGGAGGTATATCCTCATGTATTTGTTTGCCTAATTACATTGGGGCCCCTCCAAATTGTCGCCCAGAGTGTACAATTAATGCTGATTGTCCTAGTAATTTGGCTTGTATGAACCAGAGATGCAAAGATCCTTGTCCAGGCTCTTGTGGTTTAAACGCTCAATGTTTTGTCAAGAAGCACATGCCGATTTGCACTTGTCTTGACAATTATGAAGGAGATGCATTTACTGAATGTAAACTTCAAGAACAAATTAATGATGAAATAGATTTGTGTAATCCATCACCCTGTGGTCCTAATGCCATTTGTAATAACGGAGAGTGTACATGCCTTCCTGAATACCAAGGAGATCCGTTCTTTGAATGCAGGCCTGAATGTGTTCTGAATTCCGATTGTCCCCAAGACAAAGCTTGCCAAAAGAATAAATGTACAAACCCATGTTTAAGCAACGCTTGTGCCGCTAATGCGATATGCGAAGTTTTCAATCATGTTGCCATGTGTAGATGCCCAGAACGTATGACAGGAAACGCATTTGTTCTATGCTCACACCTGGAAGTTGTCAAACCACAGCCATGTCAACCAAGTCCTTGTGGTCCTAACAGTCAATGCCGTGAAATTAATGGGCAAGCTATATGTGCTTGTTTCATTGGATTTGTTGGAAGTCCTCCATCTTGTAGGCCTGAATGTACAGTGAGCACTGATTGTTCTCCCAACGAAGCCTGCAGCAATCAAAAATGTATCAACCCATGCCAAGGAACTTGTGGAGTGAACGCACAATGCCAAGTTATTAATCATAATCCTATTTGCTCATGTCCATCTTCTCTGACTGGAAATCCATTTGTAAGATGCTTTGTGCAAGAGTTTAAGCCTGAGTATAGTGATCCGTGCACACCATCACCTTGTGGACCAAACTCTATGTGCCAAGAAATTTCTGGAGCACCGTCATGTTCCTGTCTTGATGAATATATTGGAAAACCACCTTACTGTAAACCTGAATGTATCAGTAATACTGAATGCCCACTACACTTGGCTTGCATTAACCAGAAGTGTAAAGACCCTTGCCCAGGTTCTTGCGGATTAAACACGCAATGTCATGTAGTAAGTCACTCTCCAACCTGTTCTTGTGATTTAGAATATACAGGAAATCCATTCATAGAATGTCACCGCATACAAATAATATCTGAAGCAACAACTCCATGTCAACCTTCACCCTGTGGTGCAAATACTATTTGTAAAGAATTCAATGGTGCTGGTTCATGTGTGTGTTTGGAAGAATATTTTGGAAATCCTTATGAAGGTTGTAAACCAGAATGCATAATTAATACGGATTGTCCTTCAAACAAAGCTTGTCTGCAAAACAAATGTCAAGACCCTTGTCCAAGTGCATGCGCACCGAATGCAGTATGCCAAGTAGTGAACCATAACCCATCTTGCTCGTGCGAACGAGGATATACTGGAGATCCCTTCCGATACTGTACACCAGAACAAATTTTGGAAACGCCAATTAACGTATGTCAGCCCTCACCGTGCGGGCCGAATAGTAGATGTCAAGAAGTCAACAAACAAGCTGTATGTTCTTGTCTACCAAATTACGTTGGGTCTCCTCCTGGTTGTCACCCCGAATGTGTAACTAATGGAGAATGTCCTAGAGACATGGCTTGCATTAATCAGAAATGCGGTAACCCCTGCCTGGATGCCTGTGGAATCAATGCAGAATGCAGGGTTATAAATCATAATCCAATCTGCCAATGCACAATGCATTATACTGGAGATCCATTCACAAGATGTAATCCTATACCCCCTCCAGTTGCTAATGCTGATTTAGAACCATACAGAAATCCCTGCGTTCCGTCACCCTGTGGGCCAAATTCCATATGTCACGAAATAGGAAACATTCCCTCCTGCGCTTGTATGGATAATTATATAGGAAATCCACCGAACTGTAGGCCAGAGTGTATAGTAAATTCGGAATGTCCAACATCATTAGCTTGTATACAACAAAAATGTAAAGACCCCTGTAAAGGATCATGCGGATTAGGTGCCATATGTACAGTTTCTCGTCATACACCGATTTGTGTGTGTCCTGATGGCTATATTGGAGATGCCTTTACCATATGCCAGCCAAAACCACCAGAAGCAGATATTGTTGATAAATGCAATCCTTCACCATGCGGTTCAAATGCCATTTGTTCTGATGGTGTTTGTAGTTGCATAGAAGAACACCAAGGAGATCCATATATTGGATGCAGACCTGAATGTGTTCTTAGTACTGATTGTCCTAGAGATAAAGCTTGTGTTAAAAATAAATGCATAAATCCATGCGTAGACACATGTGCTTCTAATGCCATATGTGACGTGATAAACCACACGCCAATGTGCAGTTGTCCTCAAGGCATGACTGGAAATGCTTTCTACTCTTGTGATTTCATAAAAGTGCCTGTTGTGACAAATCCTTGCCTTCCATCACCTTGTGGTCCGAACAGTCAATGTCGTGAAATAAATGGGCAGGCTGTATGTACCTGCATCCAAGGTTATATTGGCAGTCCTCCTTTATGTCGGCCAGAATGTGTTGTGAGTTCAGACTGTCCTTCTGACAAAGCGTGCAGCAACCAAAAATGTATTAACCCATGCGATGGATCTTGTGGAATAGAAGCAAAATGCATGGTAGTTAAACACAACCCAATTTGTACCTGTCCAAATAAATACACTGGAGATCCGTTTACAAGATGCGTGCCATTTAGAGTACCTACAGCGGACGTGACGCCTTGTACGCCATCTCCATGTGGTCAAAATTCAATTTGCAAAGAAGTATCTGGAACTCCATCTTGCATGTGCATGCCAGATTTCTTTGGTACACCGCCATATTGCAAACCTGAATGCACTAGTAACAATGAATGTCCCGTTAACAAAGCTTGCATAAATCAAAAATGTGCTGATCCTTGTACCAGCGCATGTGGACTTAATGCTCTGTGTAGGACAATAAGTCATACGCCGACCTGTTTTTGTGATAACGGTTATACTGGTGATCCATTTACGAGATGCTTTATTGAAGAAATTTTATACGAACATTCGTCACCATGCGAACCCTCGCCGTGCGGACCTAATGCTTTATGCAAAGAACATAATTCAGCCGGATCGTGTGTTTGTTTACCCGATTATATTGGCAATCCGTATGAAGGTTGCAGACCAGAATGTACCATCAATACTGACTGTGAACCTAGTAAGAGTTGTATTCGCAACAAATGCCAAGACCCATGTCCAGGAACATGTGGAGCATTAGCAACGTGTGCCGTTGTAAATCATTTACCAACTTGCTCGTGTCTGGAAGGTTACACCGGAGATCCGTATAGAAGATGTGATATTATGCAAGTTCCAACAGCTATATCGATCACACCGTGCGTGCCTAATCCATGTGGCCCGAACAGTATCTGCCACACAGTTAATAATCAGAGCGCATGTTCATGTATGCCTGAATACGTGGGATCACCGCCTGGTTGCAGACCAGAATGTACAGTTAGCTCGGAATGTCCACAGAATAGAGCATGTATCAATTTAAAATGCGCAGACCCTTGTCCAAGTCATTGTGGAATAAATTCCCAATGTAAAGTCATAAACCATAGTCCTATTTGTACTTGTAAACTAGGATTTCTCGGAGACCCATTCACAAGATGTTATCCTCAACCTGAAGATATACCAGTTACTAAGAATCCGTGTTTGCCAAATCCTTGCGGTGATAACGCTATTTGTAGAGAAATAAACGGTTCGCCGTCTTGTGCATGCATACCGAATTTCCTAGGAATTCCACCAAATTGTCGACCAGAATGTGCTATAAATGAAGACTGTCCTTCTGACAAAGCCTGTTTCAATATGAAATGTGGAGATCCCTGTCCCGGAAGCTGTGGCCAAAACGCTGAGTGCTCAGTGTTCAATCATGTTCCATCCTGTGCTTGTATCCAAGGATATACCGGAAATCCATTTTCGGCTTGTTTCCTGATGAAACCTATTCAAGATGAAATACCAAAAGATCCTTGCTATCCGTCTCCGTGCGGATTCAATGCCCAATGCAATGATGGAATTTGTACATGTTTAGAAGAGTACTTCGGTGATCCTTACTTAGGTTGCAAGCCCGAATGCGTGATAAATTCAGATTGTCCCCTGAACAAAGTATGTTCAAAGAACAAATGTATGAATCCTTGTCCCGGAACATGTGCACCTACTGCCCAGTGCAGTGTTTATAACCACATACCAATTTGTACTTGTCCCGACGGTACAACGGGCAATGCTTTTGTGGAATGCCATACTATACAAGTTGTCCACGAGGAACCATGCAATCCGAGTCCGTGCGGACCAAGCAGTCAGTGTCGGTCTGTGAATAACCAAGCAGTATGCTCGTGCTTGCCATCATTCATTGGAACTCCTCCATCTTGTCGACCAGAATGCATAATTAGCGCTGAATGTCCTAGAAATGAAGCGTGTAACAACCATAAATGCATTAATCCCTGTCAAGGTAGCTGCGGATATGGAGCTAAATGTGAAGTTGTAAACCACAATCCCATATGTTCTTGTCCACCACAGTATACGGGTGATCCGTTTACAAACTGCCAGCCGATAGTGACAGCGCAATTACCTCCTGTTGATCCTTGCACGCCATCACCCTGCGGTCCATATTCTATATGTAAAGTAATCGCAGAATCACCTTCTTGCACCTGTCAGCCGGATTTCTCGGGAACGCCACCAAATTGCCGTCCAGAGTGTGTCAGTAACTCAGAGTGCCCAAGTAGTCAGGCTTGTATCAATCAGAAATGTAAAGATCCGTGTCCAGGTAGCTGTGGTTATAATGCTGACTGCAAAGTTATAAGTCATGCATTAGTTTGTTCTTGTCCAAATGGTCAAACAGGAGATCCACTTATTTCATGCAGTCCAATACGCGAAACCTTCATTGAATACAGCACGCCGTGTGAGCCTTCGCCTTGCGGTCTAAACGCAGAATGCACGCAGAAAGATAACGCTGGCTCCTGTAAATGCATTGATGGCTATATGGGAAATCCATACGAAGGATGTAGGCCAGAGTGTGTTATTAATAGTGACTGCGCTCCTATGTTGGCTTGTATTCAAAACAAATGTAAAAATCCTTGTCCCGGAGTGTGTGCGCCAAACGCAATTTGTCAAGTGGTTAATCATCTGCCATCATGTCACTGTCCACCTGGCTTAGCGGGTAATGCGTATCAATACTGTGTTACTAAAGTTGAAGACGTTAAACCAACACCGTGTAGCCCATCGCCATGCGGTCCCAACAGTGAGTGTCGCGAAGTAAACTCACAAGCCGTATGTAGTTGTCAAGCTGATTTTATGGGAACTCCTCCAAACTGTCGCCCCGAGTGCACCATCAACAGTGAATGCTCTGTTGTGAAATCATGTATTAACCGAAAATGTGTTGATCCATGCATAGGACAATGTGGTAGAAATGCAAATTGTAGAGTTATTTCTCACAATCCGATTTGTTCTTGTCAAGATCGATTTACAGGAGATCCGTTCACTAATTGCGTCCCAATTGCCATATCGAGTCTCGAAACGTATCCTGAAGTTAACCCGTGTATTCCATCACCCTGTGGACCTAATTCCATTTGTCAAGAAGTAAATGGAAATGCCCGTTGTACTTGTGTACCTAATTACAAAGGTTCTCCTCCCCGGTGCAGACCCGAGTGCACAATAAACTCCGAATGCAATGCAGCAACGGCTTGCATTAACAACATGTGCTTGGACCCCTGTCCTGGGGCATGTGGAAATAATGCTCAGTGTATTGTAAACAACCATTTGCCAATATGTTCGTGTTTGCCAGGATATACAGGAAATCCATTCAGTAGCTGTTTCCTGAAACAAGAAGAACATGTTGACCTATGTTCTCCCTCACCGTGCGGTTCAAATGCTATTTGCGAAGATGGACTGTGCACTTGTATACCAGAATATCATGGTGATCCGTATTTCGGATGTAAGCCAGAATGTGTCCTAAATTCGGACTGTGCTAGGGACAAGGCATGTATTAATAGTAAATGCAAAGATCCATGTATTGGAACTTGTGGAACAGACGCAATTTGTGAAACTATTAATCACATTCCCATGTGCTCATGTCCATCTGGTTTTACTGGTTCGCCTTTCAGTTATTGCACACAAATTTTAGAGCTACCCACGCCTGTCAATCTTTGTGTACCGTCACCTTGCGGACCAAACAGTCAATGCAGAGAGTTGAATGGACATGCCGTGTGTGTTTGTGTGAGTGGCTATCTCGGAAGTCCTCCAAATTGTCGCCCGGAGTGCATATTGAGCTCTGATTGTAAATTAAATGAAGCCTGTTCCAACCAAAAATGCATAGACCCGTGTCCTGGAGCATGTGGTCGCAATACAAAATGCATTGTTGTCAATCATAACCCCATATGCACGTGTTCGCCTGGATTTTCTGGAGATCCATTCTCATCATGCCAAATTATCCCTGCCACACCGCCTGCGAAGGTCACTCCGTGCCTACCTTCACCGTGTGGTCCAAATTCAGAATGTACAGAGAATGGTGAAAATGCAGAATGCAAATGTTTATTAGAATATATTGGCTCACCTCCTAATTGTCGACCGGAGTGTACAAGTAACACTGAATGTTCTCAAAATATGGCTTGTATTAACAGAAAATGTCAAAACCCCTGCGCAGGGGCATGTGGTATAAACGCTGAATGCAGGGTAGTAAGCCATACTCCCATATGCTTGTGTGAAAATGGATACTCAGGAGATCCATTCCTTAGCTGTAATATAATAGTATCATCCGCAGTGGTGGAACGTCCGACACCTTGTATACCATCACCATGTGGTGTTAATGCTGAATGCAGAGAACGGAATGGTGTTGGATCTTGTATTTGTTTACCTGACTATTTCGGAAACCCATACGAAGCGTGTAAGCCAGAATGCATTCAAAATTCTGACTGCCCTTCGAACCTTGCATGCTACAATAACAAATGCAAAGATCCATGCCCGGGCACTTGTGGAATTAACGCTCAGTGTAACGTCGTTAATCACAATCCTTCGTGTTCGTGTATTGAGAAATATCATGGAGATCCATACAAGATGTGCGCATTTAAAGCTGAATCGGAAATTTTAGACCCTTGCGAACCTTCGCCGTGTGGACCTAACAGCCAATGTAAATCTCAAAACGGCTTGGCGATATGTACTTGCATGCTTGGCTATCAAGGAACACCACCTTCTTGTCGCCCAGAATGTATCACTAGTTCAGAGTGCTCTCTAGATAAAGTCTACGCTTTGTGCAATGTTGTGAAGCACGTTCCTGTTTGCTCTTGTCCTAGTGGTTACGAAGGAGATCCATTTTCCATCTGTCACATCAAGCTTCCAGAATTACCACAATCAGTAGATCCATGTCAGCCAACTCCATGTGGACCCAATGCTGTATGCCACAATGGCGTATGTTCCTGCTTACCAGAGTATCAAGGGGACCCCTATTTTGGCTGTCGGCCTGAATGTGTATTGAGCACCGATTGTCCTCTGGATAAGGCTTGTTTCCGTTCAAAGTGTGTTGATCCTTGTCGTGACATGTGCGGAGTCAATGCAGAATGTAATGTCTACAACCATGTCGCTATATGTAGCTGCCCAATGGGACATACCGGAGATGCATTTACCCATTGTAAAATAATTGAAAAACCAGCCAATAAACCTTGTGAGCCTTCGCCTTGTGGACCTAACAGTGTTTGCAGAGAAGTAAATGGACAGGCAATCTGCGCTTGCATCGAATCTTTTATTGGTAATCCGCCAAACTGCCGACCTGAGTGTATTCAAAGTACAGATTGCTCTCCCTCAAAAGCTTGTATAAATAGAAAGTGCCAAGATCCATGTCCAGGATCGTGTGGTCGAAACGCTATATGCATTGTTAACAAGCATAATCCTATATGCAGCTGTCCTGCAAAGTACACAGGATCTCCATTCACTTATTGTTACGTTCAATTAGAAGAAGAGCCACAGTCTAATCCATGCGTACCATCGCCTTGTGGACCAAATAGTCTATGTAAACCAACAGCTGACGGGAAATCTTATGTGTGCACATGCCAACCATCTTTTGAAGGAACTCCACCTCTATGTCGTCGCGAATGTACAACAAGTGATGATTGTTCGTCTGACAAAGCTTGCATTAATTACAAATGTTCGGATCCTTGCCCTGGCTCCTGCGGTTTGAACACGCTTTGCGTCGTTCGACTGCACACACCTATGTGCTCATGTGAAAACGGGTACACTGGAGATCCATTTTTATCATGCTATCTGATGCAGCCAGCACATGAACCAGTTGATCCTTGCAATCCTTCACCTTGTGGCGCCAATGCTCAATGCAAAGAAACACGTAGCGGCGCAGTTGCTTGTATTTGTGAAACTGGATATTTCGGAAATCCTTACGAATCTTGCCGACCAGAGTGTGTGGTTAATACTGATTGCCCATTTAACAAAGCGTGCCTAAGAAACAAGTGTGATGACCCGTGTCCCGGTGTTTGCGGCTCTACAGCAAATTGTGAAGTTATTAATCATGTACCATCTTGCACGTGCGCGCCAGGTTACACCGGAAATCCGTACACGTACTGTCATATCATCATTAATGAACCAGTACCGAAACCGAAAAATCCTTGTTTACCGAACCTCTGTGGCAGTAATACTATATGTAACTACTCCAATGGCCAAGTATCGTGCTCATGTATGCCTGAGTTCTACGGCTCACCACCGAATTGTCGTCCAGAATGTACTGTCAATGCTGAATGTGATAAATCGAAAAGTTGCATAAGACAAAAATGTATTGATCCTTGCATTGGAGTGTGCGGACAAAATGCAGAATGTAGAGTTATTAACCACGCACCTATATGCTCGTGTAGTCTTGGATTTGAAGGTGATCCGTTTATTAGGTGCATGGAAAAGGAAAAAACACCTACGCCAATTACCAATCCTTGTATACCATCTCCTTGTGGATCCAATTCTATTTGTCAAGCTGTAAATGAAATACCGATGTGTTCGTGTGTAGAAAAATATATTGGTTCGCCGCCGAACTGCAGAGCGGAATGTGTCATTAATTCTGATTGTCCAAGCACTGAAGCTTGCATTAACCAGAAATGTAGAGATCCATGCCCTGGCTCTTGTGGTCTTTACACAGAATGTCACGTTTATCAACATTCAGCCATATGTAGTTGCAATGAAGGGTACACCGGAAATCCTTTCCAGAGCTGTCAAATCAAGCAAAATATTGAACCTGTTCCAAGTACATATGATAATTGTAATCCAAATCCATGTGGCGCAAATGCTGATTGCAATGATGGAGTTTGTAAATGTAGAAATAATTACTTCGGTAATCCCTATCTTAGCTGCCGACCAGAATGTACTCACAGTTCGGAATGCGCAAAATCTTTAACATGTATTAACAACAAATGTACAAATCCATGTATTAATATATGTGGTGAAAATGCCTTGTGTGAAGTATACAATCATATGCCTATGTGTAGCTGCCCTCCAAATACAACTGGGAATGCATTTTTCTCGTGTACACCGATTAAAGTAATCCAGGATACGAACCCTTGCCAACCATCTCCTTGTGGTCCAAACAGCGTATGCCGTGCACTTTCAGGACAAGTAATGTGCTCTTGTATAACTGGTTACATCGGTACGCCACCATCTTGTAGACCAGAATGTTTAGTGGATTCTGATTGCACGATTCTTTTGTCTTGTTCGAATCAAAAATGTGTAGATCCATGTCAAGGTTCATGTGGAATGAACGCTGAGTGTAGAGTTCACAACCACAAACCAATATGCTACTGTAGGAATGGACTTACTGGTGATCCTTTCTCTTACTGTAGAGTTATTCAAAAAGAACCACCAAAAACCGCACCATGTGAACCATCGCCATGTGGACCAAACTCTGTTTGTAAATCAAACGGCGAAGAGCCACAGTGCCTATGTCAAACTGGATTTATTGGGTCTCCTCCATACTGTCGTCCAGAGTGTATTTCTAATAGCGAATGCAGCTTCAATAAGGCGTGCATCAACAATAAGTGCGACGATCCCTGTCTTGGAGCATGCGGTCCTAACGCTGAATGTCGAGTTATCAGTCATTCACCACAATGCACTTGCCAATCTGGCTATGAAGGAGATGCATTCAATTTGTGCCACCCTAAACGAGACCACGAACCAGTCACACCTTCCGAACCTTGTGTTCCAAATCCCTGCGGTCCGAATGCTATCTGTCAAGAACGTTATAATATCGGCAGTTGTACTTGTGCGAATGGTTTCTTCGGTGATCCTTACGAAGGTTGCAGACCTGAATGTATTGTTAATTCTGATTGTGCCGAAAGCAGAGCTTGTATAAACAAAAAATGCCAAGATCCTTGCCCAGGGCTTTGTGGAGTAAACGCTCAATGCCAAACAACTAACCACGTTCCATCATGTACTTGTATACATGGATATGTGGGAAATGCTTACGAAAGCTGTATACTCAGAGAAGAAAAACCGACAAACCCATGCTCACCGTCGCCTTGTGGTGCCTACAGTACTTGTAAAACTATAAGCAACCAGGCAGTTTGTACGTGCTTGCCAGATTACGTTGGAAATCCGCCAAGTTGTCGACCAGAATGTATCATTAGTTCGGAGTGTCCCTTGAATAAAGCATGCGTTCGTAAGAAATGTGTAGATCCATGCATAGGAACATGCGGGGAAAATTCAGAATGTCGCGTACATCAACACAGTCCCTATTGTACTTGTCTGCCAGGCTATGAAGGCGATCCCTTTATAAGATGCTCTAAAGAAATTTTATCCACTCCACCTGTTGCCTCACCTTGTGAACCGAGTCCGTGTGGGCCATTCGCAACATGCAGAGACATAAATGATTCCCCAATATGCAGCTGCAAGCCAGGATATATCGGTGCTCCACCTCGCTGTGCACCAGAGTGTACTATAAATGAAGATTGCCCTAACAACAAAGCGTGTGTTCGTGAAAAATGTGTAGATCCATGTCTTGGATCTTGCGGTACTCATACCGACTGTCGAGCAATGAACCACGTAGCTATTTGTACTTGTCTTTCCGGATATCGAGGCGATCCGTTTATTGGTTGTTCATACCAAGACATTCAGCCACCGGTGTCATTCGACGCATGTATTCAATCACCGTGTGGTATTAACGCGGCGTGTGACAATGGAACGTGCACTTGCATTAGTGACTATCATGGCAATCCGTATATAGAATGTAGGCCGGAGTGCACTAGTGACAATGATTGCCAAAAACAACTAGCATGTGTCAACTATAAATGTATTAATCCTTGTAAAAATGCTTGCGGGATTAATGCGGTCTGTAATGTTTACAATCATATTGCAATTTGTGAATGTCCTACGCCACTTCAAGGAGACGCTTTTATATCCTGTCATCACGCGATTGAGCCATCAATATCAGATCCATGTACGCCTAACCCTTGCGGACCAAATAGTATTTGTCGTGCTGAAGGAATCGTAGCGCACTGTTCATGTCGGCCTCCAATGTTCGAAGATCCTCCAAGCTGTCGACCAGAATGTCGCGTAGATTCAGAGTGTCCACCTAACCGTGCTTGTAGAAACAACAGATGTCGCGACCCGTGTCCAGGATCATGTGGTGCTTCTGCAATTTGCCACATTCGATCACACTCACCTATATGTGTATGCCCAGCAAACTACGTTGGAGATCCGTTTATTCATTGTCTCCCAGCTATTGAAGCAGAGCCTTCGACTCAAGCACCTCAATCTTGCACAAACTGTGGACCAAATTCGGACTGTATAAATGGGCTCTGTAGCTGTAAATCGGGCTACGTTGGAGCGCCACCCTATTGCCGCCACGAGTGTCTCAGTTCCAGCGACTGCGAATGGCACCTTATGTGTTTGAATCTGCGTTGTGTAGACCCATGCCGCGGAGCCTGTGGACAAGGCGCTCTTTGCGAATCTCTTGCTCATGAGCCTCATTGTACTTGTCCTTCCTCCACTACTGGAAATCCGTTCTTCGAATGTCGGCCCATCGTTACAACCCAGAAAACTCCGAATGACCCTTGCAACCCATCACCATGTGGGCCTGGTGCTTTATGTAGCGCTAGGGGAGCGAGTGCGTCATGTGAATGTGAGCCTGGACTCTTCGGTGACCCATACAGTGGATGCCGCCCAGAATGTGTATCAGACTCGGACTGTTCACCTTCTCGTGCGTGCATGCGTTCTCATTGCCGGGATCCCTGTCAAGGAACTTGTGGTATAGGAGCTGACTGCGAAACTGTCAACCACATTCCTTTATGTTCTTGTCCAACAGGAACTAGAGGAAATGCTTTTGAAAAGTGTGAAAAGATTATTACAGCACCACCTTGCAACCCCTCACCGTGTGGACCAGGTGCTGTGTGCACTACATCAGGAAGCAGTGCCATATGTTCATGTCCAAGTGGAACTTATGGAGATGCTAAATCGACAGGATGCAGACCGGAATGTGTTGTTAGCTCTGAATGTCCACGTGATAGAGCATGTGTGCGCAACAAATGCATTGACCCATGTATTGGAACATGTGGAAATGGCGCGATGTGTCGAGTATTTGATCACGCACCAATTTGCTCTTGTCCACCGACTACTACCGGGAATCCATTTACAGAATGCACTTTAAAAGATGTCACTCCACCTACTTTTGACCCTTGCGACCCTAACCCTTGTGGAATTCATGGAACTTGCCGCGACGGACAATGCATATATCCAGAGTGTATCGTGAATGATGATTGTCCCGGTGACCGTGCGTGTATCAACAGGAAATGTGCCGATCCGTGTGTAAATGCTTGCGGTATAAACGCCATTTGTACGGGCATCAGACATACAGCGCCAACTCCACCGACACCTGAATGTGTAAATGATAATCAATGTGCTGATGATGCCGCTTGCGTTGATTCACGATGCTCACCAGTCTGCGGATCCAATAATTGTGGCATTAATGCCCGTTGCTTGGCTAAACAACACAGAGCACGTTGTACATGTTTACCGGGCTATGAAGGTGATGCTTACACTGGATGTTACTCGGTGCAATGTCACAGCAACAACGATTGTCCAGAAGACGAAAGTTGTGAAGGCGCTTCATGTGTGAAGGTTTGTTCACGCGTTCGTTGCGGAATCGAAGCGCGATGCGTCGCAAGAGGTCACACCGCATCATGTGAATGTAACCCTAGCGCAAGAGGAGACCCTTGGACCGAATGTCACATAGCCGAATGTAATGCAAATGAAGATTGCCCATTATGGTTAGCCTGTAAAGCGAATAAGTGTAAGGATCCTTGTCCTGGAGCTTGTGCACCTGGAGCCGTTTGCACAGTACTACGACATCAACCAACATGCGAATGTCCTCGAGGAACAAATGGCAATCCTAAAATAGAATGTCGACAAGTGGCAAACGAAGAGGAATGCCAATACGATGCTGAATGTGGACCAGGTCTGGCATGTCTACAAGGAAACTGCAAAAATCCGTGCGAACCAACTTCGTGTGGAACACGAGCCGTCTGTCGCGTTGCTAATACTCTACCTTTCCGCACCCTGGTTTGCGAATGTCCGAAACCACTCACTGGGGACGCATCTCTACAATGCAATCCAAGAGGAGAATGTACGTCAAACGACGATTGTAGTTCAGAAGAGAGCTGCATAAACAAGCGTTGCGTGAACGTTTGTAGCAACGGCGCCTGCGGTGTAGGTGCTGAATGCCGCGCTCAGTCTCATAGAGCTAACTGTGTCTGCGTACCACCATTACAGGGTGACCCACGTGTAGCTTGTATGCCTAGTACCCCGACTGCAGAATGCGTCGTAGATTCAGATTGTGGTAGCGCCGAGGCATGTGTATCACGACGATGTGTTTCGGCATGTATTGGAGCTTGCGGGACGGGTGCATTGTGTGACGCTGCGCAGCATAGAGCACGCTGTCACTGTCCACCGGGGACTGCTGGAGATCCTGCAAGAATATGCTATACACCTGAGTGTACATCTGATGACAACTGCCCATTCGATAAAACGTGTTTCAATGGATACTGCAAGGATCCTTGTGGTGTGGGCTCTCCGTGCGGACGCGACGCAAGCTGTGAGGTTGTAGCTCACGTCGCCACTTGTCGCTGTCCACCCGGTACGCAGGGCGACCCTCGTCGCGCCTGTATCTCAGCGGCCTGTCATTATAATGAAGACTGCGATGATTCACAACTCTGTAATCGTCTCAACCGCGTCTGCCAATCAGCGTGTACAGACAACTCTTGCGCTCCTGGTGCTTCATGTACAGGAGAGAATCACCGCCCCACCTGCAAGTGTATTCCTGGATATATTGGTGATCCATATCAACGTGGATGTACATTTGCCCAAGATACCACTGAATGTACAACGGATGCTGATTGCTCAGCGCCTTTAGCCTGTGTGGACGCACGCTGTATCGATCTCTGCCTGAATAATCCGTGCGATAGTGGTCTCATATGTAGAACAGTTGATGTGCTTCCTTTACGAGCAGTTGCTTGTGTATGCCCTGATGGAGGTCGAGCTGCACCGGATAGTGGCTGTCGCACACCACCAGAAGTAGAATGTTCCGTGGACTCGGATTGCGCTAGTAGTCAAATGTGCTTCCGTGGTAGTTGCGTCGAAGCCTGTAAAGCTGATCCATGTGGACAGAACGCCCTATGCGATTCGATTGATCATGCATCACGTTGCGTTTGTCCACCTGGATACAACGGAAACCCAAGATTTGAATGTAACACAGTGCCACAAGAACCAATAGTTTGGGAATGCTACGAAGACAACGAGTGTGGACCTGAACGCGCCTGTATCAAACGATCATGTGTCAATCCGTGTATTGATGGTTGTGGTATTGGAGCTCTATGTCGGGTGATTGATCATAAGCCACAGTGCTCTTGTCCAAACGGTTTTTCGGGCGATGCATACATTCGATGCTTACCACCATCCGAGAAGTCTTTTATTCCACTTGGTTGCAAAGCTAATTCAGAATGCCCATTATCTCAAGCCTGTATTAATGGTGCTTGTGCCGACCCATGTGCTTGTGGCGCACAAGCTGATTGCTCAATTGTGAGACATCATCCAGTTTGTTACTGTAAACAAGGCTATTCTGGAAATCCCTATATTGGATGCACTAAAGTTGGGTGCGACTCAGATTCTGAATGCTCGGACAGCGATTTATGTTACAACGGAGCTTGCCTTAATCCTTGCCTAATAGATACCCCGTGTGCTATTAGTGCTGAATGTTATGGCGTTAACCACCGTGCAAGTTGTCGTTGCCCATCTGGCACTGTTGGAAATCCATTCACGAGATGTATAGCAGCTGAATGCGAAACAGATAATGATTGCAATGATGATAGTGTTTGTGCGAAGGGAACGTGTTACAATGCTTGTTCTGTCAACGGCATTAGCTCTTGTGCAGATAATGCCGAATGTTTCTCGCGTAACCATGCGGCATCGTGTAGATGTCCACCAGCTTTCCCGATCGGAGATCCTTCTGTTCATTGCCAAAAAGCGACGGTATTAAACGAACCTGAGTGTATAATGGACGGTGATTGCCCCAGCGGTCACGCTTGTCTCAAGGATGAATGCCGTGAAGCTTGTTCCGAACTTAAGCCGTGCAAAGGAAATTCCCGTTGTTCAGTTTCAGACAGTATACCGTTCCGAACTCTGATTTGTCGTTGCCCAGAAGGCTTTGTACCTTCTGAAGATGGTAGCTGCAAGCCGGCCAATTTACCACCCCTTGGTTGCTCTTCGGATAATGACTGCACAGACCAAGAGTCTTGTGTTAACAGAAATTGCAGAAATCCATGTAACTGTGGTGATAACGCGGATTGTTTTGTTAAAGATCATAGACCTATTTGTTCATGCCGTAATGGATACGAAGGAGATCCTTACCGCACTTGTCGCGTTGTGGGTTGCCGTACAAATTCAGAGTGTGACACCCGAGAAGCTTGTATAAATGGAAATTGTATAAATCCTTGTTTAACAAACAGCACATGTGGACCAAATGCCGAATGCTTCGTTCAAAAGAACCAACCGCTGTGTCGTTGTCGTGTTGGATTTGAAGGAGACGCCTATTTAGGTTGTAATGCGATAGAATGTAGATCAAACGGAGATTGTCCACGTGATAAGCAATGTAAAGCTCACAGATGTATTAATCCTTGCTTCATTGACAATATATGCGGTACGCACTCTAATTGTCTGGTTCGTAATCATTTAGCAGTATGTAAATGCGACCAAGGATATGGCGGAAATCCATACATTGAATGTAAGCCGCAATTTGCTCAAGAATGCTACGTCGATGCTGATTGTCCGTCAAGAGCAGCCTGTTTGTCTTCCAGATGCGTTAACCCTTGCACGACATTAAAACCGTGCGCTAATCCTGCTACGTGTGAGGTCTCACCGACATTGCCAGTGCGTACAATGCTATGTACTTGCCCACCAGGTTTTGTGAGCAACGGTGGAGGCATATGTCGCCCAGTCATTGAATTCTTTGAATCGACTTGTGAAATTGATAGCAACTGTACATCGAACCATGCTTGTATATCATCTGTATGTAAAAATCCTTGTGATTGTGGACCAAACACTGACTGTATTATGAAAGATCACAAGCCTGTTTGTGCTTGTCGACAAGGCTTTATAGGGGATGCTTCGTCAGGTTGCTATGAAATACAATGCCAATCTGATTCTCATTGTGCTGACGACGAAACGTGTATAAATAGGCGTTGTGTCCCTGCTTGTTCGGTAAATGCTAATACGTGCGGGCAATCGGCTGAATGTTATGGATTAGAACATCGTGCATCCTGTCGCTGTAAGATCGGTACAGTTGGAAACCCATCTATAGCTTGCACTCCCATTGGCTGCAGAACTGACACAGATTGTCCATCTGATAAATCATGTATCAATTCCAAATGTGATACGCCCTGCAATGCAGATATTTGCCAGGAACCAGCTCAGTGCAAGGTACATTTACATCAAGCTCATTGCGCATGTCCTCCGGGATTCACCAATACAGGGAAAGAATGTAGAAAAACTGAAGGACCACAATGTATAAGTGATATAGACTGCCCTTCGGGAACAGGATGTCTTAATTATAGATGTGTCAACCCATGCCTGGTATCAAACCCATGTAGTGAAAATGCGCAGTGCAAGATTGTAGACACCATGCCTGTAAAAACCATGGTTTGTGAATGTTTGCCTGGATACAAAGGAAATGCATTACAAGAATGCAAGCCATATCAAACTGTTGCTAAATGCATCGAAGGTCAAGGATTAGACTTGTATGGTGAATGTATTCCTTGTCGACCAGCAGAAGGACGTATTATAGATTCTAGGGGTCGATGCGTTTGTGACTCGGAACGTGGTTTTATAATTCAAGGAGATAAATGCGTTGCTGGCGGCTGCCGCACTGACGACAATTGCGCAGATAATTCGCGATGCATTCGCGGTCAATGTGTAGATGCCTGCAAAGCTGAGCCTTGTGGTATTAACGCAACCTGTGATGCGGTGGGGCATCGCTCTCATTGCACTTGCATTGCCGGCTACACTGGAAATCCTAGAATTCAGTGTAATGCAACAACAACAATGTACCGAACCGATTTCCCAACACCAGATATTCAGGTCGAATGTTTGGCTGACGGAGTTAGAGTCCGACTTAAGATTAAAGATTTCAACGGCCTTTTGTACGTAAAAAGTTACAGTAAGGATGAGAGATGCAGGAAAGTTGTAGAGATGCCTAAAGACGAAGAAAGTTTTGTTTTCTTCACTGTACATTTCGGAGATTGCGGCCTTGTTCATGTCAATGGCTTAGCAAGCTTCGTTCTAGTAATGCAAACTCATCTGAAACTGGTAACATCAACCACAAAAGCATTCCACATCAAATGCATATACAAAACTGGTGAACAAAACGTAACTCTTGCATTCAATGTGTCCATGTTAACAACAGCAGGCACAATCGCCAATACCGGCCCTCCGCCTACTTGCTCCATGAGAATAATTTCACGTTCTGGAGACCAAGTCAGTTCCGCAGAAATAGGAGAGAACCTCGTTTTACAAGTTGATGTCCAACCATCTAGTATCTACGGAGGTTTTGCACGCAGCTGCGTTGCAAAAACAAGTGAAGTATCAACTAACGTAGAAAATGAGTATCTTGTAACAGACGAGGACGGTTGTGCTAAGGACCCCGCTATTTTCGGTGAATGGGAACGAAGCGAGGACGGCAGCGCGTTGCGTGCCGCTTTCAATGCTTTCAAGTTCCCCAGTAGTGACAATATACGATTCCAATGCAACATTCGCGTCTGCTTTGGAAAATGCGTACCGGTTAACTGTCGCGGTTCGGACGCATACGGTAAACGAAGAAAACGAGAAGTGACCGACGAAAGCACCGCTTTGACGATGCCGGTAGGTCAACTTCGAGAGGAGGTGACCGTCGAATCGAACCAAATACTAACGACGCAGCGACGCGAACCGTCACAAGTGGCTCGGCAGCGTGATGGTACTGGTGCAGAAGGTGCCAGTCAGAGCAGTGGAGAAGTGTGCGTGTCAGCAGCCGGACTCGCGGTCGCATTGGCGCTGACCGCATTACTGGCGTTAGTAGCCGTGGCGGCTGCGGTCGCTTGTTGGCTCGTAGCCTGGAGACGTGCACGTCCTCCTCCAGCACCGCTTCCACATCCGCCGGACTTCCCCAATCCGCTGTTCCAGCGTTGA
Protein
MYIDSLPLVVWTLLVTTTHVATQSQYGIGLGIKREVFFLNLEDGYFGCQVNESTQILQLYELSKLCDGVTDCYKGSDELKSELKCSDDCTKEDGAQCVNGACLNGVCHCNDGFGGCNCQDPDINECKDRPCDVFAHCTNTVGSFQCSCFPGYEGDGFTCRDINECEDPAIASRCVENAECCNLPAHFICKCNRGFEGDGEEECRDIDECRRPGACGTHAICRNYPGNYTCSCQAGYTGNPFDGCVDVDECINESTCGEVAICRNIDGGYECSCPPGYEGDPRVACHDHDECARAACGRGALCENLPGAYRCVCPPGFDGNPDVLCSDVDECKSSETVCGAHAVCTNTAGSYVCTCAPEYTGDAYAQDGCLDLDECQTLEKPCGTNAICENSAPGYNCVCPQGFAAQPDPQIACEQVDVNILCKSNFDCTNNAECIDHQCFCKEGFNAKGSICEDVDECSNNKSVCGENALCINIPGGYNCQCAAGFVGSPPKIGCRAPCEDVKCGKHAYCKPDGMEAYCVCEDGWTFNPHDIAAGCIDLDECDISLGPVGRCGKNAICSNTPGSFSCNCPEGYTGDAYKQCSDIDECQLEGACGLGADCLNRDGSYSCECPDGTIPDPDPHIRCAEILACKGDKDCPGNAVCDSNARCLCPEPNIGNDCRHPCESLQCGTNSECLLSDQEAQCTCKSGFTGDPSSLLGCQDMNECDEKPCGVGAVCKNLPGRFQCECPATFTGNPYVEGCNPGKILSECSNLNPCPEGEQCILHDGGNVCICPQGFTRNSETGLCEDINECVQHGRSPCGLNAICKNLPGSYECKCPQDYSGNPYKICELCDDISCQCQPPYKMIDGSCVLSGCGKDNKCGTGAECIVISDEVSYCACPAGYTQTSDSTCEDINECTSGTPVCGFGAECINTVGSFECKCPPGYSKDKIEGHCSLNQKRCISDSDCFPNEKCVQPGKCMCPPPFYLDVTDGQKCKSPCERFTCGINAKCTPSDPPRCMCMAGYEGDPYTGCTKRNECHSSPCAYGAICHDQKGGYKCDCPPNMIGDPYRSGCVFEEEPTQKHLCSSDDQCPNTLACLNHTCISPCATISCGPNAFCEVENHAAWCRCDPGYTKPEGGKCISACDTYNCAPGAQCIISKTGPTCVCVEGFVGNPFPGGSCSRDQCGPGIPCEDPLTCVAGRCRQRCEGVLCGVGATCDSQTGRCVCNPFFIGNPDLLCMPPVSPPACEPNCGTNAHCVYGKDNICKCNKGFTGNPYKKCLSRKQITCATASCGRNAVCQQTKSSIECLCPPGYVGNPNIQCKDIDECGTNPCGENALCINTPGSFSCICRSRYVGNPYELCSQVSVAKCTDGAVCTCSHNTTCPHGFVCDKSKCVDLCEKLACGPKSVCEEGVCHCLPSHTGDPNDLRKGCVPDDSCLVDGDCKDSEICFQVAKNTRKCVDSCSKLQCGPNSLCIGANHQAHCICADGYIGKPTDVKVGCHLEQREPNEFECNDNSDCNEPFVCMSLEGSTKRCIDLCTTIACSANEVCRVVAESARCECDNGFLWNPVTSNCEQPSTPNCQEDDDCDDNKSCNKDVLGVKKCEDSCSVFNCPENSKCVTKNHKSKCECINGFIGNPNDRDGCLAIDKNECSDDAQCRESEVCRTFGGNKKCVSACQNVVCGPNAFCITKNHIARCQCPSGPFTGSPDDLEKGCQSVPCVHNDDCLSHQLCNRMTYTCINACTVNSCGDNAVCIAENHKIICQCPNGYSPDPKPEVSCQKDDACNSNPCHPSAICESSFSSFSCQCPNGYVGDPIKDGCRKQDICLRDGDCPREAVCVENRCVNTCDGACGLNSLCQIINRKAVCMCPEGYEKIQDNACKKKLLACSSEKDCGGDICNNGQCFTACKNSSQCEFGDICKNNLCVAQCNKHTQCGHGQACIGGQCLIGCRNNEDCFSEEACVNNKCVNPCLTTKPCGPNAICSRINHSTNCECPLGFQGAPTPQQGCVRKPSVCDRTSDCPPDHMCIGFLCQVPCKDSTGCAIGEKCSDNKCLRICHSSTNCLHGEHCDAGVCVPGCKSDLDCLNNLVCNNMKCQCTAGFELRNEECTNLNECLEYPCHPSAQCVDTPGSYKCVCSVGAAGDPYRSGCLLPNQCRNDEQCDNSLACIQGKCSNPCQNNTCGTNAECSVMNHNVMCACKKGYLGNPFDKNIGCFKVECVDDSDCNTEKYCDLKFNKCSDVCEPSICDGGNCKIENHKMLCTCPTGYLFKDKKCVDLNECLSSPCPLNSKCFNTLGSYKCECVNGTVQDTITGSCKLPGDCVTDDDCTQVTKCFNNHCVNPCEKLSPCGENANCFVTKHKAECECPSDSQGDPYKKCIKFECTKDNHCPQEEACVNNKCKNACSLPRACGRNADCFSKSHVGNCICSPGYTGDPVLGCVPIQYCTTDDRCSSGTKCVDNLCVGLCKNSRDCLNNQVCIKNTCRVSCSLNDTCPEFQYCLNSICTKEVQCISNDDCLDDEKCSTGKNGIPQCIKVCDKHPCGRQAECLGKNHQPTCSCALGFFGDPLEGCQRKECDTDTECSEDKVCDRNMCKIACLVKNECRENSICSSEKHKNVCYCQPGYTGDPIKGCTEINWCKLSPCANGAECKSARDRAECTCPANTVGNPYEEGCRKAEECRFNRDCPTAARCTVIDGTRKCTDACENVKCGLNAECFASRHSAQCRCKTGFIGNANSEKGCHLREISCTSKSNCPDDQYCHKGICKALCLLDEECASNEKCFGGQCLNPCQLEKTCGLNAICRTDNHIVQCSCPQSFTGNQDMECIRIPRLCGSAGDCENGHMCKDSMCIPRCNIDEECALNERCTKGGCLLTCRVDNDCFPGHICLEQSCQYGCRYDDDCGPEEFCKNDVCKNPCDSDVNPCGPNAVCSVLERIAHCSCIEGLIPNPTPNIGCIRAPSSECRQNTDCTDGWTCEDSRCRPACTADGSQCLQGERCDEGVCRYACTSDEHCSDDEICDGRSCTIGCRSNSHCSSKLACISGQCRDPCTEPASCGINAICATKDHQPVCTCPRKLAGDPKLVCSRVTTSCGSNQNCPDGFSCYGDTCHPSCRSDNVCLSNEKCIRGICRTICNSDTACSEGYICENRICKQGCRDDNACEETHACVKGQCKDPCSQGACGICSECKVQNHRPQCSCASNYTGNPLVECRRKKTLCDGFCPCDQSGYCISLCDENSDCPCGDKCIEGGCLTRCSPRNKCPERQICQQGVCTPGCNNDKDCSDDMFCSSNLCVNACQEESCGINALCLTTRHRAVCSCPSGYSGDPLKECNQFECQNNEDCGTDEECYTDGKCKNVCSGACGLNALCRSVDRSPQCSCPPNYQGNPQIECTKPTTGSCLRNPCGVNARCRDLDDGSYECTCPPNCAGNPQRQCFCGKMEPCAYKPCGTNAQCRVNRIGEAQCYCPRNYPNGDPNIECAQERSVIDCRTTGCGINGECLREGAEFVCRCVPGTEGQADIECHTSIECTSDVECPVDKVCLSLHCVDPCTLRGACGEDALCAPLMHMAQCSCPQCYVGQPRISCRLDPNCKPTTDYNSTFSCSEDKPCPPKLACDLNSNQCRNPCLGYQNCKLNQKCEVRDHKPVCVCRNGFALNEKGELTCAPEHAECTRDDQCPSNAACRDYKCVNPCLTSKEPICPKGKQCEVLDHRAMCLCVQDCNPSVSICRTDKGCPNNLACRDYQCKDPCNGACGGAPCTVEDHHPVCKFCPHGFTHDEKHGCIKAVECSDHEQCPSNMACMADRCADPCSQGGPCTPGQSCTVLNHQPVCSKVCQCQTSSDCVSYSNSVCDGCNCVLGDKPKTNCAHCRPGVPCDPFSGACMENDQPKNVPLTDVTSTTTSEDTETSTKDDSLNYLTYSTNIDDEQIDTTSSDLKLSTDYHNIITEKPSTLHIDDIATKSTLADDLSTTDSFDETYLTKSITRSGLNATADTNISLFNYTSTKFHTTDSLLTDIYDFQNVTEADQKSYATIPINTEKIYDSEKPAFTTQKYIDTTINEKTTIFSSLVKEPISKPLYLDKSDEPVQSSSTIHEESTLKPNVKQTTQVAEKPISIENKNTKTPENQRKLNGNYTNIADGYGPVSHSVNEKSATKMTTPLPKTKPTNPSEIPLTASEITINYYTTEGSSVESTLSEEITLTNQDTAATSMKTLTSGIEMDTGVNAEENNKSTNFYTSTIQYSTQNDMSDSHETVSTDFKVATTTSPTVHIIDNQSDQINYSEKNAYQTTKNAPSLNPTTTNYYHTVITMEEKWDSSENDLIETTTEAQLKQTNYEFKLTDTNDLNKQNDTTTIPTGGIVEFLTHKATKSDDTIVTISTEPYTIFNSNEETTHKPVQPLNKQKPTQFIKYETTTEFTQSSNDDIKQLSEYPKEQFNILNERITTGSSLASQTDAEGVEITSSLTTMSKSTISTLDIHETIPNLGLSTQSGSYEFTSSIPQVFSTTNSDVILDQDNLFLHPNIATINYKATDKNDNQETTSQYNDNENEFPLTSTVTYDNTGKSEPAESQHMHSSDINKVTNGNENNLLSTTYRDVTTSQYDSETEDSNSESQSMQSATTDQPINIQTNENENKLPSTTSITTSHYDSETEDSNSKSQSTQSATTDQLTSVQMNDNDNKLPSTVSVTTSRYDGETENSVSESQSGQSTNVNRATSMYANDNENNLPSTTSITRSHYDSETEDSNSELQITQSTTTTQATSIQPNDNENKLPSTTFITTSHDDSETEDSDSESQTTHSRTTNQATSMYANDNENKLPSTASVTTVHYGTETEDYNSESQTTQSTITNQATGIQTNDNVNKLPSTAYGTTSHYDSETEDSISESQSTQSTITNQASSIYANDNKNKLPSTASVTKSHYDSETEDSDSESQTTHRRTTNQATRMYANDNENKLPSTASPTTSYYDTETQDYNSESQSTHNVTTDQATSIYANENENKLPSTASIATSHYDSETEDFNLESQTPQSTITKQATNTYANDNENKLPSTASVTTSHYDSETEESDSESQTTHSRTTNQATSMYANDNENKLPSTASPTTSHYDTETQDYNSESQSTHSVTTDQATSIYANENENKLPSTASIATSHYESETEDSNLESQTPQSTITNQATNTYANDNENNLTSTASVNTSHYDSETDDSNSESKSTQRTITNQVTSIYANDNENKLPSTASVTTVHYDTETQDYNSESQTTQSTITNQATSIQTNDNENKLPSTASVTTVHYDTETQDYNSKSQTTQSTITNQATSIYANDNENNLPSTAFVTASHYDSETEDSNSESQTTQRTISNQVTNIHANDNENILASTASGTTSHYNSETEDSISESQTTQSTIANQATSIQTNDNENKLPSTASVTTVHYDTETQDYNSKSQTTQSTITNQATSIYANDNENNLPSTAFVTASHYDSETEDSNSESQTTQRTISNQVTNIHANDNENILASTASGTTSHYNSETEDSISESKSTQSTITNQATSTYANDNENKLLSTASVTASHYDSETDDSNSESQSTQSRNINRATTIYANENENNLPSTAFVTASHYDSETEDSISESQTPQSTITNQATSVQTNDNENILPSTASVTTVHYDTETQDYNSESKSTQSTITNQATSIQTNDNENKLPSTASVTTVHYDTETQDYNSESQSTQSTITNQATSIYANDNENNLPSTAFVTASHYDSETEDSNSESQTPQSTITNQATSVQTNDNENILPSTASVTTVHYDTETQDYNSESQSTQSTITNQATSIQTNDNENKLPSTASVTTVHYDSETDDSNSESQTPQSTITNQATSIYANDNENNLPSTAFVTASHYDSETEDSNSESQTTQRTISNQVTNIHANDNENILPSAASVTTVHYDTESQNSNSESQTTQVTITKQATSIQTNDNENKLPSTASITASYYDNETENSNLESQTPQNTITNQATSTYANDNENKLPSTASVTTVPYNNESDEFKTGSQSIHSTAANQHSSIQTNETRIPLTTPIVESYHNTEIKGSQRESHNTQSTDTTYTESYDSKYELPLTTAFTTLYYNSESDLSRTESLATQRIATGKDTNIESNQDHYQTTVDATESLSTENVVDSFTSTAVTNLATLIDENVNKFSESQHSTTILTAQDETTFKPYSEVDFTTVFHNIKTVENDFNADKDDDYLTQEISTTTEPSTIDYLNNPCDLPEMKCAQNTSCKVVNHAAVCVCDSAGNNCVRESSGTPKVPEPCHSDRDCIEIEACFMGLCQDPCEFDNVCGIQANCQRVKHRPMCSCPAGYDGDPAIKCSPKIFGCTRNDDCQSTEACINNACQHPCAIHNPCAPNAVCINTNHGSDCSCVEGFQGNGYVGCVPVVESTSVCQYNEDCPPELLCDRLNRKCINPCAINKCGDNAECLPSNHGIQCKCAPGFTGNAFLECYQVQGCRSDNECANSEACINGKCGSPCRCGINAVCDVINHRASCKCLQGYTGNPQIGCEPPTNPCSPNPCGINALCEIDNGNPICYCPKGLTGNPFKNCIPEGNECEPNPCGPNSGCRLIDDKPACFCLPNYEGSPPRMPCKLPNNPCNPSPCGPNTQCTVLSNGFSKCSCLPGYVESPNTVRGCIEARNPCEPSPCGVGARCDPNKTPSCFCPENTVGNPYKSCDSNRGYLPPVANVLCQPGPCGPNADCFVSSNREVCYCKTGFSGDPYLGCQNQISPCAPNACGPRAICQVKFDGQAFCVCPEGSVGDAYSIEGCILRECEVDDGCPTNKACIGYSCQDPCPGVCGLNTKCHVEAHRPVCFCEEGFIGNPLICCLPPEDQKSISPCNKIQCGINAICQEVGDRAVCSCPLDFIGDPTIECKPECMMNSDCSSNEACINKKCIDPCASANICGINAVCLCSDHTVSCLCPDGYIGDPLTQCIYKPIIIVPDNSTAQPCSPNPCDQNAPCDTYGNQFAICDACVGLNSLNNPSCRPECVLNSDCSFDKSCLRNKCLNPCPGSCGINAECTVYNHDPVCQCVNGFEGNPYEHCKPSVRPITHETCNNVQCGANAICRDFNGALACHCLPDFYGNPYISCRPQCVVNSDCSPELACFHNKCEDPCTNVCGIGALCKTVNHHAVCYCESGQIGDPYVRCQNAPALPPSLSVCDPSPCGPYSRCLVSSNGFAMCSCLPGHKGIAPMCQPECVSNADCQQMETCVNQRCINPCLGSCGVNADCVVVNHNPICTCSRGKSGDPFVACTDITEVVPSERNPCVPSPCGPNSVCEIKSNHPVCSCRPNYSGTPPYCRPECVISQECPSNKACINEKCLDPCTGACGNNAKCVVINHTPLCSCLDGYKGDAFVGCNAISNDDTETLCNPSPCGENTICNVINNIARCSCIPPNIGNPYAGGCRPECSLNSDCPNHLACLSNHCRDPCKDLCGVNAECIVTNHVPVCTCFRGHEGDPFIACNRQEQKPRNPESPCEPSPCGANSDCHIVSGRAACSCRPGYLGAPPACRPECAVNSDCPATRACINHKCKDPCINSCGIDARCHVVGHNPICTCPENLSEGDPFIKCTRKTIMPTHTDPCLMSPCGPYATCRNEDGRAICACEPGTLGAPPSCRPQCVINQDCPLALACLGGNCVNPCIGSCGFNARCSVQNHRPVCSCDDGFSGDPFAGCNPIEISKEAPRQPCHPSPCGANAICREKDGAGSCTCLDDFYGDPYSGCRPECLMNTDCAREKSCFNNRCIDPCSGTCGQNTQCRVVNHAPSCYCLSGFTGNPLHACVPVKPFPDNLDPCHPSPCGPYSKCRISNGHAVCTCLDMCIGSPPNCHPECIVSSDCRSDKACINQKCQDPCSGICGINAKCQVVNHNPICSCLSDYTGDPFVRCYIDDRQMTPINNCVPSPCGPNSQCKEVDGVAVCSCIENYVGRPPNCRPECVMNVECSGNLACIAERCSDPCPGSCGFHAICTVVNHVPTCTCDHGYTGDPFSGCSSIPSIEPQPQSLCSRSPCGANAICKERNGVGSCSCLPDYYGDPYIECRPECVLNSDCTKDKACINNKCKDPCPGVCGMNAECRVNNHAPSCACLPGYEGNPFSSCYISTFEDPVNPCVPSPCGPYSLCRENNGHAICSCQEHYFGSPPFCRPECMVSSDCMPNKACINKKCVDPCSGACGNNAKCTVVNHNPLCSCPKDYTGDPFVHCSYETRPEPKPSGNPCIPSPCGPHSQCRVIGETAACSCQLGFIGRAPNCRPECIFDEECPSNLACIREKCANPCEGSCGSNTNCVVINHKAVCHCRESYTGDPFSGCYFIVTVPSEEETNPCNPSPCGPNALCKERNSAGSCTCIPDYFGDPYLGCRPECVTNNDCTFDKACSNNKCVDPCQGACGINSQCTVAHHNPVCLCVDGYEGNPAVSCHPQRKPPLADTNPCIPSPCGPYSHCKVVDDHGVCSCQEGYIGSPPACRPECVTSTDCPQNQACIRQKCKDPCPGTCGTNARCLVINHNPICTCKPGFTGDPFNFCQLEQKPIIEGPKGNPCIPSPCGPYSQCKIIADAPACSCLPNYLGVAPNCRPECSINAECPGSLACQNEKCVDPCPGSCGFNAECSVANHVALCNCIPGYSGDPFSGCSLFQHIPEPPPNPCSPSPCGANAICKERNGVGSCTCLPEYFGDPYTGCRPECVSNSDCDRNKACSNNRCKDPCPGTCGINAECRTVNHSPTCSCLTGYTGDPLVKCDFETITEKNEPVQNPCKPSPCGPNSLCKVVNGHSVCTCDTGYIGTPPSCRPECLVSVECSQDKACIGKKCLDPCPNTCGLNARCQVINHNPVCSCTPGFTGDPFTKCNPEERMVQSNPCQPSPCGPNAECRVIGDQAACSCLPNYIGRVPNCRPECTIDAECPSNAACINERCKDPCERACGVNAMCLTVNHKPICSCQQGFTGDASISCDQLIISSTEMTPTSSPCTPSPCGPNAECREHNGAGACVCSEGYEGDPYSPQGCRRECESNDECAPNLACTRYKCIDPCPRTCGQLAQCIVENHAPVCSCPRGYTGDPFFQCKQILMDPSPPKNPCEPTPCGPNSQCRQVNMQAVCSCLPNYIGSPPSCRPQCVVNSECDTSKACINQKCDDPCPNTCGLRAHCLVKNHNPICTCPVGMTGDPFTQCYQIPPTTERPPTCTPSPCGPHSRCQLLASGPACSCLPGYVGSPPSCRPECTINSECPASLACVRQKCEDPCPGSCGVDANCHVLNHVAICVCNEGFTGDPFSRCLPISGTPTTPEPSDPCNPSPCGPNARCDNGFCTCLPDYSGNPYESCRPECTGSQECPRDKACFRNKCRDPCPGVCGLNAKCDVINHIPTCSCISDFTGNPFTHCNRIEGKQTDKPRDPCHPSPCGPNSVCKTVDNAAVCACLESFQGTPPACRPECIVSSECPSTKACVNQKCINPCINACGVSARCEVINHSPICSCSPEQTGDPFKSCYDVVNTPPEPIDACNPSPCGPNAQCIQRNEKANCRCLENYIGQPPNCRPECVINPDCPSNQACVRNKCIDPCPGSCGINADCVIVSHTVSCICREKYTGNPFMQCVPQEEIVTKPCDPSPCGANALCTQREGAGSCSCLEGYQGNPYEGCRPECVLSSDCPADKSCIRNKCADPCPGICGTNAECNVINHVPSCACLKGYSGNPFTQCSKDEPIEFSRPCQPSPCGPNSVCRENGGLASCECLPEYIGAPPDCRPECTVSNECPSDRACHKLKCADPCRGTCGIGAHCQVVNHSPLCSCPAGTSGDPFKRCFETVLYEPGQPVQPCQPNPCGPYSECRALNENPSCSCMQGYAGVPPNCHPECLVNTDCPSHQACIAEKCTNPCEGSCGFKAECRVQDHIPICSCPVGYSGDPFIQCSEVIITPTPSPEPCNPSPCGSNALCNAGLCTCAHGYFGDPYVGCRLECSTNGECSPTRTCQGGKCVDPCPGACGTNAICSINNHIPSCTCPPNTFGDPFTFCTEVVHQDTPTSACSPSPCGPYSECSVSANGAAACSCKSGHVGSPPSCRPECLVSAECKLQQACIDRRCRDPCEGACGRGARCQVIAHSPICTCNDGFTGDPFSYCYPAPATPPTPIDPCQPSPCGPNSMCVNSGETPACSCHPGFIGTPPNCRPECTISAECPATLACVGQKCKNPCEQACGPRALCSVVDHRATCACEPGLEGDPFQGCSPARAPPKIEYLNPCEPSPCGANAVCKIQGNAGSCTCLPEYFGDPYQGCRPECLTDSDCPLVSSCSRNKCINPCLGACGVNTECFVNNHKPMCNCKSGFTGNPMTICSALRENDVYIENVCNPSPCGNNAICKNINEQPVCSCLANFIGSPPNCRPECIVNSECKPSKACINQRCINPCPKPCGKNSECKVINHSPICSCRQGYSGNPFTMCNLVLQTLPSVVETSNPCSPSPCGPYSECRNNNGLASCSCLSTYIGSPPFCKPECVVNSDCPSNLGCISEKCRDPCEGSCGLFAKCFVNNHVPVCLCPEGFTGDPFSQCVEKPVKEITPTLQLDPCQPSPCGPNTECRNGVCSCINGYHGDPNLGCRPECVYNADCPSDKGCQKNKCINPCIGTCGVNAICDVMNHIPMCSCPKGMVGNAFVECRAVAVTATSPCSPSPCGPNSQCQQSNGQAVCSCVPGYKGSPPTCRPECVVSLECPLNQACNNQKCLNPCIGACGAGAVCDVINHNPICTCPPSFTGDPFVRCSVIVAVEPTVNPCEPSPCGPNSICKISGENPICACLQDYKGTPPNCRPECISNSECEYHLACQNKKCIDPCLGTCGSNAECRVVSHAPNCICQVGYTGDPFAYCSMLAVMDYTEILTPCSPSPCGANAICREQKGVGSCQCLDGYSGNPYEGCRPECVVNSDCPLNKACSRMKCVDPCPGVCGSNALCLVNNHMPTCICQPGYTGNPFGYCTIMQEPQVLETNPCNPTPCGANSQCKEINGQAVCSCLPSFSGSPPNCRPECVVSSECPPDLSCSSQKCINPCEGACGENARCNVINHSPICVCKQGLTGNPFTRCYPITGSKPPQNIPIQDPCISSPCGPYAECRNIEHAPSCACKLNYVGTPPNCRPECTINSECSSNQACINEKCRDPCLGACGINAQCSVFNHVAQCSCIEQHTGDPFTRCSPAIEQDEFSEPDPCNPSPCGGNAECNNGICTCLPDYQGDPYFGCRPECLLNNDCPQEKACVKKKCVDPCFNTCGTDAICNVYNHLPMCSCPNGFTGNAFLQCRPIKNIEEINPCSPSPCGPNSQCREVNGQAICSCFPGFFGAPPTCRPECISSAECALNKACSNQRCIDPCKGNCGTAAICQVINHNPICSCPQRFTGDPFSRCSVQEEEIPQYVNPCEPSPCGPNSICKEVGNSPSCACLETYLGHPPNCRPECIANSECPNSMACMNQKCKDPCPGSCGSNAECKVVSHAPQCICSPGYTGDPFIACLVQDIPLTPCQPSPCGPNAICKQQGNAGACVCLPEYLGNPYEGCRPECIVNSDCATNLACIQNKCKNPCNSACGLNAICNVINHSPKCECLPGLTGNPYQNCYEQSADTPSVTKNPCTPSRCGPNSICKINNEQAVCTCQQDFIGTPPSCKPECVVSSECSQQQACIKKKCRNPCEGVCGQNSECKVINHSPICTCRVHYTGDPFNGCSKIVAAEIIPLPTNPCLPSPCGPFAQCRDIGGSPSCSCLPLYIGQPPNCRPECTINTDCPSDKSCINERCIDPCPGSCGIYAECRVQNHVSICTCLEGYTGDPFNACILKPQKDPVPSDLCNPSPCGPNAICNDGICSCLPEFQGDPYFECRPECTISSECPMNKACVKNHCVDPCPNTCGTNAICQAINHMAVCTCPAGMSGNAFIQCNPIKEFSIVNPCQPSPCGANSQCRELNGQAICTCLPGYRGTAPYCRPECVASSECPSDKACSNQKCINPCQGTCGVAAQCQVIHHNPICTCSTGFTGDPFTRCTATPLELPTAPINPCQPSPCGPNSICQENGSQIPSCQCMPEYIGAPPNCRPECLANSECAPHLACINKKCQNPCEKACGTNAECRVVSHTAVCICPEGYSGDAAIQCSQNAVVPFETLSACEPSPCGANAECIERASAGACICRKGYIGNPYDGCHPECVVSSDCPSNKACTRNKCIDPCPGTCASNANCQVVNHSPLCTCKTGYIGDPFTACKLEPQLDLPVNPCQPSPCGPNSQCKVSNGLSICSCLPEYSGSPPNCRPECVVSAECPSEKTCRNKKCVSPCPDPCGQNTNCKVINHSPICSCQSGYTGDPFSRCYRVTITELPPQQQRDPCVPSPCGPNSYCQDLRGIPSCSCLPNFEGNPPNCRPECTINEDCASNLACINQKCKDPCPGSCGINANCQTQNHIAICSCIESFTGDAFTQCKPIPFIEESDPCNPSPCGINAECSNGKCTCFEEYQGDPYTGCRPECLESSECERDKACIKNKCKDPCPGTCASNAECNVINHIPMCSCPERMTGNAFVECRPIIEAVITNPCEPSPCGPNSRCRDVNNQAVCSCAPNNIGSPPSCRPECTISSECPLNQACSNQRCVDPCIGSCGVNAECKVVNHNPICSCPTFYTGDPFSRCMRQPERLPEPTNPCAPSPCGPNSVCREVNGAPSCICLEGFKGQPPYCKPECSSNEECSPHLSCIRNKCKNPCENVCAVNAECKVVSHSPVCVCQYGFTGDPFFECIQEPLYTEPITSPCSPSPCGANAICKERDNAGSCSCIDGYMGNPYEGCRPECVVNTDCPSNRACVNYKCNDPCPGSCGTNAECQTVNHVPLCTCINGYTGDPFRYCVYQDSPVLAPVDVCNPSPCGPNSQCRTINGQAVCSCLIEYVGSPPNCRPECIVSSECSHDKACVNNKCVNPCPKPCGVNADCKMINHSPICSCKNAYTGDPFTVCTAIKHEPVPDTSDPCVPSPCGPYSQCRNIGNNPSCSCLPTYTGSPPNCRPECIIHSDCPGDRACIGSKCLDPCPGSCGISATCNVQNHIPICTCIEGYIGDPFTDCKPKPLEVEPSVTDACTNIRCGSNAECINGQCQCFPEYHGDPYFSCRPECVFSSDCDETKACILKKCVDPCIGACGQNAICQVFNHIPMCSCNNGFTGNAFVRCNAVREPTIKHPCSTAVCGPNSQCREVHDQAVCSCLPSYLGTPPACRPECVVNAECPQNQACMKQKCINPCAGTCGSRASCDVINHNPICTCPAGYSGDPFVECKVLYNTPPVVIDPCQPSPCGPNSICEVKNNNPSCTCKEEYNGQPPYCKPECISNSECAPHLACIKQKCRDPCIKACGTNAECRVVSHSAMCICPQGYLGDPFIQCSVKIEDEILPPCSPSPCGPNAICREHHNIGACICNDGYFGNPYEGCRPECISNSDCPGDRACIGNKCQDPCPGTCGINSECTTVYHSPTCTCIQGYTGDALRRCNPILPQENIQENLCIPNPCGAHSQCREINDCNSNKACVNHKCINPCPGPCGEKAECKVFNHNPICSCHSGFTGDPFTRCYPKPVIQTIYEERNDPCVPSPCGPLSICRNVGDQPSCSCAPGYIGSPPNCRPECVTNQECQSSLACINEKCKDPCPGSCGQNAKCSVIEHVSICTCLEGYKGDPFTSCAPQPIQDLVPADLCNPSPCGSNAECNNGECSCLPDYRGDPYLGCRPECTISSDCQKNQICAKKKCFNPCPDTCGQNAICEVINHVPMCSCPAGFTGNSFVTCNAIQVPIAINPCNPSPCGPNSQCKEIKNVAVCSCIPGFSGNPPTCRPECTTSAECSLDKACNNYKCINPCNGACGIGAFCQVVNHNPICSCPNEYTGDPFTRCVLKPAEIQPQVNPCSPSPCGPNSICQNNNDSPSCSCLPEYTGVPPNCRPECTSNSECGNHLACINNKCGDPCVGACGQNAECRVVSHTPNCVCPSGFIGDPFIQCSIQQILHENITPCVPSPCGSNALCKERNNAGSCVCLPGYFGNPYEGCRPECIVNTDCPSNRICQQNKCQDPCPGTCAANAQCNTVNHAPICTCLPGFTGNPFQSCLIIQNIEIETNPCSPNPCGPNSICKEVNEQAVCTCLADYRGAPPNCRPECVVSAECPTNKACVSLKCQDPCIGQCGLNTKCQVINHSPICSCIERFTGDPFSRCFALVSSPPTHEEQPKNPCLPSPCGPFSECRDIGGISSCICLPNYIGAPPNCRPECTINADCPSNLACMNQRCKDPCPGSCGLNAQCFVKKHMPICTCLDNYEGDAFTECKLQEQINDEIDLCNPSPCGPNAICNNGECTCLPEYQGDPFFECRPECVLNSDCPQDKACQKNKCTNPCLSNACAANAICEVFNHVAMCRCPERMTGNAFVLCSHLEVVKPQPCQPSPCGPNSQCREINGQAICACFIGFVGSPPSCRPECTVSTDCSPNEACSNQKCINPCQGTCGVNAQCQVINHNPICSCPSSLTGNPFVRCFVQEFKPEYSDPCTPSPCGPNSMCQEISGAPSCSCLDEYIGKPPYCKPECISNTECPLHLACINQKCKDPCPGSCGLNTQCHVVSHSPTCSCDLEYTGNPFIECHRIQIISEATTPCQPSPCGANTICKEFNGAGSCVCLEEYFGNPYEGCKPECIINTDCPSNKACLQNKCQDPCPSACAPNAVCQVVNHNPSCSCERGYTGDPFRYCTPEQILETPINVCQPSPCGPNSRCQEVNKQAVCSCLPNYVGSPPGCHPECVTNGECPRDMACINQKCGNPCLDACGINAECRVINHNPICQCTMHYTGDPFTRCNPIPPPVANADLEPYRNPCVPSPCGPNSICHEIGNIPSCACMDNYIGNPPNCRPECIVNSECPTSLACIQQKCKDPCKGSCGLGAICTVSRHTPICVCPDGYIGDAFTICQPKPPEADIVDKCNPSPCGSNAICSDGVCSCIEEHQGDPYIGCRPECVLSTDCPRDKACVKNKCINPCVDTCASNAICDVINHTPMCSCPQGMTGNAFYSCDFIKVPVVTNPCLPSPCGPNSQCREINGQAVCTCIQGYIGSPPLCRPECVVSSDCPSDKACSNQKCINPCDGSCGIEAKCMVVKHNPICTCPNKYTGDPFTRCVPFRVPTADVTPCTPSPCGQNSICKEVSGTPSCMCMPDFFGTPPYCKPECTSNNECPVNKACINQKCADPCTSACGLNALCRTISHTPTCFCDNGYTGDPFTRCFIEEILYEHSSPCEPSPCGPNALCKEHNSAGSCVCLPDYIGNPYEGCRPECTINTDCEPSKSCIRNKCQDPCPGTCGALATCAVVNHLPTCSCLEGYTGDPYRRCDIMQVPTAISITPCVPNPCGPNSICHTVNNQSACSCMPEYVGSPPGCRPECTVSSECPQNRACINLKCADPCPSHCGINSQCKVINHSPICTCKLGFLGDPFTRCYPQPEDIPVTKNPCLPNPCGDNAICREINGSPSCACIPNFLGIPPNCRPECAINEDCPSDKACFNMKCGDPCPGSCGQNAECSVFNHVPSCACIQGYTGNPFSACFLMKPIQDEIPKDPCYPSPCGFNAQCNDGICTCLEEYFGDPYLGCKPECVINSDCPLNKVCSKNKCMNPCPGTCAPTAQCSVYNHIPICTCPDGTTGNAFVECHTIQVVHEEPCNPSPCGPSSQCRSVNNQAVCSCLPSFIGTPPSCRPECIISAECPRNEACNNHKCINPCQGSCGYGAKCEVVNHNPICSCPPQYTGDPFTNCQPIVTAQLPPVDPCTPSPCGPYSICKVIAESPSCTCQPDFSGTPPNCRPECVSNSECPSSQACINQKCKDPCPGSCGYNADCKVISHALVCSCPNGQTGDPLISCSPIRETFIEYSTPCEPSPCGLNAECTQKDNAGSCKCIDGYMGNPYEGCRPECVINSDCAPMLACIQNKCKNPCPGVCAPNAICQVVNHLPSCHCPPGLAGNAYQYCVTKVEDVKPTPCSPSPCGPNSECREVNSQAVCSCQADFMGTPPNCRPECTINSECSVVKSCINRKCVDPCIGQCGRNANCRVISHNPICSCQDRFTGDPFTNCVPIAISSLETYPEVNPCIPSPCGPNSICQEVNGNARCTCVPNYKGSPPRCRPECTINSECNAATACINNMCLDPCPGACGNNAQCIVNNHLPICSCLPGYTGNPFSSCFLKQEEHVDLCSPSPCGSNAICEDGLCTCIPEYHGDPYFGCKPECVLNSDCARDKACINSKCKDPCIGTCGTDAICETINHIPMCSCPSGFTGSPFSYCTQILELPTPVNLCVPSPCGPNSQCRELNGHAVCVCVSGYLGSPPNCRPECILSSDCKLNEACSNQKCIDPCPGACGRNTKCIVVNHNPICTCSPGFSGDPFSSCQIIPATPPAKVTPCLPSPCGPNSECTENGENAECKCLLEYIGSPPNCRPECTSNTECSQNMACINRKCQNPCAGACGINAECRVVSHTPICLCENGYSGDPFLSCNIIVSSAVVERPTPCIPSPCGVNAECRERNGVGSCICLPDYFGNPYEACKPECIQNSDCPSNLACYNNKCKDPCPGTCGINAQCNVVNHNPSCSCIEKYHGDPYKMCAFKAESEILDPCEPSPCGPNSQCKSQNGLAICTCMLGYQGTPPSCRPECITSSECSLDKVYALCNVVKHVPVCSCPSGYEGDPFSICHIKLPELPQSVDPCQPTPCGPNAVCHNGVCSCLPEYQGDPYFGCRPECVLSTDCPLDKACFRSKCVDPCRDMCGVNAECNVYNHVAICSCPMGHTGDAFTHCKIIEKPANKPCEPSPCGPNSVCREVNGQAICACIESFIGNPPNCRPECIQSTDCSPSKACINRKCQDPCPGSCGRNAICIVNKHNPICSCPAKYTGSPFTYCYVQLEEEPQSNPCVPSPCGPNSLCKPTADGKSYVCTCQPSFEGTPPLCRRECTTSDDCSSDKACINYKCSDPCPGSCGLNTLCVVRLHTPMCSCENGYTGDPFLSCYLMQPAHEPVDPCNPSPCGANAQCKETRSGAVACICETGYFGNPYESCRPECVVNTDCPFNKACLRNKCDDPCPGVCGSTANCEVINHVPSCTCAPGYTGNPYTYCHIIINEPVPKPKNPCLPNLCGSNTICNYSNGQVSCSCMPEFYGSPPNCRPECTVNAECDKSKSCIRQKCIDPCIGVCGQNAECRVINHAPICSCSLGFEGDPFIRCMEKEKTPTPITNPCIPSPCGSNSICQAVNEIPMCSCVEKYIGSPPNCRAECVINSDCPSTEACINQKCRDPCPGSCGLYTECHVYQHSAICSCNEGYTGNPFQSCQIKQNIEPVPSTYDNCNPNPCGANADCNDGVCKCRNNYFGNPYLSCRPECTHSSECAKSLTCINNKCTNPCINICGENALCEVYNHMPMCSCPPNTTGNAFFSCTPIKVIQDTNPCQPSPCGPNSVCRALSGQVMCSCITGYIGTPPSCRPECLVDSDCTILLSCSNQKCVDPCQGSCGMNAECRVHNHKPICYCRNGLTGDPFSYCRVIQKEPPKTAPCEPSPCGPNSVCKSNGEEPQCLCQTGFIGSPPYCRPECISNSECSFNKACINNKCDDPCLGACGPNAECRVISHSPQCTCQSGYEGDAFNLCHPKRDHEPVTPSEPCVPNPCGPNAICQERYNIGSCTCANGFFGDPYEGCRPECIVNSDCAESRACINKKCQDPCPGLCGVNAQCQTTNHVPSCTCIHGYVGNAYESCILREEKPTNPCSPSPCGAYSTCKTISNQAVCTCLPDYVGNPPSCRPECIISSECPLNKACVRKKCVDPCIGTCGENSECRVHQHSPYCTCLPGYEGDPFIRCSKEILSTPPVASPCEPSPCGPFATCRDINDSPICSCKPGYIGAPPRCAPECTINEDCPNNKACVREKCVDPCLGSCGTHTDCRAMNHVAICTCLSGYRGDPFIGCSYQDIQPPVSFDACIQSPCGINAACDNGTCTCISDYHGNPYIECRPECTSDNDCQKQLACVNYKCINPCKNACGINAVCNVYNHIAICECPTPLQGDAFISCHHAIEPSISDPCTPNPCGPNSICRAEGIVAHCSCRPPMFEDPPSCRPECRVDSECPPNRACRNNRCRDPCPGSCGASAICHIRSHSPICVCPANYVGDPFIHCLPAIEAEPSTQAPQSCTNCGPNSDCINGLCSCKSGYVGAPPYCRHECLSSSDCEWHLMCLNLRCVDPCRGACGQGALCESLAHEPHCTCPSSTTGNPFFECRPIVTTQKTPNDPCNPSPCGPGALCSARGASASCECEPGLFGDPYSGCRPECVSDSDCSPSRACMRSHCRDPCQGTCGIGADCETVNHIPLCSCPTGTRGNAFEKCEKIITAPPCNPSPCGPGAVCTTSGSSAICSCPSGTYGDAKSTGCRPECVVSSECPRDRACVRNKCIDPCIGTCGNGAMCRVFDHAPICSCPPTTTGNPFTECTLKDVTPPTFDPCDPNPCGIHGTCRDGQCIYPECIVNDDCPGDRACINRKCADPCVNACGINAICTGIRHTAPTPPTPECVNDNQCADDAACVDSRCSPVCGSNNCGINARCLAKQHRARCTCLPGYEGDAYTGCYSVQCHSNNDCPEDESCEGASCVKVCSRVRCGIEARCVARGHTASCECNPSARGDPWTECHIAECNANEDCPLWLACKANKCKDPCPGACAPGAVCTVLRHQPTCECPRGTNGNPKIECRQVANEEECQYDAECGPGLACLQGNCKNPCEPTSCGTRAVCRVANTLPFRTLVCECPKPLTGDASLQCNPRGECTSNDDCSSEESCINKRCVNVCSNGACGVGAECRAQSHRANCVCVPPLQGDPRVACMPSTPTAECVVDSDCGSAEACVSRRCVSACIGACGTGALCDAAQHRARCHCPPGTAGDPARICYTPECTSDDNCPFDKTCFNGYCKDPCGVGSPCGRDASCEVVAHVATCRCPPGTQGDPRRACISAACHYNEDCDDSQLCNRLNRVCQSACTDNSCAPGASCTGENHRPTCKCIPGYIGDPYQRGCTFAQDTTECTTDADCSAPLACVDARCIDLCLNNPCDSGLICRTVDVLPLRAVACVCPDGGRAAPDSGCRTPPEVECSVDSDCASSQMCFRGSCVEACKADPCGQNALCDSIDHASRCVCPPGYNGNPRFECNTVPQEPIVWECYEDNECGPERACIKRSCVNPCIDGCGIGALCRVIDHKPQCSCPNGFSGDAYIRCLPPSEKSFIPLGCKANSECPLSQACINGACADPCACGAQADCSIVRHHPVCYCKQGYSGNPYIGCTKVGCDSDSECSDSDLCYNGACLNPCLIDTPCAISAECYGVNHRASCRCPSGTVGNPFTRCIAAECETDNDCNDDSVCAKGTCYNACSVNGISSCADNAECFSRNHAASCRCPPAFPIGDPSVHCQKATVLNEPECIMDGDCPSGHACLKDECREACSELKPCKGNSRCSVSDSIPFRTLICRCPEGFVPSEDGSCKPANLPPLGCSSDNDCTDQESCVNRNCRNPCNCGDNADCFVKDHRPICSCRNGYEGDPYRTCRVVGCRTNSECDTREACINGNCINPCLTNSTCGPNAECFVQKNQPLCRCRVGFEGDAYLGCNAIECRSNGDCPRDKQCKAHRCINPCFIDNICGTHSNCLVRNHLAVCKCDQGYGGNPYIECKPQFAQECYVDADCPSRAACLSSRCVNPCTTLKPCANPATCEVSPTLPVRTMLCTCPPGFVSNGGGICRPVIEFFESTCEIDSNCTSNHACISSVCKNPCDCGPNTDCIMKDHKPVCACRQGFIGDASSGCYEIQCQSDSHCADDETCINRRCVPACSVNANTCGQSAECYGLEHRASCRCKIGTVGNPSIACTPIGCRTDTDCPSDKSCINSKCDTPCNADICQEPAQCKVHLHQAHCACPPGFTNTGKECRKTEGPQCISDIDCPSGTGCLNYRCVNPCLVSNPCSENAQCKIVDTMPVKTMVCECLPGYKGNALQECKPYQTVAKCIEGQGLDLYGECIPCRPAEGRIIDSRGRCVCDSERGFIIQGDKCVAGGCRTDDNCADNSRCIRGQCVDACKAEPCGINATCDAVGHRSHCTCIAGYTGNPRIQCNATTTMYRTDFPTPDIQVECLADGVRVRLKIKDFNGLLYVKSYSKDERCRKVVEMPKDEESFVFFTVHFGDCGLVHVNGLASFVLVMQTHLKLVTSTTKAFHIKCIYKTGEQNVTLAFNVSMLTTAGTIANTGPPPTCSMRIISRSGDQVSSAEIGENLVLQVDVQPSSIYGGFARSCVAKTSEVSTNVENEYLVTDEDGCAKDPAIFGEWERSEDGSALRAAFNAFKFPSSDNIRFQCNIRVCFGKCVPVNCRGSDAYGKRRKREVTDESTALTMPVGQLREEVTVESNQILTTQRREPSQVARQRDGTGAEGASQSSGEVCVSAAGLAVALALTALLALVAVAAAVACWLVAWRRARPPPAPLPHPPDFPNPLFQR
Summary
Description
Fibrillin-1: Structural component of the 10-12 nm diameter microfibrils of the extracellular matrix, which conveys both structural and regulatory properties to load-bearing connective tissues. Fibrillin-1-containing microfibrils provide long-term force bearing structural support. In tissues such as the lung, blood vessels and skin, microfibrils form the periphery of the elastic fiber, acting as a scaffold for the deposition of elastin. In addition, microfibrils can occur as elastin-independent networks in tissues such as the ciliary zonule, tendon, cornea and glomerulus where they provide tensile strength and have anchoring roles. Fibrillin-1 also plays a key role in tissue homeostasis through specific interactions with growth factors, such as the bone morphogenetic proteins (BMPs), growth and differentiation factors (GDFs) and latent transforming growth factor-beta-binding proteins (LTBPs), cell-surface integrins and other extracellular matrix protein and proteoglycan components. Regulates osteoblast maturation by controlling TGF-beta bioavailability and calibrating TGF-beta and BMP levels, respectively. Negatively regulates osteoclastogenesis by binding and sequestering an osteoclast differentiation and activation factor TNFSF11. This leads to disruption of TNFSF11-induced Ca(2+) signaling and impairment of TNFSF11-mediated nuclear translocation and activation of transcription factor NFATC1 which regulates genes important for osteoclast differentiation and function. Mediates cell adhesion via its binding to cell surface receptors integrins ITGAV:ITGB3 and ITGA5:ITGB1. Binds heparin and this interaction plays an important role in the assembly of microfibrils.
Asprosin: Hormone that targets the liver to increase plasma glucose levels. Secreted by white adipose tissue and circulates in the plasma. Acts in response to fasting and promotes blood glucose elevation by binding to the surface of hepatocytes. Promotes hepatocyte glucose release by activating the protein kinase A activity in the liver, resulting in rapid glucose release into the circulation.
Fibrillin-2: Fibrillins are structural components of 10-12 nm extracellular calcium-binding microfibrils, which occur either in association with elastin or in elastin-free bundles. Fibrillin-2-containing microfibrils regulate the early process of elastic fiber assembly. Regulates osteoblast maturation by controlling TGF-beta bioavailability and calibrating TGF-beta and BMP levels, respectively.
Fibrillin-2: Fibrillins are structural components of 10-12 nm extracellular calcium-binding microfibrils, which occur either in association with elastin or in elastin-free bundles. Fibrillin-2-containing microfibrils regulate the early process of elastic fiber assembly. Regulates osteoblast maturation by controlling TGF-beta bioavailability and calibrating TGF-beta and BMP levels, respectively (PubMed:20855508).
Fibrillin-1: Structural component of the 10-12 nm diameter microfibrils of the extracellular matrix, which conveys both structural and regulatory properties to load-bearing connective tissues (PubMed:1860873, PubMed:15062093). Fibrillin-1-containing microfibrils provide long-term force bearing structural support. In tissues such as the lung, blood vessels and skin, microfibrils form the periphery of the elastic fiber, acting as a scaffold for the deposition of elastin. In addition, microfibrils can occur as elastin-independent networks in tissues such as the ciliary zonule, tendon, cornea and glomerulus where they provide tensile strength and have anchoring roles. Fibrillin-1 also plays a key role in tissue homeostasis through specific interactions with growth factors, such as the bone morphogenetic proteins (BMPs), growth and differentiation factors (GDFs) and latent transforming growth factor-beta-binding proteins (LTBPs), cell-surface integrins and other extracellular matrix protein and proteoglycan components (PubMed:27026396). Regulates osteoblast maturation by controlling TGF-beta bioavailability and calibrating TGF-beta and BMP levels, respectively (By similarity). Negatively regulates osteoclastogenesis by binding and sequestering an osteoclast differentiation and activation factor TNFSF11. This leads to disruption of TNFSF11-induced Ca(2+) signaling and impairment of TNFSF11-mediated nuclear translocation and activation of transcription factor NFATC1 which regulates genes important for osteoclast differentiation and function (PubMed:24039232). Mediates cell adhesion via its binding to cell surface receptors integrins ITGAV:ITGB3 and ITGA5:ITGB1 (PubMed:12807887, PubMed:17158881). Binds heparin and this interaction has an important role in the assembly of microfibrils (PubMed:11461921).
