| Retrocopy Name | MSL3P1 |
 |
| Species | Homo sapiens | |
| Coordinates (hg38) | chr2:233865442-233868323 UCSC | |
| Coordinates (T2T) | chr2:234354245-234357127 UCSC | |
| Coordinates (hg19) | chr2:234774088-234776969 UCSC | |
| Strand | - | |
| Parental Sequence | NM_001193270.2 | |
| Parental seq. overlap | 1834 bp | |
| Parental seq. overlap (%) | 70.5% | |
| Genomic Region |
Intergenic |
|
| Retrocopy Summary | MSL3P1, located on chr2:233865442-233868323, is a retrocopy of the parental gene MSL3. Retrocopies of protein-coding genes, also known as processed pseudogenes, are intriguing genomic elements with implications in genome evolution and diseases. While some retrocopies are non-functional, there are examples of retrocopies (retrogenes) acquiring regulatory roles or exhibiting neofunctionalization unrelated to their parental genes. |
| Gene Name | MSL3 |
| Full Name | MSL complex subunit 3 |
| Also known as | MRSXBA|MRXS36|MRXSBA|MSL3L1 |
| Coordinate | chrX:11758159-11775772 |
| Strand | + |
| Gene summary | This gene encodes a nuclear protein that is similar to the product of the Drosophila male-specific lethal-3 gene. The Drosophila protein plays a critical role in a dosage-compensation pathway, which equalizes X-linked gene expression in males and females. Thus, the human protein is thought to play a similar function in chromatin remodeling and transcriptional regulation, and it has been found as part of a complex that is responsible for histone H4 lysine-16 acetylation. This gene can undergo X inactivation. Alternative splicing results in multiple transcript variants. Related pseudogenes have been identified on chromosomes 2, 7 and 8. [provided by RefSeq, Jul 2010] |
| Species | Scientific Name | Retrocopy | |
 |
Chimpanzee | Pan troglodytes | MSL3P1 |
 |
Bonobo | Pan paniscus | MSL3P1 |
 |
Gorilla | Gorilla gorilla | MSL3P1 |
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Orangutan | Pongo abelii | MSL3P1 |
 |
Gibbon | Nomascus leucogenys | MSL3P3 |
 |
Green monkey | Chlorocebus sabaeus | MSL3P2 |
 |
Crab-eating macaque | Macaca fascicularis | MSL3P3 |
 |
Rhesus | Macaca mulatta | MSL3P3 |
 |
Baboon | Papio anubis | MSL3P2 |
 |
Golden snub-nosed monkey | Rhinopithecus roxellana | MSL3P4 |
 |
Marmoset | Callithrix jacchus | MSL3P1 |
 |
Mouse lemur | Microcebus murinus | Without Homology |
 |
Mouse | Mus musculus | Without Homology |
 |
