Gene
KWMTBOMO16029 Validated by peptides from experiments
Pre Gene Modal
BGIBMGA004547
Annotation
PREDICTED:_twitchin_[Amyelois_transitella]
Full name
Twitchin
+ More
Titin
Titin homolog
Myosin light chain kinase, smooth muscle
Myosin-binding protein C, fast-type
Myosin-binding protein C, cardiac-type
Myosin-binding protein C, slow-type
Striated muscle-specific serine/threonine-protein kinase
M-protein, striated muscle
Striated muscle preferentially expressed protein kinase
Obscurin
Myomesin-3
Titin
Titin homolog
Myosin light chain kinase, smooth muscle
Myosin-binding protein C, fast-type
Myosin-binding protein C, cardiac-type
Myosin-binding protein C, slow-type
Striated muscle-specific serine/threonine-protein kinase
M-protein, striated muscle
Striated muscle preferentially expressed protein kinase
Obscurin
Myomesin-3
Alternative Name
Uncoordinated protein 22
Connectin
Rhabdomyosarcoma antigen MU-RMS-40.14
Telokin
Kinase-related protein
D-Titin
Kettin
C-protein, skeletal muscle fast isoform
C-protein, cardiac muscle isoform
C-protein, skeletal muscle slow isoform
Aortic preferentially expressed protein 1
Muscle M-line assembly protein Unc-89
Myomesin family member 3
Obscurin-RhoGEF
Obscurin-myosin light chain kinase
Connectin
Rhabdomyosarcoma antigen MU-RMS-40.14
Telokin
Kinase-related protein
D-Titin
Kettin
C-protein, skeletal muscle fast isoform
C-protein, cardiac muscle isoform
C-protein, skeletal muscle slow isoform
Aortic preferentially expressed protein 1
Muscle M-line assembly protein Unc-89
Myomesin family member 3
Obscurin-RhoGEF
Obscurin-myosin light chain kinase
Location in the cell
Nuclear Reliability : 2.341
Sequence
CDS
ATGTCTGTTAAATTATTCACTCGATTGGTTTGTTTCAAGATTACAATAGATTCCGCTGACGAAGAGAAACAGAAACAACCGGACGGTAAAGCGCCAACGTTCGCGCGTAAACCGGCCATCAGACAAGAAGACGATGGCAAACGGTTGATATTCGAGTGCCGCATTGAGGCTGAGCCTGTACCCGGCGTGACCTGGTTCCACAACGCCGTGGAAGTAAAACCCGGAGCAAGACATAAGTTGACAGTAAGCAAGGAAGGCAAATCGTACTATGCCTCGTTGGAAATCAACAATGTAACCGTTGAAGATGCCGGGAAGTACAAGGTTACAGCCAAGAACGAACTTGGCGAAAGCAACGCCACGATCAGCTTAAATTTCGACAGCGACGAAGCGCCCGTACCTGAGGACTTTATCAAACCAACGTTCACGGAAAGACCGGTCATCAGGCAATCGGACGATGGTACCAAAATCACATTCGAATGCAGATGTGTTGGCAAACCGAAACCAACCATAGCTTGGTACCATGGCAAAAAAATGATAAAAGAAAGTAGCAGATATAAAATAACGTTAGAAGAGGATCAAACTCTATATCACATGGCACGACTCGAAATCATAGGCGTAGAGAATTCGGACAGGGGAGAATATAGGGCTTTAGCGAAAAACAAGCATGGTGAAGGTGTAGCGAAAATAAATTTAAACTTCGAAGGAGGAGATAAACCTAAAATCCCCGATGGTAAAGCACCAAGGTTCCCTAAAAAGCCTACGATAAGACAAGAAGGGGACTTATTGATAATGGAATGTGTGCTTGAGGCTTATCCAGTCCCAGACATCACATGGTTTCATGGAGACAGAGAAATTAAAGACGGTCCAAAAATGAAGATGTCTAGAAAAGCAACTGGAAAAGATACATTTAATTTAACACTAGAAATTTTGAGTCCTTCTAAAGAAGACGGGGGAAACTATAGGTGTAATGCCTTCAACTTGTTTGGTGAGAGCAATGCCAACATTGCTCTAAATTTCCAAGGTGGGGATGATGAGAACGGTTTCGCACCGTCGTTCGTGGAGAAACCCCGAATCATTCCCAATGAAGATGGTACACTCATTACGATGCGTTGTGTCTGCAAAGCCAAGCCGGCGGCCGAAGTATCGTGGTACAGGGGCACGACGGTCATCAAGGCTAGTAGTAAAATTGAAATCAAATCTAGTAAAATTGAAGAAGATGTTTATGAACTGTTATTGCTTTTAACAAATCCGACGGCAGCGGATGGTGGCGCTTACCGCTGTCACGTCAAGAATGAATTTGGTGAAAGCAATGCTAATCTCAATTTGAACATCGAAGCCGAACCCGAACCGGAGGGAGAAGGCCCGACGTTTGTCGAGAAACCTACCATTCAGTCCAAGGACAACGGCAAATTAGTCATAATGGGATGCAAGGTCAAAGCTAGCCCGAGACCGACTATCGTGTGGTACCACGAGGGTAAAGAAATCAAGGAATCATCGAAAATTAAGACCAGGATTGAAGTACATGAAGACATTTACACAATTATCCTAGAACTTATCGATCCTGGCATCGAAGACTCCGGATTGTATAAATGCAATATCAAAAATGAACTTGGAGAGCTCAATGCGAATTTAACGCTTAATATTGAAATCATTCCAGTTATCAAGGAAAAGCCAAAGATCATTAAGATAGTTAAGAAGAAGACTGTTATTGTTGAATGTAAAGTATTAAGTAAATTTGCACCTCAATGTACTTGGTTCAAAGAAGCCAGTGCTGTCAAAGAAGACTCTAGGCATACTGTGCTAATTGAACCTGTGAGAGAGGGTGAATTCGCAGTCAAATTGGAAATCTCAAACGTTTCACAAACCGACAAGGGTTCGTATAAACTCGTTGCTAAGAACGAGAAAGGTGAGGCCACATCGCAACAAGTTGAAATCACAGAGATTCCTGAGGAGAAAGGAGAAAAGCCTCATATCATCAAACACCTCAGGAGCTTGGCTAGAAAAGAAAACGAGGAAGCTGAATTTATCGCAGTCCTCAAAACATCAGATCAGTCATGTCGATGCACTTGGTACAAAAACTCCACCGTCATCAGAGATACATCTGAAGTGAACACATCTTTTGATGGTACCAACGCTAGACTCATCATTAGAAAGGTCTCTTCGAAATACGTTGCCAACTACAGAGTTGTGATTAAGAACGAATACGGCGAAGACGAATCTAGCGCAGATTTGACTATTGTTGATGAAAAGAAAAAGAAAAAGGAGGAGGAAGAAGAAGAAATCACTGTTATCGAAGAGTCTGAGGAAGAAATGTCGATCGTGGAAGAGAAATCAATAATTGAAGAAAACCACGTCGATGAAAAGAAAAAGAACGAAGAAATAAAAAAGAAAGAAGAAGAAAAAACGACAATTGAAGAAAAGAAAACAGCATCCAAAAAAGTAACTAAGAAAGGAGAAATTACAATAGAAAATAACCAAGAGGAAATGGAGATTGAATCTAAAAAGGCTGACTCTAAAGTGGAATCCAAAAAAATTGAGACCAAAAAGGAAGAAACAAGAAAAGCAGAATTAGAAGCCGAAGAGGCCAAAAAAATTATCGAAAAGAAAACAAACAAGACTGAGGAAGAGAAGAAAGCTCTACTTGAAAAACTTGAGAAAAAGAAGCCTGAACCTGAGCCTGAGAAAAAGATTGAAGGTATTCCTAAGCTGAAATCGGTGAAACCCAAGGAAGAACCTGTCGAAACCAAAAAGGAGGTATCTAAAAAATCCACAGAAGAAAAGAAAAAAGTGGTTAAAAAGAAGGTTGTTGCTAAAAAAGAGGAGGATGAAATCGAGTTCGTCGATGATTACGAGCGTCCAGTTCTGGAGAAATATGAAAAGATTACACCGACACCTCTTGCTAAAAAAGCAAAACAGGATGATACACCAAAGGGTAAACGTGCATCAGTTTCGGAAAGCGTTAAAAGTGATCAATTCAGTGAAGATGAACCTTCTATTGCTGAACCGACCCCTGAGAAAAAAACCAAGGTTGAATTTAACGATAAGGTCGACGAAGACAAGGCTGAGTCTAGGAGATCAAGTATTAAAAAAGGCATTCCCAAACCAGAGGAGCCGGTAGATGAACTAACAAACATCAAATTATCAAAAAAACCATCTAAACAAATCGAGGAACCGCTTGAAGAACCACAAGTAGCTAAAACAAAAAAACCAGTCCGAAAGCCGGGTGACACTGACGAATTCATTGACGATTACGAACGGCCAGAGTTGGAGAAATACGATAAACTGACGCCAACTCCTTTAGATAAAACCAATAAAGTGAACGGAGTTGATGAGGCTGATTCGAAATTCGTGGACGATTACGAAAAGCCCGAACTTGAGAAATACGAAAAAGTAGCACCAACACCCAAAGACAAACGTCGAACTAGTGATACACAGGACGATGTGGATATGATGAAGGGTAAAATTAAACCAAAAGAGAAAGAAGAAGAACCGGAAATGCCTACACTACGCAAACGTCCTGTCCAAAAAGACAAGGTTGTCGAGGAAGAGTTTGTCGACGATTACGAAAGACCAGTCCTCGAGAAATACGAGAAAATCACACCCACACCACTCGAGAAAAAGAAAAAGGAGGATAAGAAACTAGAAGAAGAAACACAGTCCACCACGGCAACTAGGCGACGTTCTGTCAAAGACAAAGAGAGTGCTAAACCAGAGGAGGACAAAAAACCAGATGAAGAAACGCCTTCCGCAACAGCGACTAGGCGGCGATCTGTCAAAGACAAAGACAATGACAAACCAGAGCCTATGGATGTTGATGAAAACTTCAGCATTACCAAACCTAAGACTCCGGCTAAGCCTGGACAAGAACCTGAAACATCACTTACACACAAAACACCGGCTGAAATTAAGCCTACGGAAGACGAGGCTGAAGCCAAACTCCACGTTAAGAAACCAGAGATCATTGAAGAAAAAACACTTAAGAGACCTTCACCTAAAGATAAAGAACCTAAGGAAGACGACACAGAGGAGGCTGTCAGTCTCAGCAAACCGCGCAAAAAGACAAGCACGACTGCTCCCGAAGAGGCGCAGCTCACACAAAAGACTCCTGCTAAGAAAAAACTAACGGAGGGTGCTGAAGCAGCAACGTTAAAGGTCAAAAAACCTGCTGTTGTCAAGAAAGATGACGACCAAGAGTATGAGCTTGACTTTGTGGATGACTATGAGAGGCCTGTACTGGAGAAATATGAAAAGATTAGCCCGACACCGATTGTCAGGGAGAAGAAAGAAAAAGAAACCAAGACTGAAAGCAGAAGAACTTCGATTCAAAGCGAGGTTAAGGAAGAAACAAAATCAGAAAGTCGAAGAAGTTCTATCATCGAAAACAAAGCTGTTAAGCTCACAAAAGAAACTGCCGAATCTAGAAAATCTTCTATTTCTTCTGTGGCTGAACAACAAGAAGTTTCTACACTGAAAAAATCTTCAGCGCAAAGGACGAGCATTAAAGCAGCAGAAGCCAGTGAAGTGGAGCAAATAAAACTAAAAGATGACGTTACAATGAGAGTTGAAGAAAAGACAGAATCTGATGATAAACCTACAGATAAAACATATCCATGGCGACGCACAAAAACAGACACACAGGAACCGAAAGAAGATATTGAACCGAAACCTAAAGAGAGCTTAGAGAGTCAAGAGCAAGTCCCGAAACGCCGACAAAGTAAAACGGAGGAAAACGAAACAGTTGAAGAAGTCGAAAAGCCTAAGCCAAAACGAAAATTATCCACGCAACGTGTGCGTCCCAAAAATTGTTCAAAGAAAGCAAACGAGGAAAACGAGAGTATTGAGGAGATAGAAGTCACAGAGAAAGCTACTAAGCCAGAAGAGTTAATTGACAAACAGACAGATACAAAACCTACACGTAAACCTAGTGCAACCGATGAGAACAAAGAAAATATACCAGAAAACAAACTAACTGAAAAAACAGATGTAAAACGTCAAGTTTCTATTGATGAACCGTTAGAAACTGCTTCCTCTTCACGTTTACCGAGTCAAGTTGCTGAGGATGGCGATGATAAGATAGTTGAACATAAGCAATCAAAAAGGCGTGTTTCAGTAGATAGACCGACAGAGCCAACCTATCCTTGGCGTCGACCCAGTAGGGCTGATGAGGATTACGAGATGACAGATATTAGTAATCGACAAGAACCAAAGACTCTTATTGAATCTAATGATTTCCAAACACCTTCAGATGAACTTATTAAAACTGAGGAAGAGAAAAACAGACCCGAATTATCTGAAAAACCGAAAGATGAAATAAAAGAGTCGATTGAACAACCTAAATATCCTTGGCAACGACCCAAAAAAGCTGTCGAGGTAAAGAAAGAAACAGAGGCTACTGACAAATCAAACGACGAAAAGAAATCGCCAAGTCAGCCAAAGTACCCGTGGCAAAAGCCCAAGAAAGTTGACGAGGAGCCGGAAGCTACTAAACAAGTACCACAAACAAAAACAGACGTCACAGAAAATACGAAGGAAACTGAGGCACCTTTCCTTAAAAAAATTGAACCTAAAAAGGAAGGTTTAGATGACCAGAAGCCTCAAGTGGATAATGATAAAATTCCCGAGAAAATACAAGTAGAATTAGATTCTACAGATATAAAGGAACCTGACACTCAATACAAAACTGACACTGTACAAGACAGACAATCACCATATCCGTGGAGGAAACAACACACAGAGGGTGATGCCACAGATGGAAAAGACGAACCTAAGCCAGCTACATTAGGAATACCACAGGCTGCTTTTATCAGCAGTCCCGACCTAACACCTAATGAGAAAGTGGCTGTAAAAGAAGAAAAAATCGAGGAAGAAGCAAAGAAGGCTAAGTTGTCATCTGTCAAAAAGAAGGCCGAAGAACTTCCCGAAATTCCAGATTACGAGAGACCTGATCTTGAACAATACGAAAAAATTTCGCCGACACCAACTACAAGAGACAAACCGGACAAAGATAAGCCGGTTCCTAAGGTACCTGAAATAAAGGCACCTGAAGAGAAGCCAGCTGCACCCAAAATTGAGGTTATCCGTGAGAAATCGCCGAAACCAGAAATGCCCAGGAAACCGTCATTGGTGCCGGGCGCCCCAGTGGGTAGACGTGGTTCCCTAATTCCTCCACCCGAGGAAATGGGAAGACGTCCTTCTCTCATTATAAGCGACGAGAAACGCGGCAGGCCGGGTGAAGTCACAGACGAGCGGCGAAAGTCCGGAGATGCAAGAAGGCCTTCACTACAAGAACTGGAGGACCTGATTAACAAGCCTTCAATACCATTGAAGCCTATCGGAAATGGAGGTCCGCCAGCCATTGTTATGGTAGAAGAAAATTACTCTGCTATTGAAGATCAAACTGGCTACATCACCATACAAGTCGAAGGCAACCCGGCGCCAACGTTCAAGTTCTACAAGGGAGTATCTGAAATCATTGAGGGAGGACGTTTCAAGTTTGTTACGGACGGTGAAACCGGTCTTATTACTTTGTGCATAAGGAAAGTGAAGCCCCACGATGAAGGAAAATACAAAGCTGTCGTCAGCAACATCCATGGCGAGGATAGTGCTGAGATGCAATTTTATGTATCTGATGCCAGTGGTATGGACTTCCGAGCCATGCTTAGAAGAAGAAAGTACGCTAAATGGGGAGAAAAGAAAGAAGATCCAGATTGGGGAGATCTCAAAGAAACTGAGAAACCTATCCCCCCCCTCAAAAAAGTGGAAAAGAAACAAGAGTCGTTCTTGAAGCCACTCGTGGATCAAAATGTTAAGGAGGGCAAGGATAAGAAGGTGGTCTTCGAAGCCATCTTCACTAAGCCTAATTCGAAACCGAAATGGTTGTTCCGTAAAGACGAATTATTCCCTAGTACAAAATATAAGATAGTAAACGAACAAGATTCCTACAAACTCATTATCATGAATCCTAAAGTTGACGATACTGGAAAGATCACATTGGAAATCGGCGGCGTTTCATGCTCTGCCTTCCTGCACGTTGATGAACCGGACCCCACTTATACCTTCACGAAACCTTTGAAAAAGAACACCAGTGGCTACACTAAGCACGAAGTGTTACTTGAGTGTGCCGTATCCAACAGTTTGGCTATCGTTTCCTGGTGGAAAGGAGACCAGAAACTGGAAGACGGTGACGAGTACCAAATCTCAAAGGACTTGTCCGGTGTCTGCAAGCTTATCATCAAAAATGCCAAGTTCGATCATGCTGGCAAATACACTTGCAGGATTGAGAAGCAACCAGACAAAACGGAGACTGATGTCAAGATCGTAGAATACCCATACAAATTCACCAAGGTATTAAAATCACAACAAGCCATCGAAAAGGACACCATCACGCTGCTCTGTGAGCTAGATGACGCGAGTGGTGATGTGAAATGGTTCAAGAACAATGAGCCTCTGAAACCAGACAAGCGAATTTCAATTGTGAAAGAAGGTCGCAAGCGGAAGGTTATCATAAAGGACGCCAAGGTCACAGACGCTGGACACTTCAAGTGTACCACTAACGCTGACGAGACTCAGTGCGAACTTATTGTCAATTACGCGAATCGGTTCAACAAGAAGCTGAAAGACACAGAAGCTATTGAGAGAGATAGGGTCGTCCTCGAAGTCGAGCTGCAAGATCAAACAGCAGAAGCAGTTTGGTCGTTCAACGGACAACCAATCGTACCCAATGAGAGAATTGAAATAAAAAATCTGGGCGGTGGCAAACACCAACTAATCTTCAACAAACTAGAGATGGAAGACGACGGTGAAATCTTGTGCGAATCTGGCAAGCTGACCTCTTCTTGTAAATTGACTGTGAAGAAGGGTGAATCCAAACCTGCCATCGAATGTCCTGATGAATTCAATGGTCCTGCTGGACATCCCTTCGTCATTGAGGTGCCTTATAAAGTTACTGGTACCCGACAAACACCAATTGAAGCGAAATTATGGAAAGACGGAAAAGCCTTACCAGCCAAAGAAGTCGAGGTTGTTGTTGAACAAGAAAAGGTTCTCTTCAAATTTAAGAAGCCGTCACGCGAAGGATCAGGAAAATACCAGATCAAATTGTCGAACGCCCAGGGTGAAGACTCTAAAGATGTTAATATCACCATGCAGAGCGCGCCTACAGCTCCGCAAGATGTAGAAGTGTCAGAGGTCTTCCAAACTTCTTGCGTTGTCGCGTGGAAAACGCCACAGGATGACGGTGGTTCACCAATCATCAAATACGTTATCGAGAGACAGGATATGTCTCTCAAAGCCGGTTGGGACAATGTGGCTGAAGTACCATACGGTGAACCAACTAAGTTCAAGGTAGAAGACCTCATCCCCAAGAAGACGTACAAATTTAGAATCCGTGCTGTTAACAAGATCGGTTCAAGCGAACCCGGTCTCTTCTCCAAACCCGTTTTGGCCAAGGATCCTTGGGATGAGCCATCGAAACCTAAAAACGTGGAACTCACTGACTGGGACAAGGATCACGCAGACCTTAAGTGGCAGAAACCTGAGAACGATGGCGGTGCTCCCATCACTGGCTACGTCATTGAGTATAAGGAGAAATTCGGCAAAGACTGGGTAACCGGTAAGGAGGTGTCCGGCGATTGCTTAGCTGCCACGCAGGATGGATTGAAGGAAGGTTGCACCTACGAATTCAGGGTCCGAGCGATCAACAAAGCCGGCCCCGGTGAACCAAGTGACGCTACCAAACCCATCATTGCTAAATGCCGATTTGTCAAACCTTATATTATCGGTGAGGGTCTTCAGAACATGATCATCAAGAAGGGACAGGTGATAAGTTTCGATATTAAATACGGCGGTGAACCTGAACCGGAGGTTAAATGGATGAAGGGAGAAGAGGAAATTCGGGACGATGGAGACCGTATCACCATTGACAAGTACGAAAGGAACACGGTCCTCACGGTCAGAAAGACCACCAGACCAGACAGTGGCAAATACAAATTGGTATTGACCAACTCTTCGGGAACATGCGAGAGTATTGCTGATGTTGTCGTGCTTGACAAACCGAACAGGCCTAACGGTCCAATTGAGGTGGTTGACATTCGTGCCGAGAAAGCAACTGTCAAATGGCAGAAACCTGATGACTGGCAAGGGTCCGACATCACCGGATACACTCTTGAGAAAATGGATATGGATACTGGAAACTGGGTACCTTGTGGTGAGACTGGACCTGAACCAACAGAATTCACAGTGAAGGGTCTCACACCTAACCATAAGTACAAATTTAGAGTCCGTGCAGTCAATAAGGAAGGAGAATCTGAACCTCTAGAAACTGACGGATTCATTGTCGCCAAAAATCCGTATGACCCACCAAAGGCGCCTGGAAAGCCGACGATCGTCGATTACGACAATATGTCTGTAACTTTACAATGGGAACCTCCAAGCGACAACGGCGGCAGACCCGTATTGGGATACGTAGTAGAAATGAAGGATAAATTTGCTCCTGATTGGATTGAGGTTGTCAAGACGAATGATACAAAGACCGAATACAAGGTAGAAGGTCTCAAAGAAAAGATGGTTTACCAGTTCCGTGTCAAAGCTTACAACAAAGCTGGAGTTGGTGACGCTTCAGAGCCCACTGACAACCATCTATGTAAACATAAGAACCTCAAGCCACGCATCGAGCGCAGTACATTCAAGTCTGTTATCATCAAGGCTGGTCGTACTCACAAATGGTCTGTGGATGTCATTGGTGAACCTCCACCAGAGACCACCTGGTCTTGGCGGGACAACATTAAGCTGGTGAACACAGAACGCATCAAGATTGAGAATCGCGATTACCACACTGATTTCACGATCGTGAACGCAGTGCGCCGCGACACCGGCAAGTACACGCTCCGCGCCGAGAACTGCAACGGCTCCGACGAGGAGACAGTCGAGCTCACCGTCCTCAGCAAGCCGAGCTCGCCCAAAGGACCTTTGGAGGTTACGGATATCCACGCCGAAGGCTGCAAGGTCAAATGGGAGAAGCCGGAAGACGACGGTGGCTCGCCGGTCAAGGAGTACGAAATCGAGAAAATGGATCTCGCTACCGGCAAATGGGTCAGAGTCGGAAGAGTCGCCGGCGACAAGAAGCCTCTGGAAATGGACATCACTGGCCTGGAACCAGGTCACCAGTACAAGTTCAGGGTTACTGCTGTCAATGACGAAGGCGACTCTGAGCCCCTGGAAGCCGAGCGGGCTATACTCGCTAAGAATCCGTTCGATGTGTCCGAGAAGCCGATGAACGTGGAAGTCGCCGACCACGACAACCAGAGCGCCGAGATCAAATGGGAGCCGCCCAAGTCCGACGGCGGAGCCCCAGTGCAGAAGTACATCATACAGAAGAAGCCCAAGGGCGGAGACTGGGAGAACGCTGTTGAGGTTCCTGGTACGCAGACGTCAGGAAAAGTGGAGGGTCTACCCGAGGGCAGCGAATTCCAGTTCCGCGTGATCGCTGTCAACAAGGCCGGACAGTCTGAGCCTTCAGAGCCCACCAAGATGACCACCATTCGGCACAAGGCCTTGAAACCGCGCATCGACCGCACCAACCTGAAAGCTTTGGCCGTGAAGGCGGGCAAGCCTATATTCTTCGACGTGAATGTTAGGGGAGAACCAGCGCCAAAGGTGCAATGGTTCCAGAAGTGGAAGAACGAAGAGAAAGAGGTCACGGCCAACGTTATAAACGTGGACTACAACACGAAACTGGACATCAAGGAGTCGGTCCGCGCCATGACCGGCACGTACCGCATCGTGGCGACCAACGAGCACGGCAAGGACGAGGCCGAGGTGGAGATCACGGTGCTGTCCTCGCCCAGCAAGCCCGGCGGCCCGCTCAAGGTCTCCGACGTTACCAAGAACGGCTGCAAACTGCAGTGGAAGAAGCCGGAAGATGACGGCGGCAAACCTGTCACCGGCTACATGGTCGAGAAGCTCAACAAAGCGACAGGCCGATGGGTGCCGGTCGGCAAGACCGACGACACGGAGATGGACATCAAGGGTCTCCAGGAGGGCGAGGAGTACGAGTTCAGGGTCAAAGCGATCAACGACGAGGGAGAATCTGAACCGCTCAAGACCGACCATTCGATCATCGCTAAGAATCCTTATGACATACCTGGAAAGCCTTCGGTGCCGACACTCGAGGACTGGGACGTGGATCGCGTGGACCTCAAATGGGAGGCGCCGAAGAACAACGGCGGAGCTCCCATCACCGGTTACATCATTGAGAAGAAAGAGAAATACGGGCAGTGGCAGGAAGCTCTAGTCACAACGACGCCAGAATGCAAGGCCCGCGTTCCGGATCTGAAGGAAGGCAACGTCTACCAGTTCCGGGTTCGAGCCGTGAACAAGGCGGGCCCCGGCGAGCCCGGCGACGCCACGCAGCCGCACACCGCCAAGGCGCGCTTCTTGAAGCCTCACATCAACCGCGACAAGATGGTGGCCATCCGGGTCCGCGCCGGCGCCACCATTAAACTAGACGTCGACATCAGAGGGGAACCGCCTCCGACCAAGACTTGGACTTTCGCTAAGAAGGTCCTGGAAACCGGAGCCGGCATCAAGATCGAGAACGAAGACTACAACACTAAAATGCAGATATTCGACTCCTCGTGGAAGAACAGTGGCATCTACACCCTGAAAGCGGAGAACGATTCGGGCGTCGACGAAGCCACAGTCGAGGTCACCGTCTTAGACAAACCTGGCAAGCCCGAAGGTCCGCTGGAGGTGTCCGACGTCCACGCCGAGCACGTGAAGCTGAGCTGGAACAAGCCCAAGCACACGGGAGGGCTGCCGCTCAGCGCCTACGTGGTCGAGAAGATGGACACCCTCACCGGGAAGTGGGTGCCGGCCGGTACCGTGCAGCCCGACACCACCGAGGCCACGGTTACAGGCCTCGAACCCGGTCACACGTACCAGTTCCGCGTGAAGGCTGTGAACGAGGAGGGAGAGTCGGAGCCGCTGGAGACCGACCACGGCGTGCTCGCCAAGAACCCGTACGACGTGCCCGCGCCGCCCGGCCTGCCGGACATCGTCGACTGGGACGAGAAGTCCGTCAAGCTCAAATGGGAGCCGCCCATCCGGGACAACGGGGCGCCCATCACCGGCTACATCATCGAGCTCATGGACAGAGACAGGGGCGAGTTCGTTAAGGCCGCCGAAATCCACGACAACGTCTGCCAGGGTACAGTACCCAAGCTGGAAGAGGGCAACCAGTACCAGTTCAGAGTACGAGCCCTCAACAAGGCGGGACAGTCTGAACCCTCAGAGAATACTAACTGGCACACGGCTAAGCCTAGATTCTTGAAGCCGCGCATCGACCGCACGAACCTGGGCGCGGTGACGGTGAAGGCGGGCCTGCCCGTGTCGCTCGACGTCAAGGTCTTCGGGGAACCCCCGGCTACCGTCACTTGGCACTACAAGGGCGAAGAGTTAAAGAACAGGGAAAACCTCGAGATAATAAATGTGGACTACAACACGAAGTTCCTGATGACGAAGAGCAAGCGCGCCAACAGCGGCGTTTACGTCATCAAGGCGAAAAACGAAGTGGGAGAGGACGAGGCTGAAGTCGAAATCACTGTGCTGGGTAAACCATCCAAGCCTAAAGGACCACTTGACGTGTCCGATATCACGAAGAACGGCTGCACGTTGACGTGGAAGAAGCCGGAAGACGACGGCGGCTCTCCCATTGAGTACTACGAGATCGAGAAACTCGATCCGCTCACTGGACAATGGATTCCGTGCGGTACAGCCAAAGACACGAAGGCCAACATCGCGGGCTTGCAGGAAGGTAAACCTTACAAGTTCCGAGTTAAGGCCGTGAATAAGGAAGGCGAATCCGAGGAACTCGAAACCGAGAAACCGATTATCGCCAAGAATCCCTTCGACGAGCCCGGCAAGCCTGGACGTCCCGAGCCCAGGAACTGGGACAAGGACTTTGTGGAACTCGAATGGTCCGCGCCCAAGGACGACGGAGGCGCCCCCATCACCGGCTACATCGTGCAGAAACGAGAGAAGGGGGGCAGATCCTGGCAGGACTGTCTCAAGACGACCGGCGACAGGCCCACGGGCCGCGTCACCGACGTCGAAGAGGGACACGAATACGAGTTCAGGGTTATCGCTCTCAACAAAGCTGGTCCTTCAGAACCTTCAGAGCCTAGCAAGTCTGTTATTGCTAAGCCTAGATTCCTGAAACCGCACATCGACCGTAAGAATCTTCAAAAGAAGAAGATCAAGGTCGGCCAGCCCCTCAAGATGGAAGCCGATGTCAAAGGCGAACCAGAACCGACAATCACTTGGACATTCAACGATCAGACCCTCAAGACGGCAGATCGCGTGACCATCGAGAACAAGGACTATCACACTTCGTTCATCAAACAGAAGATGGTCAGGACGGACGCCGGAAAGTATGTCGTCACAGCCAAGAACGATTCGGGAACTGACACCGTGGAAGTGGAGGTCGAGGTCGTCAGCAAACCCTCGAAGCCGAAGGGACCGTTGAAGGTGTCGGACGTGAAGGCCGACGGCTGCAAGCTGAAGTGGGAGCCGCCGGAAGACGACGGCGGCGAGCCCATCGAGAGCTACGTCGTGGAGCGCATGGACACGGACTCCGGACGATGGGTCCCTGTCTGCACCACCAAGACCCCAGAGGCTGACGTCACCGGCCTCAATGAAGGCAAAGACTATATGTTCAGGGTGAAAGCGGTCAACCCTGAGGGCGAGAGCGAGCCGCTCGTCACCGAGTCCGCCACCACAGCCAAGAACCCATATGGCGAGCCCGACGCTCCCGGCAAGCCCGAATTCAAGGACTGGAGCAAGGAGCACGTGGACCTCAAATGGGAGAAGCCGACCAACGATGGCGGGGCTCCCATCACCGCATACATCGTCGAGAAGAAGGACAGGGACACCGGCAAATGGGTTAAGGCGGTCGAGGTGCCGGGCAACAAGACGGAGGCCCGGGTGCCGGACCTCATTGAGGGCAAGCAGTACCAGTTCCGTGTGAAGGCCGTGAACAAGGCCGGGCCCGGGAAACCTTCTGCCGCCACTGATAACCTCCTGATCAAGGACAGATTCGCTCCGCCGAAGATCGACCGCACCAACATGCGCGACATCACCATCAAGGCCGGGCAGCACATTAGGCTGGACGTCAAGGTCAGCGGAGAGCCGCCGCCGACCAAGACTTGGTTCCACAACAAGGAGAGGTTGTCTTCAAGGGACGACCTTTCAGTGGACGTGGAGGATTACAAGACGAAGCTCTCTGTGGTGATAGCTTCCCGCAAGCACAGCGGAAGCTACACGCTCAAGGCGGAGAACAGCAGCGGCAAGGACGAGGCCACCATCCAAGTTCACGTTTTGGATGTCCCCGCTAAGCCCGAGGGACCGCTGAAGATATCGGACGTGCACAAGGAAGGTTGCACGCTGAAGTGGAGTCCTCCGCTGGACGACGGCGGCGCGCCCATCGACCACTACCTCGTCGAGAAGCTGGACACGGAGACCGGGCGCTGGATGCCGGCCGCCAAGACCAAGGACCCCAAGGCCGAGCTGGAGAACCTCGTCCCCGGACACGAGTACAAGTTCAGAGTGTCCGCCGTCAACAACGAGGGGCAGTCCGAGCCGCTGGAGGCAGAACATTCGATCATCGCTAAAAATCCGTTTGACGAGCCCGGCAAGCCCGGCACACCTGAGGTGGTGGACTGGGACAAGGACCACGTGGACCTCAAATGGGAGAAGCCGGTCAAGGACGGCGGAGCTCCCATCACCGGGTACATCATCGAGAAACGCGAAGTCGGCTCGCCTAAGTGGGTGAAGGCTTGCGAGGTCGGACCTAACGACAACGACAAGGCCACAGTGCCGAACCTGGACGAAGGTACGGAGTACGAGTTCCGTGTCCGTGCGGTCAACGAGGCCGGCCCGGGCGAGCCCAGCGACGCCAGCAAGAGCGTCGTCTGCAAGCCCAGGAGACTGCCCCCAAAGATCGATCGTCGCAACCTTCGTACCATCAAGGTCCGCGAGGGCGAGCCCATCGCGCTGGACGTGAAGGTCTCCGGCGAGCCCGCCCCCGAGGTCACGTGGACCCTCAACGGAAAGTCCGTCCTCAGTGGAAACGGACTCAAACTGGTGAACGTGCCGTACATAAGCAAGTATCAGCACGCGAGTCCGCGCCGCAAGGACTCCGGCACGTACAAGATACAGGCCACCAACAAGTACGGGCAGGACACCGCCGAGCTCGAGATCATTGTCACATCGAAACCCGACAAGCCGGAGGGGCCGCTCGAAGTGTCGGACGTGCACAAGGACGGCTGCACGCTCAAGTGGAAGCGGCCCAAGGACGACGGAGGCGAGCCCATCGACTCCTACCTCGTCGAGAAGTACGACACCGAGACCGGCGTGTGGCTGCCCGTGGGCAACACCATCGGCAACGTGCCCGAGATGGAAGTCGAGGGTCTAACGCCGGGCCACGAGTACAAGTTCCGCGTGAAGGCGATCAATAAGGAGGGTGAATCGGAGCCTCTAGATACGTACGGAGCTATTGTCGCTAAGGATCCCTACACCGTACCAGACGCGCCTTCAGCTCCCGTCCCAGACGACTGGTCGGCCAACCACGTGGACCTCAAATGGGAGGCGCCGCTATCAGACGGAGGATCGCCCATTATCGGCTACATCGTCGAGAAGAAAGACAAATACAGTCCGCTGTGGGAGAAGGCGGTGGAGACCCACACGCCCACACCCACTGCTACTGTAAATGGGCTGATCGAAGGCAACGAGTACCAGTTCCGTGTGATCGCTATCAACAAGGCTGGTCAGAGCAAACCCTCGGACTCTTCTAAGAACTTCGTGGCGAAGGCTCGCTTCCTGGCTCCGAAGATCGACAGGAGACACCTCCGTGACGTCACTCTGTCCGCCGGAGCTACACTCAAGCTGGAGGCCGCCGTCGCAGGAGAACCAGCTCCAGCTGTTGAATGGAGATACCAAAATATGCCTCTGCGGCCATCGAAGGCGGTGAGCATCGACAACCCGGAGTACTTCACGAAGCTGGTGGTGCGGCCGGTGCGGCGCGACGACACCGGCGAGTACACCGTCACCGCGGTCAACTCCAGCGGGAAAGACGCCGTCACCATCAACGTCACCGTCACCGACAAGCCCACCAAGCCCGAGGGACCGATACAGATCTCGGATGTCCACAAAGAGGGAGCTACACTCAAATGGAAGAGGCCCAAGGACGACGGCGGCACTCCCATCGAGTACTACCAGATCGACAAGCTCGACACCGACACCGGCTGCTGGGTGCCCTGTGCTAGATCTGAGGAGCCTAAATGCGACGTCACCGGCTTGACTCCTGGCAAGGAGTACAAGTTCCGCGTGTCTGCCGTCAATGCTGAGGGCGAATCTGAACCGCTGGTGACAGACCACGCCATCGTCGCCAAGAATCCGTTCGACGAACCTGGCGCACCCGGAACGCCAACCGTTACCGACTGGGACAAGGACCACGTGGACCTCAAATGGACCCCACCACGCGAAGACGGCGGCGCTCCTGTCGAAGCTTACATCGTCGAGAAGAAGGACAAATTTGGCAACTGGGAGAAGGCCGTCGAGGTACCGGCCAGCAAGACCTCCGCCACCGTGCCCGATCTCATCGAAGGACAGACCTACGAGTTTAGAGTACGTGCGGTGAACAAGGCCGGGCCAGGCGAGCCCAGCGATAGCACTCATCCTATCGTCGCCAAGCCCAGGAACATGGCGCCCAAGATCGACAGGACCAACCTTATCGATATTAAGATCAAAGTCGGACAGAAATTCGGATTTGATGTTAAGGTATCCGGAGAACCGATGCCTGTAACGAAATGGTACCTGGCGAAGAAGGAAGTGAAGTCCGGCGGCGACATGAAGGTGCAGCACGCGGACTACAACACGAAGCTGAGCTGCAAGGCGGCCACGCGCGCCGACAGCGGCCGCTACACCGTCACCGCGGAGAACAGCAACGGGAAGGACGTGGCCGAGGTCGAGGTCGTCGTGCTCAGCGTGCCCGCGCCACCCGGTGGACCACTTAAGGTATCGGACGTACACGCGAACGGCGCCACGTTGTCGTGGAGGCCGCCGCCCGACGACGGCGGACAGCCCATCGACAAGTACGTGGTGGAGCGCATGGACGAGGCCACGGGGCGCTGGGTCACGGCCGGCGAGACCGACGGGCCCGTCACCAGCCTCGCCGTCGACGGCCTGCAGCCCGGGCACAAGTACAAGTTCCGGGTCAGCGCTGTCAACAGGCAAGGCCGTTCCGACCCCCTTACGACCCCGCACTCCACGGAAGCCAAGAATCCGTTCGACGTGGCTGGCAAACCTGGCACACCGAAGATCAAGGACTTCGACAAAGACTTTGTGGAACTGGAATGGACCAGACCGCAAACCGATGGAGGGGCTCCCATCACTGGATACGTCATTGAGAAGAAGGATCGATTCGCGCCCGACTGGGAAGAATGCGCAAAGATCGACGGTGATGTTACATCTGGCAAAGTCCCGGACCTCATTGAAGGCAATACATATGAATTCCGTGTTCGTGCCGTCAACAAGGCCGGCAAGGGTGAGCCTAGTGACGGCACCGCTCCACACCTGGCCCGTCCCAAGAACCTGCCGCCCAAGATCGACAGGAACTTCATGTTCGACATCAAAGTTAAGGTCGGACAGAACTTCGACCTCGAGGTGCCGGTCGCCGGCGAACCCACTCCGACCAAGGAGTGGCTCCACGGTGACAACGTTGTCCTCAACACCGACAGAATCAAGATCGTCAATGACGACCACAGCACGAAGTTCCGCGTCATCGATGCCAAGCGAGCGGACACCGGCACGTACACGCTCAAAGCGAGAAACATCAACGGTACCGACACCGCTACCGTCAAGGTGCTGGTCATGGACGTGCCCACCGCTCCCGAGGGACCGCTGCGTGCCGACGACATCACTAAATCTGGATGCACGCTGCGCTGGAGACCACCCAAGGACGACGGTGGTGCCGAAATCACACACTACGTCGTCGAGAAAATGGACCAGGAGAACTTGCGCTGGATCCCTGCCGGCGAGGTACAGGGCTGCAACATCAGGATAGATCATCTCATCGAAGGACACGACTACAACTTCAGAGTCCGCGCCGTCAACAAACATGGCGAGTCTCAACCTCTTGTTGGACACGAGCCCATCACTGCCAAAGATCCTTATGGTACCCCCGACAAGCCCGGAACACCTGTCGTCAAAGACTGGGACAAAGATCACATGGACCTGGAATGGGTGCCACCAAAGAAGGACGGAGGTTCACCCATTACTGGCTACATTATAGAAGCGAAGAAGAAGTATGGACCTTGGGAAGTGGCGGCCACCGTGCCAGGAAATCAAACCACCGCTACAGTACCTGGCTTACAAGAAGGCGAGGAATACGAGTTCAGAGTAATCGCTGTTAATAAGGCCGGCAATGGAGAACCTAGCGATGGGTCCACTCCACAAGTCGCTAAGGCCAGGTTCTGTGCCCCACACTTCGATAAGATGTTACTCGCAGATAAGACAGTTAAGGCGGGACAGAGGATTCAATACGAGATCCCTATCGAAGCTTCGCCTAAACCTACTGTCGAGTGGCAGATCAACGGCAAAGTCGTCCATCCTTCGGACAGGGTCGACATACAACTGCTGCACAACAGGGTCATACTGGACATTCCATTCTCCGTCCGCAGCGACGGAGGCGTTTATAAACTGACCCTCAAGAACGACCTCGGAGTCTGCTCGGCAACTGCGCAAGTCACAGTGCTGGACAAACCCTCGAGACCGGAGAAGCCGTTGACCGTTTCCGATATCACGAAAGACTCTTGCTCGTTATCGTGGAGAGTGCCTCTGGACGACGGAGGTTCGCCGATCTTACATTACGTCATAGAAAAGATGGACCTGACCCGCGGCACTTGGTCGGACGCTGGAATGAGCACATTCCTGTCGCACCAGGTCACTAGATTAATTCACAAGAAAGAGTATTTGTTCAGAGTGAGCGCCGTGAATGCCATCGGACAATCTGAACCTCTTGAACTGGAGAGAGCTATCGTCGCCAAGAACGAATTCGACGAGCCCACCGCGCCTGGCAAACCTGAAGCCACAGACTGGAGCAAGAATCACGTCGACCTACAATGGGCTGCGCCTAAATCGGACGGAGGATCGCCGATTACCGGCTACATCATTCAGAAGAAAGAAAAGGGAAGCCCGTACTGGGTGAACGCTGTGCATGTACCACCCAGCAAGACCAAAGCCACCGTGCCCGACTTAACCGAGGGTCAAGATTACGAGTTCAGAGTGATCGCCGTCAATCAAGCCGGTCAGTCCGAGCCTAGCGAGCCCTCTGACGTCATCACCGCCAAGGACAGGTTCGTCGCACCCAAGATCCTTACTCCCCTCAAGGAGATCCGCATCAAGGCCGGTCTTATCTTCCACTTCGACGTGGACTTTATCGGGGAACCTACTCCCGAGGTCACATGGACGTGTGACGGTAAACCTGTTGTAACTAACGAAAGAACGACGGTTACGTCTGTCGGCCATCACACCATTATCCACACGGTTAACTGCAAACGCTCCGAGGCTGGTACATACCATCTCAAATTGAAGAACGATTCCGGCACCGATGAAGGCTCCTTCGAATTGATAGTGCTCGATGTGCCGGGAGCTCCCCAGCCTCCGTTCACTTACGAGGAAATCACAGCACAATCGGTTACTTTGTCATGGAAACCTCCCAAAGATAATGGCGGCAGTGAACTCACAGCCTACGTCATTGAGAAACGTGACCTCAGTCACGGCGGCGGCTGGGTGCCGGCGGTAACGTACGTCAACCCGAAGTACAACCACGCTACTGTCCCCAGGCTCTCGGAGGGCACACAGTACGAGTTCAGAGTATTCGCTGAGAACTTGCAAGGACGCTCCGAACCTTTGGTCACAGATAAGCCTATTGTCGCCAAAAACCAGTACACGGTGCCTGGTAAACCCGGGAAACCTGAGCTCGTCTCTGCAGACAAAGACCACATCAAGGTCAGATGGTCTTCGCCTATTTCGAACGGTGGATCTAACATTCTCGGCTATGATGTTGAAAGGAGAGACAAGGCCACTGGCCGCTGGATCAAACTGAACAAGGAACCCGTGAGGTTCAATGAATACCAAGACGATAGAGTGCAAGAAGGTCACCAGTATGAGTACAGAGTGTCCGCCGTTAATGCAGCAGGACCTGGACAACCTTCTGACGAATCTAACGTGTTCATCGCGAAGCCCATGAAGGAGAAACCCAAACTCTGGCTTGATCACCTGATCGGCAAGAAGATCAAGGTTCGCGCCGGTGAACCAATCAACATTAACATTCCAATCACCGGCGCTCCCACGCCGACCATCTCGTGGACTAAGGGCTCCGTTCCTCTTGTGCCATCGCACAGATTATCAGCTGAAACCAAGAACGATGAGACTAAACTGTCTATCGAGAAATCAACAAGAGAAGACGCCGGAAAATACACAATTTCCGCGTCCTCTCATGTGCAACCCGTTACGCACGACGCCATCAGCCTCACGTGGCAGCCTCCCACCGACGACGGCGGCAGCGAGATCACCGGCTACGTCGTTGAAGTCGCCGAATTTGGTGTCAACGATTGGCGCACCGTGGCCGGATTCTGCCCTAAATGTTCGTTCACTGTGAAGAACTTAACCGAAGGCAAGAAGTACGTATTCAGAGTGCGCGCCGAGAATCTGTACGGCCTCTCCGATCCTCTGGAGAGCAAACCGATCATTGCCAAGTCGCCGTTCGATCCGCCCGACGCGCCGGACACGCCGAAGGTCACCGGGTACAGCTCCAACAGCTGCGCACTGGAATGGCACCCGCCCGCGAACTGTGGCGGCAAGCCTGTCACCGGATACTATGTCGAGAAGAGGGAACGCGGTGGGGACTGGGTAAAGGTCAACAACTACCCCACTCCCAATACGTGCTATACCGTTTCGGACTTGCGGGAAGGAAACAAGTATGAGTTCCGTGTGATCGCCGTCAACGAGGCTGGACCCGGGAAACCGAGCAAGCCTACCGAGCCGATCACTGCTCAAACACAGCGACTCAAGCCTAGCGCTCCTGAAGCGCCGAAACCGGACAGAATCACTAAAGATTCCGTCACTTTATCCTGGAGACCACCTAAAAGCGACGGTGGAGCTAAGATTAAGGGCTACATCGTACAGCAAAAGGGCAAGGGTGACAAAGACTGGAAGGACGTCAATGACGTACCTATTCCAAGCCTCGTACATACTGTACCGAAACTCAAGGAAGGCGAAGAATACCAGTTCAGGGTTATCGCCGTTAACGAAGTCGGTAAATCGGAGCCAAGTAAACCTACCGCTGACATTACTATCGCCGAACAACCAAACAAGCCTTGCATGGACCTGGGCGGCGTCAGAGACATCACGGTGCGCGCCGGAGAAGACTTCTCCATTCACGTGCCGTACACTGGGTTCCCGCAGCCGACCGCGCAATGGTTCGCTGACGACAACCTGCTCGATGTCGAAGGCGACTCGAGAATTTTCCAAAAGATTACGCCCGATTCGGCATCTCTGGTCGTCAAGAACGCTAAGAGATCCGACGGAGGACAATACCGCCTGCAGCTGCGTAATCCCTCTGGATATGACACAGCCACGATCAACGTCAGAGTGCTGGATCGACCCGGAAAACCGGAGAACTTGCGCGCTGACGAATTCGAAGGCGAAGCTCTCACGCTGTACTGGAACCCACCGAAAGAGAACGGCGGCGGTGAAATTACCAACTACGTCGTCGAGAAACGCGAGGCGCGCACGCCGAACTGGACCAAGGTGTCCGGCTACGTCACGACTCCGTTCCTGCGCGTCAAAAACCTGACTGTCGGGAAGAGCTACGAGTTCAGAGTTATGGCCGAAAACCAGTACGGACAGTCGGACCCGGCGCAAACAACTGAACCGATCAGGGCCAGACATCCGTTCGACCCGCCCGGCCCGCCCGGCGTGCCGAAGTCGGTTGAAACCAGCGAAACTTCTATCACCATTACTTGGACCAAACCACGCCACGACGGTGGCTCTCCTATCACTGGTTACATAGTAGAGAAGCGACTCATCACGGAGGATAAGTGGACCAAGGCATGCCACGCGCACGTGCCCGACACGACGCTGAAGGTTACCGGTTTGATCGAGAACCACGAGTACGAGTTCCGTGTGTCCGCTGTGAACGCGGCGGGCCAGGGTCCCTGGTCGCAGAGCTCGGACGCCATCCGCGCTCGGGCGCCGCCCAACTCGCCGCGCATCACCAGCGACCTCAGCCTCAGGGACATCACTGTCATCGCCGGGGAGGAGATCAAGATCACCGTGCCCTTCACTGGCAACCCAAGACCTAAGGTGTCATGGATAGTGAACAACGACGAAGTATTCCCGGACAACCGTATCCGCTTCGTGACCACGGACATCGACACAGTGTTCTACAACTCATGCGCCAAGCGTACCGACACCGGCTCCTACACTATTCAACTGGTCAACAGCGAGGGCTCGGACAGCGCCACTTGCAGGGTACTCGTAGTTGACAAACCGACCCCGCCCGTGGGACCGCTGGACGCGTACGACATCACGCCCGACACGTGCACGTTGTCATGGAAACCGCCACTAGACGACGGCGGCTCTCCCATCACCAACTACGTCGTCGAGAAGATGGACAATAACGGAATCTGGACAAAGATATCATCGTTCGTTCGCAACTGTCACTACAACGTCATGGGCCTGGAACCGAACAGGAAATACTTGTTCAGGGTACGCGCCGAAAATCAATATGGCGTATCGGAACCTTTGACAATGGACGACTCTATTACGGCCAAGTTCCCGTTCACGATTCCCGAGCCGCCGGGAGCGCCGCGCGTCACGGACTGGGACGGCTCCACGGCGACCGTGCTGTGGGACCGGCCGCGCTCGGACGGCGGCTCCCGCATCCAGGGCTACAAGATCGAGTACAGGGACGTGCAGGACGGCGTCTGGAACAGCGCTGACTATCTCGTTAAGGATTGTAATTACCAGGCGTACAACTTGGAGCCGGGCCACGAGTACGAGTTCCGCGTGCGCGCCAAGAACGCGGCCGGCTTCAGCAAGTACTCGGGCTCGTCGCAGCGGTTCCGCGTGCGGGCGCGCTGCGGGCCCCCCGCGCCCCCCACCGCGCCGCGCGTGCTGCGCGTCGGCAGGAACTACGTCGACCTCAGCTGGGACCCGCCCAAGCACGACGGAGGTTCTCGCGTGACCGGCTACGTGATCGAGCGGCGCGACGTGGGCAGCTCGGTGTGGGTCAAGTGCAACGACTACAACGTGCAAGACACGACCTTCACCGCGCTCAACCTCAACGAGAAGGCGGACTACGAGTTCCGCATCATCGCCGTCAACGCGGCGGGTAAATCCGAGCCTTCTTCGTGCACGACTCCCGTACGTACCGGCGAAGAGATCGGAGGAACGAAGCCGGAGTGGGTGAAACAGCTGCCGGCCATCATGAGCGCCCCGCTCGGCCGCCCCTACACCCTGGAGTGCGTGGCGAGCGGGAACCCCGTGCCCACGGGCAGATGGCTCAAGAACGGCAGAGAAATCGTTCTTGGTACCAGGTTCATATCAGAGTCTCGTGAGGGTACACTGAAGCTCAATATCCTGGAGGCCGCGGACGCCGACGAGGGTGACTACACTTGTGAGGCGGTTAATAACATTGGCTTCATCTACTGTACTGGTCACCTTAAGATTGGAAGTCCACCACGCATCACCCGAATGCCTGGCGACCTTCACCTCCCCGAACACGACAACACCAAGATCAAGATCCTGTACACGGGAGACCAGCCCGCTGACGTCACGCTGTCCCGGGACGGACACAATCTCAAGGAGTCGCCGCATCTCAAGTTCACCGTATTCGATGATTACATACTTATATTCATCAAGGACATCACTAAGGACGATATGGGCATATACAAAGTATCGATAAAGAACAACTCTGGCGAGACGTCGGACACGTTCTCCGTGACGGTGACGGGGCTGCCCGGCCCGCCACAGGGACCCCTCGAAGCGTCCGACATCTCCAAGCACTCCTGCACGCTGGCCTGGAAGCCTCCCACGTACGACGGAGGGATGCCCGTCACTCACTACGTCATCGAGCGTAACGACACCTCGGGAACGGCCTGGATCACCATCGCCTCGTCCGTCCGGGACACCAAGTTCATTGTCCAGGGACTCACCGAAGGACACGAGTACAACTTTAGAATTCACGCTGCGAACGAGAACGGTATCGGACCAGCTCTGGAAGGCCTCAATCCGATTAAGGCTAAAGCACCATACGATCCGCCATCTGCTCCTGGTATTCCCAAGATCCTGGAGGTCGGAGGCGACTTCGTCCACTTGGAATGGGACAAACCAGAAAATGATGGAGGTGCTAGGATTCTAGGCTACTGGGTCGACAAGCGCGAAGTGGGCACATCGACGTGGCAGCGCGTGAACCCGACGCTGTGCCTGCCGAACCAGATCAACTGCTCCAACCTCATCGAGGGCCGCCAGTACGAGTTCCGCGTGGTCGCGCAGAACGAGGCCGGCGCGTCGCCGCCCAGCACCGCCAGCCAACAGGTCAAGGTCGTCGATCCTAAAGCCGCCACGCCACCAGAGATAGTGAAGCCACTGAAGAACGCCAACTGCATCCAGTACCACAACGCCAAGTTCCAGTGCACCATCACCGGGTCGCCCAGACCCACCATCACTTGGTACAAGGGAGCTCGCGAGATAACGAACGGACCGCGGTACCGCATCTGGAGCGAGGGCGACAACTACTTCTTGACTGTCAACGACGTGTTCGGCGAGGACGCCGACGAATACGTCTGCAGGGCCGTCAACAAGGCAGGAGTCAAGAGCACCAGAGCTGAACTACTTATTATGACCGCCCCGAAACTGAACGTGCCACCTCGGTTCCGCGTCACCGCCTACTTCGACAAGGGCGAGAACGTGGTCGTCAAGATCCCCTTCACCGGACACCCCATACCCAAGATCACTTGGGTCAGGGAGGGAGAGACCATCGAGTCTGGACTTCACTATCACGTGGAGAGGAAAGAACGTCACGCCATCCTGACCATCCGCGACGCGAGCAAGATCGACTCTGGTCCCTACAGGATCACGGCAGAGAACGAGCTGGGGCAGGACACGGCCATCATCAACATTGAGATCAGCGATCGGCCGGACCCACCGCGCTTCCCAGCGGTGGACAGCATCGGCGTGGACTCGCTGGCGCTGAGCTGGCGCGCCCCGGTGTGGGACGGCGGCTCCGACATCACCAACTACCTGGTCGAGAAGCGAGAGCACCCCATGACCAGCTGGATCAGGGTCGGGAATACCAGGTTCACGACAATGGCTATAACCGGTCTGGTCCCGGGCAAGCAGTACGAGTTCAGGGTGTACGCTGAGAACATATACGGCCGGTCGGACCCCAGCGAGCCGACCTCGCTCGTGCAGACCAAGGCGATCGTTAAAAAGGAACTCAAGAAGAAGGAATACCCGGTGGACGAATCAGGCAAACGCATCCGCACGAACGCAGACCACGGCCCCGTCAAGGACTACGACAGCTACGTGTTCGACATCTACAGCAAGTACGTGCCGCAGCCCGTGGACATCAACACGTGCTCGGTTTACGACAAATACGACATACTAGAAGAGATTGGCACAGGCGCGTTCGGCGTGGTGCACCGCTGCCGCGAGCGCGCCACCGGCAACATCTTCGCGGCCAAGTTCATCCCGGTCGCCGGGGCCATGGAGAAGGAGCTCATCAAGAAGGAAATCGACATCATGAACCAGCTGCACCACAGGAAGCTGATCAACTTGCACGACGCCTTCGAGGACGATGACGAGATGGTGCTCATATTCGAGTTCCTGTCCGGCGGCGAGTTGTTCGAGCGCATTACGGAGCCCGGCTACAACATGAGCGAGGCGGAGGCCGCGCACTACATGAGGCAGATCTGCGAGGGCGTGAGGCACATGCACGAGCAGAACATCATACACCTCGACCTCAAGCCCGAGAACGTCATGTGCCAGACCAGGACCGGAACCGACGTTAAGATCATCGACTTCGGATTAGCGACGAAGCTGGACCCGAACGAAGTGGTGAAGATCTCGACTGGAACCGCAGAGTTCGCCGCTCCGGAGATCGTAGAGAGGGAACCGGTCGGCTTCTACACGGACATGTGGGCCGTGGGAGTACTGGCCTATGTGCTATTATCCGGACTGTCGCCATTCGCCGGCAACAACGACATTGACACGCTCAAGAACGTAAAGGCTTGCGACTGGGAGTTCGACGAGGAAGCCTTCCAGCACGTCTCCGACGACGCCAAGGACTTCATCAGGAGGCTGCTCATTAAGAACAAGGAAAAACGTATGACCGCCCACGAGTGCCTGGTTCACAAGTGGCTGGCCGGCGACGCGGCCTCTAGTCGCACCGCCACCATCGAGGCGAGGAGATACGAAGCCATGAGGAACAGGCTCCGGGAGAGATACGAGAACTGGTCGTCATTCAAGTTGCCGATCGGCAGACTCAGCGAGTACAGCTCGCTCAGGAAACTCCTCATCGAGAAGTGGAAGATATACGACGGACAGTTCGACCGTCGGCAGGCGGCGCCGCGCTTCGTGATCAAGCCGCAGTCGGCGTTCTGCTACGAGGGCCAGTCCGTGAAGCTGTACTGCCGCATCATCGCGTGCGCCACGCCCACCGTCACCTGGTCCCGGAACAACCACGAGCTGCGCCAGTCCGTCAAGTTCATGAAGAGATACGCCGGCGACGATTATTACTTCATCATAAACCGCGTCAAGCTGGAGGATCGCGGCGAGTACATCATCAGGGCGGAGAACCACTACGGCTTCAGGGAGGAAGTGGTATTCCTGAATGTGCAACCCGTGCCCAAAGTCCAGCGCACGCACGTGTCGGAGGCCCCGCGGCGCCGCGAGCCGCTGCCCTACACGTTCTGGCAGGAGACCAGCGAGACGGCGCCCGCCTTCACCTTCCAGCTGCGGCCGCGCGTCATGCAGGCGCGCGACACCTGCAAGCTGCTGTGCTGCCTCAGCGGCAAGCCCACGCCCACCGTCAAGTGGTACAAGGACAAACGCGAGCTGTCGAAGTACGACTACGCGATGGCGCACTCGGACGGCGTCGTGACCATGGAGATCATAGACTGTCGGCCCGAGGACAGCGGCAAGTACACGTGCGTCGCCACCAACGTGCACGGCACCGACGAGACCTCGTGCGTCGTTATCGTTGAAGGCGAGGTGACGTCACCCGAACAACAGCGGATGGTGCACAACTTCTTACACTCGGGCGACCGGAGGTACATCGAGAAGCCGCTGAAGCCCGCCCCGCCGCCCATCATCACCAAGACGAAGGTGACGATAGACCCTCCATCGAAGACGGGTCCTCGTCCGAAGTACTCCCCACAGAGCTCCGTGGACGCGAAGAAGAAATACGGATCCAGACTCGACTCGGACGCGTCGTCGCGGTCCAGAAGCGCCACCAAGGAATTGATAATGCCGGCGGCGGACTCGTCGATGTGCGCGCCGACGTTCGCCCGCAGCCTGCCCGCCACGCTGTGCGCGCGCGACGCGGCGCCGCTGCTGCTGTCGTGCGCCGTGCGCGGCGACCCCGAGCCCGCCGTGCGCTGGTACAAGGACGCGAGCCCGCTGCACTCCTCAGAGGTCGTGGACTTGAAATACAAGAACGGCGTAGCGTCGTTGGCCATCAACGAGGTGTTCCCTGAGGATGAAGGGGTGTACTCCCTGAAGGCCACCAACAGCCAGGGAGAGGTGGAGACCAAATGTATAGTTACAGTTAAACCAATGGACACGAGCGCCGGCAGCGCGGCACTGAAGGCCGGAGACAAGCCGCCGAGGATAGTGGACCACGCCGTCTCGCAGGTCGTCAACGACGGCGACCCGGTCACGCTGTCCTGCAGGATCGTGGGAGCCGAACGCTTCGATGTCGTCTGGCTGCACAACAACAAGGAGATCAAACCGTCCAAAGACTTCCAGTACTCGAGCGAGGCGAACATACACAAGCTGCACATCGCCGAAATATTCCCAGAGGATGCCGGTACATACACGTGCGAGGCGTTCAACGACGCCGGCGAGTCGTTCTCGTCGTGCTCGGTGGTGGTGCGCGTGCCGGGCGAGGCGCCCCCCGCCCCGCACTACGTGGCCTTCCCCGCCTCGCTCACCGTCAACGCAACCGAGCCCGCCGTCTTCACCGCAGAGCTGGACAAGCCACCGCTCCAGCTCCAGTGGCTGAAGGACGGCAAGCCGGTGGACGAGAGCTCGCCCCGGTACCGGTTCAGCATGGAGGGCGAGGCGCGGTACCGCCTCGAGCTGGTGGGCGCCGCCCAGGGGGACGCCGGCCAGTACCAGGCCCGGGCCGTCGGCTCCAAGGGAGACGCGCTCGCATCCTTCTATCTCAACGTCACCGACCACTAG
Protein
MSVKLFTRLVCFKITIDSADEEKQKQPDGKAPTFARKPAIRQEDDGKRLIFECRIEAEPVPGVTWFHNAVEVKPGARHKLTVSKEGKSYYASLEINNVTVEDAGKYKVTAKNELGESNATISLNFDSDEAPVPEDFIKPTFTERPVIRQSDDGTKITFECRCVGKPKPTIAWYHGKKMIKESSRYKITLEEDQTLYHMARLEIIGVENSDRGEYRALAKNKHGEGVAKINLNFEGGDKPKIPDGKAPRFPKKPTIRQEGDLLIMECVLEAYPVPDITWFHGDREIKDGPKMKMSRKATGKDTFNLTLEILSPSKEDGGNYRCNAFNLFGESNANIALNFQGGDDENGFAPSFVEKPRIIPNEDGTLITMRCVCKAKPAAEVSWYRGTTVIKASSKIEIKSSKIEEDVYELLLLLTNPTAADGGAYRCHVKNEFGESNANLNLNIEAEPEPEGEGPTFVEKPTIQSKDNGKLVIMGCKVKASPRPTIVWYHEGKEIKESSKIKTRIEVHEDIYTIILELIDPGIEDSGLYKCNIKNELGELNANLTLNIEIIPVIKEKPKIIKIVKKKTVIVECKVLSKFAPQCTWFKEASAVKEDSRHTVLIEPVREGEFAVKLEISNVSQTDKGSYKLVAKNEKGEATSQQVEITEIPEEKGEKPHIIKHLRSLARKENEEAEFIAVLKTSDQSCRCTWYKNSTVIRDTSEVNTSFDGTNARLIIRKVSSKYVANYRVVIKNEYGEDESSADLTIVDEKKKKKEEEEEEITVIEESEEEMSIVEEKSIIEENHVDEKKKNEEIKKKEEEKTTIEEKKTASKKVTKKGEITIENNQEEMEIESKKADSKVESKKIETKKEETRKAELEAEEAKKIIEKKTNKTEEEKKALLEKLEKKKPEPEPEKKIEGIPKLKSVKPKEEPVETKKEVSKKSTEEKKKVVKKKVVAKKEEDEIEFVDDYERPVLEKYEKITPTPLAKKAKQDDTPKGKRASVSESVKSDQFSEDEPSIAEPTPEKKTKVEFNDKVDEDKAESRRSSIKKGIPKPEEPVDELTNIKLSKKPSKQIEEPLEEPQVAKTKKPVRKPGDTDEFIDDYERPELEKYDKLTPTPLDKTNKVNGVDEADSKFVDDYEKPELEKYEKVAPTPKDKRRTSDTQDDVDMMKGKIKPKEKEEEPEMPTLRKRPVQKDKVVEEEFVDDYERPVLEKYEKITPTPLEKKKKEDKKLEEETQSTTATRRRSVKDKESAKPEEDKKPDEETPSATATRRRSVKDKDNDKPEPMDVDENFSITKPKTPAKPGQEPETSLTHKTPAEIKPTEDEAEAKLHVKKPEIIEEKTLKRPSPKDKEPKEDDTEEAVSLSKPRKKTSTTAPEEAQLTQKTPAKKKLTEGAEAATLKVKKPAVVKKDDDQEYELDFVDDYERPVLEKYEKISPTPIVREKKEKETKTESRRTSIQSEVKEETKSESRRSSIIENKAVKLTKETAESRKSSISSVAEQQEVSTLKKSSAQRTSIKAAEASEVEQIKLKDDVTMRVEEKTESDDKPTDKTYPWRRTKTDTQEPKEDIEPKPKESLESQEQVPKRRQSKTEENETVEEVEKPKPKRKLSTQRVRPKNCSKKANEENESIEEIEVTEKATKPEELIDKQTDTKPTRKPSATDENKENIPENKLTEKTDVKRQVSIDEPLETASSSRLPSQVAEDGDDKIVEHKQSKRRVSVDRPTEPTYPWRRPSRADEDYEMTDISNRQEPKTLIESNDFQTPSDELIKTEEEKNRPELSEKPKDEIKESIEQPKYPWQRPKKAVEVKKETEATDKSNDEKKSPSQPKYPWQKPKKVDEEPEATKQVPQTKTDVTENTKETEAPFLKKIEPKKEGLDDQKPQVDNDKIPEKIQVELDSTDIKEPDTQYKTDTVQDRQSPYPWRKQHTEGDATDGKDEPKPATLGIPQAAFISSPDLTPNEKVAVKEEKIEEEAKKAKLSSVKKKAEELPEIPDYERPDLEQYEKISPTPTTRDKPDKDKPVPKVPEIKAPEEKPAAPKIEVIREKSPKPEMPRKPSLVPGAPVGRRGSLIPPPEEMGRRPSLIISDEKRGRPGEVTDERRKSGDARRPSLQELEDLINKPSIPLKPIGNGGPPAIVMVEENYSAIEDQTGYITIQVEGNPAPTFKFYKGVSEIIEGGRFKFVTDGETGLITLCIRKVKPHDEGKYKAVVSNIHGEDSAEMQFYVSDASGMDFRAMLRRRKYAKWGEKKEDPDWGDLKETEKPIPPLKKVEKKQESFLKPLVDQNVKEGKDKKVVFEAIFTKPNSKPKWLFRKDELFPSTKYKIVNEQDSYKLIIMNPKVDDTGKITLEIGGVSCSAFLHVDEPDPTYTFTKPLKKNTSGYTKHEVLLECAVSNSLAIVSWWKGDQKLEDGDEYQISKDLSGVCKLIIKNAKFDHAGKYTCRIEKQPDKTETDVKIVEYPYKFTKVLKSQQAIEKDTITLLCELDDASGDVKWFKNNEPLKPDKRISIVKEGRKRKVIIKDAKVTDAGHFKCTTNADETQCELIVNYANRFNKKLKDTEAIERDRVVLEVELQDQTAEAVWSFNGQPIVPNERIEIKNLGGGKHQLIFNKLEMEDDGEILCESGKLTSSCKLTVKKGESKPAIECPDEFNGPAGHPFVIEVPYKVTGTRQTPIEAKLWKDGKALPAKEVEVVVEQEKVLFKFKKPSREGSGKYQIKLSNAQGEDSKDVNITMQSAPTAPQDVEVSEVFQTSCVVAWKTPQDDGGSPIIKYVIERQDMSLKAGWDNVAEVPYGEPTKFKVEDLIPKKTYKFRIRAVNKIGSSEPGLFSKPVLAKDPWDEPSKPKNVELTDWDKDHADLKWQKPENDGGAPITGYVIEYKEKFGKDWVTGKEVSGDCLAATQDGLKEGCTYEFRVRAINKAGPGEPSDATKPIIAKCRFVKPYIIGEGLQNMIIKKGQVISFDIKYGGEPEPEVKWMKGEEEIRDDGDRITIDKYERNTVLTVRKTTRPDSGKYKLVLTNSSGTCESIADVVVLDKPNRPNGPIEVVDIRAEKATVKWQKPDDWQGSDITGYTLEKMDMDTGNWVPCGETGPEPTEFTVKGLTPNHKYKFRVRAVNKEGESEPLETDGFIVAKNPYDPPKAPGKPTIVDYDNMSVTLQWEPPSDNGGRPVLGYVVEMKDKFAPDWIEVVKTNDTKTEYKVEGLKEKMVYQFRVKAYNKAGVGDASEPTDNHLCKHKNLKPRIERSTFKSVIIKAGRTHKWSVDVIGEPPPETTWSWRDNIKLVNTERIKIENRDYHTDFTIVNAVRRDTGKYTLRAENCNGSDEETVELTVLSKPSSPKGPLEVTDIHAEGCKVKWEKPEDDGGSPVKEYEIEKMDLATGKWVRVGRVAGDKKPLEMDITGLEPGHQYKFRVTAVNDEGDSEPLEAERAILAKNPFDVSEKPMNVEVADHDNQSAEIKWEPPKSDGGAPVQKYIIQKKPKGGDWENAVEVPGTQTSGKVEGLPEGSEFQFRVIAVNKAGQSEPSEPTKMTTIRHKALKPRIDRTNLKALAVKAGKPIFFDVNVRGEPAPKVQWFQKWKNEEKEVTANVINVDYNTKLDIKESVRAMTGTYRIVATNEHGKDEAEVEITVLSSPSKPGGPLKVSDVTKNGCKLQWKKPEDDGGKPVTGYMVEKLNKATGRWVPVGKTDDTEMDIKGLQEGEEYEFRVKAINDEGESEPLKTDHSIIAKNPYDIPGKPSVPTLEDWDVDRVDLKWEAPKNNGGAPITGYIIEKKEKYGQWQEALVTTTPECKARVPDLKEGNVYQFRVRAVNKAGPGEPGDATQPHTAKARFLKPHINRDKMVAIRVRAGATIKLDVDIRGEPPPTKTWTFAKKVLETGAGIKIENEDYNTKMQIFDSSWKNSGIYTLKAENDSGVDEATVEVTVLDKPGKPEGPLEVSDVHAEHVKLSWNKPKHTGGLPLSAYVVEKMDTLTGKWVPAGTVQPDTTEATVTGLEPGHTYQFRVKAVNEEGESEPLETDHGVLAKNPYDVPAPPGLPDIVDWDEKSVKLKWEPPIRDNGAPITGYIIELMDRDRGEFVKAAEIHDNVCQGTVPKLEEGNQYQFRVRALNKAGQSEPSENTNWHTAKPRFLKPRIDRTNLGAVTVKAGLPVSLDVKVFGEPPATVTWHYKGEELKNRENLEIINVDYNTKFLMTKSKRANSGVYVIKAKNEVGEDEAEVEITVLGKPSKPKGPLDVSDITKNGCTLTWKKPEDDGGSPIEYYEIEKLDPLTGQWIPCGTAKDTKANIAGLQEGKPYKFRVKAVNKEGESEELETEKPIIAKNPFDEPGKPGRPEPRNWDKDFVELEWSAPKDDGGAPITGYIVQKREKGGRSWQDCLKTTGDRPTGRVTDVEEGHEYEFRVIALNKAGPSEPSEPSKSVIAKPRFLKPHIDRKNLQKKKIKVGQPLKMEADVKGEPEPTITWTFNDQTLKTADRVTIENKDYHTSFIKQKMVRTDAGKYVVTAKNDSGTDTVEVEVEVVSKPSKPKGPLKVSDVKADGCKLKWEPPEDDGGEPIESYVVERMDTDSGRWVPVCTTKTPEADVTGLNEGKDYMFRVKAVNPEGESEPLVTESATTAKNPYGEPDAPGKPEFKDWSKEHVDLKWEKPTNDGGAPITAYIVEKKDRDTGKWVKAVEVPGNKTEARVPDLIEGKQYQFRVKAVNKAGPGKPSAATDNLLIKDRFAPPKIDRTNMRDITIKAGQHIRLDVKVSGEPPPTKTWFHNKERLSSRDDLSVDVEDYKTKLSVVIASRKHSGSYTLKAENSSGKDEATIQVHVLDVPAKPEGPLKISDVHKEGCTLKWSPPLDDGGAPIDHYLVEKLDTETGRWMPAAKTKDPKAELENLVPGHEYKFRVSAVNNEGQSEPLEAEHSIIAKNPFDEPGKPGTPEVVDWDKDHVDLKWEKPVKDGGAPITGYIIEKREVGSPKWVKACEVGPNDNDKATVPNLDEGTEYEFRVRAVNEAGPGEPSDASKSVVCKPRRLPPKIDRRNLRTIKVREGEPIALDVKVSGEPAPEVTWTLNGKSVLSGNGLKLVNVPYISKYQHASPRRKDSGTYKIQATNKYGQDTAELEIIVTSKPDKPEGPLEVSDVHKDGCTLKWKRPKDDGGEPIDSYLVEKYDTETGVWLPVGNTIGNVPEMEVEGLTPGHEYKFRVKAINKEGESEPLDTYGAIVAKDPYTVPDAPSAPVPDDWSANHVDLKWEAPLSDGGSPIIGYIVEKKDKYSPLWEKAVETHTPTPTATVNGLIEGNEYQFRVIAINKAGQSKPSDSSKNFVAKARFLAPKIDRRHLRDVTLSAGATLKLEAAVAGEPAPAVEWRYQNMPLRPSKAVSIDNPEYFTKLVVRPVRRDDTGEYTVTAVNSSGKDAVTINVTVTDKPTKPEGPIQISDVHKEGATLKWKRPKDDGGTPIEYYQIDKLDTDTGCWVPCARSEEPKCDVTGLTPGKEYKFRVSAVNAEGESEPLVTDHAIVAKNPFDEPGAPGTPTVTDWDKDHVDLKWTPPREDGGAPVEAYIVEKKDKFGNWEKAVEVPASKTSATVPDLIEGQTYEFRVRAVNKAGPGEPSDSTHPIVAKPRNMAPKIDRTNLIDIKIKVGQKFGFDVKVSGEPMPVTKWYLAKKEVKSGGDMKVQHADYNTKLSCKAATRADSGRYTVTAENSNGKDVAEVEVVVLSVPAPPGGPLKVSDVHANGATLSWRPPPDDGGQPIDKYVVERMDEATGRWVTAGETDGPVTSLAVDGLQPGHKYKFRVSAVNRQGRSDPLTTPHSTEAKNPFDVAGKPGTPKIKDFDKDFVELEWTRPQTDGGAPITGYVIEKKDRFAPDWEECAKIDGDVTSGKVPDLIEGNTYEFRVRAVNKAGKGEPSDGTAPHLARPKNLPPKIDRNFMFDIKVKVGQNFDLEVPVAGEPTPTKEWLHGDNVVLNTDRIKIVNDDHSTKFRVIDAKRADTGTYTLKARNINGTDTATVKVLVMDVPTAPEGPLRADDITKSGCTLRWRPPKDDGGAEITHYVVEKMDQENLRWIPAGEVQGCNIRIDHLIEGHDYNFRVRAVNKHGESQPLVGHEPITAKDPYGTPDKPGTPVVKDWDKDHMDLEWVPPKKDGGSPITGYIIEAKKKYGPWEVAATVPGNQTTATVPGLQEGEEYEFRVIAVNKAGNGEPSDGSTPQVAKARFCAPHFDKMLLADKTVKAGQRIQYEIPIEASPKPTVEWQINGKVVHPSDRVDIQLLHNRVILDIPFSVRSDGGVYKLTLKNDLGVCSATAQVTVLDKPSRPEKPLTVSDITKDSCSLSWRVPLDDGGSPILHYVIEKMDLTRGTWSDAGMSTFLSHQVTRLIHKKEYLFRVSAVNAIGQSEPLELERAIVAKNEFDEPTAPGKPEATDWSKNHVDLQWAAPKSDGGSPITGYIIQKKEKGSPYWVNAVHVPPSKTKATVPDLTEGQDYEFRVIAVNQAGQSEPSEPSDVITAKDRFVAPKILTPLKEIRIKAGLIFHFDVDFIGEPTPEVTWTCDGKPVVTNERTTVTSVGHHTIIHTVNCKRSEAGTYHLKLKNDSGTDEGSFELIVLDVPGAPQPPFTYEEITAQSVTLSWKPPKDNGGSELTAYVIEKRDLSHGGGWVPAVTYVNPKYNHATVPRLSEGTQYEFRVFAENLQGRSEPLVTDKPIVAKNQYTVPGKPGKPELVSADKDHIKVRWSSPISNGGSNILGYDVERRDKATGRWIKLNKEPVRFNEYQDDRVQEGHQYEYRVSAVNAAGPGQPSDESNVFIAKPMKEKPKLWLDHLIGKKIKVRAGEPININIPITGAPTPTISWTKGSVPLVPSHRLSAETKNDETKLSIEKSTREDAGKYTISASSHVQPVTHDAISLTWQPPTDDGGSEITGYVVEVAEFGVNDWRTVAGFCPKCSFTVKNLTEGKKYVFRVRAENLYGLSDPLESKPIIAKSPFDPPDAPDTPKVTGYSSNSCALEWHPPANCGGKPVTGYYVEKRERGGDWVKVNNYPTPNTCYTVSDLREGNKYEFRVIAVNEAGPGKPSKPTEPITAQTQRLKPSAPEAPKPDRITKDSVTLSWRPPKSDGGAKIKGYIVQQKGKGDKDWKDVNDVPIPSLVHTVPKLKEGEEYQFRVIAVNEVGKSEPSKPTADITIAEQPNKPCMDLGGVRDITVRAGEDFSIHVPYTGFPQPTAQWFADDNLLDVEGDSRIFQKITPDSASLVVKNAKRSDGGQYRLQLRNPSGYDTATINVRVLDRPGKPENLRADEFEGEALTLYWNPPKENGGGEITNYVVEKREARTPNWTKVSGYVTTPFLRVKNLTVGKSYEFRVMAENQYGQSDPAQTTEPIRARHPFDPPGPPGVPKSVETSETSITITWTKPRHDGGSPITGYIVEKRLITEDKWTKACHAHVPDTTLKVTGLIENHEYEFRVSAVNAAGQGPWSQSSDAIRARAPPNSPRITSDLSLRDITVIAGEEIKITVPFTGNPRPKVSWIVNNDEVFPDNRIRFVTTDIDTVFYNSCAKRTDTGSYTIQLVNSEGSDSATCRVLVVDKPTPPVGPLDAYDITPDTCTLSWKPPLDDGGSPITNYVVEKMDNNGIWTKISSFVRNCHYNVMGLEPNRKYLFRVRAENQYGVSEPLTMDDSITAKFPFTIPEPPGAPRVTDWDGSTATVLWDRPRSDGGSRIQGYKIEYRDVQDGVWNSADYLVKDCNYQAYNLEPGHEYEFRVRAKNAAGFSKYSGSSQRFRVRARCGPPAPPTAPRVLRVGRNYVDLSWDPPKHDGGSRVTGYVIERRDVGSSVWVKCNDYNVQDTTFTALNLNEKADYEFRIIAVNAAGKSEPSSCTTPVRTGEEIGGTKPEWVKQLPAIMSAPLGRPYTLECVASGNPVPTGRWLKNGREIVLGTRFISESREGTLKLNILEAADADEGDYTCEAVNNIGFIYCTGHLKIGSPPRITRMPGDLHLPEHDNTKIKILYTGDQPADVTLSRDGHNLKESPHLKFTVFDDYILIFIKDITKDDMGIYKVSIKNNSGETSDTFSVTVTGLPGPPQGPLEASDISKHSCTLAWKPPTYDGGMPVTHYVIERNDTSGTAWITIASSVRDTKFIVQGLTEGHEYNFRIHAANENGIGPALEGLNPIKAKAPYDPPSAPGIPKILEVGGDFVHLEWDKPENDGGARILGYWVDKREVGTSTWQRVNPTLCLPNQINCSNLIEGRQYEFRVVAQNEAGASPPSTASQQVKVVDPKAATPPEIVKPLKNANCIQYHNAKFQCTITGSPRPTITWYKGAREITNGPRYRIWSEGDNYFLTVNDVFGEDADEYVCRAVNKAGVKSTRAELLIMTAPKLNVPPRFRVTAYFDKGENVVVKIPFTGHPIPKITWVREGETIESGLHYHVERKERHAILTIRDASKIDSGPYRITAENELGQDTAIINIEISDRPDPPRFPAVDSIGVDSLALSWRAPVWDGGSDITNYLVEKREHPMTSWIRVGNTRFTTMAITGLVPGKQYEFRVYAENIYGRSDPSEPTSLVQTKAIVKKELKKKEYPVDESGKRIRTNADHGPVKDYDSYVFDIYSKYVPQPVDINTCSVYDKYDILEEIGTGAFGVVHRCRERATGNIFAAKFIPVAGAMEKELIKKEIDIMNQLHHRKLINLHDAFEDDDEMVLIFEFLSGGELFERITEPGYNMSEAEAAHYMRQICEGVRHMHEQNIIHLDLKPENVMCQTRTGTDVKIIDFGLATKLDPNEVVKISTGTAEFAAPEIVEREPVGFYTDMWAVGVLAYVLLSGLSPFAGNNDIDTLKNVKACDWEFDEEAFQHVSDDAKDFIRRLLIKNKEKRMTAHECLVHKWLAGDAASSRTATIEARRYEAMRNRLRERYENWSSFKLPIGRLSEYSSLRKLLIEKWKIYDGQFDRRQAAPRFVIKPQSAFCYEGQSVKLYCRIIACATPTVTWSRNNHELRQSVKFMKRYAGDDYYFIINRVKLEDRGEYIIRAENHYGFREEVVFLNVQPVPKVQRTHVSEAPRRREPLPYTFWQETSETAPAFTFQLRPRVMQARDTCKLLCCLSGKPTPTVKWYKDKRELSKYDYAMAHSDGVVTMEIIDCRPEDSGKYTCVATNVHGTDETSCVVIVEGEVTSPEQQRMVHNFLHSGDRRYIEKPLKPAPPPIITKTKVTIDPPSKTGPRPKYSPQSSVDAKKKYGSRLDSDASSRSRSATKELIMPAADSSMCAPTFARSLPATLCARDAAPLLLSCAVRGDPEPAVRWYKDASPLHSSEVVDLKYKNGVASLAINEVFPEDEGVYSLKATNSQGEVETKCIVTVKPMDTSAGSAALKAGDKPPRIVDHAVSQVVNDGDPVTLSCRIVGAERFDVVWLHNNKEIKPSKDFQYSSEANIHKLHIAEIFPEDAGTYTCEAFNDAGESFSSCSVVVRVPGEAPPAPHYVAFPASLTVNATEPAVFTAELDKPPLQLQWLKDGKPVDESSPRYRFSMEGEARYRLELVGAAQGDAGQYQARAVGSKGDALASFYLNVTDH
Summary
Description
Regulator of muscle contraction and relaxation. Senses mechanical strain that occurs during muscle activity by unfolding in clearly resolvable steps at differing forces (PubMed:18390597, PubMed:7190524). Plays a role in the organization of sarcomeres in body wall muscles (PubMed:25851606).
Key component in the assembly and functioning of vertebrate striated muscles. By providing connections at the level of individual microfilaments, it contributes to the fine balance of forces between the two halves of the sarcomere. The size and extensibility of the cross-links are the main determinants of sarcomere extensibility properties of muscle. In non-muscle cells, seems to play a role in chromosome condensation and chromosome segregation during mitosis. Might link the lamina network to chromatin or nuclear actin, or both during interphase.