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs. Involved in angiogenesis; negatively regulates endothelial cell proliferation and migration and angiogenic sprouting. Involved in the maturation of both CD4(+) and CD8(+) cells in the thymus. Important for follicular differentiation and possibly cell fate selection within the follicle. During cerebellar development, functions as a receptor for neuronal DNER and is involved in the differentiation of Bergmann glia. Represses neuronal and myogenic differentiation. May play an essential role in postimplantation development, probably in some aspect of cell specification and/or differentiation. May be involved in mesoderm development, somite formation and neurogenesis. Involved in determination of left/right symmetry by modulating the balance between motile and immotile (sensory) cilia at the left-right organiser (LRO) (By similarity).
Essential signaling protein which has a major role in many developmental processes (PubMed:3935325). Functions as a receptor for membrane-bound ligands Delta and Serrate to regulate cell-fate determination (PubMed:10935637, PubMed:15620650, PubMed:12909620, PubMed:18243100). Upon ligand activation, and releasing from the cell membrane, the Notch intracellular domain (NICD) forms a transcriptional activator complex with Su(H) (Suppressor of hairless) and activates genes of the E(spl) complex (PubMed:7671825). Regulates oogenesis, the differentiation of the ectoderm and the development of the central and peripheral nervous system, eye, wing disk, muscles and segmental appendages such as antennae and legs, through lateral inhibition or induction (PubMed:11719214, PubMed:12369105, PubMed:3935325). Regulates neuroblast self-renewal, identity and proliferation through the regulation of bHLH-O proteins; in larval brains, involved in the maintenance of type II neuroblast self-renewal and identity by suppressing erm expression together with pnt; might also regulate dpn expression through the activation of the transcriptional regulator Su(H) (PubMed:27151950, PubMed:28899667, PubMed:20152183, PubMed:18342578, PubMed:23056424, PubMed:21262215).
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus (PubMed:21378985, PubMed:21378989). Affects the implementation of differentiation, proliferation and apoptotic programs (By similarity). Involved in bone remodeling and homeostasis. In collaboration with RELA/p65 enhances NFATc1 promoter activity and positively regulates RANKL-induced osteoclast differentiation (PubMed:29149593). Positively regulates self-renewal of liver cancer cells (PubMed:25985737).
Functions as a receptor for membrane-bound ligands Jagged1, Jagged2 and Delta1 to regulate cell-fate determination (PubMed:15350543). Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs (By similarity).
Functions as a receptor for membrane-bound ligands Jagged1, Jagged2 and Delta1 to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs (By similarity). May play a role during CNS development.
May play an integral structural role in elastic-fiber architectural organization and/or assembly.
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination (PubMed:10393120). Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus (PubMed:10393120, PubMed:18710934). Affects the implementation of differentiation, proliferation and apoptotic programs (PubMed:10393120, PubMed:18710934). May play an essential role in postimplantation development, probably in some aspect of cell specification and/or differentiation (By similarity). In collaboration with RELA/p65 enhances NFATc1 promoter activity and positively regulates RANKL-induced osteoclast differentiation (PubMed:18710934). Positively regulates self-renewal of liver cancer cells (By similarity).
Fibrillin-1: Structural component of the 10-12 nm diameter microfibrils of the extracellular matrix, which conveys both structural and regulatory properties to load-bearing connective tissues. Fibrillin-1-containing microfibrils provide long-term force bearing structural support. In tissues such as the lung, blood vessels and skin, microfibrils form the periphery of the elastic fiber, acting as a scaffold for the deposition of elastin. In addition, microfibrils can occur as elastin-independent networks in tissues such as the ciliary zonule, tendon, cornea and glomerulus where they provide tensile strength and have anchoring roles. Fibrillin-1 also plays a key role in tissue homeostasis through specific interactions with growth factors, such as the bone morphogenetic proteins (BMPs), growth and differentiation factors (GDFs) and latent transforming growth factor-beta-binding proteins (LTBPs), cell-surface integrins and other extracellular matrix protein and proteoglycan components (By similarity). Regulates osteoblast maturation by controlling TGF-beta bioavailability and calibrating TGF-beta and BMP levels, respectively (PubMed:20855508). Negatively regulates osteoclastogenesis by binding and sequestering an osteoclast differentiation and activation factor TNFSF11. This leads to disruption of TNFSF11-induced Ca(2+) signaling and impairment of TNFSF11-mediated nuclear translocation and activation of transcription factor NFATC1 which regulates genes important for osteoclast differentiation and function (PubMed:24039232). Mediates cell adhesion via its binding to cell surface receptors integrins ITGAV:ITGB3 and ITGA5:ITGB1. Binds heparin and this interaction plays an important role in the assembly of microfibrils (By similarity).
Functions as a receptor for membrane-bound ligands Jagged1, Jagged2 and Delta1 to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs (By similarity). Acts instructively to control the cell fate determination of CNS multipotent progenitor cells, resulting in astroglial induction and neuron/oligodendrocyte suppression.
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs. Involved in angiogenesis; negatively regulates endothelial cell proliferation and migration and angiogenic sprouting. Involved in the maturation of both CD4(+) and CD8(+) cells in the thymus. Important for follicular differentiation and possibly cell fate selection within the follicle. During cerebellar development, functions as a receptor for neuronal DNER and is involved in the differentiation of Bergmann glia. Represses neuronal and myogenic differentiation. May play an essential role in postimplantation development, probably in some aspect of cell specification and/or differentiation. May be involved in mesoderm development, somite formation and neurogenesis (By similarity). Involved in determination of left/right symmetry by modulating the balance between motile and immotile (sensory) cilia at the left-right organiser (LRO).
Fibrillin-3: Fibrillins are structural components of 10-12 nm extracellular calcium-binding microfibrils, which occur either in association with elastin or in elastin-free bundles. Fibrillin-containing microfibrils provide long-term force bearing structural support.
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs. Involved in angiogenesis; negatively regulates endothelial cell proliferation and migration and angiogenic sprouting. Involved in the maturation of both CD4(+) and CD8(+) cells in the thymus. Important for follicular differentiation and possibly cell fate selection within the follicle. During cerebellar development, functions as a receptor for neuronal DNER and is involved in the differentiation of Bergmann glia. Represses neuronal and myogenic differentiation. May play an essential role in postimplantation development, probably in some aspect of cell specification and/or differentiation. May be involved in mesoderm development, somite formation and neurogenesis (By similarity). Involved in determination of left/right symmetry by modulating the balance between motile and immotile (sensory) cilia at the left-right organiser (LRO) (By similarity).
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs (By similarity). Involved in bone remodeling and homeostasis. In collaboration with RELA/p65 enhances NFATc1 promoter activity and positively regulates RANKL-induced osteoclast differentiation. Positively regulates self-renewal of liver cancer cells (By similarity).
Required to maintain the integrity of photoreceptor cells (PubMed:27737822, PubMed:28378834, PubMed:30052645). Specifically required for normal morphology of the photoreceptor ciliary pocket, and might thus facilitate protein trafficking between the photoreceptor inner and outer segments via the transition zone (PubMed:27737822).
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs. Involved in angiogenesis; negatively regulates endothelial cell proliferation and migration and angiogenic sprouting. Involved in the maturation of both CD4(+) and CD8(+) cells in the thymus. Important for follicular differentiation and possibly cell fate selection within the follicle. During cerebellar development, functions as a receptor for neuronal DNER and is involved in the differentiation of Bergmann glia. Represses neuronal and myogenic differentiation. May play an essential role in postimplantation development, probably in some aspect of cell specification and/or differentiation. May be involved in mesoderm development, somite formation and neurogenesis. May enhance HIF1A function by sequestering HIF1AN away from HIF1A (By similarity). Required for the THBS4 function in regulating protective astrogenesis from the subventricular zone (SVZ) niche after injury. Involved in determination of left/right symmetry by modulating the balance between motile and immotile (sensory) cilia at the left-right organiser (LRO) (By similarity).
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs. Involved in angiogenesis; negatively regulates endothelial cell proliferation and migration and angiogenic sprouting. Involved in the maturation of both CD4(+) and CD8(+) cells in the thymus. Important for follicular differentiation and possibly cell fate selection within the follicle. During cerebellar development, functions as a receptor for neuronal DNER and is involved in the differentiation of Bergmann glia. Represses neuronal and myogenic differentiation. May play an essential role in postimplantation development, probably in some aspect of cell specification and/or differentiation. May be involved in mesoderm development, somite formation and neurogenesis. May enhance HIF1A function by sequestering HIF1AN away from HIF1A. Required for the THBS4 function in regulating protective astrogenesis from the subventricular zone (SVZ) niche after injury. Involved in determination of left/right symmetry by modulating the balance between motile and immotile (sensory) cilia at the left-right organiser (LRO).
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination (By similarity). Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus (By similarity). Affects the implementation of differentiation, proliferation and apoptotic programs (By similarity). Involved in angiogenesis; negatively regulates endothelial cell proliferation and migration and angiogenic sprouting (By similarity). Involved in the maturation of both CD4(+) and CD8(+) cells in the thymus (By similarity). Important for follicular differentiation and possibly cell fate selection within the follicle (By similarity). During cerebellar development, functions as a receptor for neuronal DNER and is involved in the differentiation of Bergmann glia (PubMed:11182080). Represses neuronal and myogenic differentiation (By similarity). May play an essential role in postimplantation development, probably in some aspect of cell specification and/or differentiation (By similarity). May be involved in mesoderm development, somite formation and neurogenesis (By similarity). May enhance HIF1A function by sequestering HIF1AN away from HIF1A (By similarity). Required for the THBS4 function in regulating protective astrogenesis from the subventricular zone (SVZ) niche after injury (By similarity). Involved in determination of left/right symmetry by modulating the balance between motile and immotile (sensory) cilia at the left-right organiser (LRO) (By similarity).
Key regulator of transforming growth factor beta (TGFB1, TGFB2 and TGFB3) that controls TGF-beta activation by maintaining it in a latent state during storage in extracellular space. Associates specifically via disulfide bonds with the Latency-associated peptide (LAP), which is the regulatory chain of TGF-beta, and regulates integrin-dependent activation of TGF-beta.
Key regulator of transforming growth factor beta (TGFB1, TGFB2 and TGFB3) that controls TGF-beta activation by maintaining it in a latent state during storage in extracellular space (PubMed:2022183, PubMed:8617200, PubMed:8939931). Associates specifically via disulfide bonds with the Latency-associated peptide (LAP), which is the regulatory chain of TGF-beta, and regulates integrin-dependent activation of TGF-beta (PubMed:8617200, PubMed:8939931, PubMed:15184403). Outcompeted by LRRC32/GARP for binding to LAP regulatory chain of TGF-beta (PubMed:22278742).
Functions as a receptor for membrane-bound ligands Jagged1, Jagged2 and Delta1 to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs (By similarity). May regulate branching morphogenesis in the developing vascular system.
Functions as a receptor for membrane-bound ligands Jagged1, Jagged2 and Delta1 to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs. May regulate branching morphogenesis in the developing vascular system (By similarity).
Key regulator of transforming growth factor beta (TGFB1, TGFB2 and TGFB3) that controls TGF-beta activation by maintaining it in a latent state during storage in extracellular space. Associates specifically via disulfide bonds with the Latency-associated peptide (LAP), which is the regulatory chain of TGF-beta, and regulates integrin-dependent activation of TGF-beta. Outcompeted by LRRC32/GARP for binding to LAP regulatory chain of TGF-beta.
Key regulator of transforming growth factor beta (TGFB1, TGFB2 and TGFB3) that controls TGF-beta activation by maintaining it in a latent state during storage in extracellular space (PubMed:7593177). Associates specifically via disulfide bonds with the Latency-associated peptide (LAP), which is the regulatory chain of TGF-beta, and regulates integrin-dependent activation of TGF-beta (By similarity). Outcompeted by LRRC32/GARP for binding to LAP regulatory chain of TGF-beta (By similarity).
Its binding to fibronectin and some other ligands is calcium dependent. May act as an adapter that mediates the interaction between FBN1 and ELN.
Involved in cell adhesion and required for organ positioning and attachment (PubMed:25917920, PubMed:11470827, PubMed:11470828). At the hypodermal surface, required for attachment of the hypdermermis to the basal cuticle in postembryonic development, possibly through intermediate filaments of the cytoskeleton (PubMed:11470828).
Orphan receptor involved in cell adhesion and probably in cell-cell interactions specifically involving cells of the immune system. May play a role in regulatory T-cells (Treg) development.
Orphan receptor involved in cell adhesion and probably in cell-cell interactions involved specifically cells of the immune system. May play a role in regulatory T-cells (Treg) development.
Ligand for multiple Notch receptors and involved in the mediation of Notch signaling (By similarity). Seems to be involved in cell-fate decisions.
Its binding to fibronectin and some other ligands is calcium dependent. May act as an adapter that mediates the interaction between FBN1 and ELN (PubMed:17255108).
Ligand for Notch receptors and involved in the mediation of Notch signaling (By similarity). Seems to be involved in cell-fate decisions.
Ligand for multiple Notch receptors and involved in the mediation of Notch signaling (PubMed:18660822, PubMed:20437614). May be involved in cell-fate decisions during hematopoiesis (PubMed:9462510). Seems to be involved in early and late stages of mammalian cardiovascular development. Inhibits myoblast differentiation (By similarity). Enhances fibroblast growth factor-induced angiogenesis (in vitro).
Ligand for multiple Notch receptors and involved in the mediation of Notch signaling. May be involved in cell-fate decisions during hematopoiesis. Seems to be involved in early and late stages of mammalian cardiovascular development. Inhibits myoblast differentiation (By similarity). May regulate fibroblast growth factor-induced angiogenesis.
Incorporated into fibronectin-containing matrix fibers. Plays a role in cell adhesion and migration along protein fibers within the extracellular matrix (ECM). Important for certain developmental processes and contributes to the supramolecular organization of ECM architecture, in particular to those of basement membranes.
Isoform a: Involved in regulating the shape and adhesion of cells in the developing pharynx, intestine, body-wall muscle and gonadal tissue (PubMed:16120639). During gonadogenesis, regulates the width of gonads and the migration of distal tip cells (DTC) (PubMed:15556862, PubMed:17043142, PubMed:22298704). Together with type IV collagen let-2 and downstream of metalloprotease mig-17, recruits nidogen nid-1 to the gonad basement membrane thereby inducing basement membrane remodeling required for the directional migration of DTCs (PubMed:15556863, PubMed:19104038). Acts antagonistically with metalloprotease gon-1 to maintain optimal levels of type IV collagen emb-9 in the gonad basement membrane during gonadogenesis (PubMed:15556862, PubMed:17043142, PubMed:22298704). Required for larval development (PubMed:17043142).
Isoform c: Involved in the assembly of the flexible hemicentin-containing tracks found joining the pharynx and body-wall-muscle basement membranes.
Required to maintain the integrity of photoreceptor cells (By similarity). Specifically required for normal morphology of the photoreceptor ciliary pocket, and might thus facilitate protein trafficking between the photoreceptor inner and outer segments via the transition zone (By similarity).
Plays a role in the control of cell growth and differentiation. Promotes osteoblast cell differentiation and terminal mineralization.
Putative Notch ligand involved in the mediation of Notch signaling. Involved in limb development (By similarity).
Binds to TGFBR2 and activates TGFB signaling. In lung cancer cells, could serve as an endogenous autocrine and paracrine ligand of TGFBR2, which could regulate TGFBR2 signaling and hence modulate epithelial-mesenchymal transition and cancer progression.
Incorporated into fibronectin-containing matrix fibers. May play a role in cell adhesion and migration along protein fibers within the extracellular matrix (ECM). Could be important for certain developmental processes and contribute to the supramolecular organization of ECM architecture, in particular to those of basement membranes. Has been implicated in a role in cellular transformation and tumor invasion, it appears to be a tumor suppressor. May play a role in haemostasis and thrombosis owing to its ability to bind fibrinogen and incorporate into clots. Could play a significant role in modulating the neurotrophic activities of APP, particularly soluble APP.
Binds to TGFBR2 and activates TGFB signaling.
Promotes cleavage furrow maturation during cytokinesis in preimplantation embryos (PubMed:21215633). May play a role in the architecture of adhesive and flexible epithelial cell junctions (PubMed:17015624). May play a role during myocardial remodeling by imparting an effect on cardiac fibroblast migration (PubMed:24951538).
Promotes cleavage furrow maturation during cytokinesis in preimplantation embryos. May play a role in the architecture of adhesive and flexible epithelial cell junctions. May play a role during myocardial remodeling by imparting an effect on cardiac fibroblast migration.
Plays a role in the control of cell growth and differentiation. Promotes osteoblast cell differentiation and terminal mineralization (By similarity).
Could function as an adhesive molecule and its matrix bound and soluble fragments may play a critical role in vascular biology.
Plays a central role in cell polarity establishment (PubMed:2344615, PubMed:12900452, PubMed:10102271, PubMed:11740560). Participates in the assembly, positioning and maintenance of adherens junctions via its interaction with the SAC complex (PubMed:11740560, PubMed:12900452, PubMed:10102271, PubMed:11076972). Controls the coalescence of the spots of zonula adherens (ZA) into a adhesive ring around the cells (PubMed:11740560). It may act as a signal (PubMed:2344615). Involved in morphogenesis of the photoreceptor rhabdomere, for positioning and growth of rhabdomere and AJ during the crucial period of photoreceptor extension along the proximodistal axis of the retina (PubMed:12900452). Component of the crb-galla-Xpd (CGX) complex which is essential for proper mitotic chromosome segregation in early embryos (PubMed:25065591). The CGX complex is also required for cell proliferation in developing wing disks (PubMed:25065591). In the CGX complex, acts with galla-1 or galla-2 to recruit Xpd and thus form the functional complex. Together with apn, plays a key role in trachea development at larval stages (PubMed:30645584).
Lipid-binding protein required for SHH long-range signaling by binding to the dually lipid-modified SHH (ShhNp) and by promoting ShhNp mobilization, solubilization and release from the cell membrane (PubMed:22902404, PubMed:22677548). Acts by enhancing the proteolytic processing (shedding) of the lipid-modified N- and C- terminal of ShhNp at the cell surface (PubMed:24522195). Synergizes with DISP1 to cause an increase in SHH secretion (PubMed:22902404). Probable cell surface coreceptor for VEGFR2 involved in VEGFR2-mediated angiogenesis (PubMed:27834687).
Involved in several cell fate decisions that require cell-cell interactions. It is possible that lin-12 encodes a membrane-bound receptor for a signal that enables expression of the ventral uterine precursor cell fate. Activity in cell fate decisions and tumorigenesis is negatively regulated by sel-10.
Lipid-binding protein required for SHH long-range signaling by binding to the dually lipid-modified SHH (ShhNp) and by promoting ShhNp mobilization, solubilization and release from the cell membrane (PubMed:22902404, PubMed:22677548). Acts by enhancing the proteolytic processing (shedding) of the lipid-modified N- and C- terminal of ShhNp at the cell surface (PubMed:24522195). Synergizes with DISP1 to increase SHH secretion (PubMed:22902404). Probable cell surface coreceptor for VEGFR2 involved in VEGFR2-mediated angiogenesis (PubMed:27834687).
Lipid-binding protein required for SHH long-range signaling by binding to the dually lipid-modified SHH (ShhNp) and by promoting ShhNp mobilization, solubilization and release from the cell membrane. Acts by enhancing the proteolytic processing (shedding) of the lipid-modified N- and C- terminal of ShhNp at the cell surface. Synergizes with DISP1 to cause an increase in SHH secretion. Probable cell surface coreceptor for VEGFR2 involved in VEGFR2-mediated angiogenesis.
Apical polarity protein that plays a central role during the epithelial-to-mesenchymal transition (EMT) at gastrulation, when newly specified mesodermal cells move inside the embryo. Acts by promoting cell ingression, the process by which cells leave the epithelial epiblast and move inside the embryo to form a new tissue layer. The anisotropic distribution of CRB2 and MYH10/myosin-IIB at cell edges define which cells will ingress: cells with high apical CRB2 are probably extruded from the epiblast by neighboring cells with high levels of apical MYH10/myosin-IIB. Also required for maintenance of the apical polarity complex during development of the cortex.
Asprosin: Hormone that targets the liver to increase plasma glucose levels. Secreted by white adipose tissue and circulates in the plasma. Acts in response to fasting and promotes blood glucose elevation by binding to the surface of hepatocytes. Promotes hepatocyte glucose release by activating the protein kinase A activity in the liver, resulting in rapid glucose release into the circulation.
Fibrillin-2: Fibrillins are structural components of 10-12 nm extracellular calcium-binding microfibrils, which occur either in association with elastin or in elastin-free bundles. Fibrillin-2-containing microfibrils regulate the early process of elastic fiber assembly. Regulates osteoblast maturation by controlling TGF-beta bioavailability and calibrating TGF-beta and BMP levels, respectively.
Fibrillin-2: Fibrillins are structural components of 10-12 nm extracellular calcium-binding microfibrils, which occur either in association with elastin or in elastin-free bundles. Fibrillin-2-containing microfibrils regulate the early process of elastic fiber assembly. Regulates osteoblast maturation by controlling TGF-beta bioavailability and calibrating TGF-beta and BMP levels, respectively (PubMed:20855508).
Fibrillin-1: Structural component of the 10-12 nm diameter microfibrils of the extracellular matrix, which conveys both structural and regulatory properties to load-bearing connective tissues (PubMed:1860873, PubMed:15062093). Fibrillin-1-containing microfibrils provide long-term force bearing structural support. In tissues such as the lung, blood vessels and skin, microfibrils form the periphery of the elastic fiber, acting as a scaffold for the deposition of elastin. In addition, microfibrils can occur as elastin-independent networks in tissues such as the ciliary zonule, tendon, cornea and glomerulus where they provide tensile strength and have anchoring roles. Fibrillin-1 also plays a key role in tissue homeostasis through specific interactions with growth factors, such as the bone morphogenetic proteins (BMPs), growth and differentiation factors (GDFs) and latent transforming growth factor-beta-binding proteins (LTBPs), cell-surface integrins and other extracellular matrix protein and proteoglycan components (PubMed:27026396). Regulates osteoblast maturation by controlling TGF-beta bioavailability and calibrating TGF-beta and BMP levels, respectively (By similarity). Negatively regulates osteoclastogenesis by binding and sequestering an osteoclast differentiation and activation factor TNFSF11. This leads to disruption of TNFSF11-induced Ca(2+) signaling and impairment of TNFSF11-mediated nuclear translocation and activation of transcription factor NFATC1 which regulates genes important for osteoclast differentiation and function (PubMed:24039232). Mediates cell adhesion via its binding to cell surface receptors integrins ITGAV:ITGB3 and ITGA5:ITGB1 (PubMed:12807887, PubMed:17158881). Binds heparin and this interaction has an important role in the assembly of microfibrils (PubMed:11461921).
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs. Involved in angiogenesis; negatively regulates endothelial cell proliferation and migration and angiogenic sprouting. Involved in the maturation of both CD4(+) and CD8(+) cells in the thymus. Important for follicular differentiation and possibly cell fate selection within the follicle. During cerebellar development, functions as a receptor for neuronal DNER and is involved in the differentiation of Bergmann glia. Represses neuronal and myogenic differentiation. May play an essential role in postimplantation development, probably in some aspect of cell specification and/or differentiation. May be involved in mesoderm development, somite formation and neurogenesis. Involved in determination of left/right symmetry by modulating the balance between motile and immotile (sensory) cilia at the left-right organiser (LRO) (By similarity).
Essential signaling protein which has a major role in many developmental processes (PubMed:3935325). Functions as a receptor for membrane-bound ligands Delta and Serrate to regulate cell-fate determination (PubMed:10935637, PubMed:15620650, PubMed:12909620, PubMed:18243100). Upon ligand activation, and releasing from the cell membrane, the Notch intracellular domain (NICD) forms a transcriptional activator complex with Su(H) (Suppressor of hairless) and activates genes of the E(spl) complex (PubMed:7671825). Regulates oogenesis, the differentiation of the ectoderm and the development of the central and peripheral nervous system, eye, wing disk, muscles and segmental appendages such as antennae and legs, through lateral inhibition or induction (PubMed:11719214, PubMed:12369105, PubMed:3935325). Regulates neuroblast self-renewal, identity and proliferation through the regulation of bHLH-O proteins; in larval brains, involved in the maintenance of type II neuroblast self-renewal and identity by suppressing erm expression together with pnt; might also regulate dpn expression through the activation of the transcriptional regulator Su(H) (PubMed:27151950, PubMed:28899667, PubMed:20152183, PubMed:18342578, PubMed:23056424, PubMed:21262215).
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus (PubMed:21378985, PubMed:21378989). Affects the implementation of differentiation, proliferation and apoptotic programs (By similarity). Involved in bone remodeling and homeostasis. In collaboration with RELA/p65 enhances NFATc1 promoter activity and positively regulates RANKL-induced osteoclast differentiation (PubMed:29149593). Positively regulates self-renewal of liver cancer cells (PubMed:25985737).
Functions as a receptor for membrane-bound ligands Jagged1, Jagged2 and Delta1 to regulate cell-fate determination (PubMed:15350543). Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs (By similarity).
Functions as a receptor for membrane-bound ligands Jagged1, Jagged2 and Delta1 to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs (By similarity). May play a role during CNS development.
May play an integral structural role in elastic-fiber architectural organization and/or assembly.
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination (PubMed:10393120). Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus (PubMed:10393120, PubMed:18710934). Affects the implementation of differentiation, proliferation and apoptotic programs (PubMed:10393120, PubMed:18710934). May play an essential role in postimplantation development, probably in some aspect of cell specification and/or differentiation (By similarity). In collaboration with RELA/p65 enhances NFATc1 promoter activity and positively regulates RANKL-induced osteoclast differentiation (PubMed:18710934). Positively regulates self-renewal of liver cancer cells (By similarity).
Fibrillin-1: Structural component of the 10-12 nm diameter microfibrils of the extracellular matrix, which conveys both structural and regulatory properties to load-bearing connective tissues. Fibrillin-1-containing microfibrils provide long-term force bearing structural support. In tissues such as the lung, blood vessels and skin, microfibrils form the periphery of the elastic fiber, acting as a scaffold for the deposition of elastin. In addition, microfibrils can occur as elastin-independent networks in tissues such as the ciliary zonule, tendon, cornea and glomerulus where they provide tensile strength and have anchoring roles. Fibrillin-1 also plays a key role in tissue homeostasis through specific interactions with growth factors, such as the bone morphogenetic proteins (BMPs), growth and differentiation factors (GDFs) and latent transforming growth factor-beta-binding proteins (LTBPs), cell-surface integrins and other extracellular matrix protein and proteoglycan components (By similarity). Regulates osteoblast maturation by controlling TGF-beta bioavailability and calibrating TGF-beta and BMP levels, respectively (PubMed:20855508). Negatively regulates osteoclastogenesis by binding and sequestering an osteoclast differentiation and activation factor TNFSF11. This leads to disruption of TNFSF11-induced Ca(2+) signaling and impairment of TNFSF11-mediated nuclear translocation and activation of transcription factor NFATC1 which regulates genes important for osteoclast differentiation and function (PubMed:24039232). Mediates cell adhesion via its binding to cell surface receptors integrins ITGAV:ITGB3 and ITGA5:ITGB1. Binds heparin and this interaction plays an important role in the assembly of microfibrils (By similarity).
Functions as a receptor for membrane-bound ligands Jagged1, Jagged2 and Delta1 to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs (By similarity). Acts instructively to control the cell fate determination of CNS multipotent progenitor cells, resulting in astroglial induction and neuron/oligodendrocyte suppression.
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs. Involved in angiogenesis; negatively regulates endothelial cell proliferation and migration and angiogenic sprouting. Involved in the maturation of both CD4(+) and CD8(+) cells in the thymus. Important for follicular differentiation and possibly cell fate selection within the follicle. During cerebellar development, functions as a receptor for neuronal DNER and is involved in the differentiation of Bergmann glia. Represses neuronal and myogenic differentiation. May play an essential role in postimplantation development, probably in some aspect of cell specification and/or differentiation. May be involved in mesoderm development, somite formation and neurogenesis (By similarity). Involved in determination of left/right symmetry by modulating the balance between motile and immotile (sensory) cilia at the left-right organiser (LRO).
Fibrillin-3: Fibrillins are structural components of 10-12 nm extracellular calcium-binding microfibrils, which occur either in association with elastin or in elastin-free bundles. Fibrillin-containing microfibrils provide long-term force bearing structural support.
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs. Involved in angiogenesis; negatively regulates endothelial cell proliferation and migration and angiogenic sprouting. Involved in the maturation of both CD4(+) and CD8(+) cells in the thymus. Important for follicular differentiation and possibly cell fate selection within the follicle. During cerebellar development, functions as a receptor for neuronal DNER and is involved in the differentiation of Bergmann glia. Represses neuronal and myogenic differentiation. May play an essential role in postimplantation development, probably in some aspect of cell specification and/or differentiation. May be involved in mesoderm development, somite formation and neurogenesis (By similarity). Involved in determination of left/right symmetry by modulating the balance between motile and immotile (sensory) cilia at the left-right organiser (LRO) (By similarity).
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs (By similarity). Involved in bone remodeling and homeostasis. In collaboration with RELA/p65 enhances NFATc1 promoter activity and positively regulates RANKL-induced osteoclast differentiation. Positively regulates self-renewal of liver cancer cells (By similarity).
Required to maintain the integrity of photoreceptor cells (PubMed:27737822, PubMed:28378834, PubMed:30052645). Specifically required for normal morphology of the photoreceptor ciliary pocket, and might thus facilitate protein trafficking between the photoreceptor inner and outer segments via the transition zone (PubMed:27737822).
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs. Involved in angiogenesis; negatively regulates endothelial cell proliferation and migration and angiogenic sprouting. Involved in the maturation of both CD4(+) and CD8(+) cells in the thymus. Important for follicular differentiation and possibly cell fate selection within the follicle. During cerebellar development, functions as a receptor for neuronal DNER and is involved in the differentiation of Bergmann glia. Represses neuronal and myogenic differentiation. May play an essential role in postimplantation development, probably in some aspect of cell specification and/or differentiation. May be involved in mesoderm development, somite formation and neurogenesis. May enhance HIF1A function by sequestering HIF1AN away from HIF1A (By similarity). Required for the THBS4 function in regulating protective astrogenesis from the subventricular zone (SVZ) niche after injury. Involved in determination of left/right symmetry by modulating the balance between motile and immotile (sensory) cilia at the left-right organiser (LRO) (By similarity).
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs. Involved in angiogenesis; negatively regulates endothelial cell proliferation and migration and angiogenic sprouting. Involved in the maturation of both CD4(+) and CD8(+) cells in the thymus. Important for follicular differentiation and possibly cell fate selection within the follicle. During cerebellar development, functions as a receptor for neuronal DNER and is involved in the differentiation of Bergmann glia. Represses neuronal and myogenic differentiation. May play an essential role in postimplantation development, probably in some aspect of cell specification and/or differentiation. May be involved in mesoderm development, somite formation and neurogenesis. May enhance HIF1A function by sequestering HIF1AN away from HIF1A. Required for the THBS4 function in regulating protective astrogenesis from the subventricular zone (SVZ) niche after injury. Involved in determination of left/right symmetry by modulating the balance between motile and immotile (sensory) cilia at the left-right organiser (LRO).
Functions as a receptor for membrane-bound ligands Jagged-1 (JAG1), Jagged-2 (JAG2) and Delta-1 (DLL1) to regulate cell-fate determination (By similarity). Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus (By similarity). Affects the implementation of differentiation, proliferation and apoptotic programs (By similarity). Involved in angiogenesis; negatively regulates endothelial cell proliferation and migration and angiogenic sprouting (By similarity). Involved in the maturation of both CD4(+) and CD8(+) cells in the thymus (By similarity). Important for follicular differentiation and possibly cell fate selection within the follicle (By similarity). During cerebellar development, functions as a receptor for neuronal DNER and is involved in the differentiation of Bergmann glia (PubMed:11182080). Represses neuronal and myogenic differentiation (By similarity). May play an essential role in postimplantation development, probably in some aspect of cell specification and/or differentiation (By similarity). May be involved in mesoderm development, somite formation and neurogenesis (By similarity). May enhance HIF1A function by sequestering HIF1AN away from HIF1A (By similarity). Required for the THBS4 function in regulating protective astrogenesis from the subventricular zone (SVZ) niche after injury (By similarity). Involved in determination of left/right symmetry by modulating the balance between motile and immotile (sensory) cilia at the left-right organiser (LRO) (By similarity).
Key regulator of transforming growth factor beta (TGFB1, TGFB2 and TGFB3) that controls TGF-beta activation by maintaining it in a latent state during storage in extracellular space. Associates specifically via disulfide bonds with the Latency-associated peptide (LAP), which is the regulatory chain of TGF-beta, and regulates integrin-dependent activation of TGF-beta.
Key regulator of transforming growth factor beta (TGFB1, TGFB2 and TGFB3) that controls TGF-beta activation by maintaining it in a latent state during storage in extracellular space (PubMed:2022183, PubMed:8617200, PubMed:8939931). Associates specifically via disulfide bonds with the Latency-associated peptide (LAP), which is the regulatory chain of TGF-beta, and regulates integrin-dependent activation of TGF-beta (PubMed:8617200, PubMed:8939931, PubMed:15184403). Outcompeted by LRRC32/GARP for binding to LAP regulatory chain of TGF-beta (PubMed:22278742).
Functions as a receptor for membrane-bound ligands Jagged1, Jagged2 and Delta1 to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs (By similarity). May regulate branching morphogenesis in the developing vascular system.
Functions as a receptor for membrane-bound ligands Jagged1, Jagged2 and Delta1 to regulate cell-fate determination. Upon ligand activation through the released notch intracellular domain (NICD) it forms a transcriptional activator complex with RBPJ/RBPSUH and activates genes of the enhancer of split locus. Affects the implementation of differentiation, proliferation and apoptotic programs. May regulate branching morphogenesis in the developing vascular system (By similarity).
Key regulator of transforming growth factor beta (TGFB1, TGFB2 and TGFB3) that controls TGF-beta activation by maintaining it in a latent state during storage in extracellular space. Associates specifically via disulfide bonds with the Latency-associated peptide (LAP), which is the regulatory chain of TGF-beta, and regulates integrin-dependent activation of TGF-beta. Outcompeted by LRRC32/GARP for binding to LAP regulatory chain of TGF-beta.
Key regulator of transforming growth factor beta (TGFB1, TGFB2 and TGFB3) that controls TGF-beta activation by maintaining it in a latent state during storage in extracellular space (PubMed:7593177). Associates specifically via disulfide bonds with the Latency-associated peptide (LAP), which is the regulatory chain of TGF-beta, and regulates integrin-dependent activation of TGF-beta (By similarity). Outcompeted by LRRC32/GARP for binding to LAP regulatory chain of TGF-beta (By similarity).
Its binding to fibronectin and some other ligands is calcium dependent. May act as an adapter that mediates the interaction between FBN1 and ELN.
Involved in cell adhesion and required for organ positioning and attachment (PubMed:25917920, PubMed:11470827, PubMed:11470828). At the hypodermal surface, required for attachment of the hypdermermis to the basal cuticle in postembryonic development, possibly through intermediate filaments of the cytoskeleton (PubMed:11470828).
Orphan receptor involved in cell adhesion and probably in cell-cell interactions specifically involving cells of the immune system. May play a role in regulatory T-cells (Treg) development.
Orphan receptor involved in cell adhesion and probably in cell-cell interactions involved specifically cells of the immune system. May play a role in regulatory T-cells (Treg) development.
Ligand for multiple Notch receptors and involved in the mediation of Notch signaling (By similarity). Seems to be involved in cell-fate decisions.
Its binding to fibronectin and some other ligands is calcium dependent. May act as an adapter that mediates the interaction between FBN1 and ELN (PubMed:17255108).
Ligand for Notch receptors and involved in the mediation of Notch signaling (By similarity). Seems to be involved in cell-fate decisions.
Ligand for multiple Notch receptors and involved in the mediation of Notch signaling (PubMed:18660822, PubMed:20437614). May be involved in cell-fate decisions during hematopoiesis (PubMed:9462510). Seems to be involved in early and late stages of mammalian cardiovascular development. Inhibits myoblast differentiation (By similarity). Enhances fibroblast growth factor-induced angiogenesis (in vitro).
Ligand for multiple Notch receptors and involved in the mediation of Notch signaling. May be involved in cell-fate decisions during hematopoiesis. Seems to be involved in early and late stages of mammalian cardiovascular development. Inhibits myoblast differentiation (By similarity). May regulate fibroblast growth factor-induced angiogenesis.
Incorporated into fibronectin-containing matrix fibers. Plays a role in cell adhesion and migration along protein fibers within the extracellular matrix (ECM). Important for certain developmental processes and contributes to the supramolecular organization of ECM architecture, in particular to those of basement membranes.
Isoform a: Involved in regulating the shape and adhesion of cells in the developing pharynx, intestine, body-wall muscle and gonadal tissue (PubMed:16120639). During gonadogenesis, regulates the width of gonads and the migration of distal tip cells (DTC) (PubMed:15556862, PubMed:17043142, PubMed:22298704). Together with type IV collagen let-2 and downstream of metalloprotease mig-17, recruits nidogen nid-1 to the gonad basement membrane thereby inducing basement membrane remodeling required for the directional migration of DTCs (PubMed:15556863, PubMed:19104038). Acts antagonistically with metalloprotease gon-1 to maintain optimal levels of type IV collagen emb-9 in the gonad basement membrane during gonadogenesis (PubMed:15556862, PubMed:17043142, PubMed:22298704). Required for larval development (PubMed:17043142).
Isoform c: Involved in the assembly of the flexible hemicentin-containing tracks found joining the pharynx and body-wall-muscle basement membranes.
Required to maintain the integrity of photoreceptor cells (By similarity). Specifically required for normal morphology of the photoreceptor ciliary pocket, and might thus facilitate protein trafficking between the photoreceptor inner and outer segments via the transition zone (By similarity).
Plays a role in the control of cell growth and differentiation. Promotes osteoblast cell differentiation and terminal mineralization.
Putative Notch ligand involved in the mediation of Notch signaling. Involved in limb development (By similarity).
Binds to TGFBR2 and activates TGFB signaling. In lung cancer cells, could serve as an endogenous autocrine and paracrine ligand of TGFBR2, which could regulate TGFBR2 signaling and hence modulate epithelial-mesenchymal transition and cancer progression.
Incorporated into fibronectin-containing matrix fibers. May play a role in cell adhesion and migration along protein fibers within the extracellular matrix (ECM). Could be important for certain developmental processes and contribute to the supramolecular organization of ECM architecture, in particular to those of basement membranes. Has been implicated in a role in cellular transformation and tumor invasion, it appears to be a tumor suppressor. May play a role in haemostasis and thrombosis owing to its ability to bind fibrinogen and incorporate into clots. Could play a significant role in modulating the neurotrophic activities of APP, particularly soluble APP.
Binds to TGFBR2 and activates TGFB signaling.
Promotes cleavage furrow maturation during cytokinesis in preimplantation embryos (PubMed:21215633). May play a role in the architecture of adhesive and flexible epithelial cell junctions (PubMed:17015624). May play a role during myocardial remodeling by imparting an effect on cardiac fibroblast migration (PubMed:24951538).
Promotes cleavage furrow maturation during cytokinesis in preimplantation embryos. May play a role in the architecture of adhesive and flexible epithelial cell junctions. May play a role during myocardial remodeling by imparting an effect on cardiac fibroblast migration.
Plays a role in the control of cell growth and differentiation. Promotes osteoblast cell differentiation and terminal mineralization (By similarity).
Could function as an adhesive molecule and its matrix bound and soluble fragments may play a critical role in vascular biology.
Plays a central role in cell polarity establishment (PubMed:2344615, PubMed:12900452, PubMed:10102271, PubMed:11740560). Participates in the assembly, positioning and maintenance of adherens junctions via its interaction with the SAC complex (PubMed:11740560, PubMed:12900452, PubMed:10102271, PubMed:11076972). Controls the coalescence of the spots of zonula adherens (ZA) into a adhesive ring around the cells (PubMed:11740560). It may act as a signal (PubMed:2344615). Involved in morphogenesis of the photoreceptor rhabdomere, for positioning and growth of rhabdomere and AJ during the crucial period of photoreceptor extension along the proximodistal axis of the retina (PubMed:12900452). Component of the crb-galla-Xpd (CGX) complex which is essential for proper mitotic chromosome segregation in early embryos (PubMed:25065591). The CGX complex is also required for cell proliferation in developing wing disks (PubMed:25065591). In the CGX complex, acts with galla-1 or galla-2 to recruit Xpd and thus form the functional complex. Together with apn, plays a key role in trachea development at larval stages (PubMed:30645584).
Lipid-binding protein required for SHH long-range signaling by binding to the dually lipid-modified SHH (ShhNp) and by promoting ShhNp mobilization, solubilization and release from the cell membrane (PubMed:22902404, PubMed:22677548). Acts by enhancing the proteolytic processing (shedding) of the lipid-modified N- and C- terminal of ShhNp at the cell surface (PubMed:24522195). Synergizes with DISP1 to cause an increase in SHH secretion (PubMed:22902404). Probable cell surface coreceptor for VEGFR2 involved in VEGFR2-mediated angiogenesis (PubMed:27834687).
Involved in several cell fate decisions that require cell-cell interactions. It is possible that lin-12 encodes a membrane-bound receptor for a signal that enables expression of the ventral uterine precursor cell fate. Activity in cell fate decisions and tumorigenesis is negatively regulated by sel-10.
Lipid-binding protein required for SHH long-range signaling by binding to the dually lipid-modified SHH (ShhNp) and by promoting ShhNp mobilization, solubilization and release from the cell membrane (PubMed:22902404, PubMed:22677548). Acts by enhancing the proteolytic processing (shedding) of the lipid-modified N- and C- terminal of ShhNp at the cell surface (PubMed:24522195). Synergizes with DISP1 to increase SHH secretion (PubMed:22902404). Probable cell surface coreceptor for VEGFR2 involved in VEGFR2-mediated angiogenesis (PubMed:27834687).
Lipid-binding protein required for SHH long-range signaling by binding to the dually lipid-modified SHH (ShhNp) and by promoting ShhNp mobilization, solubilization and release from the cell membrane. Acts by enhancing the proteolytic processing (shedding) of the lipid-modified N- and C- terminal of ShhNp at the cell surface. Synergizes with DISP1 to cause an increase in SHH secretion. Probable cell surface coreceptor for VEGFR2 involved in VEGFR2-mediated angiogenesis.
Apical polarity protein that plays a central role during the epithelial-to-mesenchymal transition (EMT) at gastrulation, when newly specified mesodermal cells move inside the embryo. Acts by promoting cell ingression, the process by which cells leave the epithelial epiblast and move inside the embryo to form a new tissue layer. The anisotropic distribution of CRB2 and MYH10/myosin-IIB at cell edges define which cells will ingress: cells with high apical CRB2 are probably extruded from the epiblast by neighboring cells with high levels of apical MYH10/myosin-IIB. Also required for maintenance of the apical polarity complex during development of the cortex.
Subunit
Interacts with COL16A1. Interacts with integrin alpha-V/beta-3. Interacts with ADAMTS10; this interaction promotes microfibril assembly. Interacts with THSD4; this interaction promotes fibril formation. Interacts (via N-terminal domain) with FBLN2, FBLN4 and FBLN5. Interacts with ELN. Forms a ternary complex with ELN and FBLN2 or FBLN5 and a significant interaction with ELN seen only in the presence of FBLN2 or FBLN5. Interacts (via N-terminal domain) with LTBP2 (via C-terminal domain) in a Ca(+2)-dependent manner. Interacts (via N-terminal domain) with LTBP1 (via C-terminal domain). Interacts with integrins ITGA5:ITGB1, ITGAV:ITGB3 and ITGAV:ITGB6. Interacts (via N-terminal domain) with BMP2, BMP4, BMP7, BMP10 and GDF5. Interacts (via N-terminal domain) with MFAP2 and MFAP5. Interacts with ADAMTSL5. Interacts with MFAP4. Interacts (via N-terminal domain) with TNFSF11 in a Ca(+2)-dependent manner.
Interacts with BMP2, BMP4, BMP7, BMP10 and GDF5 (PubMed:18339631). Interacts with MFAP2 and MFAP5 (PubMed:15131124). Interacts with ADAMTSL5 (PubMed:23010571). Interacts with MFAP4 (PubMed:26601954).
Interacts with BMP2, BMP4, BMP7, BMP10 and GDF5. Interacts with MFAP2 and MFAP5. Interacts with ADAMTSL5. Interacts with MFAP4.
Interacts with COL16A1 (PubMed:15165854). Interacts with integrin alpha-V/beta-3 (PubMed:15062093). Interacts with ADAMTS10; this interaction promotes microfibril assembly (PubMed:21402694). Interacts with THSD4; this interaction promotes fibril formation (By similarity). Interacts (via N-terminal domain) with FBLN2, FBLN4 and FBLN5 (PubMed:15790312, PubMed:17255108). Interacts with ELN (PubMed:15790312). Forms a ternary complex with ELN and FBLN2 or FBLN5 and a significant interaction with ELN seen only in the presence of FBLN2 or FBLN5 (PubMed:17255108). Interacts (via N-terminal domain) with LTBP2 (via C-terminal domain) in a Ca(+2)-dependent manner (PubMed:17293099). Interacts (via N-terminal domain) with LTBP1 (via C-terminal domain) (PubMed:17293099). Interacts with integrins ITGA5:ITGB1, ITGAV:ITGB3 and ITGAV:ITGB6 (PubMed:17158881, PubMed:12807887). Interacts (via N-terminal domain) with BMP2, BMP4, BMP7, BMP10 and GDF5 (PubMed:18339631). Interacts (via N-terminal domain) with MFAP2 and MFAP5 (PubMed:15131124). Interacts with ADAMTSL5 (PubMed:23010571). Interacts with MFAP4 (PubMed:26601954). Interacts (via N-terminal domain) with TNFSF11 in a Ca(+2)-dependent manner (PubMed:24039232).
Forms a ternary complex with nrarp and rbpj/suh.
Homomer. Interacts with Su(H) when activated. Interacts with Dx via its ANK repeats. Interacts with Dl via the EGF repeats and the Dl EGF repeats. Interacts with Nedd4 and Su(dx). Interacts with O-fut1; the interaction glycosylates N and transports N to early endosomes. Interacts with Akap200; the interaction stabilizes N/Notch protein levels by preventing Cbl-mediated ubiquitination and subsequent lysosomal degradation of N/Notch (PubMed:29309414).
Heterodimer of a C-terminal fragment N(TM) and an N-terminal fragment N(EC) which are probably linked by disulfide bonds (By similarity). Interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH2. Interacts with RELA/p65 (By similarity). Interacts with HIF1AN. Interacts (via ANK repeats) with TCIM, the interaction inhibits the nuclear translocation of NOTCH2 N2ICD (PubMed:25985737). Interacts with CUL1, RBX1, SKP1 and FBXW7 that are SCF(FBXW7) E3 ubiquitin-protein ligase complex components (PubMed:29149593). Interacts with MINAR1; this interaction increases MINAR1 stability and function (PubMed:29329397). Interacts with NOTCH2NL (NOTCH2NLA, NOTCH2NLB and/or NOTCH2NLC); leading to enhance Notch signaling pathway in a non-cell-autonomous manner (PubMed:29856954). Interacts with MDK; this interaction mediates a nuclear accumulation of NOTCH2 and therefore activation of NOTCH2 signaling leading to interaction between HES1 and STAT3 (PubMed:18469519).
Heterodimer of a C-terminal fragment N(TM) and a N-terminal fragment N(EC) which are probably linked by disulfide bonds (By similarity). Interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH3. Interacts with PSMA1. Interacts with HIF1AN.
Interacts with PSMA1 (By similarity). Heterodimer of a C-terminal fragment N(TM) and a N-terminal fragment N(EC) which are probably linked by disulfide bonds. Interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH3. Interacts with HIF1AN.
Forms part of the large latent transforming growth factor beta precursor complex; removal is essential for activation of complex (PubMed:7798248). Interacts with SDC4 (PubMed:20382221). Interacts (via C-terminal domain) with FBN1 (via N-terminal domain) in a Ca(+2)-dependent manner (PubMed:17293099).
Forms part of the large latent transforming growth factor beta precursor complex; removal is essential for activation of complex. Interacts with SDC4. Interacts (via C-terminal domain) with FBN1 (via N-terminal domain) in a Ca(+2)-dependent manner.
Heterodimer of a C-terminal fragment N(TM) and an N-terminal fragment N(EC) which are probably linked by disulfide bonds. Interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH2. Interacts with RELA/p65. Interacts with HIF1AN. Interacts (via ANK repeats) with TCIM, the interaction inhibits the nuclear translocation of NOTCH2 N2ICD (By similarity). Interacts with CUL1, RBX1, SKP1 and FBXW7 that are SCF(FBXW7) E3 ubiquitin-protein ligase complex components. Interacts with MINAR1; this interaction increases MINAR1 stability and function (By similarity). Interacts with MDK; this interaction mediates a nuclear accumulation of NOTCH2 and therefore activation of NOTCH2 signaling leading to interaction between HES1 and STAT3 (By similarity).
Interacts with COL16A1. Interacts with integrin alpha-V/beta-3. Interacts with ADAMTS10; this interaction promotes microfibril assembly (By similarity). Interacts with THSD4; this interaction promotes fibril formation (PubMed:19940141). Interacts (via N-terminal domain) with FBLN2, FBLN4 and FBLN5. Interacts with ELN. Forms a ternary complex with ELN and FBLN2 or FBLN5 and a significant interaction with ELN seen only in the presence of FBLN2 or FBLN5. Interacts (via N-terminal domain) with LTBP2 (via C-terminal domain) in a Ca(+2)-dependent manner. Interacts (via N-terminal domain) with LTBP1 (via C-terminal domain). Interacts with integrins ITGA5:ITGB1, ITGAV:ITGB3 and ITGAV:ITGB6. Interacts (via N-terminal domain) with BMP2, BMP4, BMP7, BMP10 and GDF5. Interacts (via N-terminal domain) with MFAP2 and MFAP5. Interacts with ADAMTSL5. Interacts with MFAP4. Interacts (via N-terminal domain) with TNFSF11 in a Ca(+2)-dependent manner (By similarity).
Heterodimer of a C-terminal fragment N(TM) and a N-terminal fragment N(EC) which are probably linked by disulfide bonds. Interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH3. Interacts with PSMA1 (By similarity). Interacts with HIF1AN (By similarity).
Heterodimer of a C-terminal fragment N(TM) and an N-terminal fragment N(EC) which are probably linked by disulfide bonds (By similarity). Interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH2. Interacts with RELA/p65 (By similarity). Interacts with HIF1AN. Interacts (via ANK repeats) with TCIM, the interaction inhibits the nuclear translocation of NOTCH2 N2ICD (By similarity). Interacts with CUL1, RBX1, SKP1 and FBXW7 that are SCF(FBXW7) E3 ubiquitin-protein ligase complex components.Interacts with MINAR1; this interaction increases MINAR1 stability and function (By similarity). Interacts with MDK; this interaction mediates a nuclear accumulation of NOTCH2 and therefore activation of NOTCH2 signaling leading to interaction between HES1 and STAT3 (By similarity).
Heterodimer of a C-terminal fragment N(TM) and an N-terminal fragment N(EC) which are probably linked by disulfide bonds. Interacts with DNER, DTX1, DTX2 and RBPJ/RBPSUH. Also interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH1. Notch 1 intracellular domain interacts with SNW1; the interaction involves multimerized NOTCH1 NICD and is implicated in a formation of an intermediate preactivation complex which associates with DNA-bound CBF-1/RBPJ. The activated membrane-bound form interacts with AAK1 which promotes NOTCH1 stabilization. Forms a trimeric complex with FBXW7 and SGK1. Interacts with HIF1AN. HIF1AN negatively regulates the function of notch intracellular domain (NICD), accelerating myogenic differentiation. Interacts (via NICD) with SNAI1 (via zinc fingers); the interaction induces SNAI1 degradation via MDM2-mediated ubiquitination and inhibits SNAI1-induced cell invasion. Interacts (via NICD) with MDM2A. Interacts (via NICD) with BCL6; the interaction decreases MAML1 recruitment by NOTCH1 NICD on target genes DNA and inhibits NOTCH1 transcractivation activity (By similarity). Interacts with THBS4 (By similarity). Interacts (via the EGF-like repeat region) with CCN3 (via CTCK domain). Interacts (via EGF-like domains) with DLL4 (via N-terminal DSL and MNNL domains). Interacts with ZMIZ1. Interacts (via NICD domain) with MEGF10 (via the cytoplasmic domain). Interacts with DLL1 and JAG1 (By similarity). Interacts (via NICD domain) with PRAG1 (By similarity). Forms a complex with PRAG1, N1ICD and MAML1, in a MAML1-dependent manner (By similarity). Interacts (via transmembrane region) with PSEN1; the interaction is direct (By similarity).
Heterodimer of a C-terminal fragment N(TM) and an N-terminal fragment N(EC) which are probably linked by disulfide bonds. Interacts with DNER, DTX1, DTX2 and RBPJ/RBPSUH. Also interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH1. Notch 1 intracellular domain interacts with SNW1; the interaction involves multimerized NOTCH1 NICD and is implicated in a formation of an intermediate preactivation complex which associates with DNA-bound CBF-1/RBPJ. The activated membrane-bound form interacts with AAK1 which promotes NOTCH1 stabilization. Forms a trimeric complex with FBXW7 and SGK1. Interacts with HIF1AN. HIF1AN negatively regulates the function of notch intracellular domain (NICD), accelerating myogenic differentiation. Interacts (via NICD) with SNAI1 (via zinc fingers); the interaction induces SNAI1 degradation via MDM2-mediated ubiquitination and inhibits SNAI1-induced cell invasion. Interacts (via NICD) with MDM2A. Interacts (via NICD) with BCL6; the interaction decreases MAML1 recruitment by NOTCH1 NICD on target genes DNA and inhibits NOTCH1 transcractivation activity. Interacts with THBS4. Interacts (via the EGF-like repeat region) with CCN3 (via CTCK domain) (PubMed:12050162). Interacts (via EGF-like domains) with DLL4 (via N-terminal DSL and MNNL domains) (By similarity). Interacts with ZMIZ1. Interacts (via NICD domain) with MEGF10 (via the cytoplasmic domain) (PubMed:28498977). Interacts with DLL1 and JAG1 (PubMed:28089369). Interacts (via NICD domain) with PRAG1 (PubMed:25038227). Forms a complex with PRAG1, N1ICD and MAML1, in a MAML1-dependent manner (PubMed:25038227). Interacts (via transmembrane region) with PSEN1; the interaction is direct (By similarity).
Heterodimer of a C-terminal fragment N(TM) and an N-terminal fragment N(EC) which are probably linked by disulfide bonds. Interacts with DNER, DTX1, DTX2 and RBPJ/RBPSUH. Also interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH1. Notch 1 intracellular domain interacts with SNW1; the interaction involves multimerized NOTCH1 NICD and is implicated in a formation of an intermediate preactivation complex which associates with DNA-bound CBF-1/RBPJ. The activated membrane-bound form interacts with AAK1 which promotes NOTCH1 stabilization. Forms a trimeric complex with FBXW7 and SGK1. Interacts with HIF1AN. HIF1AN negatively regulates the function of notch intracellular domain (NICD), accelerating myogenic differentiation. Interacts (via NICD) with SNAI1 (via zinc fingers); the interaction induces SNAI1 degradation via MDM2-mediated ubiquitination and inhibits SNAI1-induced cell invasion. Interacts (via NICD) with MDM2A. Interacts (via NICD) with BCL6; the interaction decreases MAML1 recruitment by NOTCH1 NICD on target genes DNA and inhibits NOTCH1 transcractivation activity (By similarity). Interacts with THBS4 (By similarity). Interacts (via the EGF-like repeat region) with CCN3 (via CTCK domain) (By similarity). Interacts (via EGF-like domains) with DLL4 (via N-terminal DSL and MNNL domains) (PubMed:25700513). Interacts with ZMIZ1 (By similarity). Interacts (via NICD domain) with MEGF10 (via the cytoplasmic domain). Interacts with DLL1 and JAG1 (By similarity). Interacts (via NICD domain) with PRAG1 (By similarity). Forms a complex with PRAG1, N1ICD and MAML1, in a MAML1-dependent manner (By similarity). Interacts (via transmembrane region) with PSEN1; the interaction is direct (By similarity).
Forms part of the large latent transforming growth factor beta precursor complex; removal is essential for activation of complex. Interacts with LTBP1 and TGFB1.
Heterodimer of a C-terminal fragment N(TM) and an N-terminal fragment N(EC) which are probably linked by disulfide bonds. Interacts with DNER, DTX1, DTX2 and RBPJ/RBPSUH. Also interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH1 (PubMed:11101851, PubMed:12370315). The NOTCH1 intracellular domain interacts with SNW1; the interaction involves multimerized NOTCH1 NICD and is implicated in a formation of an intermediate preactivation complex which associates with DNA-bound CBF-1/RBPJ (PubMed:10713164). The activated membrane-bound form interacts with AAK1 which promotes NOTCH1 stabilization. Forms a trimeric complex with FBXW7 and SGK1. Interacts with HIF1AN. HIF1AN negatively regulates the function of notch intracellular domain (NICD), accelerating myogenic differentiation (PubMed:17573339). Interacts (via NICD) with SNAI1 (via zinc fingers); the interaction induces SNAI1 degradation via MDM2-mediated ubiquitination and inhibits SNAI1-induced cell invasion. Interacts (via NICD) with MDM2A. Interacts (via NICD) with BCL6; the interaction decreases MAML1 recruitment by NOTCH1 NICD on target genes DNA and inhibits NOTCH1 transcractivation activity. Interacts with THBS4 (By similarity). Interacts (via the EGF-like repeat region) with CCN3 (via CTCK domain) (PubMed:12050162). Interacts (via EGF-like domains) with DLL4 (via N-terminal DSL and MNNL domains) (By similarity). Interacts with ZMIZ1. Interacts (via NICD domain) with MEGF10 (via the cytoplasmic domain). Interacts with DLL1 and JAG1 (By similarity). Interacts (via NICD domain) with PRAG1 (By similarity). Forms a complex with PRAG1, N1ICD and MAML1, in a MAML1-dependent manner (By similarity). Interacts (via transmembrane region) with PSEN1; the interaction is direct (PubMed:30598546).