Serine/threonine-protein kinase (PubMed:18390597, PubMed:20346955). Key component in the assembly and functioning of muscles. By providing connections at the level of individual microfilaments, it contributes to the fine balance of forces between the two halves of the sarcomere. The size and extensibility of the cross-links are the main determinants of sarcomere extensibility properties of muscle. In non-muscle cells, seems to play a role in chromosome condensation and chromosome segregation during mitosis. Might link the lamina network to chromatin or nuclear actin, or both during interphase (By similarity).
Calcium/calmodulin-dependent myosin light chain kinase implicated in smooth muscle contraction via phosphorylation of myosin light chains (MLC). Also regulates actin-myosin interaction through a non-kinase activity. Phosphorylates PTK2B/PYK2 and myosin light-chains. Involved in the inflammatory response (e.g. apoptosis, vascular permeability, leukocyte diapedesis), cell motility and morphology, airway hyperreactivity and other activities relevant to asthma. Required for tonic airway smooth muscle contraction that is necessary for physiological and asthmatic airway resistance. Necessary for gastrointestinal motility. Implicated in the regulation of endothelial as well as vascular permeability, probably via the regulation of cytoskeletal rearrangements. In the nervous system it has been shown to control the growth initiation of astrocytic processes in culture and to participate in transmitter release at synapses formed between cultured sympathetic ganglion cells. Critical participant in signaling sequences that result in fibroblast apoptosis. Plays a role in the regulation of epithelial cell survival. Required for epithelial wound healing, especially during actomyosin ring contraction during purse-string wound closure. Mediates RhoA-dependent membrane blebbing. Triggers TRPC5 channel activity in a calcium-dependent signaling, by inducing its subcellular localization at the plasma membrane. Promotes cell migration (including tumor cells) and tumor metastasis. PTK2B/PYK2 activation by phosphorylation mediates ITGB2 activation and is thus essential to trigger neutrophil transmigration during acute lung injury (ALI). May regulate optic nerve head astrocyte migration. Probably involved in mitotic cytoskeletal regulation. Regulates tight junction probably by modulating ZO-1 exchange in the perijunctional actomyosin ring. Mediates burn-induced microvascular barrier injury; triggers endothelial contraction in the development of microvascular hyperpermeability by phosphorylating MLC. Essential for intestinal barrier dysfunction. Mediates Giardia spp.-mediated reduced epithelial barrier function during giardiasis intestinal infection via reorganization of cytoskeletal F-actin and tight junctional ZO-1. Necessary for hypotonicity-induced Ca(2+) entry and subsequent activation of volume-sensitive organic osmolyte/anion channels (VSOAC) in cervical cancer cells (By similarity).
Calcium/calmodulin-dependent myosin light chain kinase implicated in smooth muscle contraction via phosphorylation of myosin light chains (MLC). Also regulates actin-myosin interaction through a non-kinase activity. Phosphorylates PTK2B/PYK2 and myosin light-chains. Involved in the inflammatory response (e.g. apoptosis, vascular permeability, leukocyte diapedesis), cell motility and morphology, airway hyperreactivity and other activities relevant to asthma. Required for tonic airway smooth muscle contraction that is necessary for physiological and asthmatic airway resistance. Necessary for gastrointestinal motility. Implicated in the regulation of endothelial as well as vascular permeability, probably via the regulation of cytoskeletal rearrangements. In the nervous system it has been shown to control the growth initiation of astrocytic processes in culture and to participate in transmitter release at synapses formed between cultured sympathetic ganglion cells. Critical participant in signaling sequences that result in fibroblast apoptosis. Plays a role in the regulation of epithelial cell survival. Required for epithelial wound healing, especially during actomyosin ring contraction during purse-string wound closure. Mediates RhoA-dependent membrane blebbing. Triggers TRPC5 channel activity in a calcium-dependent signaling, by inducing its subcellular localization at the plasma membrane. Promotes cell migration (including tumor cells) and tumor metastasis. PTK2B/PYK2 activation by phosphorylation mediates ITGB2 activation and is thus essential to trigger neutrophil transmigration during acute lung injury (ALI). May regulate optic nerve head astrocyte migration. Probably involved in mitotic cytoskeletal regulation. Regulates tight junction probably by modulating ZO-1 exchange in the perijunctional actomyosin ring. Mediates burn-induced microvascular barrier injury; triggers endothelial contraction in the development of microvascular hyperpermeability by phosphorylating MLC. Essential for intestinal barrier dysfunction. Mediates Giardia spp.-mediated reduced epithelial barrier function during giardiasis intestinal infection via reorganization of cytoskeletal F-actin and tight junctional ZO-1. Necessary for hypotonicity-induced Ca(2+) entry and subsequent activation of volume-sensitive organic osmolyte/anion channels (VSOAC) in cervical cancer cells. Responsible for high proliferative ability of breast cancer cells through anti-apoptosis.
Calcium/calmodulin-dependent myosin light chain kinase implicated in smooth muscle contraction via phosphorylation of myosin light chains (MLC). Also regulates actin-myosin interaction through a non-kinase activity. Phosphorylates PTK2B/PYK2 and myosin light-chains. Involved in the inflammatory response (e.g. apoptosis, vascular permeability, leukocyte diapedesis), cell motility and morphology, airway hyperreactivity and other activities relevant to asthma. Required for tonic airway smooth muscle contraction that is necessary for physiological and asthmatic airway resistance. Necessary for gastrointestinal motility. Implicated in the regulation of endothelial as well as vascular permeability, probably via the regulation of cytoskeletal rearrangements. In the nervous system it has been shown to control the growth initiation of astrocytic processes in culture and to participate in transmitter release at synapses formed between cultured sympathetic ganglion cells. Critical participant in signaling sequences that result in fibroblast apoptosis. Plays a role in the regulation of epithelial cell survival. Required for epithelial wound healing, especially during actomyosin ring contraction during purse-string wound closure. Mediates RhoA-dependent membrane blebbing. Triggers TRPC5 channel activity in a calcium-dependent signaling, by inducing its subcellular localization at the plasma membrane. Promotes cell migration (including tumor cells) and tumor metastasis. PTK2B/PYK2 activation by phosphorylation mediates ITGB2 activation and is thus essential to trigger neutrophil transmigration during acute lung injury (ALI). May regulate optic nerve head astrocyte migration. Probably involved in mitotic cytoskeletal regulation. Regulates tight junction probably by modulating ZO-1 exchange in the perijunctional actomyosin ring. Mediates burn-induced microvascular barrier injury; triggers endothelial contraction in the development of microvascular hyperpermeability by phosphorylating MLC. Essential for intestinal barrier dysfunction. Mediates Giardia spp.-mediated reduced epithelial barrier function during giardiasis intestinal infection via reorganization of cytoskeletal F-actin and tight junctional ZO-1. Necessary for hypotonicity-induced Ca(2+) entry and subsequent activation of volume-sensitive organic osmolyte/anion channels (VSOAC) in cervical cancer cells.
Key component in the assembly and functioning of adult and embryonic striated muscles and muscle tendons. By providing connections at the level of individual microfilaments, it contributes to the fine balance of forces between the two halves of the sarcomere. The size and extensibility of the cross-links are the main determinants of sarcomere extensibility properties of muscle. In non-muscle cells, seems to play a role in chromosome condensation and chromosome segregation during mitosis. Might link the lamina network to chromatin or nuclear actin, or both during interphase.
Structural component of the muscle M line which is involved in assembly and organization of sarcomere (PubMed:22467859, PubMed:26251439). Required for the development and organization of indirect flight muscle sarcomeres by regulating the formation of M line and H zone and the correct assembly of thick and thin filaments in the sarcomere (PubMed:22467859, PubMed:26251439). Likely to have serine/threonine-protein kinase activity as one of the two protein kinase domains appears to be functional (Probable).
May link the intermediate filament cytoskeleton to the M-disk of the myofibrils in striated muscle.
Structural component of striated muscles which plays a role in myofibrillogenesis. Probably involved in the assembly of myosin into sarcomeric A bands in striated muscle (By similarity). Has serine/threonine protein kinase activity and phosphorylates N-cadherin CDH2 and sodium/potassium-transporting ATPase subunit ATP1B1 (PubMed:23392350). Binds (via the PH domain) strongly to phosphatidylinositol 3,4-bisphosphate (PtdIns(3,4)P2) and phosphatidylinositol 4,5-bisphosphate (PtdIns(4,5)P2), and to a lesser extent to phosphatidylinositol 3-phosphate (PtdIns(3)P), phosphatidylinositol 4-phosphate (PtdIns(4)P), phosphatidylinositol 5-phosphate (PtdIns(5)P) and phosphatidylinositol 3,4,5-trisphosphate (PtdIns(3,4,5)P3) (By similarity).
Isoform 2 and isoform 3: bind phosphatidylinositol bisphosphates (PIP2s) via their PH domains and negatively regulate the PI3K/AKT/mTOR signaling pathway, thus contributing to the regulation of cardiomyocyte size and adhesion.
Key component in the assembly and functioning of vertebrate striated muscles. By providing connections at the level of individual microfilaments, it contributes to the fine balance of forces between the two halves of the sarcomere. The size and extensibility of the cross-links are the main determinants of sarcomere extensibility properties of muscle. In non-muscle cells, seems to play a role in chromosome condensation and chromosome segregation during mitosis. Might link the lamina network to chromatin or nuclear actin, or both during interphase.
Serine/threonine-protein kinase (PubMed:18390597, PubMed:20346955). Key component in the assembly and functioning of muscles. By providing connections at the level of individual microfilaments, it contributes to the fine balance of forces between the two halves of the sarcomere. The size and extensibility of the cross-links are the main determinants of sarcomere extensibility properties of muscle. In non-muscle cells, seems to play a role in chromosome condensation and chromosome segregation during mitosis. Might link the lamina network to chromatin or nuclear actin, or both during interphase (By similarity).
Calcium/calmodulin-dependent myosin light chain kinase implicated in smooth muscle contraction via phosphorylation of myosin light chains (MLC). Also regulates actin-myosin interaction through a non-kinase activity. Phosphorylates PTK2B/PYK2 and myosin light-chains. Involved in the inflammatory response (e.g. apoptosis, vascular permeability, leukocyte diapedesis), cell motility and morphology, airway hyperreactivity and other activities relevant to asthma. Required for tonic airway smooth muscle contraction that is necessary for physiological and asthmatic airway resistance. Necessary for gastrointestinal motility. Implicated in the regulation of endothelial as well as vascular permeability, probably via the regulation of cytoskeletal rearrangements. In the nervous system it has been shown to control the growth initiation of astrocytic processes in culture and to participate in transmitter release at synapses formed between cultured sympathetic ganglion cells. Critical participant in signaling sequences that result in fibroblast apoptosis. Plays a role in the regulation of epithelial cell survival. Required for epithelial wound healing, especially during actomyosin ring contraction during purse-string wound closure. Mediates RhoA-dependent membrane blebbing. Triggers TRPC5 channel activity in a calcium-dependent signaling, by inducing its subcellular localization at the plasma membrane. Promotes cell migration (including tumor cells) and tumor metastasis. PTK2B/PYK2 activation by phosphorylation mediates ITGB2 activation and is thus essential to trigger neutrophil transmigration during acute lung injury (ALI). May regulate optic nerve head astrocyte migration. Probably involved in mitotic cytoskeletal regulation. Regulates tight junction probably by modulating ZO-1 exchange in the perijunctional actomyosin ring. Mediates burn-induced microvascular barrier injury; triggers endothelial contraction in the development of microvascular hyperpermeability by phosphorylating MLC. Essential for intestinal barrier dysfunction. Mediates Giardia spp.-mediated reduced epithelial barrier function during giardiasis intestinal infection via reorganization of cytoskeletal F-actin and tight junctional ZO-1. Necessary for hypotonicity-induced Ca(2+) entry and subsequent activation of volume-sensitive organic osmolyte/anion channels (VSOAC) in cervical cancer cells (By similarity).
Calcium/calmodulin-dependent myosin light chain kinase implicated in smooth muscle contraction via phosphorylation of myosin light chains (MLC). Also regulates actin-myosin interaction through a non-kinase activity. Phosphorylates PTK2B/PYK2 and myosin light-chains. Involved in the inflammatory response (e.g. apoptosis, vascular permeability, leukocyte diapedesis), cell motility and morphology, airway hyperreactivity and other activities relevant to asthma. Required for tonic airway smooth muscle contraction that is necessary for physiological and asthmatic airway resistance. Necessary for gastrointestinal motility. Implicated in the regulation of endothelial as well as vascular permeability, probably via the regulation of cytoskeletal rearrangements. In the nervous system it has been shown to control the growth initiation of astrocytic processes in culture and to participate in transmitter release at synapses formed between cultured sympathetic ganglion cells. Critical participant in signaling sequences that result in fibroblast apoptosis. Plays a role in the regulation of epithelial cell survival. Required for epithelial wound healing, especially during actomyosin ring contraction during purse-string wound closure. Mediates RhoA-dependent membrane blebbing. Triggers TRPC5 channel activity in a calcium-dependent signaling, by inducing its subcellular localization at the plasma membrane. Promotes cell migration (including tumor cells) and tumor metastasis. PTK2B/PYK2 activation by phosphorylation mediates ITGB2 activation and is thus essential to trigger neutrophil transmigration during acute lung injury (ALI). May regulate optic nerve head astrocyte migration. Probably involved in mitotic cytoskeletal regulation. Regulates tight junction probably by modulating ZO-1 exchange in the perijunctional actomyosin ring. Mediates burn-induced microvascular barrier injury; triggers endothelial contraction in the development of microvascular hyperpermeability by phosphorylating MLC. Essential for intestinal barrier dysfunction. Mediates Giardia spp.-mediated reduced epithelial barrier function during giardiasis intestinal infection via reorganization of cytoskeletal F-actin and tight junctional ZO-1. Necessary for hypotonicity-induced Ca(2+) entry and subsequent activation of volume-sensitive organic osmolyte/anion channels (VSOAC) in cervical cancer cells. Responsible for high proliferative ability of breast cancer cells through anti-apoptosis.
Calcium/calmodulin-dependent myosin light chain kinase implicated in smooth muscle contraction via phosphorylation of myosin light chains (MLC). Also regulates actin-myosin interaction through a non-kinase activity. Phosphorylates PTK2B/PYK2 and myosin light-chains. Involved in the inflammatory response (e.g. apoptosis, vascular permeability, leukocyte diapedesis), cell motility and morphology, airway hyperreactivity and other activities relevant to asthma. Required for tonic airway smooth muscle contraction that is necessary for physiological and asthmatic airway resistance. Necessary for gastrointestinal motility. Implicated in the regulation of endothelial as well as vascular permeability, probably via the regulation of cytoskeletal rearrangements. In the nervous system it has been shown to control the growth initiation of astrocytic processes in culture and to participate in transmitter release at synapses formed between cultured sympathetic ganglion cells. Critical participant in signaling sequences that result in fibroblast apoptosis. Plays a role in the regulation of epithelial cell survival. Required for epithelial wound healing, especially during actomyosin ring contraction during purse-string wound closure. Mediates RhoA-dependent membrane blebbing. Triggers TRPC5 channel activity in a calcium-dependent signaling, by inducing its subcellular localization at the plasma membrane. Promotes cell migration (including tumor cells) and tumor metastasis. PTK2B/PYK2 activation by phosphorylation mediates ITGB2 activation and is thus essential to trigger neutrophil transmigration during acute lung injury (ALI). May regulate optic nerve head astrocyte migration. Probably involved in mitotic cytoskeletal regulation. Regulates tight junction probably by modulating ZO-1 exchange in the perijunctional actomyosin ring. Mediates burn-induced microvascular barrier injury; triggers endothelial contraction in the development of microvascular hyperpermeability by phosphorylating MLC. Essential for intestinal barrier dysfunction. Mediates Giardia spp.-mediated reduced epithelial barrier function during giardiasis intestinal infection via reorganization of cytoskeletal F-actin and tight junctional ZO-1. Necessary for hypotonicity-induced Ca(2+) entry and subsequent activation of volume-sensitive organic osmolyte/anion channels (VSOAC) in cervical cancer cells.
Key component in the assembly and functioning of adult and embryonic striated muscles and muscle tendons. By providing connections at the level of individual microfilaments, it contributes to the fine balance of forces between the two halves of the sarcomere. The size and extensibility of the cross-links are the main determinants of sarcomere extensibility properties of muscle. In non-muscle cells, seems to play a role in chromosome condensation and chromosome segregation during mitosis. Might link the lamina network to chromatin or nuclear actin, or both during interphase.
Structural component of the muscle M line which is involved in assembly and organization of sarcomere (PubMed:22467859, PubMed:26251439). Required for the development and organization of indirect flight muscle sarcomeres by regulating the formation of M line and H zone and the correct assembly of thick and thin filaments in the sarcomere (PubMed:22467859, PubMed:26251439). Likely to have serine/threonine-protein kinase activity as one of the two protein kinase domains appears to be functional (Probable).
May link the intermediate filament cytoskeleton to the M-disk of the myofibrils in striated muscle.