Forms part of the large latent transforming growth factor beta precursor complex; removal is essential for activation of complex (PubMed:9660815). Interacts with LTBP1 and TGFB1 (PubMed:9660815).
Interacts with TGFB1; associates via disulfide bonds with the Latency-associated peptide chain (LAP) regulatory chain of TGFB1, leading to regulate activation of TGF-beta-1 (PubMed:10930463, PubMed:2022183, PubMed:8617200, PubMed:15567420, PubMed:8939931, PubMed:22278742). LTBP1 does not bind directly to TGF-beta-1, the active chain of TGFB1 (PubMed:10930463). Interacts (via C-terminal domain) with FBN1 (via N-terminal domain) (PubMed:12429738, PubMed:17293099). Interacts with FBN2 (PubMed:12429738). Interacts with ADAMTSL2 (PubMed:18677313).
Heterodimer of a C-terminal fragment N(TM) and a N-terminal fragment N(EC) which are probably linked by disulfide bonds. Interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH4.
Heterodimer of a C-terminal fragment N(TM) and a N-terminal fragment N(EC) which are probably linked by disulfide bonds (By similarity). Interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH4.
Interacts with TGFB1; associates via disulfide bonds with the Latency-associated peptide chain (LAP) regulatory chain of TGFB1, leading to regulate activation of TGF-beta-1. LTBP1 does not bind directly to TGF-beta-1, the active chain of TGFB1. Interacts (via C-terminal domain) with FBN1 (via N-terminal domain). Interacts with FBN2. Interacts with ADAMTSL2.
Homotetramer.
Forms part of the large latent transforming growth factor beta (TGFB1) precursor complex; removal is essential for activation of complex.
Forms part of the large latent transforming growth factor beta precursor complex; removal is essential for activation of complex.
Homotrimer; disulfide-linked. Interacts with LAMA2 (PubMed:10022829). Interacts with FBN1 (via N-terminal domain). Forms a ternary complex with ELN and FBN1 (By similarity).
Homomultimerizes and interacts with various extracellular matrix components. Interacts with FBLN7 (By similarity). Interacts with the mature/soluble form of DTR. Interacts with CCN3 (By similarity).
Homotrimer; disulfide-linked. Interacts with LAMA2 (By similarity). Interacts with FBN1 (via N-terminal domain). Forms a ternary complex with ELN and FBN1 (PubMed:17255108).
Homomultimerizes and interacts with various extracellular matrix components such as FN1, LAMA1, NID, AGC1 and CSPG2.
Interacts with NOTCH2 and NOTCH3 (By similarity). Interacts with NOTCH1 (in the presence of calcium ions) (PubMed:18660822).
Interacts with NOTCH1 (PubMed:28089369). Interacts with NOTCH2 and NOTCH3 (By similarity).
Interacts with NOTCH1, NOTCH2 and NOTCH3.
Homomultimerizes and interacts with various extracellular matrix components.
Homotrimer. Binds to PKC beta-1 (By similarity). Interacts with ATRAID; the interaction promotes osteoblast cell differentiation and mineralization.
Forms homooligomers and heterooligomers with SCUBE1. Interacts with TGFBR2 through the CUB domain; this interaction does not affect TGFB1-binding to TGFBR2.
Homomultimerizes and interacts with various extracellular matrix components such as FN1, LAMA1, LAMA2, NID, ACAN, CSPG2 and type IV collagen. Interacts also with APP and FGB. Interacts with FBLN7 (By similarity). Interacts with CCN3 (PubMed:9927660).
(Microbial infection) Interacts with human papillomavirus/HPV type 16, 18 and 31 proteins E6.
Forms a complex with MPDZ (By similarity). Forms a complex with MPP4 and MPP5.
Interacts with ATRAID; the interaction promotes osteoblast cell differentiation and mineralization (By similarity). Homotrimer. Binds to PKC beta-1.
Homomultimerizes and interacts with various extracellular matrix components such as FN1, LAMA1, LMA2, NID, ACAN, CSPG2 and type IV collagen. Binding analysis demonstrated for isoform C a 100-fold stronger binding to the basement membrane protein NID than for isoform D. Interacts with FBLN7. Interacts with CCN3 (By similarity).
Forms homooligomers and heterooligomers with SCUBE2 and SCUBE3.
Component of the SAC complex, a complex composed of crb, Patj and sdt (PubMed:11740560, PubMed:10102271, PubMed:11076972). May interact with the par-6 complex, which is composed of par-6, baz and aPKC, via its interaction with Patj (PubMed:12900452, PubMed:10102271, PubMed:11076972). Interacts with other proteins with Patj and sdt via its short cytoplasmic tail (PubMed:11740560). Component of the CGX complex composed of crb, galla (galla-1 or galla-2) and Xpd (PubMed:25065591). Able to interact independently (via intracellular domain) with galla-1, galla-2 and Xpd (PubMed:25065591). Interacts with apn (PubMed:30645584).
Interacts with SHH via the cholesterol anchor of the dually lipid-modified SHH (ShhNp) (PubMed:22902404). Interacts with PTCH1 (PubMed:22902404). Forms homooligomers and heterooligomers with SCUBE1 and SCUBE3 (By similarity). Interacts with VEGFR2 (PubMed:27834687).
Interacts with sel-10.
Interacts with SHH via the cholesterol anchor of the dually lipid-modified SHH (ShhNp) (PubMed:19480626, PubMed:22902404). Interacts with PTCH1 (PubMed:19480626, PubMed:22902404). Forms homooligomers and heterooligomers with SCUBE1 and SCUBE3 (By similarity). Interacts with VEGFR2 (PubMed:27834687).
Interacts with SHH via the cholesterol anchor of the dually lipid-modified SHH (ShhNp) (By similarity). Interacts with PTCH1 (By similarity). Forms homooligomers and heterooligomers with SCUBE1 and SCUBE3 (By similarity). Interacts with VEGFR2 (By similarity).
Interacts with BMP2, BMP4, BMP7, BMP10 and GDF5 (PubMed:18339631). Interacts with MFAP2 and MFAP5 (PubMed:15131124). Interacts with ADAMTSL5 (PubMed:23010571). Interacts with MFAP4 (PubMed:26601954).
Interacts with BMP2, BMP4, BMP7, BMP10 and GDF5. Interacts with MFAP2 and MFAP5. Interacts with ADAMTSL5. Interacts with MFAP4.
Interacts with COL16A1 (PubMed:15165854). Interacts with integrin alpha-V/beta-3 (PubMed:15062093). Interacts with ADAMTS10; this interaction promotes microfibril assembly (PubMed:21402694). Interacts with THSD4; this interaction promotes fibril formation (By similarity). Interacts (via N-terminal domain) with FBLN2, FBLN4 and FBLN5 (PubMed:15790312, PubMed:17255108). Interacts with ELN (PubMed:15790312). Forms a ternary complex with ELN and FBLN2 or FBLN5 and a significant interaction with ELN seen only in the presence of FBLN2 or FBLN5 (PubMed:17255108). Interacts (via N-terminal domain) with LTBP2 (via C-terminal domain) in a Ca(+2)-dependent manner (PubMed:17293099). Interacts (via N-terminal domain) with LTBP1 (via C-terminal domain) (PubMed:17293099). Interacts with integrins ITGA5:ITGB1, ITGAV:ITGB3 and ITGAV:ITGB6 (PubMed:17158881, PubMed:12807887). Interacts (via N-terminal domain) with BMP2, BMP4, BMP7, BMP10 and GDF5 (PubMed:18339631). Interacts (via N-terminal domain) with MFAP2 and MFAP5 (PubMed:15131124). Interacts with ADAMTSL5 (PubMed:23010571). Interacts with MFAP4 (PubMed:26601954). Interacts (via N-terminal domain) with TNFSF11 in a Ca(+2)-dependent manner (PubMed:24039232).
Forms a ternary complex with nrarp and rbpj/suh.
Homomer. Interacts with Su(H) when activated. Interacts with Dx via its ANK repeats. Interacts with Dl via the EGF repeats and the Dl EGF repeats. Interacts with Nedd4 and Su(dx). Interacts with O-fut1; the interaction glycosylates N and transports N to early endosomes. Interacts with Akap200; the interaction stabilizes N/Notch protein levels by preventing Cbl-mediated ubiquitination and subsequent lysosomal degradation of N/Notch (PubMed:29309414).
Heterodimer of a C-terminal fragment N(TM) and an N-terminal fragment N(EC) which are probably linked by disulfide bonds (By similarity). Interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH2. Interacts with RELA/p65 (By similarity). Interacts with HIF1AN. Interacts (via ANK repeats) with TCIM, the interaction inhibits the nuclear translocation of NOTCH2 N2ICD (PubMed:25985737). Interacts with CUL1, RBX1, SKP1 and FBXW7 that are SCF(FBXW7) E3 ubiquitin-protein ligase complex components (PubMed:29149593). Interacts with MINAR1; this interaction increases MINAR1 stability and function (PubMed:29329397). Interacts with NOTCH2NL (NOTCH2NLA, NOTCH2NLB and/or NOTCH2NLC); leading to enhance Notch signaling pathway in a non-cell-autonomous manner (PubMed:29856954). Interacts with MDK; this interaction mediates a nuclear accumulation of NOTCH2 and therefore activation of NOTCH2 signaling leading to interaction between HES1 and STAT3 (PubMed:18469519).
Heterodimer of a C-terminal fragment N(TM) and a N-terminal fragment N(EC) which are probably linked by disulfide bonds (By similarity). Interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH3. Interacts with PSMA1. Interacts with HIF1AN.
Interacts with PSMA1 (By similarity). Heterodimer of a C-terminal fragment N(TM) and a N-terminal fragment N(EC) which are probably linked by disulfide bonds. Interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH3. Interacts with HIF1AN.
Forms part of the large latent transforming growth factor beta precursor complex; removal is essential for activation of complex (PubMed:7798248). Interacts with SDC4 (PubMed:20382221). Interacts (via C-terminal domain) with FBN1 (via N-terminal domain) in a Ca(+2)-dependent manner (PubMed:17293099).
Forms part of the large latent transforming growth factor beta precursor complex; removal is essential for activation of complex. Interacts with SDC4. Interacts (via C-terminal domain) with FBN1 (via N-terminal domain) in a Ca(+2)-dependent manner.
Heterodimer of a C-terminal fragment N(TM) and an N-terminal fragment N(EC) which are probably linked by disulfide bonds. Interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH2. Interacts with RELA/p65. Interacts with HIF1AN. Interacts (via ANK repeats) with TCIM, the interaction inhibits the nuclear translocation of NOTCH2 N2ICD (By similarity). Interacts with CUL1, RBX1, SKP1 and FBXW7 that are SCF(FBXW7) E3 ubiquitin-protein ligase complex components. Interacts with MINAR1; this interaction increases MINAR1 stability and function (By similarity). Interacts with MDK; this interaction mediates a nuclear accumulation of NOTCH2 and therefore activation of NOTCH2 signaling leading to interaction between HES1 and STAT3 (By similarity).
Interacts with COL16A1. Interacts with integrin alpha-V/beta-3. Interacts with ADAMTS10; this interaction promotes microfibril assembly (By similarity). Interacts with THSD4; this interaction promotes fibril formation (PubMed:19940141). Interacts (via N-terminal domain) with FBLN2, FBLN4 and FBLN5. Interacts with ELN. Forms a ternary complex with ELN and FBLN2 or FBLN5 and a significant interaction with ELN seen only in the presence of FBLN2 or FBLN5. Interacts (via N-terminal domain) with LTBP2 (via C-terminal domain) in a Ca(+2)-dependent manner. Interacts (via N-terminal domain) with LTBP1 (via C-terminal domain). Interacts with integrins ITGA5:ITGB1, ITGAV:ITGB3 and ITGAV:ITGB6. Interacts (via N-terminal domain) with BMP2, BMP4, BMP7, BMP10 and GDF5. Interacts (via N-terminal domain) with MFAP2 and MFAP5. Interacts with ADAMTSL5. Interacts with MFAP4. Interacts (via N-terminal domain) with TNFSF11 in a Ca(+2)-dependent manner (By similarity).
Heterodimer of a C-terminal fragment N(TM) and a N-terminal fragment N(EC) which are probably linked by disulfide bonds. Interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH3. Interacts with PSMA1 (By similarity). Interacts with HIF1AN (By similarity).
Heterodimer of a C-terminal fragment N(TM) and an N-terminal fragment N(EC) which are probably linked by disulfide bonds (By similarity). Interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH2. Interacts with RELA/p65 (By similarity). Interacts with HIF1AN. Interacts (via ANK repeats) with TCIM, the interaction inhibits the nuclear translocation of NOTCH2 N2ICD (By similarity). Interacts with CUL1, RBX1, SKP1 and FBXW7 that are SCF(FBXW7) E3 ubiquitin-protein ligase complex components.Interacts with MINAR1; this interaction increases MINAR1 stability and function (By similarity). Interacts with MDK; this interaction mediates a nuclear accumulation of NOTCH2 and therefore activation of NOTCH2 signaling leading to interaction between HES1 and STAT3 (By similarity).
Heterodimer of a C-terminal fragment N(TM) and an N-terminal fragment N(EC) which are probably linked by disulfide bonds. Interacts with DNER, DTX1, DTX2 and RBPJ/RBPSUH. Also interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH1. Notch 1 intracellular domain interacts with SNW1; the interaction involves multimerized NOTCH1 NICD and is implicated in a formation of an intermediate preactivation complex which associates with DNA-bound CBF-1/RBPJ. The activated membrane-bound form interacts with AAK1 which promotes NOTCH1 stabilization. Forms a trimeric complex with FBXW7 and SGK1. Interacts with HIF1AN. HIF1AN negatively regulates the function of notch intracellular domain (NICD), accelerating myogenic differentiation. Interacts (via NICD) with SNAI1 (via zinc fingers); the interaction induces SNAI1 degradation via MDM2-mediated ubiquitination and inhibits SNAI1-induced cell invasion. Interacts (via NICD) with MDM2A. Interacts (via NICD) with BCL6; the interaction decreases MAML1 recruitment by NOTCH1 NICD on target genes DNA and inhibits NOTCH1 transcractivation activity (By similarity). Interacts with THBS4 (By similarity). Interacts (via the EGF-like repeat region) with CCN3 (via CTCK domain). Interacts (via EGF-like domains) with DLL4 (via N-terminal DSL and MNNL domains). Interacts with ZMIZ1. Interacts (via NICD domain) with MEGF10 (via the cytoplasmic domain). Interacts with DLL1 and JAG1 (By similarity). Interacts (via NICD domain) with PRAG1 (By similarity). Forms a complex with PRAG1, N1ICD and MAML1, in a MAML1-dependent manner (By similarity). Interacts (via transmembrane region) with PSEN1; the interaction is direct (By similarity).
Heterodimer of a C-terminal fragment N(TM) and an N-terminal fragment N(EC) which are probably linked by disulfide bonds. Interacts with DNER, DTX1, DTX2 and RBPJ/RBPSUH. Also interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH1. Notch 1 intracellular domain interacts with SNW1; the interaction involves multimerized NOTCH1 NICD and is implicated in a formation of an intermediate preactivation complex which associates with DNA-bound CBF-1/RBPJ. The activated membrane-bound form interacts with AAK1 which promotes NOTCH1 stabilization. Forms a trimeric complex with FBXW7 and SGK1. Interacts with HIF1AN. HIF1AN negatively regulates the function of notch intracellular domain (NICD), accelerating myogenic differentiation. Interacts (via NICD) with SNAI1 (via zinc fingers); the interaction induces SNAI1 degradation via MDM2-mediated ubiquitination and inhibits SNAI1-induced cell invasion. Interacts (via NICD) with MDM2A. Interacts (via NICD) with BCL6; the interaction decreases MAML1 recruitment by NOTCH1 NICD on target genes DNA and inhibits NOTCH1 transcractivation activity. Interacts with THBS4. Interacts (via the EGF-like repeat region) with CCN3 (via CTCK domain) (PubMed:12050162). Interacts (via EGF-like domains) with DLL4 (via N-terminal DSL and MNNL domains) (By similarity). Interacts with ZMIZ1. Interacts (via NICD domain) with MEGF10 (via the cytoplasmic domain) (PubMed:28498977). Interacts with DLL1 and JAG1 (PubMed:28089369). Interacts (via NICD domain) with PRAG1 (PubMed:25038227). Forms a complex with PRAG1, N1ICD and MAML1, in a MAML1-dependent manner (PubMed:25038227). Interacts (via transmembrane region) with PSEN1; the interaction is direct (By similarity).
Heterodimer of a C-terminal fragment N(TM) and an N-terminal fragment N(EC) which are probably linked by disulfide bonds. Interacts with DNER, DTX1, DTX2 and RBPJ/RBPSUH. Also interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH1. Notch 1 intracellular domain interacts with SNW1; the interaction involves multimerized NOTCH1 NICD and is implicated in a formation of an intermediate preactivation complex which associates with DNA-bound CBF-1/RBPJ. The activated membrane-bound form interacts with AAK1 which promotes NOTCH1 stabilization. Forms a trimeric complex with FBXW7 and SGK1. Interacts with HIF1AN. HIF1AN negatively regulates the function of notch intracellular domain (NICD), accelerating myogenic differentiation. Interacts (via NICD) with SNAI1 (via zinc fingers); the interaction induces SNAI1 degradation via MDM2-mediated ubiquitination and inhibits SNAI1-induced cell invasion. Interacts (via NICD) with MDM2A. Interacts (via NICD) with BCL6; the interaction decreases MAML1 recruitment by NOTCH1 NICD on target genes DNA and inhibits NOTCH1 transcractivation activity (By similarity). Interacts with THBS4 (By similarity). Interacts (via the EGF-like repeat region) with CCN3 (via CTCK domain) (By similarity). Interacts (via EGF-like domains) with DLL4 (via N-terminal DSL and MNNL domains) (PubMed:25700513). Interacts with ZMIZ1 (By similarity). Interacts (via NICD domain) with MEGF10 (via the cytoplasmic domain). Interacts with DLL1 and JAG1 (By similarity). Interacts (via NICD domain) with PRAG1 (By similarity). Forms a complex with PRAG1, N1ICD and MAML1, in a MAML1-dependent manner (By similarity). Interacts (via transmembrane region) with PSEN1; the interaction is direct (By similarity).
Forms part of the large latent transforming growth factor beta precursor complex; removal is essential for activation of complex. Interacts with LTBP1 and TGFB1.
Heterodimer of a C-terminal fragment N(TM) and an N-terminal fragment N(EC) which are probably linked by disulfide bonds. Interacts with DNER, DTX1, DTX2 and RBPJ/RBPSUH. Also interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH1 (PubMed:11101851, PubMed:12370315). The NOTCH1 intracellular domain interacts with SNW1; the interaction involves multimerized NOTCH1 NICD and is implicated in a formation of an intermediate preactivation complex which associates with DNA-bound CBF-1/RBPJ (PubMed:10713164). The activated membrane-bound form interacts with AAK1 which promotes NOTCH1 stabilization. Forms a trimeric complex with FBXW7 and SGK1. Interacts with HIF1AN. HIF1AN negatively regulates the function of notch intracellular domain (NICD), accelerating myogenic differentiation (PubMed:17573339). Interacts (via NICD) with SNAI1 (via zinc fingers); the interaction induces SNAI1 degradation via MDM2-mediated ubiquitination and inhibits SNAI1-induced cell invasion. Interacts (via NICD) with MDM2A. Interacts (via NICD) with BCL6; the interaction decreases MAML1 recruitment by NOTCH1 NICD on target genes DNA and inhibits NOTCH1 transcractivation activity. Interacts with THBS4 (By similarity). Interacts (via the EGF-like repeat region) with CCN3 (via CTCK domain) (PubMed:12050162). Interacts (via EGF-like domains) with DLL4 (via N-terminal DSL and MNNL domains) (By similarity). Interacts with ZMIZ1. Interacts (via NICD domain) with MEGF10 (via the cytoplasmic domain). Interacts with DLL1 and JAG1 (By similarity). Interacts (via NICD domain) with PRAG1 (By similarity). Forms a complex with PRAG1, N1ICD and MAML1, in a MAML1-dependent manner (By similarity). Interacts (via transmembrane region) with PSEN1; the interaction is direct (PubMed:30598546).
Forms part of the large latent transforming growth factor beta precursor complex; removal is essential for activation of complex (PubMed:9660815). Interacts with LTBP1 and TGFB1 (PubMed:9660815).
Interacts with TGFB1; associates via disulfide bonds with the Latency-associated peptide chain (LAP) regulatory chain of TGFB1, leading to regulate activation of TGF-beta-1 (PubMed:10930463, PubMed:2022183, PubMed:8617200, PubMed:15567420, PubMed:8939931, PubMed:22278742). LTBP1 does not bind directly to TGF-beta-1, the active chain of TGFB1 (PubMed:10930463). Interacts (via C-terminal domain) with FBN1 (via N-terminal domain) (PubMed:12429738, PubMed:17293099). Interacts with FBN2 (PubMed:12429738). Interacts with ADAMTSL2 (PubMed:18677313).
Heterodimer of a C-terminal fragment N(TM) and a N-terminal fragment N(EC) which are probably linked by disulfide bonds. Interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH4.
Heterodimer of a C-terminal fragment N(TM) and a N-terminal fragment N(EC) which are probably linked by disulfide bonds (By similarity). Interacts with MAML1, MAML2 and MAML3 which act as transcriptional coactivators for NOTCH4.
Interacts with TGFB1; associates via disulfide bonds with the Latency-associated peptide chain (LAP) regulatory chain of TGFB1, leading to regulate activation of TGF-beta-1. LTBP1 does not bind directly to TGF-beta-1, the active chain of TGFB1. Interacts (via C-terminal domain) with FBN1 (via N-terminal domain). Interacts with FBN2. Interacts with ADAMTSL2.
Homotetramer.
Forms part of the large latent transforming growth factor beta (TGFB1) precursor complex; removal is essential for activation of complex.
Forms part of the large latent transforming growth factor beta precursor complex; removal is essential for activation of complex.
Homotrimer; disulfide-linked. Interacts with LAMA2 (PubMed:10022829). Interacts with FBN1 (via N-terminal domain). Forms a ternary complex with ELN and FBN1 (By similarity).
Homomultimerizes and interacts with various extracellular matrix components. Interacts with FBLN7 (By similarity). Interacts with the mature/soluble form of DTR. Interacts with CCN3 (By similarity).
Homotrimer; disulfide-linked. Interacts with LAMA2 (By similarity). Interacts with FBN1 (via N-terminal domain). Forms a ternary complex with ELN and FBN1 (PubMed:17255108).
Homomultimerizes and interacts with various extracellular matrix components such as FN1, LAMA1, NID, AGC1 and CSPG2.
Interacts with NOTCH2 and NOTCH3 (By similarity). Interacts with NOTCH1 (in the presence of calcium ions) (PubMed:18660822).
Interacts with NOTCH1 (PubMed:28089369). Interacts with NOTCH2 and NOTCH3 (By similarity).
Interacts with NOTCH1, NOTCH2 and NOTCH3.
Homomultimerizes and interacts with various extracellular matrix components.
Homotrimer. Binds to PKC beta-1 (By similarity). Interacts with ATRAID; the interaction promotes osteoblast cell differentiation and mineralization.
Forms homooligomers and heterooligomers with SCUBE1. Interacts with TGFBR2 through the CUB domain; this interaction does not affect TGFB1-binding to TGFBR2.
Homomultimerizes and interacts with various extracellular matrix components such as FN1, LAMA1, LAMA2, NID, ACAN, CSPG2 and type IV collagen. Interacts also with APP and FGB. Interacts with FBLN7 (By similarity). Interacts with CCN3 (PubMed:9927660).
(Microbial infection) Interacts with human papillomavirus/HPV type 16, 18 and 31 proteins E6.
Forms a complex with MPDZ (By similarity). Forms a complex with MPP4 and MPP5.
Interacts with ATRAID; the interaction promotes osteoblast cell differentiation and mineralization (By similarity). Homotrimer. Binds to PKC beta-1.
Homomultimerizes and interacts with various extracellular matrix components such as FN1, LAMA1, LMA2, NID, ACAN, CSPG2 and type IV collagen. Binding analysis demonstrated for isoform C a 100-fold stronger binding to the basement membrane protein NID than for isoform D. Interacts with FBLN7. Interacts with CCN3 (By similarity).
Forms homooligomers and heterooligomers with SCUBE2 and SCUBE3.
Component of the SAC complex, a complex composed of crb, Patj and sdt (PubMed:11740560, PubMed:10102271, PubMed:11076972). May interact with the par-6 complex, which is composed of par-6, baz and aPKC, via its interaction with Patj (PubMed:12900452, PubMed:10102271, PubMed:11076972). Interacts with other proteins with Patj and sdt via its short cytoplasmic tail (PubMed:11740560). Component of the CGX complex composed of crb, galla (galla-1 or galla-2) and Xpd (PubMed:25065591). Able to interact independently (via intracellular domain) with galla-1, galla-2 and Xpd (PubMed:25065591). Interacts with apn (PubMed:30645584).
Interacts with SHH via the cholesterol anchor of the dually lipid-modified SHH (ShhNp) (PubMed:22902404). Interacts with PTCH1 (PubMed:22902404). Forms homooligomers and heterooligomers with SCUBE1 and SCUBE3 (By similarity). Interacts with VEGFR2 (PubMed:27834687).
Interacts with sel-10.
Interacts with SHH via the cholesterol anchor of the dually lipid-modified SHH (ShhNp) (PubMed:19480626, PubMed:22902404). Interacts with PTCH1 (PubMed:19480626, PubMed:22902404). Forms homooligomers and heterooligomers with SCUBE1 and SCUBE3 (By similarity). Interacts with VEGFR2 (PubMed:27834687).
Interacts with SHH via the cholesterol anchor of the dually lipid-modified SHH (ShhNp) (By similarity). Interacts with PTCH1 (By similarity). Forms homooligomers and heterooligomers with SCUBE1 and SCUBE3 (By similarity). Interacts with VEGFR2 (By similarity).
Miscellaneous
Asprosin: Was named after the Greek word for white, because of the reduction in subcutaneous white adipose tissue that is displayed by asprosin-deficient patients.
Most adhesion GPCRs proteins undergo autoproteolysis at the GPS domain. ADGRE1 is predicted non-cleavable because of the lack of a consensus catalytic triad sequence within GPS domain.
Although involved in the same pathway as gon-1 and mig-17, it is probably not cleaved by these metalloproteases.
Separation of neuroblasts from the ectoderm into the inner part of embryo is one of the first steps of CNS development in insects, this process is under control of the neurogenic genes.
Notch and Serrate may interact at the protein level, it is conceivable that the Serrate and Delta proteins may compete for binding with the Notch protein.
When exogenously expressed, the C-terminal part is nuclear, phosphorylated, and acts as an insulin-responsive transcriptional activator.
Most adhesion GPCRs proteins undergo autoproteolysis at the GPS domain. ADGRE1 is predicted non-cleavable because of the lack of a consensus catalytic triad sequence within GPS domain.
Although involved in the same pathway as gon-1 and mig-17, it is probably not cleaved by these metalloproteases.
Separation of neuroblasts from the ectoderm into the inner part of embryo is one of the first steps of CNS development in insects, this process is under control of the neurogenic genes.
Notch and Serrate may interact at the protein level, it is conceivable that the Serrate and Delta proteins may compete for binding with the Notch protein.
When exogenously expressed, the C-terminal part is nuclear, phosphorylated, and acts as an insulin-responsive transcriptional activator.
Similarity
Belongs to the fibrillin family.
Belongs to the NOTCH family.
Belongs to the LTBP family.
Belongs to the EYS family.
Belongs to the fibulin family.
Belongs to the G-protein coupled receptor 2 family. Adhesion G-protein coupled receptor (ADGR) subfamily.
Belongs to the Crumbs protein family.
Belongs to the NOTCH family.
Belongs to the LTBP family.
Belongs to the EYS family.
Belongs to the fibulin family.
Belongs to the G-protein coupled receptor 2 family. Adhesion G-protein coupled receptor (ADGR) subfamily.
Belongs to the Crumbs protein family.
Keywords
Calcium
Complete proteome
Direct protein sequencing
Disulfide bond
EGF-like domain
Extracellular matrix
Glycoprotein
Hormone
Phosphoprotein
Reference proteome
Repeat
Secreted
Signal
Alternative splicing
Disease mutation
Polymorphism
3D-structure
Aortic aneurysm
Dwarfism
Heparin-binding
Activator
Angiogenesis
ANK repeat
Cell membrane
Developmental protein
Differentiation
Membrane
Metal-binding
Notch signaling pathway
Nucleus
Receptor
Transcription
Transcription regulation
Transmembrane
Transmembrane helix
Endosome
Neurogenesis
Oogenesis
Ubl conjugation
Cytoplasm
Methylation
Glaucoma
Growth factor binding
Hydroxylation
Cell projection
Cytoskeleton
Sensory transduction
Vision
Isopeptide bond
Proto-oncogene
Triplet repeat expansion
Cytoplasmic vesicle
Cleavage on pair of basic residues
Amelogenesis imperfecta
Cell adhesion
Cell junction
Adaptive immunity
G-protein coupled receptor
Immunity
Transducer
Deafness
Basement membrane
Sushi
Chromosomal rearrangement
Host-virus interaction
Cell cycle
Cell division
Leber congenital amaurosis
Retinitis pigmentosa
Age-related macular degeneration
Immunoglobulin domain
Mitosis
Lipid-binding
Gastrulation
Feature
chain Fibrillin-1
splice variant In isoform 2.
sequence variant In DA9; dbSNP:rs137852826.
glycosylation site N-linked (GlcNAc...) asparagine
splice variant In isoform 2.
sequence variant In DA9; dbSNP:rs137852826.
glycosylation site N-linked (GlcNAc...) asparagine
Uniprot
P98133.2
P35556.3
Q61555.2
P35555.4
P21783.3
P07207.3
+ More
Q9TV36.1 Q04721.3 Q9UM47.2 Q61982.1 Q14767.3 Q28019.2 O35516.2 Q61554.2 Q9R172.2 A2RUV0.2 Q75N90.3 P46530.1 O35806.1 Q9QW30.1 O08999.2 B8JI71.2 G3I6Z6.2 Q01705.3 Q07008.3 Q8K4G1.2 P46531.4 Q8N2S1.2 Q14766.4 P31695.3 Q99466.2 Q8CG19.2 P10079.2 Q00918.1 Q61810.4 Q9NS15.4 P37889.2 P34576.2 Q61549.1 Q5Y4N8.1 Q14246.3 Q8MJJ9.1 Q90Y57.1 P98095.2 Q90Y54.1 O42182.1 P78504.3 Q63722.2 Q9QXX0.1 O77469.3 Q5R6R1.3 Q8TER0.2 B3EWY9.1 O88281.1 O73775.2 Q92832.4 Q9QYE5.2 Q9Y219.3 Q8IX30.1 P18168.3 P23142.4 Q66PY1.1 P97607.1 D3YXG0.1 P82279.2 Q96RW7.2 Q62919.2 Q70E20.2 Q5ZQU0.2 Q08879.2 Q8IWY4.3 P10040.3 Q9JJS0.1 P14585.1 Q6NZL8.2 Q9NQ36.3 A0A2K5V015.1 Q5G872.1 Q5IJ48.2
Q9TV36.1 Q04721.3 Q9UM47.2 Q61982.1 Q14767.3 Q28019.2 O35516.2 Q61554.2 Q9R172.2 A2RUV0.2 Q75N90.3 P46530.1 O35806.1 Q9QW30.1 O08999.2 B8JI71.2 G3I6Z6.2 Q01705.3 Q07008.3 Q8K4G1.2 P46531.4 Q8N2S1.2 Q14766.4 P31695.3 Q99466.2 Q8CG19.2 P10079.2 Q00918.1 Q61810.4 Q9NS15.4 P37889.2 P34576.2 Q61549.1 Q5Y4N8.1 Q14246.3 Q8MJJ9.1 Q90Y57.1 P98095.2 Q90Y54.1 O42182.1 P78504.3 Q63722.2 Q9QXX0.1 O77469.3 Q5R6R1.3 Q8TER0.2 B3EWY9.1 O88281.1 O73775.2 Q92832.4 Q9QYE5.2 Q9Y219.3 Q8IX30.1 P18168.3 P23142.4 Q66PY1.1 P97607.1 D3YXG0.1 P82279.2 Q96RW7.2 Q62919.2 Q70E20.2 Q5ZQU0.2 Q08879.2 Q8IWY4.3 P10040.3 Q9JJS0.1 P14585.1 Q6NZL8.2 Q9NQ36.3 A0A2K5V015.1 Q5G872.1 Q5IJ48.2
Pubmed
7835900
19393038
8557636
21989719
8120105
14702039
+ More
15372022 1852206 15131124 18339631 19159218 23010571 24899048 26601954 7493032 9714438 9737771 10797416 11754102 19006240 20799338 21248752 25834781 27196565 7744963 19468303 8307578 11470817 16407178 20855508 24039232 8364578 15221638 16572171 15489334 7691719 1852207 8430317 10636927 9817919 2739055 1860873 11461921 12807887 15165854 15790312 17158881 17255108 17293099 20979188 21594992 21594993 21402694 24665001 24039054 24613577 24275569 24982166 26091039 27026396 27087445 26860060 9362480 8568869 8653794 12511552 15062093 19446531 24035709 8594563 10633129 12203987 1852208 1301946 1569206 8406497 8504310 8281141 7977366 8188302 8004112 7951214 7911051 8040326 8071963 7870075 8136837 7762551 7611299 7738200 8882780 8863159 9254848 9150726 9338581 9338588 9401003 8988160 9016526 9837823 9452085 10694921 10441597 10425041 11700157 12203992 12402346 11826022 12161601 12525539 14695540 15161917 16222657 16220557 17657824 18435798 19533785 19293843 20803651 21034599 19941982 20547088 20375004 21683322 21542060 22772377 2402639 11485984 3935325 3097517 10731132 12537572 10731137 3037327 2981631 2780284 8162848 7671825 10206646 10206647 10935637 11719214 11799064 12369105 12909620 15620649 15620650 17329366 18243100 18342578 18327897 20152183 21262215 23056424 27268051 27151950 28899667 29309414 14573873 10036187 16710414 1303260 9244302 10079256 11101851 12370315 17081983 17573339 18469519 18669648 18299578 19690332 20068231 21681853 21378989 21378985 23186163 25985737 29149593 29856954 29329397 17401372 16773578 21793104 21712856 23389697 8878478 15057824 17292860 24129315 25394726 9388399 10227618 10371548 10854111 11058919 11102981 10802807 11559313 11755616 11810186 12146805 12136071 12589106 12810003 15229130 15364702 15378071 15350543 15300988 16009764 15818833 18273901 23731542 24000151 7918097 11518718 11459941 15019995 7798248 8697098 12508121 10930463 10743502 11104663 19361779 20617341 20382221 22539340 8524260 8440332 8917536 10393120 7609614 18710934 19144319 21183079 21949356 7829516 19940141 11182080 11438922 20431018 24226769 14962672 11347906 8297791 10028916 22673903 26479776 1295745 11577080 9602168 16141072 23594743 27737822 28378834 30052645 21804562 10734111 8449489 7956822 12123574 12807718 1426644 1425352 9653148 10437788 8486742 9384671 10882062 10882063 11226752 12050162 15240571 15965470 18628966 21464124 21757702 23160044 23886940 23615612 25038227 28089369 28498977 30127001 15802643 1764995 15057822 25700513 12208849 19836010 15164053 1831692 9590294 10713164 16025100 20616313 22128911 21147854 21245387 25547411 26522984 12795601 15576031 16011479 16530044 28439555 30598546 25132448 9271198 9660815 16157329 23440719 25641372 2350783 15815621 8537398 2022183 8617200 8939931 10677208 12429738 15184403 15567420 18088087 18677313 22278742 14607119 1312643 9150355 8681805 14656967 10233982 11344305 9168133 9693032 14574404 12711388 12711389 2514273 3498216 2784773 2060714 15659374 2247454 7593177 7730318 12062452 12154076 9620332 17974005 19344874 27068007 8245130 10406956 8841408 8850569 10022829 11737251 25917920 9851916 11470827 11470828 12754521 17761667 8550607 9169125 15883173 15578266 7601460 17823986 24530099 25713288 11846885 7806230 16641997 8737292 18318008 22171320 9268641 9207788 9462510 10329626 11780052 8955070 9207787 10978356 21269460 18660822 19586525 9585603 10220506 10533065 11058898 11152664 11157803 11139247 11180599 12022040 12297837 12442286 12649809 12497640 15712272 16575836 23801938 20437614 7697721 10551863 10556292 9923656 15556863 16120639 15556862 17043142 19104038 22298704 15194686 22490231 23765379 9693030 8975702 16554811 21723284 16959974 9341252 9486542 9315665 10662552 15234972 21441952 2125287 1840519 15829515 15760269 2269669 9106159 10318851 15498874 10591208 11829738 2527614 1400330 7534784 7642629 8552629 9278415 9393974 9811350 9466671 9927660 11792823 11238726 12200142 11836357 11850827 12644824 19139490 24084572 8948600 17015624 21215633 24951538 10508521 11734541 15914641 12567265 11389483 11231775 11559858 12573663 12700176 12843338 15024725 15459956 15623792 15691574 16205573 17128490 16936081 17438615 17724218 18055821 18682808 19140180 19956407 20108431 20683928 20591486 21987686 20956273 22128245 21602930 22065545 22334370 28819299 14570714 10548494 12665856 15162516 8354280 2249686 7844816 9299350 10400671 11589703 17699513 12270931 16753137 18691976 2344615 12537569 3107986 10102271 11076972 11740560 12900452 17893096 25065591 30645584 11528127 11287194 22677548 22902404 24522195 26875496 27834687 3419531 7906398 3000611 9389650 11087664 19480626 15753045 15660164 16626681 15851977 25557779 25557780
15372022 1852206 15131124 18339631 19159218 23010571 24899048 26601954 7493032 9714438 9737771 10797416 11754102 19006240 20799338 21248752 25834781 27196565 7744963 19468303 8307578 11470817 16407178 20855508 24039232 8364578 15221638 16572171 15489334 7691719 1852207 8430317 10636927 9817919 2739055 1860873 11461921 12807887 15165854 15790312 17158881 17255108 17293099 20979188 21594992 21594993 21402694 24665001 24039054 24613577 24275569 24982166 26091039 27026396 27087445 26860060 9362480 8568869 8653794 12511552 15062093 19446531 24035709 8594563 10633129 12203987 1852208 1301946 1569206 8406497 8504310 8281141 7977366 8188302 8004112 7951214 7911051 8040326 8071963 7870075 8136837 7762551 7611299 7738200 8882780 8863159 9254848 9150726 9338581 9338588 9401003 8988160 9016526 9837823 9452085 10694921 10441597 10425041 11700157 12203992 12402346 11826022 12161601 12525539 14695540 15161917 16222657 16220557 17657824 18435798 19533785 19293843 20803651 21034599 19941982 20547088 20375004 21683322 21542060 22772377 2402639 11485984 3935325 3097517 10731132 12537572 10731137 3037327 2981631 2780284 8162848 7671825 10206646 10206647 10935637 11719214 11799064 12369105 12909620 15620649 15620650 17329366 18243100 18342578 18327897 20152183 21262215 23056424 27268051 27151950 28899667 29309414 14573873 10036187 16710414 1303260 9244302 10079256 11101851 12370315 17081983 17573339 18469519 18669648 18299578 19690332 20068231 21681853 21378989 21378985 23186163 25985737 29149593 29856954 29329397 17401372 16773578 21793104 21712856 23389697 8878478 15057824 17292860 24129315 25394726 9388399 10227618 10371548 10854111 11058919 11102981 10802807 11559313 11755616 11810186 12146805 12136071 12589106 12810003 15229130 15364702 15378071 15350543 15300988 16009764 15818833 18273901 23731542 24000151 7918097 11518718 11459941 15019995 7798248 8697098 12508121 10930463 10743502 11104663 19361779 20617341 20382221 22539340 8524260 8440332 8917536 10393120 7609614 18710934 19144319 21183079 21949356 7829516 19940141 11182080 11438922 20431018 24226769 14962672 11347906 8297791 10028916 22673903 26479776 1295745 11577080 9602168 16141072 23594743 27737822 28378834 30052645 21804562 10734111 8449489 7956822 12123574 12807718 1426644 1425352 9653148 10437788 8486742 9384671 10882062 10882063 11226752 12050162 15240571 15965470 18628966 21464124 21757702 23160044 23886940 23615612 25038227 28089369 28498977 30127001 15802643 1764995 15057822 25700513 12208849 19836010 15164053 1831692 9590294 10713164 16025100 20616313 22128911 21147854 21245387 25547411 26522984 12795601 15576031 16011479 16530044 28439555 30598546 25132448 9271198 9660815 16157329 23440719 25641372 2350783 15815621 8537398 2022183 8617200 8939931 10677208 12429738 15184403 15567420 18088087 18677313 22278742 14607119 1312643 9150355 8681805 14656967 10233982 11344305 9168133 9693032 14574404 12711388 12711389 2514273 3498216 2784773 2060714 15659374 2247454 7593177 7730318 12062452 12154076 9620332 17974005 19344874 27068007 8245130 10406956 8841408 8850569 10022829 11737251 25917920 9851916 11470827 11470828 12754521 17761667 8550607 9169125 15883173 15578266 7601460 17823986 24530099 25713288 11846885 7806230 16641997 8737292 18318008 22171320 9268641 9207788 9462510 10329626 11780052 8955070 9207787 10978356 21269460 18660822 19586525 9585603 10220506 10533065 11058898 11152664 11157803 11139247 11180599 12022040 12297837 12442286 12649809 12497640 15712272 16575836 23801938 20437614 7697721 10551863 10556292 9923656 15556863 16120639 15556862 17043142 19104038 22298704 15194686 22490231 23765379 9693030 8975702 16554811 21723284 16959974 9341252 9486542 9315665 10662552 15234972 21441952 2125287 1840519 15829515 15760269 2269669 9106159 10318851 15498874 10591208 11829738 2527614 1400330 7534784 7642629 8552629 9278415 9393974 9811350 9466671 9927660 11792823 11238726 12200142 11836357 11850827 12644824 19139490 24084572 8948600 17015624 21215633 24951538 10508521 11734541 15914641 12567265 11389483 11231775 11559858 12573663 12700176 12843338 15024725 15459956 15623792 15691574 16205573 17128490 16936081 17438615 17724218 18055821 18682808 19140180 19956407 20108431 20683928 20591486 21987686 20956273 22128245 21602930 22065545 22334370 28819299 14570714 10548494 12665856 15162516 8354280 2249686 7844816 9299350 10400671 11589703 17699513 12270931 16753137 18691976 2344615 12537569 3107986 10102271 11076972 11740560 12900452 17893096 25065591 30645584 11528127 11287194 22677548 22902404 24522195 26875496 27834687 3419531 7906398 3000611 9389650 11087664 19480626 15753045 15660164 16626681 15851977 25557779 25557780
EMBL
L28748
DAAA02029120
DAAA02029121
DAAA02029122
U03272
AK300440
+ More
AC025169 AC034235 AC113387 X62009 AB209735 L39790 AC102317 AC127358 S69359 L13923 AB177803 GU143398 AC022467 AC084757 AC084758 CH471082 BC146854 L19896 X63556 X62008 S54426 S54425 M33874 M16152 M16153 M16149 M16150 M16151 K03508 M13689 K03507 AE014298 AL035436 AL035395 M16025 M12175 AF073800 AF308601 AF315356 AL359752 AL512503 AL596222 U77493 U97669 AF058900 AF058881 AF058882 AF058883 AF058884 AF058885 AF058886 AF058887 AF058888 AF058889 AF058890 AF058891 AF058892 AF058893 AF058894 AF058895 AF058896 AF058897 AF058898 AF058899 AC004257 AC004663 X74760 Z37976 S82451 AC013451 U35363 D32210 AC154173 AC164091 CH466620 X68279 U31881 L29454 U22493 AL844547 AL928930 AF164486 AAMC01043423 AAMC01043424 AAMC01043425 AAMC01043426 BC133053 AY165863 AY165864 AY165865 AB177797 AB177798 AB177799 AB177800 AB053450 AC008946 AC022146 X69088 Y12760 M93661 AF004874 AK052980 BX005106 BX323836 CR456624 CU570696 JH001398 Z11886 AF508809 AB100603 AL732541 CH466542 BC138441 BC138442 L02613 X68278 AK154528 AK157475 AJ238029 X82562 X57405 AABR06021907 AABR06021908 CH474001 AF410798 AF410799 AC157561 BC059016 AF308602 AL592301 AL354671 M73980 AB209873 Y13622 AF051344 AF051345 AK074499 AC010412 M34057 AF489528 AB208801 AC019195 AC019127 AC020594 CH471053 BC130289 L48925 BP291349 M80456 U43691 AF030001 CT009767 AB016771 AB016772 AB016773 AB016774 D63395 D86566 U95299 U89335 AL662884 BX284686 BX284927 CR812478 CR933878 AB023961 AB024520 AB024578 AF346465 AF346434 AF346435 AF346436 AF346437 AF346438 AF346439 AF346440 AF346441 AF346442 AF346443 AF346444 AF346445 AF346446 AF346447 AF346448 AF346449 AF346450 AF346451 AF346452 AF346453 AF346454 AF346455 AF346456 AF346457 AF346458 AF346459 AF346460 AF346461 AF346462 AF346463 AF346464 AY143161 AF022889 AC118018 AC126550 AC154178 AC154491 CT033758 BC094612 AK050380 AK080024 AAN38831.1 L08692 X17530 M17421 X17533 M55431 L40459 AK080869 AC134563 AF135960 AK024477 AF011407 BC008761 AL117551 X75285 AF135253 AF135239 AF135240 AF135241 AF135242 AF135243 AF135244 AF135245 AF135246 AF135247 AF135248 AF135249 AF135250 AF135251 AF135252 AC121990 AC131764 CH466523 AF139060 Z30974 Z30423 X93328 U66888 BC075688 AY686632 X81479 AB065918 DQ217942 AK131562 AK297003 AK297011 AC020895 AC025278 BC059395 AF395659 AF229448 X82494 AY130458 AY130456 AY130457 AY130459 AK304827 AC090509 AF229451 AF013751 AF013752 AF003837 U73936 AF028593 U61276 AK302554 AL035456 BC126205 BC126207 U77720 L38483 AF171092 BC058675 AB212860 AY851363 AF051401 AF051402 AF051403 AF070477 Z68749 Z68219 NDHI03003297 CR860424 AC005237 AC093585 AC104809 AK074062 AK074075 AF439717 AF439718 BC027939 JR987773 AB011532 AF051399 AF051400 D83017 AK313445 EU518937 AC010811 AC067794 AC069575 AC087279 AC090707 AC090857 AC099730 AC105190 AC108460 CH471064 BC069674 BC096100 BC096101 BC096102 U57523 AF038572 AC160929 AF010137 Y14495 AF020201 AF003521 AF029778 AF029779 AF111170 Y14330 AY639608 AF452494 AK092062 AK291218 Z97832 CH471081 BC052263 CR936607 AAH52263.2 AAN76808.1 AAU08347.1 BAC03798.1 M35759 X56811 AE014297 X53741 X53742 X53743 U01244 AF126110 AF217999 AL021391 Z95331 Z98047 BC022497 AY040589 AY639609 CT009658 BC079849 AAH79849.1 AAU08348.1 U70050 AC111145 AC113326 AC115051 AC124120 AF154671 AY043323 AY043324 AY043325 AJ748821 BX640729 AK299368 AL136322 AL139136 AL513325 AL356315 CH471067 BC136271 AF156100 AK056336 AK056557 AL118512 AL121996 AL133515 AL133553 AL135796 AL135797 AL391824 BX928748 AJ306906 U48246 AY169783 AJ584850 BC145886 AK032805 AABR03068156 AABR03069106 AABR03069488 AABR03071665 AABR03072503 AF439715 AF439719 X70854 X70853 AK086451 AK035388 BC007140 AY040588 AF525689 Z99756 Z82214 M33753 AY118509 X05144 AJ400878 M12069 Z14092 AF276425 AK041590 BC066066 AJ400877 AK123039 AC079296 BC111690 AB193554 AY741664 DQ438942 AY720432 AK123000 AK126775 AL445489 AL365504 DQ426866
AC025169 AC034235 AC113387 X62009 AB209735 L39790 AC102317 AC127358 S69359 L13923 AB177803 GU143398 AC022467 AC084757 AC084758 CH471082 BC146854 L19896 X63556 X62008 S54426 S54425 M33874 M16152 M16153 M16149 M16150 M16151 K03508 M13689 K03507 AE014298 AL035436 AL035395 M16025 M12175 AF073800 AF308601 AF315356 AL359752 AL512503 AL596222 U77493 U97669 AF058900 AF058881 AF058882 AF058883 AF058884 AF058885 AF058886 AF058887 AF058888 AF058889 AF058890 AF058891 AF058892 AF058893 AF058894 AF058895 AF058896 AF058897 AF058898 AF058899 AC004257 AC004663 X74760 Z37976 S82451 AC013451 U35363 D32210 AC154173 AC164091 CH466620 X68279 U31881 L29454 U22493 AL844547 AL928930 AF164486 AAMC01043423 AAMC01043424 AAMC01043425 AAMC01043426 BC133053 AY165863 AY165864 AY165865 AB177797 AB177798 AB177799 AB177800 AB053450 AC008946 AC022146 X69088 Y12760 M93661 AF004874 AK052980 BX005106 BX323836 CR456624 CU570696 JH001398 Z11886 AF508809 AB100603 AL732541 CH466542 BC138441 BC138442 L02613 X68278 AK154528 AK157475 AJ238029 X82562 X57405 AABR06021907 AABR06021908 CH474001 AF410798 AF410799 AC157561 BC059016 AF308602 AL592301 AL354671 M73980 AB209873 Y13622 AF051344 AF051345 AK074499 AC010412 M34057 AF489528 AB208801 AC019195 AC019127 AC020594 CH471053 BC130289 L48925 BP291349 M80456 U43691 AF030001 CT009767 AB016771 AB016772 AB016773 AB016774 D63395 D86566 U95299 U89335 AL662884 BX284686 BX284927 CR812478 CR933878 AB023961 AB024520 AB024578 AF346465 AF346434 AF346435 AF346436 AF346437 AF346438 AF346439 AF346440 AF346441 AF346442 AF346443 AF346444 AF346445 AF346446 AF346447 AF346448 AF346449 AF346450 AF346451 AF346452 AF346453 AF346454 AF346455 AF346456 AF346457 AF346458 AF346459 AF346460 AF346461 AF346462 AF346463 AF346464 AY143161 AF022889 AC118018 AC126550 AC154178 AC154491 CT033758 BC094612 AK050380 AK080024 AAN38831.1 L08692 X17530 M17421 X17533 M55431 L40459 AK080869 AC134563 AF135960 AK024477 AF011407 BC008761 AL117551 X75285 AF135253 AF135239 AF135240 AF135241 AF135242 AF135243 AF135244 AF135245 AF135246 AF135247 AF135248 AF135249 AF135250 AF135251 AF135252 AC121990 AC131764 CH466523 AF139060 Z30974 Z30423 X93328 U66888 BC075688 AY686632 X81479 AB065918 DQ217942 AK131562 AK297003 AK297011 AC020895 AC025278 BC059395 AF395659 AF229448 X82494 AY130458 AY130456 AY130457 AY130459 AK304827 AC090509 AF229451 AF013751 AF013752 AF003837 U73936 AF028593 U61276 AK302554 AL035456 BC126205 BC126207 U77720 L38483 AF171092 BC058675 AB212860 AY851363 AF051401 AF051402 AF051403 AF070477 Z68749 Z68219 NDHI03003297 CR860424 AC005237 AC093585 AC104809 AK074062 AK074075 AF439717 AF439718 BC027939 JR987773 AB011532 AF051399 AF051400 D83017 AK313445 EU518937 AC010811 AC067794 AC069575 AC087279 AC090707 AC090857 AC099730 AC105190 AC108460 CH471064 BC069674 BC096100 BC096101 BC096102 U57523 AF038572 AC160929 AF010137 Y14495 AF020201 AF003521 AF029778 AF029779 AF111170 Y14330 AY639608 AF452494 AK092062 AK291218 Z97832 CH471081 BC052263 CR936607 AAH52263.2 AAN76808.1 AAU08347.1 BAC03798.1 M35759 X56811 AE014297 X53741 X53742 X53743 U01244 AF126110 AF217999 AL021391 Z95331 Z98047 BC022497 AY040589 AY639609 CT009658 BC079849 AAH79849.1 AAU08348.1 U70050 AC111145 AC113326 AC115051 AC124120 AF154671 AY043323 AY043324 AY043325 AJ748821 BX640729 AK299368 AL136322 AL139136 AL513325 AL356315 CH471067 BC136271 AF156100 AK056336 AK056557 AL118512 AL121996 AL133515 AL133553 AL135796 AL135797 AL391824 BX928748 AJ306906 U48246 AY169783 AJ584850 BC145886 AK032805 AABR03068156 AABR03069106 AABR03069488 AABR03071665 AABR03072503 AF439715 AF439719 X70854 X70853 AK086451 AK035388 BC007140 AY040588 AF525689 Z99756 Z82214 M33753 AY118509 X05144 AJ400878 M12069 Z14092 AF276425 AK041590 BC066066 AJ400877 AK123039 AC079296 BC111690 AB193554 AY741664 DQ438942 AY720432 AK123000 AK126775 AL445489 AL365504 DQ426866
Proteomes
PRIDE
P98133
P35556
Q61555
P35555
P21783
P07207
+ More
Q9TV36 Q04721 Q9UM47 Q61982 Q14767 Q28019 O35516 Q61554 Q9R172 Q75N90 P46530 O35806 Q9QW30 O08999 G3I6Z6 Q01705 Q07008 Q8K4G1 P46531 Q8N2S1 Q14766 P31695 Q99466 Q8CG19 P10079 Q00918 Q61810 Q9NS15 P37889 P34576 Q61549 Q5Y4N8 Q14246 Q8MJJ9 Q90Y57 P98095 Q90Y54 O42182 P78504 Q63722 Q9QXX0 Q5R6R1 Q8TER0 O88281 O73775 Q92832 Q9QYE5 Q9Y219 Q8IX30 P18168 P23142 Q66PY1 P97607 D3YXG0 P82279 Q96RW7 Q62919 Q70E20 Q5ZQU0 Q08879 Q8IWY4 P10040 Q9JJS0 P14585 Q6NZL8 Q9NQ36 Q5G872 Q5IJ48
Q9TV36 Q04721 Q9UM47 Q61982 Q14767 Q28019 O35516 Q61554 Q9R172 Q75N90 P46530 O35806 Q9QW30 O08999 G3I6Z6 Q01705 Q07008 Q8K4G1 P46531 Q8N2S1 Q14766 P31695 Q99466 Q8CG19 P10079 Q00918 Q61810 Q9NS15 P37889 P34576 Q61549 Q5Y4N8 Q14246 Q8MJJ9 Q90Y57 P98095 Q90Y54 O42182 P78504 Q63722 Q9QXX0 Q5R6R1 Q8TER0 O88281 O73775 Q92832 Q9QYE5 Q9Y219 Q8IX30 P18168 P23142 Q66PY1 P97607 D3YXG0 P82279 Q96RW7 Q62919 Q70E20 Q5ZQU0 Q08879 Q8IWY4 P10040 Q9JJS0 P14585 Q6NZL8 Q9NQ36 Q5G872 Q5IJ48
Pfam
PF00683 TB
+ More
PF12662 cEGF
PF18193 Fibrillin_U_N
PF07645 EGF_CA
PF12661 hEGF
PF00008 EGF
PF12796 Ank_2
PF07684 NODP
PF00066 Notch
PF11936 DUF3454
PF06816 NOD
PF00023 Ank
PF02210 Laminin_G_2
PF01382 Avidin
PF00431 CUB
PF01821 ANATO
PF00057 Ldl_recept_a
PF01390 SEA
PF00092 VWA
PF00002 7tm_2
PF01825 GPS
PF07657 MNNL
PF01414 DSL
PF06119 NIDO
PF00041 fn3
PF00094 VWD
PF00090 TSP_1
PF00053 Laminin_EGF
PF12947 EGF_3
PF00093 VWC
PF07699 Ephrin_rec_like
PF07679 I-set
PF07474 G2F
PF00054 Laminin_G_1
PF12662 cEGF
PF18193 Fibrillin_U_N
PF07645 EGF_CA
PF12661 hEGF
PF00008 EGF
PF12796 Ank_2
PF07684 NODP
PF00066 Notch
PF11936 DUF3454
PF06816 NOD
PF00023 Ank
PF02210 Laminin_G_2
PF01382 Avidin
PF00431 CUB
PF01821 ANATO
PF00057 Ldl_recept_a
PF01390 SEA
PF00092 VWA
PF00002 7tm_2
PF01825 GPS
PF07657 MNNL
PF01414 DSL
PF06119 NIDO
PF00041 fn3
PF00094 VWD
PF00090 TSP_1
PF00053 Laminin_EGF
PF12947 EGF_3
PF00093 VWC
PF07699 Ephrin_rec_like
PF07679 I-set
PF07474 G2F
PF00054 Laminin_G_1
Interpro
IPR026823
cEGF
+ More
IPR009030 Growth_fac_rcpt_cys_sf
IPR036773 TB_dom_sf
IPR040872 Fibrillin_U_N
IPR001881 EGF-like_Ca-bd_dom
IPR000152 EGF-type_Asp/Asn_hydroxyl_site
IPR017878 TB_dom
IPR000742 EGF-like_dom
IPR018097 EGF_Ca-bd_CS
IPR013032 EGF-like_CS
IPR000800 Notch_dom
IPR024600 DUF3454_notch
IPR002110 Ankyrin_rpt
IPR036770 Ankyrin_rpt-contain_sf
IPR035993 Notch-like_dom_sf
IPR010660 Notch_NOD_dom
IPR022362 Notch_1
IPR020683 Ankyrin_rpt-contain_dom
IPR011656 Notch_NODP_dom
IPR008297 Notch
IPR022336 Notch_2
IPR022331 Notch_3
IPR001791 Laminin_G
IPR013320 ConA-like_dom_sf
IPR022355 Notch_4
IPR036896 Avidin-like_sf
IPR005468 Avidin/str
IPR000859 CUB_dom
IPR005469 Avidin
IPR035914 Sperma_CUB_dom_sf
IPR017889 Avidin-like_CS
IPR000020 Anaphylatoxin/fibulin