Structural component of striated muscles which plays a role in myofibrillogenesis. Probably involved in the assembly of myosin into sarcomeric A bands in striated muscle (By similarity). Has serine/threonine protein kinase activity and phosphorylates N-cadherin CDH2 and sodium/potassium-transporting ATPase subunit ATP1B1 (PubMed:23392350). Binds (via the PH domain) strongly to phosphatidylinositol 3,4-bisphosphate (PtdIns(3,4)P2) and phosphatidylinositol 4,5-bisphosphate (PtdIns(4,5)P2), and to a lesser extent to phosphatidylinositol 3-phosphate (PtdIns(3)P), phosphatidylinositol 4-phosphate (PtdIns(4)P), phosphatidylinositol 5-phosphate (PtdIns(5)P) and phosphatidylinositol 3,4,5-trisphosphate (PtdIns(3,4,5)P3) (By similarity).
Isoform 2 and isoform 3: bind phosphatidylinositol bisphosphates (PIP2s) via their PH domains and negatively regulate the PI3K/AKT/mTOR signaling pathway, thus contributing to the regulation of cardiomyocyte size and adhesion.
Catalytic Activity
ATP + L-seryl-[protein] = ADP + H(+) + O-phospho-L-seryl-[protein]
ATP + L-threonyl-[protein] = ADP + H(+) + O-phospho-L-threonyl-[protein]
[myosin light chain]-L-serine + ATP = [myosin light chain]-O-phospho-L-serine + ADP + H(+)
[myosin light chain]-L-threonine + ATP = [myosin light chain]-O-phospho-L-threonine + ADP + H(+)
ATP + L-threonyl-[protein] = ADP + H(+) + O-phospho-L-threonyl-[protein]
[myosin light chain]-L-serine + ATP = [myosin light chain]-O-phospho-L-serine + ADP + H(+)
[myosin light chain]-L-threonine + ATP = [myosin light chain]-O-phospho-L-threonine + ADP + H(+)
Cofactor
Mg(2+)
Ca(2+)
Ca(2+)
Biophysicochemical Properties
5.2 uM for MLC (isoform Smooth-muscle at 22 degrees Celsius)
6.5 uM for MLC (isoform 1 at 22 degrees Celsius)
7.2 uM for MLC (isoform 2 at 22 degrees Celsius)
6.5 uM for MLC (isoform 1 at 22 degrees Celsius)
7.2 uM for MLC (isoform 2 at 22 degrees Celsius)
Subunit
May interact (via protein kinase and CRD domains) with mak-1 (via protein kinase domain).
Interacts with MYOM1, MYOM2, tropomyosin and myosin. Interacts with actin, primarily via the PEVK domains and with MYPN. Interacts with FHL2, NEB, CRYAB, LMNA/lamin-A and LMNB/lamin-B. Interacts with TCAP/telethonin and/or ANK1 isoform Mu17/ank1.5, via the first two N-terminal immunoglobulin domains. Interacts with TRIM63, TRIM55, ANKRD1, ANKRD2, ANKRD23, and CAPN3 through several Ig domains. Interacts with NBR1 through the protein kinase domain (By similarity). Interacts with CMYA5 (By similarity).
Interacts with MYOM1, MYOM2, tropomyosin and myosin. Interacts with actin, primarily via the PEVK domains and with MYPN (By similarity). Interacts with FHL2, NEB, CRYAB, LMNA/lamin-A and LMNB/lamin-B. Interacts with TCAP/telethonin and/or ANK1 isoform Mu17/ank1.5, via the first two N-terminal immunoglobulin domains. Interacts with TRIM63 and TRIM55, through several domains including immunoglobulin domains 141 and 142. Interacts with ANKRD1, ANKRD2 and ANKRD23, via the region between immunoglobulin domains 77 and 78 and interacts with CAPN3, via immunoglobulin domain 79. Interacts with NBR1 through the protein kinase domain. Interacts with CALM/calmodulin. Isoform 6 interacts with OBSCN isoform 3. Interacts with CMYA5.
Interacts (via C-terminus) with myosin. Interacts with actin.
All isoforms including Telokin bind calmodulin. Interacts with SVIL (By similarity). Interacts with CTTN; this interaction is reduced during thrombin-induced endothelial cell (EC) contraction but is promoted by the barrier-protective agonist sphingosine 1-phosphate (S1P) within lamellipodia. A complex made of ABL1, CTTN and MYLK regulates cortical actin-based cytoskeletal rearrangement critical to sphingosine 1-phosphate (S1P)-mediated endothelial cell (EC) barrier enhancement. Binds to NAA10/ARD1 and PTK2B/PYK2 (By similarity).
All isoforms including Telokin bind calmodulin. Interacts with SVIL (By similarity). Interacts with CTTN; this interaction is reduced during thrombin-induced endothelial cell (EC) contraction but is promoted by the barrier-protective agonist sphingosine 1-phosphate (S1P) within lamellipodia. A complex made of ABL1, CTTN and MYLK regulates cortical actin-based cytoskeletal rearrangement critical to sphingosine 1-phosphate (S1P)-mediated endothelial cell (EC) barrier enhancement. Binds to NAA10/ARD1 and PTK2B/PYK2.
All isoforms including Telokin bind calmodulin. Interacts with CTTN; this interaction is reduced during thrombin-induced endothelial cell (EC) contraction but is promoted by the barrier-protective agonist sphingosine 1-phosphate (S1P) within lamellipodia. A complex made of ABL1, CTTN and MYLK regulates cortical actin-based cytoskeletal rearrangement critical to sphingosine 1-phosphate (S1P)-mediated endothelial cell (EC) barrier enhancement. Binds to NAA10/ARD1 (By similarity). Interacts with SVIL and PTK2B/PYK2.
All isoforms including Telokin bind calmodulin.
Interacts with USP25 (isoform USP25m only); the interaction prevents proteasomal degradation of MYBPC1.
Interacts with MTM1 (By similarity). Isoform 3 is found as a monomer or homodimer.
Interacts with MTM1 (By similarity).
Interacts with MTM1. Isoform 3 is found as a monomer or homodimer.
Interacts with myosin (PubMed:22467859). May interact (via protein kinase domain 1) with ball (PubMed:26251439). May interact (via protein kinase domain 1 or 2) with mask (PubMed:26251439). May interact (via protein kinase domain 2) with Tm1/tropomyosin-1 (PubMed:26251439).
Homodimer.
Interacts (via protein kinase domain 1) with CDH2 and (via protein kinase domain 1) with ATP1B1 (PubMed:23392350). Isoform 2 is found in a complex with DSG2, DESM, GJA1, CDH2 and VCL (PubMed:28826662). Isoform 3 is found in a complex with DSG2, DESM, GJA1, CDH2, ANK3 and VCL (PubMed:28826662).
Interacts with MYOM1, MYOM2, tropomyosin and myosin. Interacts with actin, primarily via the PEVK domains and with MYPN. Interacts with FHL2, NEB, CRYAB, LMNA/lamin-A and LMNB/lamin-B. Interacts with TCAP/telethonin and/or ANK1 isoform Mu17/ank1.5, via the first two N-terminal immunoglobulin domains. Interacts with TRIM63, TRIM55, ANKRD1, ANKRD2, ANKRD23, and CAPN3 through several Ig domains. Interacts with NBR1 through the protein kinase domain (By similarity). Interacts with CMYA5 (By similarity).
Interacts with MYOM1, MYOM2, tropomyosin and myosin. Interacts with actin, primarily via the PEVK domains and with MYPN (By similarity). Interacts with FHL2, NEB, CRYAB, LMNA/lamin-A and LMNB/lamin-B. Interacts with TCAP/telethonin and/or ANK1 isoform Mu17/ank1.5, via the first two N-terminal immunoglobulin domains. Interacts with TRIM63 and TRIM55, through several domains including immunoglobulin domains 141 and 142. Interacts with ANKRD1, ANKRD2 and ANKRD23, via the region between immunoglobulin domains 77 and 78 and interacts with CAPN3, via immunoglobulin domain 79. Interacts with NBR1 through the protein kinase domain. Interacts with CALM/calmodulin. Isoform 6 interacts with OBSCN isoform 3. Interacts with CMYA5.
Interacts (via C-terminus) with myosin. Interacts with actin.
All isoforms including Telokin bind calmodulin. Interacts with SVIL (By similarity). Interacts with CTTN; this interaction is reduced during thrombin-induced endothelial cell (EC) contraction but is promoted by the barrier-protective agonist sphingosine 1-phosphate (S1P) within lamellipodia. A complex made of ABL1, CTTN and MYLK regulates cortical actin-based cytoskeletal rearrangement critical to sphingosine 1-phosphate (S1P)-mediated endothelial cell (EC) barrier enhancement. Binds to NAA10/ARD1 and PTK2B/PYK2 (By similarity).
All isoforms including Telokin bind calmodulin. Interacts with SVIL (By similarity). Interacts with CTTN; this interaction is reduced during thrombin-induced endothelial cell (EC) contraction but is promoted by the barrier-protective agonist sphingosine 1-phosphate (S1P) within lamellipodia. A complex made of ABL1, CTTN and MYLK regulates cortical actin-based cytoskeletal rearrangement critical to sphingosine 1-phosphate (S1P)-mediated endothelial cell (EC) barrier enhancement. Binds to NAA10/ARD1 and PTK2B/PYK2.
All isoforms including Telokin bind calmodulin. Interacts with CTTN; this interaction is reduced during thrombin-induced endothelial cell (EC) contraction but is promoted by the barrier-protective agonist sphingosine 1-phosphate (S1P) within lamellipodia. A complex made of ABL1, CTTN and MYLK regulates cortical actin-based cytoskeletal rearrangement critical to sphingosine 1-phosphate (S1P)-mediated endothelial cell (EC) barrier enhancement. Binds to NAA10/ARD1 (By similarity). Interacts with SVIL and PTK2B/PYK2.
All isoforms including Telokin bind calmodulin.
Interacts with USP25 (isoform USP25m only); the interaction prevents proteasomal degradation of MYBPC1.
Interacts with MTM1 (By similarity). Isoform 3 is found as a monomer or homodimer.
Interacts with MTM1 (By similarity).
Interacts with MTM1. Isoform 3 is found as a monomer or homodimer.
Interacts with myosin (PubMed:22467859). May interact (via protein kinase domain 1) with ball (PubMed:26251439). May interact (via protein kinase domain 1 or 2) with mask (PubMed:26251439). May interact (via protein kinase domain 2) with Tm1/tropomyosin-1 (PubMed:26251439).
Homodimer.
Interacts (via protein kinase domain 1) with CDH2 and (via protein kinase domain 1) with ATP1B1 (PubMed:23392350). Isoform 2 is found in a complex with DSG2, DESM, GJA1, CDH2 and VCL (PubMed:28826662). Isoform 3 is found in a complex with DSG2, DESM, GJA1, CDH2, ANK3 and VCL (PubMed:28826662).
Miscellaneous
Determination of the mutation frequency of the unc-22 gene has been used to study the biological effects of short duration spaceflight.
In some isoforms, after the PEVK repeat region there is a long PEVK duplicated region. On account of this region, it has been very difficult to sequence the whole protein. The length of this region (ranging from 183 to 2174 residues), may be a key elastic element of titin.
In asthmatic patients, overexpression promotes actin filament propulsion, thus contributing to airway hyperresponsiveness. Some MYLK variants may contribute to acute lung injury (ALI) susceptibility. Potential therapeutic target in the treatment of burn edema.
Expression is under the tight control of the locus control region (LCRs).
In some isoforms, after the PEVK repeat region there is a long PEVK duplicated region. On account of this region, it has been very difficult to sequence the whole protein. The length of this region (ranging from 183 to 2174 residues), may be a key elastic element of titin.
In asthmatic patients, overexpression promotes actin filament propulsion, thus contributing to airway hyperresponsiveness. Some MYLK variants may contribute to acute lung injury (ALI) susceptibility. Potential therapeutic target in the treatment of burn edema.
Expression is under the tight control of the locus control region (LCRs).
Similarity
Belongs to the protein kinase superfamily. CAMK Ser/Thr protein kinase family.
Belongs to the immunoglobulin superfamily. MyBP family.
Belongs to the immunoglobulin superfamily. MyBP family.
Keywords
3D-structure
Alternative splicing
ATP-binding
Calcium
Calmodulin-binding
Complete proteome
Cytoplasm
Disulfide bond
Immunoglobulin domain
Kelch repeat
Kinase
Magnesium
Metal-binding
Nucleotide-binding
Phosphoprotein
Reference proteome
Repeat
Transferase
Coiled coil
Direct protein sequencing
Methylation
Nucleus
TPR repeat
WD repeat
Cardiomyopathy
Disease mutation
Limb-girdle muscular dystrophy
Polymorphism
Alternative promoter usage
Membrane
Actin-binding
Cell projection
Cytoskeleton
Acetylation
Aortic aneurysm
Cell cycle
Cell division
Chromosome
Developmental protein
Mitosis
Muscle protein
SH3 domain
Cell adhesion
Thick filament
Ubl conjugation
Zinc
Differentiation
Cell membrane
Glycoprotein
Lipid-binding
Secreted
Feature
chain Twitchin
splice variant In isoform e.
sequence variant In CMD1G; affects interaction with TCAP/telethonin; dbSNP:rs139517732.
splice variant In isoform e.
sequence variant In CMD1G; affects interaction with TCAP/telethonin; dbSNP:rs139517732.