IPR037286 Fibulin-2
IPR036465 vWFA_dom_sf
IPR002172 LDrepeatLR_classA_rpt
IPR036055 LDL_receptor-like_sf
IPR000082 SEA_dom
IPR002035 VWF_A
IPR000832 GPCR_2_secretin-like
IPR017981 GPCR_2-like
IPR001740 GPCR_2_EMR1-like_rcpt
IPR017983 GPCR_2_secretin-like_CS
IPR000203 GPS
IPR017048 Fibulin-1
IPR026219 Jagged/Serrate
IPR011651 Notch_ligand_N
IPR001774 DSL
IPR001007 VWF_dom
IPR036116 FN3_sf
IPR035976 Sushi/SCR/CCP_sf
IPR013783 Ig-like_fold
IPR003961 FN3_dom
IPR000436 Sushi_SCR_CCP_dom
IPR003886 NIDO_dom
IPR000884 TSP1_rpt
IPR036383 TSP1_rpt_sf
IPR001846 VWF_type-D
IPR005533 AMOP_dom
IPR002049 Laminin_EGF
IPR011489 EMI_domain
IPR024731 EGF_dom
IPR033108 Jag2
IPR011641 Tyr-kin_ephrin_A/B_rcpt-like
IPR013106 Ig_V-set
IPR009017 GFP
IPR006605 G2_nidogen/fibulin_G2F
IPR003599 Ig_sub
IPR007110 Ig-like_dom
IPR013098 Ig_I-set
IPR036179 Ig-like_dom_sf
IPR003598 Ig_sub2
IPR009030 Growth_fac_rcpt_cys_sf
IPR036773 TB_dom_sf
IPR040872 Fibrillin_U_N
IPR001881 EGF-like_Ca-bd_dom
IPR000152 EGF-type_Asp/Asn_hydroxyl_site
IPR017878 TB_dom
IPR000742 EGF-like_dom
IPR018097 EGF_Ca-bd_CS
IPR013032 EGF-like_CS
IPR000800 Notch_dom
IPR024600 DUF3454_notch
IPR002110 Ankyrin_rpt
IPR036770 Ankyrin_rpt-contain_sf
IPR035993 Notch-like_dom_sf
IPR010660 Notch_NOD_dom
IPR022362 Notch_1
IPR020683 Ankyrin_rpt-contain_dom
IPR011656 Notch_NODP_dom
IPR008297 Notch
IPR022336 Notch_2
IPR022331 Notch_3
IPR001791 Laminin_G
IPR013320 ConA-like_dom_sf
IPR022355 Notch_4
IPR036896 Avidin-like_sf
IPR005468 Avidin/str
IPR000859 CUB_dom
IPR005469 Avidin
IPR035914 Sperma_CUB_dom_sf
IPR017889 Avidin-like_CS
IPR000020 Anaphylatoxin/fibulin
IPR037286 Fibulin-2
IPR036465 vWFA_dom_sf
IPR002172 LDrepeatLR_classA_rpt
IPR036055 LDL_receptor-like_sf
IPR000082 SEA_dom
IPR002035 VWF_A
IPR000832 GPCR_2_secretin-like
IPR017981 GPCR_2-like
IPR001740 GPCR_2_EMR1-like_rcpt
IPR017983 GPCR_2_secretin-like_CS
IPR000203 GPS
IPR017048 Fibulin-1
IPR026219 Jagged/Serrate
IPR011651 Notch_ligand_N
IPR001774 DSL
IPR001007 VWF_dom
IPR036116 FN3_sf
IPR035976 Sushi/SCR/CCP_sf
IPR013783 Ig-like_fold
IPR003961 FN3_dom
IPR000436 Sushi_SCR_CCP_dom
IPR003886 NIDO_dom
IPR000884 TSP1_rpt
IPR036383 TSP1_rpt_sf
IPR001846 VWF_type-D
IPR005533 AMOP_dom
IPR002049 Laminin_EGF
IPR011489 EMI_domain
IPR024731 EGF_dom
IPR033108 Jag2
IPR011641 Tyr-kin_ephrin_A/B_rcpt-like
IPR013106 Ig_V-set
IPR009017 GFP
IPR006605 G2_nidogen/fibulin_G2F
IPR003599 Ig_sub
IPR007110 Ig-like_dom
IPR013098 Ig_I-set
IPR036179 Ig-like_dom_sf
IPR003598 Ig_sub2
SUPFAM
Gene 3D
ProteinModelPortal
P98133.2
P35556.3
Q61555.2
P35555.4
P21783.3
P07207.3
+ More
Q9TV36.1 Q04721.3 Q9UM47.2 Q61982.1 Q14767.3 Q28019.2 O35516.2 Q61554.2 Q9R172.2 A2RUV0.2 Q75N90.3 P46530.1 O35806.1 Q9QW30.1 O08999.2 B8JI71.2 G3I6Z6.2 Q01705.3 Q07008.3 Q8K4G1.2 P46531.4 Q8N2S1.2 Q14766.4 P31695.3 Q99466.2 Q8CG19.2 P10079.2 Q00918.1 Q61810.4 Q9NS15.4 P37889.2 P34576.2 Q61549.1 Q5Y4N8.1 Q14246.3 Q8MJJ9.1 Q90Y57.1 P98095.2 Q90Y54.1 O42182.1 P78504.3 Q63722.2 Q9QXX0.1 O77469.3 Q5R6R1.3 Q8TER0.2 B3EWY9.1 O88281.1 O73775.2 Q92832.4 Q9QYE5.2 Q9Y219.3 Q8IX30.1 P18168.3 P23142.4 Q66PY1.1 P97607.1 D3YXG0.1 P82279.2 Q96RW7.2 Q62919.2 Q70E20.2 Q5ZQU0.2 Q08879.2 Q8IWY4.3 P10040.3 Q9JJS0.1 P14585.1 Q6NZL8.2 Q9NQ36.3 A0A2K5V015.1 Q5G872.1 Q5IJ48.2
Q9TV36.1 Q04721.3 Q9UM47.2 Q61982.1 Q14767.3 Q28019.2 O35516.2 Q61554.2 Q9R172.2 A2RUV0.2 Q75N90.3 P46530.1 O35806.1 Q9QW30.1 O08999.2 B8JI71.2 G3I6Z6.2 Q01705.3 Q07008.3 Q8K4G1.2 P46531.4 Q8N2S1.2 Q14766.4 P31695.3 Q99466.2 Q8CG19.2 P10079.2 Q00918.1 Q61810.4 Q9NS15.4 P37889.2 P34576.2 Q61549.1 Q5Y4N8.1 Q14246.3 Q8MJJ9.1 Q90Y57.1 P98095.2 Q90Y54.1 O42182.1 P78504.3 Q63722.2 Q9QXX0.1 O77469.3 Q5R6R1.3 Q8TER0.2 B3EWY9.1 O88281.1 O73775.2 Q92832.4 Q9QYE5.2 Q9Y219.3 Q8IX30.1 P18168.3 P23142.4 Q66PY1.1 P97607.1 D3YXG0.1 P82279.2 Q96RW7.2 Q62919.2 Q70E20.2 Q5ZQU0.2 Q08879.2 Q8IWY4.3 P10040.3 Q9JJS0.1 P14585.1 Q6NZL8.2 Q9NQ36.3 A0A2K5V015.1 Q5G872.1 Q5IJ48.2
Ontologies
GO
GO:0005509
GO:0042593
GO:0005201
GO:0005576
GO:0010737
GO:0005615
GO:0062023
GO:0005179
GO:0031012
GO:0006006
GO:0001527
GO:0034199
GO:0008201
GO:0030326
GO:0060346
GO:0035583
GO:0048048
GO:0030198
GO:0030501
GO:0043010
GO:0030023
GO:0045669
GO:0035108
GO:0005604
GO:0001656
GO:0001501
GO:0043687
GO:0035582
GO:0007507
GO:0005178
GO:0071560
GO:0005788
GO:2001205
GO:0044877
GO:0042802
GO:0044267
GO:0045671
GO:1990314
GO:0048050
GO:0033627
GO:0050793
GO:0030154
GO:0005886
GO:0038023
GO:0000122
GO:0001525
GO:0060271
GO:0016021
GO:0005654
GO:0061314
GO:0005737
GO:0035204
GO:0048749
GO:0010001
GO:1900087
GO:0008356
GO:0008284
GO:0008347
GO:0043525
GO:0030720
GO:0060250
GO:0007519
GO:0005829
GO:0030713
GO:0035003
GO:0097150
GO:0005634
GO:0022416
GO:0036099
GO:0007398
GO:0045466
GO:0007314
GO:0016360
GO:0002052
GO:0050877
GO:0007473
GO:0045893
GO:0010628
GO:2000035
GO:0007298
GO:0005915
GO:2000048
GO:0005769
GO:0048665
GO:0005796
GO:0007451
GO:0035153
GO:0061382
GO:0009952
GO:0060571
GO:0007450
GO:0007015
GO:0035162
GO:0007346
GO:0005768
GO:0007422
GO:0048052
GO:0008045
GO:0004888
GO:0035172
GO:0032991
GO:0030139
GO:0007474
GO:0042691
GO:0048863
GO:0046666
GO:0035214
GO:0042689
GO:0008587
GO:0007405
GO:0046667
GO:0060289
GO:0046329
GO:0016348
GO:0042676
GO:0045316
GO:0035222
GO:0001708
GO:0001745
GO:0035165
GO:0060288
GO:0048664
GO:0007440
GO:0040008
GO:0035171
GO:0048190
GO:0007498
GO:0007464
GO:0036011
GO:0014019
GO:0008407
GO:0050768
GO:0042688
GO:0048803
GO:0009986
GO:1902692
GO:1990433
GO:0030708
GO:0007297
GO:0002213
GO:0007476
GO:0048542
GO:0046843
GO:0007446
GO:0007400
GO:0009608
GO:0050767
GO:0016333
GO:0016330
GO:0007419
GO:0043697
GO:0035167
GO:0007423
GO:0007411
GO:0030718
GO:0007616
GO:0007455
GO:0010629
GO:0006110
GO:0005887
GO:0046331
GO:0005912
GO:0008340
GO:0007403
GO:0009950
GO:0046716
GO:0042067
GO:0007219
GO:0036335
GO:0003682
GO:0051489
GO:0007391
GO:0007447
GO:0005770
GO:0030707
GO:0042686
GO:0048477
GO:0007478
GO:0061331
GO:0007521
GO:0045595
GO:0045944
GO:0007293
GO:0006367
GO:0010838
GO:0006915
GO:0019827
GO:0003184
GO:0001709
GO:0016020
GO:0060413
GO:0007399
GO:2001204
GO:0046579
GO:0002315
GO:0030097
GO:0043235
GO:0007275
GO:0009887
GO:0043066
GO:0045967
GO:2000249
GO:0046849
GO:0070374
GO:0000139
GO:0007050
GO:0006355
GO:0005789
GO:0072104
GO:0048844
GO:0007221
GO:0030900
GO:0045296
GO:0048663
GO:0015629
GO:0045665
GO:0045746
GO:0019899
GO:0048661
GO:0045596
GO:0006605
GO:0097435
GO:0070062
GO:0019838
GO:0007179
GO:0050436
GO:0009306
GO:0005623
GO:0071953
GO:0072015
GO:0001701
GO:0005929
GO:0072014
GO:0001947
GO:0035264
GO:0006959
GO:0072602
GO:0001890
GO:1990705
GO:0002437
GO:0043065
GO:0006357
GO:0045672
GO:0035622
GO:0043011
GO:0070986
GO:0001889
GO:0060674
GO:0051059
GO:0072576
GO:0042742
GO:0061073
GO:0030513
GO:0042060
GO:0002011
GO:0007368
GO:0072574
GO:0001822
GO:0042246
GO:0021986
GO:0001756
GO:0021531
GO:0001840
GO:0048699
GO:0048259
GO:0031016
GO:0048337
GO:0048936
GO:0031017
GO:0021514
GO:0042663
GO:0035907
GO:0021523
GO:0055016
GO:0002244
GO:0005856
GO:0033165
GO:0050896
GO:0007601
GO:0046549
GO:0035845
GO:0045494
GO:0016324
GO:0021915
GO:0005794
GO:0035924
GO:0005112
GO:0003203
GO:0061384
GO:0043565
GO:0003162
GO:0010832
GO:0045668
GO:0045687
GO:0048708
GO:0030334
GO:0050434
GO:0045747
GO:0060253
GO:1903849
GO:0008593
GO:2000737
GO:2001027
GO:0055008
GO:0030514
GO:0003182
GO:0072044
GO:0007492
GO:0048711
GO:0003181
GO:0000978
GO:0060317
GO:0045618
GO:0001228
GO:0003198
GO:0048845
GO:0003209
GO:0045607
GO:0009912
GO:0003344
GO:0060843
GO:0090051
GO:0031069
GO:0045892
GO:0048103
GO:0060982
GO:0061344
GO:0003252
GO:0001726
GO:0060548
GO:0071372
GO:0032496
GO:0030182
GO:0002040
GO:0014031
GO:0003160
GO:0032495
GO:0021515
GO:0042127
GO:0072017
GO:0045608
GO:0031410
GO:0035914
GO:0048873
GO:0003241
GO:0007386
GO:0003219
GO:0060528
GO:0060740
GO:0062043
GO:0008285
GO:0071944
GO:0060956
GO:0045165
GO:0030216
GO:1901201
GO:0061419
GO:0008544
GO:0003157
GO:0043086
GO:0014807
GO:0003332
GO:0035148
GO:0003222
GO:0050679
GO:0060768
GO:0005783
GO:0003180
GO:1902263
GO:0030027
GO:2000974
GO:0001837
GO:0060411
GO:0046982
GO:0003256
GO:0035116
GO:0060979
GO:0045955
GO:0046533
GO:0003151
GO:0060948
GO:0010718
GO:0003270
GO:0003208
GO:0031960
GO:0003192
GO:0010614
GO:0003207
GO:0031100
GO:0007409
GO:0003197
GO:2000811
GO:0070168
GO:0007283
GO:0030324
GO:0003700
GO:0090090
GO:0003169
GO:0030335
GO:0045662
GO:0004857
GO:0010468
GO:0003213
GO:1902339
GO:0002051
GO:0046427
GO:0048754
GO:0060038
GO:0001669
GO:0060412
GO:0030279
GO:0010812
GO:0060842
GO:0050678
GO:0060045
GO:0003264
GO:0072144
GO:0002193
GO:0120163
GO:0045603
GO:0003214
GO:0003273
GO:0045070
GO:0048709
GO:1901189
GO:0048715
GO:0031490
GO:0007420
GO:0030162
GO:0046879
GO:0050431
GO:0006955
GO:0006457
GO:0001558
GO:0030252
GO:0005024
GO:0017015
GO:0005539
GO:0035904
GO:0003281
GO:0060976
GO:1901388
GO:0070613
GO:0001886
GO:0001944
GO:0001569
GO:0045446
GO:0045766
GO:0045602
GO:0032880
GO:0001763
GO:0030879
GO:0035278
GO:0048471
GO:0030425
GO:0038045
GO:0005739
GO:0032967
GO:0043025
GO:0032579
GO:0071305
GO:0071374
GO:0036120
GO:0071260
GO:2000741
GO:0060430
GO:0032331
GO:0045780
GO:0060349
GO:1902462
GO:0036363
GO:0030502
GO:0050840
GO:0010811
GO:0005518
GO:0005882
GO:0030056
GO:0019215
GO:0007160
GO:0007166
GO:0002250
GO:0004930
GO:0009897
GO:0007189
GO:0007155
GO:0007186
GO:0016504
GO:0030878
GO:0060218
GO:1903561
GO:0042472
GO:0031101
GO:0048752
GO:1904888
GO:0060325
GO:0032474
GO:0060351
GO:0009953
GO:0060117
GO:0060872
GO:0043589
GO:0090497
GO:0035122
GO:0045599
GO:0001953
GO:0061156
GO:0035909
GO:0061444
GO:0030336
GO:0008083
GO:0045639
GO:0005543
GO:0072006
GO:0061309
GO:0022408
GO:0005198
GO:0001974
GO:0003215
GO:0045445
GO:0002456
GO:0042491
GO:0072070
GO:0048018
GO:0045177
GO:0048839
GO:0008104
GO:0040017
GO:0005815
GO:0001750
GO:0010469
GO:0030197
GO:0005176
GO:0010669
GO:1903363
GO:0033689
GO:0005635
GO:0005080
GO:0030155
GO:0030217
GO:0045061
GO:1990134
GO:0042475
GO:0007605
GO:0042492
GO:0016331
GO:0003016
GO:0051291
GO:0022617
GO:0045880
GO:0051260
GO:0043208
GO:0007435
GO:0045179
GO:0035017
GO:0007436
GO:0048100
GO:0030673
GO:0014009
GO:1900025
GO:0001933
GO:1904237
GO:0016032
GO:2000146
GO:2000647
GO:1904188
GO:0008022
GO:0007566
GO:0070051
GO:0001968
GO:0007162
GO:0070373
GO:2001202
GO:0072378
GO:0048146
GO:0001666
GO:0008584
GO:0009617
GO:0051301
GO:0007049
GO:0032154
GO:0007157
GO:0007156
GO:0030054
GO:0042803
GO:0005913
GO:0050839
GO:0005938
GO:0007163
GO:0005902
GO:0001917
GO:0007267
GO:0042462
GO:0007009
GO:0045197
GO:0045667
GO:0070207
GO:0045778
GO:0006954
GO:0019897
GO:0009791
GO:0007512
GO:0007596
GO:0035332
GO:0016332
GO:0003383
GO:0061024
GO:0046621
GO:0106036
GO:0035239
GO:0061336
GO:0007443
GO:0005819
GO:0046664
GO:0007424
GO:0032435
GO:0035090
GO:0045570
GO:0098813
GO:0016028
GO:0033157
GO:0061541
GO:0016334
GO:0051642
GO:0046665
GO:0034332
GO:0042051
GO:0045186
GO:0030507
GO:0035088
GO:0045176
GO:0050821
GO:0045218
GO:0060438
GO:0042052
GO:0016327
GO:0035002
GO:0097108
GO:1902732
GO:0008289
GO:0003413
GO:0042661
GO:0045168
GO:0018991
GO:0043054
GO:0040028
GO:0001085
GO:0090575
GO:0040025
GO:0002119
GO:0042659
GO:0048747
GO:0042694
GO:0051146
GO:0007517
GO:0030141
GO:0007224
GO:0008015
GO:0055111
GO:0001707
GO:0010470
GO:0072358
GO:0010951
GO:0014028
GO:0019828
GO:0045199
GO:0005515
GO:0030414
GO:0008270
GO:0003707
PANTHER
Topology
Subcellular location
Secreted
Fibrillin-1 and Asprosin chains are still linked together during the secretion from cells, but are subsequently separated by furin. With evidence from 1 publications.
Cell membrane
Nucleus Following proteolytical processing NICD is translocated to the nucleus. With evidence from 4 publications.
Endosome
Cytoplasm Following proteolytical processing NICD is translocated to the nucleus. Retained at the cytoplasm by TCIM (PubMed:25985737). With evidence from 26 publications.
Cell projection Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium (PubMed:27737822, PubMed:30052645). May localize to the cilium axoneme (By similarity). May also be expressed in the interphotoreceptor extracellular matrix (By similarity). Unlike the primate ortholog, does not appear to be expressed in the photoreceptor outer segment (PubMed:27737822). With evidence from 1 publications.
Cilium Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium (PubMed:27737822, PubMed:30052645). May localize to the cilium axoneme (By similarity). May also be expressed in the interphotoreceptor extracellular matrix (By similarity). Unlike the primate ortholog, does not appear to be expressed in the photoreceptor outer segment (PubMed:27737822). With evidence from 1 publications.
Cytoskeleton Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium (PubMed:27737822, PubMed:30052645). May localize to the cilium axoneme (By similarity). May also be expressed in the interphotoreceptor extracellular matrix (By similarity). Unlike the primate ortholog, does not appear to be expressed in the photoreceptor outer segment (PubMed:27737822). With evidence from 1 publications.
Cilium axoneme Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium (PubMed:27737822, PubMed:30052645). May localize to the cilium axoneme (By similarity). May also be expressed in the interphotoreceptor extracellular matrix (By similarity). Unlike the primate ortholog, does not appear to be expressed in the photoreceptor outer segment (PubMed:27737822). With evidence from 1 publications.
Extracellular space Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium (PubMed:27737822, PubMed:30052645). May localize to the cilium axoneme (By similarity). May also be expressed in the interphotoreceptor extracellular matrix (By similarity). Unlike the primate ortholog, does not appear to be expressed in the photoreceptor outer segment (PubMed:27737822). With evidence from 1 publications.
Extracellular matrix Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium (PubMed:27737822, PubMed:30052645). May localize to the cilium axoneme (By similarity). May also be expressed in the interphotoreceptor extracellular matrix (By similarity). Unlike the primate ortholog, does not appear to be expressed in the photoreceptor outer segment (PubMed:27737822). With evidence from 1 publications.
Interphotoreceptor matrix Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium (PubMed:27737822, PubMed:30052645). May localize to the cilium axoneme (By similarity). May also be expressed in the interphotoreceptor extracellular matrix (By similarity). Unlike the primate ortholog, does not appear to be expressed in the photoreceptor outer segment (PubMed:27737822). With evidence from 1 publications.
Cytoplasmic vesicle
Hyaline layer
Apical lamina
Cell junction Co-localizes with cytoplasmic intermediate filaments at hemidesmosomes. With evidence from 8 publications.
Hemidesmosome Co-localizes with cytoplasmic intermediate filaments at hemidesmosomes. With evidence from 8 publications.
Membrane
Photoreceptor outer segment Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium. Highly expressed in cone photoreceptor outer segments (By similarity). Weakly expressed in rod photoreceptor outer segments (By similarity). May localize to the cilium axoneme (By similarity). May also be secreted into the interphotoreceptor extracellular matrix (By similarity). With evidence from 1 publications.
Microtubule organizing center Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium. Highly expressed in cone photoreceptor outer segments (By similarity). Weakly expressed in rod photoreceptor outer segments (By similarity). May localize to the cilium axoneme (By similarity). May also be secreted into the interphotoreceptor extracellular matrix (By similarity). With evidence from 1 publications.
Centrosome Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium. Highly expressed in cone photoreceptor outer segments (By similarity). Weakly expressed in rod photoreceptor outer segments (By similarity). May localize to the cilium axoneme (By similarity). May also be secreted into the interphotoreceptor extracellular matrix (By similarity). With evidence from 1 publications.
Nucleus envelope
Cell surface
Basement membrane The antibody used in PubMed:17015624 and PubMed:21215633 to determine subcellular location does not distinguish between HMCN1 and HMCN2. With evidence from 7 publications.
Cleavage furrow The antibody used in PubMed:17015624 and PubMed:21215633 to determine subcellular location does not distinguish between HMCN1 and HMCN2. With evidence from 7 publications.
Apical cell membrane
Spindle Specifically localized to the apical membrane (PubMed:11076972, PubMed:2344615). Expressed in a mesh punctate pattern that overlaps with metaphase spindle microtubules (PubMed:25065591). In tracheal cells, colocalizes with apn in the subapical region, a small region of the apical membrane apical to the adherens junctions (PubMed:30645584). With evidence from 7 publications.
Cell membrane
Nucleus Following proteolytical processing NICD is translocated to the nucleus. With evidence from 4 publications.
Endosome
Cytoplasm Following proteolytical processing NICD is translocated to the nucleus. Retained at the cytoplasm by TCIM (PubMed:25985737). With evidence from 26 publications.
Cell projection Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium (PubMed:27737822, PubMed:30052645). May localize to the cilium axoneme (By similarity). May also be expressed in the interphotoreceptor extracellular matrix (By similarity). Unlike the primate ortholog, does not appear to be expressed in the photoreceptor outer segment (PubMed:27737822). With evidence from 1 publications.
Cilium Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium (PubMed:27737822, PubMed:30052645). May localize to the cilium axoneme (By similarity). May also be expressed in the interphotoreceptor extracellular matrix (By similarity). Unlike the primate ortholog, does not appear to be expressed in the photoreceptor outer segment (PubMed:27737822). With evidence from 1 publications.
Cytoskeleton Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium (PubMed:27737822, PubMed:30052645). May localize to the cilium axoneme (By similarity). May also be expressed in the interphotoreceptor extracellular matrix (By similarity). Unlike the primate ortholog, does not appear to be expressed in the photoreceptor outer segment (PubMed:27737822). With evidence from 1 publications.
Cilium axoneme Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium (PubMed:27737822, PubMed:30052645). May localize to the cilium axoneme (By similarity). May also be expressed in the interphotoreceptor extracellular matrix (By similarity). Unlike the primate ortholog, does not appear to be expressed in the photoreceptor outer segment (PubMed:27737822). With evidence from 1 publications.
Extracellular space Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium (PubMed:27737822, PubMed:30052645). May localize to the cilium axoneme (By similarity). May also be expressed in the interphotoreceptor extracellular matrix (By similarity). Unlike the primate ortholog, does not appear to be expressed in the photoreceptor outer segment (PubMed:27737822). With evidence from 1 publications.
Extracellular matrix Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium (PubMed:27737822, PubMed:30052645). May localize to the cilium axoneme (By similarity). May also be expressed in the interphotoreceptor extracellular matrix (By similarity). Unlike the primate ortholog, does not appear to be expressed in the photoreceptor outer segment (PubMed:27737822). With evidence from 1 publications.
Interphotoreceptor matrix Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium (PubMed:27737822, PubMed:30052645). May localize to the cilium axoneme (By similarity). May also be expressed in the interphotoreceptor extracellular matrix (By similarity). Unlike the primate ortholog, does not appear to be expressed in the photoreceptor outer segment (PubMed:27737822). With evidence from 1 publications.
Cytoplasmic vesicle
Hyaline layer
Apical lamina
Cell junction Co-localizes with cytoplasmic intermediate filaments at hemidesmosomes. With evidence from 8 publications.
Hemidesmosome Co-localizes with cytoplasmic intermediate filaments at hemidesmosomes. With evidence from 8 publications.
Membrane
Photoreceptor outer segment Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium. Highly expressed in cone photoreceptor outer segments (By similarity). Weakly expressed in rod photoreceptor outer segments (By similarity). May localize to the cilium axoneme (By similarity). May also be secreted into the interphotoreceptor extracellular matrix (By similarity). With evidence from 1 publications.
Microtubule organizing center Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium. Highly expressed in cone photoreceptor outer segments (By similarity). Weakly expressed in rod photoreceptor outer segments (By similarity). May localize to the cilium axoneme (By similarity). May also be secreted into the interphotoreceptor extracellular matrix (By similarity). With evidence from 1 publications.
Centrosome Localizes to discrete puncta at, or adjacent to, the photoreceptor connecting cilium. Highly expressed in cone photoreceptor outer segments (By similarity). Weakly expressed in rod photoreceptor outer segments (By similarity). May localize to the cilium axoneme (By similarity). May also be secreted into the interphotoreceptor extracellular matrix (By similarity). With evidence from 1 publications.
Nucleus envelope
Cell surface
Basement membrane The antibody used in PubMed:17015624 and PubMed:21215633 to determine subcellular location does not distinguish between HMCN1 and HMCN2. With evidence from 7 publications.
Cleavage furrow The antibody used in PubMed:17015624 and PubMed:21215633 to determine subcellular location does not distinguish between HMCN1 and HMCN2. With evidence from 7 publications.
Apical cell membrane
Spindle Specifically localized to the apical membrane (PubMed:11076972, PubMed:2344615). Expressed in a mesh punctate pattern that overlaps with metaphase spindle microtubules (PubMed:25065591). In tracheal cells, colocalizes with apn in the subapical region, a small region of the apical membrane apical to the adherens junctions (PubMed:30645584). With evidence from 7 publications.
SignalP
Position: 1 - 22,
Likelihood: 0.933495
Length:
20388
Number of predicted TMHs:
1
Exp number of AAs in TMHs:
27.82905
Exp number, first 60 AAs:
4.17121
Total prob of N-in:
0.18786
outside
1 - 20342
TMhelix
20343 - 20365
inside
20366 - 20388
Population Genetic Test Statistics
Pi
224.68637
Theta
20.776996
Tajima's D
0.323287
CLR
0.730586
CSRT
0.471926403679816
Interpretation
Uncertain