Uniprot
EC Number
2.7.11.1
2.7.11.18
2.7.11.18
Pubmed
2812002
8397135
9851916
7190524
2833427
16765996
+ More
18390597 25851606 8202162 8969309 19468303 9440711 16702235 17261657 17242355 21183079 24129315 7569978 10850961 11717165 15815621 15489334 8937992 7819249 10051295 12785098 8351016 1582406 8404852 17974005 9645487 12482578 12432079 12444090 14583192 14676215 15967462 16410549 16537787 20634290 7613868 9804419 9782056 11525170 16407954 10462489 12145747 11846417 11788824 12891679 16465475 15802564 17444505 17344846 23033978 25173926 12381307 20346955 1284247 1534225 9405419 1748666 1577772 1748667 11113114 8575746 9160829 10198165 10536370 15507455 15020676 14702039 16641997 12408982 11976941 14741352 15825080 16835238 16723733 16284075 18710790 18088087 18587400 18318008 19413330 19429448 19826488 20453870 20375339 20053363 20861316 20181817 20139351 21918590 19011151 22015949 22814378 24275569 18462678 21055718 11029314 11121372 11832329 16141072 11472067 8764148 12360480 16055522 16184195 17925381 17577141 18586037 21074048 20018858 20404178 7589469 2315320 9706877 2202734 3030394 1444462 1373815 9283094 12176732 10194305 10529260 8569750 10629221 10934048 10731132 12537572 9548712 10669599 9917396 8335002 11062264 12537569 22467859 26251439 8227129 2315308 10532952 19541641 1429890 8375400 16541075 16501887 22610851 20045868 26661508 8663449 10973969 12693553 16452087 19118250 15057822 22673903 1400348 16545539 15185077 10718198 23186163 16354304 25087613 18515368 18177667 16710414 15289607 23392350 28826662
18390597 25851606 8202162 8969309 19468303 9440711 16702235 17261657 17242355 21183079 24129315 7569978 10850961 11717165 15815621 15489334 8937992 7819249 10051295 12785098 8351016 1582406 8404852 17974005 9645487 12482578 12432079 12444090 14583192 14676215 15967462 16410549 16537787 20634290 7613868 9804419 9782056 11525170 16407954 10462489 12145747 11846417 11788824 12891679 16465475 15802564 17444505 17344846 23033978 25173926 12381307 20346955 1284247 1534225 9405419 1748666 1577772 1748667 11113114 8575746 9160829 10198165 10536370 15507455 15020676 14702039 16641997 12408982 11976941 14741352 15825080 16835238 16723733 16284075 18710790 18088087 18587400 18318008 19413330 19429448 19826488 20453870 20375339 20053363 20861316 20181817 20139351 21918590 19011151 22015949 22814378 24275569 18462678 21055718 11029314 11121372 11832329 16141072 11472067 8764148 12360480 16055522 16184195 17925381 17577141 18586037 21074048 20018858 20404178 7589469 2315320 9706877 2202734 3030394 1444462 1373815 9283094 12176732 10194305 10529260 8569750 10629221 10934048 10731132 12537572 9548712 10669599 9917396 8335002 11062264 12537569 22467859 26251439 8227129 2315308 10532952 19541641 1429890 8375400 16541075 16501887 22610851 20045868 26661508 8663449 10973969 12693553 16452087 19118250 15057822 22673903 1400348 16545539 15185077 10718198 23186163 16354304 25087613 18515368 18177667 16710414 15289607 23392350 28826662
EMBL
X15423
Z73897
Z73899
CAA33463.1
CAA98065.2
AL928681
+ More
AL928721 AL928789 CAM23449.1 CAM27059.1 X90568 X90569 AJ277892 AC009948 AC010680 FJ695199 AC023270 BC013396 BC058824 BC070170 BC107797 X98114 X98115 X83270 AF058332 AF525413 DQ248309 X64698 X64699 X64697 X69490 AL713647 AY130758 BX284605 AAN61517.1 AAN61520.1 AAN61521.1 S57131 M76233 M76234 M76181 X85337 U48959 AF069601 AF069602 AF069603 AF069604 AF096771 AF096766 AF096767 AF096768 AF096769 AF096770 AF096773 AF096774 AF096775 AY424269 AY424270 AY339601 AB037663 AK300610 AK314412 AK314443 AC020634 AC023165 CH471052 BC100761 BC100762 BC100763 BC064420 X90870 AY237727 AF314149 AY237726 AK162008 BC034209 BC045197 BC058610 AF335470 AAG34169.1 AAH34209.1 AAH45197.1 AAH58610.2 AAK53241.1 AAO85807.1 BAE36678.1 X52876 M31048 M14953 AF045285 AF045255 AF045256 AF045257 AF045260 AF045259 AF045258 AF045261 AF045263 AF045265 AF045274 AF045273 AF045272 AF045271 AF045270 AF045269 AF045268 AF045267 AF045266 AF045283 AF045282 AF045281 AF045280 AF045279 AF045278 AF045277 AF045276 AF045275 AF045284 AF045264 AF045262 M96655 M88283 M88284 S80867 AB026845 AJ238575 AJ238577 AJ271740 AJ400900 AJ400901 AJ400902 AE014296 AF045775 AF045776 AF045777 AF045778 AJ245406 AJ012279 AJ012280 AF135062 AF135167 AF241648 AF241649 BK000146 AY094749 AAC23966.1 AAF47604.1 AAG40155.1 AAM11102.1 BAA90301.2 CAA09971.1 CAB76253.1 CAB93524.1 CAB96426.1 DAA00021.1 U00922 U00923 M31209 AF059576 AF097333 X66276 X73114 AK295727 AK296681 AK303401 AL831993 AL832000 AL834249 AC010205 AC090671 AC117505 CH471054 BC092418 BC117217 BC143495 BC143502 BC143503 BC143504 U57098 AF215896 AK035543 AK164360 BC048698 BC062643 AK122488 AABR03067996 U57097 D11474 U57099 AK126500 AK289531 CR542201 AC053503 CH471063 BC006346 DQ395348 AY603755 AB037718 AE013599 DQ431841 ABD83643.1 AY578914 AL662911 AK093280 AK128233 AL591178 CH471134 BC014671 BC067101 BX537911 BX647453 BX647455 GL456158 BC044882 BC060226 AY603754 AAT80900.1
AL928721 AL928789 CAM23449.1 CAM27059.1 X90568 X90569 AJ277892 AC009948 AC010680 FJ695199 AC023270 BC013396 BC058824 BC070170 BC107797 X98114 X98115 X83270 AF058332 AF525413 DQ248309 X64698 X64699 X64697 X69490 AL713647 AY130758 BX284605 AAN61517.1 AAN61520.1 AAN61521.1 S57131 M76233 M76234 M76181 X85337 U48959 AF069601 AF069602 AF069603 AF069604 AF096771 AF096766 AF096767 AF096768 AF096769 AF096770 AF096773 AF096774 AF096775 AY424269 AY424270 AY339601 AB037663 AK300610 AK314412 AK314443 AC020634 AC023165 CH471052 BC100761 BC100762 BC100763 BC064420 X90870 AY237727 AF314149 AY237726 AK162008 BC034209 BC045197 BC058610 AF335470 AAG34169.1 AAH34209.1 AAH45197.1 AAH58610.2 AAK53241.1 AAO85807.1 BAE36678.1 X52876 M31048 M14953 AF045285 AF045255 AF045256 AF045257 AF045260 AF045259 AF045258 AF045261 AF045263 AF045265 AF045274 AF045273 AF045272 AF045271 AF045270 AF045269 AF045268 AF045267 AF045266 AF045283 AF045282 AF045281 AF045280 AF045279 AF045278 AF045277 AF045276 AF045275 AF045284 AF045264 AF045262 M96655 M88283 M88284 S80867 AB026845 AJ238575 AJ238577 AJ271740 AJ400900 AJ400901 AJ400902 AE014296 AF045775 AF045776 AF045777 AF045778 AJ245406 AJ012279 AJ012280 AF135062 AF135167 AF241648 AF241649 BK000146 AY094749 AAC23966.1 AAF47604.1 AAG40155.1 AAM11102.1 BAA90301.2 CAA09971.1 CAB76253.1 CAB93524.1 CAB96426.1 DAA00021.1 U00922 U00923 M31209 AF059576 AF097333 X66276 X73114 AK295727 AK296681 AK303401 AL831993 AL832000 AL834249 AC010205 AC090671 AC117505 CH471054 BC092418 BC117217 BC143495 BC143502 BC143503 BC143504 U57098 AF215896 AK035543 AK164360 BC048698 BC062643 AK122488 AABR03067996 U57097 D11474 U57099 AK126500 AK289531 CR542201 AC053503 CH471063 BC006346 DQ395348 AY603755 AB037718 AE013599 DQ431841 ABD83643.1 AY578914 AL662911 AK093280 AK128233 AL591178 CH471134 BC014671 BC067101 BX537911 BX647453 BX647455 GL456158 BC044882 BC060226 AY603754 AAT80900.1
Proteomes
PRIDE
Pfam
Interpro
IPR003598
Ig_sub2
+ More
IPR036179 Ig-like_dom_sf
IPR000719 Prot_kinase_dom
IPR011009 Kinase-like_dom_sf
IPR013098 Ig_I-set
IPR036116 FN3_sf
IPR008271 Ser/Thr_kinase_AS
IPR003599 Ig_sub
IPR007110 Ig-like_dom
IPR003961 FN3_dom
IPR017441 Protein_kinase_ATP_BS
IPR013783 Ig-like_fold
IPR015129 Titin_Z_rpt
IPR004168 PPAK_motif
IPR008266 Tyr_kinase_AS
IPR040849 MyBP-C_THB
IPR013106 Ig_V-set
IPR015725 MLCK1_kinase_dom
IPR036028 SH3-like_dom_sf
IPR001452 SH3_domain
IPR010939 Titin-rpts
IPR015726 Ser/Thr_kin_striated-sp
IPR000219 DH-domain
IPR035899 DBL_dom_sf
IPR011993 PH-like_dom_sf
IPR013151 Immunoglobulin
IPR000048 IQ_motif_EF-hand-BS
IPR035526 Obscurin_SH3
IPR001849 PH_domain
IPR036179 Ig-like_dom_sf
IPR000719 Prot_kinase_dom
IPR011009 Kinase-like_dom_sf
IPR013098 Ig_I-set
IPR036116 FN3_sf
IPR008271 Ser/Thr_kinase_AS
IPR003599 Ig_sub
IPR007110 Ig-like_dom
IPR003961 FN3_dom
IPR017441 Protein_kinase_ATP_BS
IPR013783 Ig-like_fold
IPR015129 Titin_Z_rpt
IPR004168 PPAK_motif
IPR008266 Tyr_kinase_AS
IPR040849 MyBP-C_THB
IPR013106 Ig_V-set
IPR015725 MLCK1_kinase_dom
IPR036028 SH3-like_dom_sf
IPR001452 SH3_domain
IPR010939 Titin-rpts
IPR015726 Ser/Thr_kin_striated-sp
IPR000219 DH-domain
IPR035899 DBL_dom_sf
IPR011993 PH-like_dom_sf
IPR013151 Immunoglobulin
IPR000048 IQ_motif_EF-hand-BS
IPR035526 Obscurin_SH3
IPR001849 PH_domain
SUPFAM
Gene 3D
ProteinModelPortal
Ontologies
GO
GO:0031672
GO:0045989
GO:0005524
GO:0005865
GO:0040017
GO:0035095
GO:0045214
GO:0004674
GO:0071688
GO:0051782
GO:0051015
GO:0051371
GO:0019901
GO:0008307
GO:0046872
GO:0006936
GO:0031430
GO:0018105
GO:0060298
GO:0008344
GO:0030018
GO:0005516
GO:0030017
GO:0018107
GO:0000794
GO:0048739
GO:0007512
GO:0055003
GO:0048769
GO:0035995
GO:0005509
GO:0055002
GO:0042802
GO:0050790
GO:0043056
GO:0030016
GO:0031674
GO:0007507
GO:0055008
GO:0060048
GO:0042805
GO:0045859
GO:0060419
GO:0010737
GO:0019899
GO:0021591
GO:0030240
GO:0043621
GO:0051592
GO:0002020
GO:0003007
GO:0030506
GO:1901897
GO:0031433
GO:0001701
GO:0030241
GO:0005859
GO:0003300
GO:0001756
GO:0004713
GO:0010628
GO:0005200
GO:0050714
GO:0030049
GO:0070062
GO:0006941
GO:0097493
GO:0005576
GO:0002576
GO:0005829
GO:0007076
GO:0031965
GO:0017022
GO:0005856
GO:0004687
GO:0032154
GO:0005737
GO:0003779
GO:0030027
GO:0090303
GO:0060414
GO:0071476
GO:0032060
GO:0015629
GO:0005886
GO:0030335
GO:0072358
GO:0051928
GO:0004672
GO:0006939
GO:0001725
GO:0006468
GO:0014820
GO:0035865
GO:0005911
GO:0071277
GO:0035690
GO:0016020
GO:0007517
GO:0007520
GO:0007498
GO:0051301
GO:0040011
GO:0007062
GO:0007522
GO:0005863
GO:0035206
GO:0007525
GO:0016203
GO:0007519
GO:0032982
GO:0005623
GO:0007155
GO:0002027
GO:0097512
GO:0055010
GO:0031034
GO:0008016
GO:0032036
GO:0031432
GO:0055013
GO:0005634
GO:0060541
GO:0042692
GO:0008285
GO:0035023
GO:0036309
GO:0007527
GO:0016301
GO:0007275
GO:0005089
GO:0005523
GO:0042803
GO:1902936
GO:0005615
GO:0030154
GO:0010314
GO:0042383
GO:0014067
GO:0046777
GO:0032266
GO:0070273
GO:0016604
GO:0043325
GO:0014704
GO:0005546
GO:0045296
GO:0005547
GO:0005515
GO:0016791
GO:0007166
GO:0000287
GO:0006281
GO:0006259
PANTHER
Topology
Subcellular location
Cytoplasm
Expressed at the outer edge of A-bands. With evidence from 12 publications.
Myofibril Expressed at the outer edge of A-bands. With evidence from 12 publications.
Sarcomere Expressed at the outer edge of A-bands. With evidence from 12 publications.
A band Expressed at the outer edge of A-bands. With evidence from 12 publications.
Nucleus
I band Localizes throughout the I-band except for dense bodies and in the outer edge of the A-band (PubMed:20346955). In embryo, co-localizes with lamin lmn-1 at the nuclear membrane. The localization to the nuclear envelope is lmn-1-dependent(PubMed:16410549). With evidence from 8 publications.
Nucleus membrane Localizes throughout the I-band except for dense bodies and in the outer edge of the A-band (PubMed:20346955). In embryo, co-localizes with lamin lmn-1 at the nuclear membrane. The localization to the nuclear envelope is lmn-1-dependent(PubMed:16410549). With evidence from 8 publications.
Cell projection Localized to stress fibers during interphase and to the cleavage furrow during mitosis. With evidence from 2 publications.
Lamellipodium Localized to stress fibers during interphase and to the cleavage furrow during mitosis. With evidence from 2 publications.
Cleavage furrow Localized to stress fibers during interphase and to the cleavage furrow during mitosis. With evidence from 2 publications.
Cytoskeleton Localized to stress fibers during interphase and to the cleavage furrow during mitosis. With evidence from 2 publications.
Stress fiber Localized to stress fibers during interphase and to the cleavage furrow during mitosis. With evidence from 2 publications.
Cytosol
Membrane
Chromosome
M line Colocalizes with CDH2 and ATP1B1 to the sarcolemma and to intercalating disks in cardiac muscles. Colocalizes with ATP1B1 to M line and Z line in cardiac muscles. One or both small isoforms, one probably containing protein kinase domain 2 and partial protein kinase domain 1 and one containing only protein kinase domain 2, localize to the extracellular side of the sarcolemma. With evidence from 14 publications.
Z line Colocalizes with CDH2 and ATP1B1 to the sarcolemma and to intercalating disks in cardiac muscles. Colocalizes with ATP1B1 to M line and Z line in cardiac muscles. One or both small isoforms, one probably containing protein kinase domain 2 and partial protein kinase domain 1 and one containing only protein kinase domain 2, localize to the extracellular side of the sarcolemma. With evidence from 14 publications.
Cell membrane Colocalizes with CDH2 and ATP1B1 to the sarcolemma and to intercalating disks in cardiac muscles. Colocalizes with ATP1B1 to M line and Z line in cardiac muscles. One or both small isoforms, one probably containing protein kinase domain 2 and partial protein kinase domain 1 and one containing only protein kinase domain 2, localize to the extracellular side of the sarcolemma. With evidence from 14 publications.
Sarcolemma Colocalizes with CDH2 and ATP1B1 to the sarcolemma and to intercalating disks in cardiac muscles. Colocalizes with ATP1B1 to M line and Z line in cardiac muscles. One or both small isoforms, one probably containing protein kinase domain 2 and partial protein kinase domain 1 and one containing only protein kinase domain 2, localize to the extracellular side of the sarcolemma. With evidence from 14 publications.
Secreted Colocalizes with CDH2 and ATP1B1 to the sarcolemma and to intercalating disks in cardiac muscles. Colocalizes with ATP1B1 to M line and Z line in cardiac muscles. One or both small isoforms, one probably containing protein kinase domain 2 and partial protein kinase domain 1 and one containing only protein kinase domain 2, localize to the extracellular side of the sarcolemma. With evidence from 14 publications.
Myofibril Expressed at the outer edge of A-bands. With evidence from 12 publications.
Sarcomere Expressed at the outer edge of A-bands. With evidence from 12 publications.
A band Expressed at the outer edge of A-bands. With evidence from 12 publications.
Nucleus
I band Localizes throughout the I-band except for dense bodies and in the outer edge of the A-band (PubMed:20346955). In embryo, co-localizes with lamin lmn-1 at the nuclear membrane. The localization to the nuclear envelope is lmn-1-dependent(PubMed:16410549). With evidence from 8 publications.
Nucleus membrane Localizes throughout the I-band except for dense bodies and in the outer edge of the A-band (PubMed:20346955). In embryo, co-localizes with lamin lmn-1 at the nuclear membrane. The localization to the nuclear envelope is lmn-1-dependent(PubMed:16410549). With evidence from 8 publications.
Cell projection Localized to stress fibers during interphase and to the cleavage furrow during mitosis. With evidence from 2 publications.
Lamellipodium Localized to stress fibers during interphase and to the cleavage furrow during mitosis. With evidence from 2 publications.
Cleavage furrow Localized to stress fibers during interphase and to the cleavage furrow during mitosis. With evidence from 2 publications.
Cytoskeleton Localized to stress fibers during interphase and to the cleavage furrow during mitosis. With evidence from 2 publications.
Stress fiber Localized to stress fibers during interphase and to the cleavage furrow during mitosis. With evidence from 2 publications.
Cytosol
Membrane
Chromosome
M line Colocalizes with CDH2 and ATP1B1 to the sarcolemma and to intercalating disks in cardiac muscles. Colocalizes with ATP1B1 to M line and Z line in cardiac muscles. One or both small isoforms, one probably containing protein kinase domain 2 and partial protein kinase domain 1 and one containing only protein kinase domain 2, localize to the extracellular side of the sarcolemma. With evidence from 14 publications.
Z line Colocalizes with CDH2 and ATP1B1 to the sarcolemma and to intercalating disks in cardiac muscles. Colocalizes with ATP1B1 to M line and Z line in cardiac muscles. One or both small isoforms, one probably containing protein kinase domain 2 and partial protein kinase domain 1 and one containing only protein kinase domain 2, localize to the extracellular side of the sarcolemma. With evidence from 14 publications.
Cell membrane Colocalizes with CDH2 and ATP1B1 to the sarcolemma and to intercalating disks in cardiac muscles. Colocalizes with ATP1B1 to M line and Z line in cardiac muscles. One or both small isoforms, one probably containing protein kinase domain 2 and partial protein kinase domain 1 and one containing only protein kinase domain 2, localize to the extracellular side of the sarcolemma. With evidence from 14 publications.
Sarcolemma Colocalizes with CDH2 and ATP1B1 to the sarcolemma and to intercalating disks in cardiac muscles. Colocalizes with ATP1B1 to M line and Z line in cardiac muscles. One or both small isoforms, one probably containing protein kinase domain 2 and partial protein kinase domain 1 and one containing only protein kinase domain 2, localize to the extracellular side of the sarcolemma. With evidence from 14 publications.
Secreted Colocalizes with CDH2 and ATP1B1 to the sarcolemma and to intercalating disks in cardiac muscles. Colocalizes with ATP1B1 to M line and Z line in cardiac muscles. One or both small isoforms, one probably containing protein kinase domain 2 and partial protein kinase domain 1 and one containing only protein kinase domain 2, localize to the extracellular side of the sarcolemma. With evidence from 14 publications.
Length:
9508
Number of predicted TMHs:
0
Exp number of AAs in TMHs:
0.00279
Exp number, first 60 AAs:
0
Total prob of N-in:
0.00000
outside
1 - 9508
Population Genetic Test Statistics
Pi
274.591806
Theta
177.766094
Tajima's D
1.363882
CLR
0.148899
CSRT
0.755212239388031
Interpretation
Uncertain