Rat | Rattus norvegicus | Without Homology |
 |
Chinese hamster | Cricetulus griseus | Without Homology |
 |
Rabbit | Oryctolagus cuniculus | Without Homology |
 |
Pig | Sus scrofa | Without Homology |
 |
Cow | Bos taurus | Without Homology |
 |
Sheep | Ovis aries | Without Homology |
 |
Dolphin | Tursiops truncatus | Without Homology |
 |
Horse | Equus caballus | Without Homology |
 |
Dog | Canis familiaris | Without Homology |
 |
Panda | Ailuropoda melanoleuca | Without Homology |
 |
Cat | Felis catus | Without Homology |
 |
Pale spear-nosed bat | Phyllostomus discolor | Without Homology |
 |
Velvety free-tailed bat | Molossus molossus | Without Homology |
 |
Greater mouse-eared bat | Myotis myotis | Without Homology |
 |
Kuhl's pipistrelle | Pipistrellus kuhlii | Without Homology |
 |
Greater horseshoe bat | Rhinolophus ferrumequinum | Without Homology |
 |
Egyptian rousette | Rousettus aegyptiacus | Without Homology |
 |
Sloth | Choloepus didactylus | Without Homology |
 |
Tasmanian Devil | Sarcophilus harrisii | Without Homology |
 |
Opossum | Monodelphis domestica | Without Homology |
 |
Platypus | Ornithorhynchus anatinus | Without Homology |
 |
Chicken | Gallus gallus | Without Homology |
 |
Turkey | Meleagris gallopavo | Without Homology |
 |
Zebra Finch | Taeniopygia guttata | Without Homology |
 |
Budgerigar | Melopsittacus undulatus | Without Homology |
 |
Painted Turtle | Chrysemys picta | Without Homology |
 |
Lizard | Anolis Carolinensis | Without Homology |
 |
Frog | Xenopus tropicalis | Without Homology |
 |
Zebrafish | Danio rerio | Without Homology |
 |
Drosophila | Drosophila melanogaster | Without Homology |
| >MSL3P1 |
| TTCGTAGATTACAGCATAAATTGGCAAGAAATGCTGTAGCTCACCTGAGGAGCAAGAGAGAAAGAAGCAGCCGCTCCAGGTTGCTTGGTGCTGACTCTGTCTTTTTTTAAAAGGCCTCTCCATCGAAGAAAAAAATGAAAATGATGAAAACTCATTAAGCAGTTCCTCTGACAGTAGTGAAGACAAGGATGAAAAAATAAGTGAAGAATGTGATATTGAAGAAAAGACTGAAGTGAAAGAAGAACCGGAGCTTCAAACAAAAAGGGAAATGGAAGAAAGAACAGTAACTCTAGAAATCCCTGAAGTTCTGAAGAGGCAGCTGGAGGATGATTGTTACTACATTAATCGGAGGAAACGGTTAGTGCAACTTCCATGCCACACCAACATCATAACGATTTTGGAATCCTATGTGAAGCATTTTGCTATCAGTGCAGCCTTTTCAGCCAATGAGAGGCCTCGTCACCATCACGCTATGCCACATGCCAGCATGAACGTGCCTTATATCCCAGCAGAAAAGAATATTGACCTTTGTAAGGAGATGGTGGATGGATTAAGAATAACCTTTGATTACACTCTCCCGTTGGTTTTACTCTATCCCTATGAACAAGCTCAGTATAAAAAGGTGACTGCATCTAAGGTTTTTCTTGCAATTAAGGAAAGTGCCACAAATACTAATAGGAGCCAGGAGAAGCTCTCTCCCAGCTTACGTTTGTTGAATCCATCCAGGCCGCAGTCTACAGAGAGTCAGTCGACCAGCGGTGAACCAGCCACCCCTAAAAGGCGCAAAGCCGAGCCGCAAGCAGTGCAGTCTCTGAGGCGGTCCTCGCCCCACACCGCCAACTGTGACAGGCTTTCTAAGAGCAGCACCTCACCTCAGCCCAAGCGCTGGCAGCAGGACATGTCCACCAGTGTGCCCAAGCTGTTCCTGCACCTGGAAAAGAAGACACCTGTGCATAGCAGATCATCTTCACCTACTCTGACTCCTAGCCAGGAAGGGAGTCCTGTGTTTGCTGGCTTTGAAGGGAGAAGAACTAATGAAATAAATGAGGTCCTCTCCTGGAAGCTCGTACCTGACAATTACCCACCAGGTGACCAGCCACCTCCACCCTCTTACATTTACGGGGCGCAACATTTGCTGCGATTGTTTGTCAAACTTCCAGAAATTCTTGGAAAAATGTCCTTTACTGAGAAGAATCTGAAGGCTTTATTGAAGCACTTTGATCTCTTTGTGAGGTTTTTAGCAGAATACCACGATGACTTCTTCCCAGAGTCAGCTTACGTCGCTGCCTCTGAGGTGCATTACAGCACCAGGAACCCCCAGGCAGTCAATAAGTGTTGATGGTTCTGTAAGAACAACTGCTCCATCTAGCATGGTGTTCTGAGTTCCAGGTAAAAAATTAACAAGGTGGTGGGTTTTTATCCAGAGCACAAAACAAAGTGCCCACCAGGGGGCTTTGACAGAGGTGTGCCCTGTTGTTTGAGTTCCCCATGTACTGTAGTTACTCTGTTTAGAATTATTTCCTAGGTGCCTGAAAGTGTTCTGACATGACACTTGCTACTTTGTAGGCCATCTGTGATGGCAGGTAAAAAGCAACTGTTCACAGTGAAATGTTCATGGAAGTGTACATAGGTTAGGCCATTTCAGCAGACATTGCAGTTAGTCAGCAAGAACCACATTGTTTCGTTATTTGTTAGCATTAAACAAAATTTTTTTTGCAAATTGGTTTCATTCTCTTGATGAAGCTGAGCAACTGTCCAACAAGGTTTAGTTTGTACTTGAAAACTGCAAAGTAGTCTCAAAGTATTTTAGAGGGAATCCATATTGATGGCAAAAGAAAATTTGCAGCTATAATTTGCTTCTGACGGTTCCTTCTCTGTGAAACATTATTTTTGGTGATCTAAAGAAAGCATTGCCTTTCTTGTTTGCAATTTTACAGCTATACTTTTTTGTGTAATGTTACGGTTCCCTTTCTGTAAAATGTTCTTTTTGGTGATCTAAATAAAGCCTCTCTTGTTTGAAAAGGTTTCTCTCTTCGCGTTAAATCTCCCCTGCCGTGCAGCCTGGTGCCGCGTAGGCTCCCGTGGGACGCTCCCGTCGGACGCCGTCCGACCTAGATTGTTAATGTTATTGTTGGGAAAGGCGAAAAAGGCAGAAAGATCCCAGAATAGCTGATCCGTTGTAACGGTTGGAACTGAAGCTGGGATAGATGGGTAGCCGAAGATCATGTGCTTCGTGAGCCCAGTGAAAATCGTAGATTg |
| >NM_001193270.2 |
| GCACGCGCGGTTGGGAGCCTCGCCCATGCTTTGTCGCGTTACCGGGGCTACCGTTTGCGCCCCCGACTGCAACGGTGGCCGCTGAGGGAGGAGGCTTCTCGAATACGGTTTCTGTCTTCGCGTTAAATGTCTCCTTCTGTGCGGCCTGGTGCCGGGTGGGCTCCTGTGGGACGCCCTGGCCGTCCGATCCAGATTGTTGATGTTATTGTTGGGAAAGACGAAAAAGGCAGAAAGATCCCAGAATATCTGATCCATTTTAATGGTTGGAACAGAAGCTGGGATAGATGGGCAGCAGAAGATCATGTGCTTCGTGATACCGATGAAAATCGTAGATTACAGCGTAAATTGGCAAGAAAAGCTGTAGCTCGCCTGAGGAGCACAGGAAGAAAGAAGAAGCGCTGCAGGTTGCCTGGTGTGGACTCTGTCTTAAAAGGCCTCCCCACTGAAGAAAAAGATGAAAATGATGAAAACTCATTAAGCAGTTCCTCTGACTGTAGTGAAAACAAGGATGAAGAAATAAGTGAAGAAAGTGATATTGAAGAAAAGACTGAAGTGAAAGAAGAACCAGAGCTTCAAACAAGAAGGGAAATGGAAGAAAGAACAATAACTATAGAAATCCCTGAAGTTCTGAAGAAGCAGCTGGAGGATGATTGTTACTACATTAACAGGAGGAAACGGTTAGTGAAACTTCCATGCCAGACCAACATCATAACGATTTTGGAATCCTATGTGAAGCATTTTGCTATCAATGCAGCCTTTTCAGCCAATGAGAGGCCTCGTCACCATCACGTTATGCCACATGCCAACATGAACGTGCATTATATCCCAGCAGAAAAGAATGTTGACCTTTGTAAGGAGATGGTGGATGGATTAAGAATAACCTTTGATTACACTCTCCCGTTGGTTTTACTCTATCCATATGAACAAGCTCAGTATAAAAAGGTGACTTCGTCTAAATTTTTTCTTCCAATTAAGGAAAGTGCCACAAGCACTAACAGGAGCCAGGAGGAACTCTCTCCCAGTCCGCCTTTGTTGAATCCATCCACGCCACAGTCCACAGAGAGTCAGCCGACCACCGGTGAACCAGCCACCCCCAAAAGGCGCAAAGCTGAGCCAGAAGCATTGCAGTCTCTGAGGCGGTCCACGCGCCACAGTGCCAACTGTGACAGGCTTTCTGAGAGCAGCGCTTCACCTCAGCCCAAGCGCCGGCAGCAGGACACATCCGCCAGCATGCCCAAGCTCTTCCTGCACCTGGAAAAGAAGACACCTGTGCATAGCAGATCATCTTCACCTATTCCTCTGACTCCTAGCAAGGAAGGGAGTGCTGTGTTTGCTGGCTTTGAAGGGAGAAGAACTAATGAAATAAACGAGGTCCTCTCCTGGAAGCTTGTGCCTGACAATTACCCCCCAGGTGACCAGCCGCCTCCACCCTCTTACATTTATGGGGCACAACATTTGCTGCGATTGTTTGTGAAACTTCCAGAAATCCTTGGAAAGATGTCCTTTTCTGAGAAGAATCTGAAGGCTTTATTGAAGCACTTTGATCTCTTTTTGAGGTTTTTAGCAGAATACCACGATGACTTCTTCCCAGAGTCGGCTTATGTCGCTGCCTGTGAGGCACATTACAGCACCAAGAACCCCCGGGCAATTTATTAAAATGTTGTTGGTTCTGTAAGAGCAACTGCTCTGTCTAGTTTGGCGCTCTGGGTTCCAGGTGAATAACTAACAAGGTGGTGGGTCTTTACCCACAGCGCAAACACAATGCCCACCTTGGGGCTCTGTTGTTTGAGTTGCCCACATACTGCAGTTATTCTGTTAGGAATGATTCCCTGGGTGCCTGAAAGTGCTCTGACACGACACTTGTTACTTTGCAGGCCATCTGTGATGGCAAGGAAAAAGCAACTATGTTCACAGTGAAATATTCGTGGAATAGGTTAGGCCATTTCAGTAGACATTGCAGTTAGTTAGCAAGAACCACATTGTCTCTTTATTTGTTAGCATTAAACAAATTTTTTTTTGCAAATTGGTTTTATTTTTTTGATGAAGCCGAGCAACTCTGTCCAAAAAGGTTTAGTTTGTACTCGGAAACCACAAAGTAGTCTCAAAGTATTTTAGAGGGAATCGATATTGATGGCAAAAGAAAATTTGCAGCTATGCATTTGCTTCTAACGGTTCCCTCTCTGTGAAACATTATTTTTGGTGATCTAAAGAAAGCATTGCCTTTCTTATTTGAGATTTTACAGCTATACTTTGTTGTGTAATGTTATGGTTCCCTTTCTGTAAAATGTTATTTTTGGTGATCTAAATAAAGCCTGTCTTGTTTGAAAGAA |
| PMID - Link | Title |
|---|---|
| 33961781 | Dual proteome-scale networks reveal cell-specific remodeling of the human interactome. |
| 31527615 | The RNA-mediated estrogen receptor α interactome of hormone-dependent human breast cancer cell nuclei. |
| 29509190 | Quantitative mapping of RNA-mediated nuclear estrogen receptor β interactome in human breast cancer cells. |
| 28514442 | Architecture of the human interactome defines protein communities and disease networks. |
| 26496610 | A human interactome in three quantitative dimensions organized by stoichiometries and abundances. |
| 26186194 | The BioPlex Network: A Systematic Exploration of the Human Interactome. |
| 21873635 | Phylogenetic-based propagation of functional annotations within the Gene Ontology consortium. |
| 20479123 | MOF and histone H4 acetylation at lysine 16 are critical for DNA damage response and double-strand break repair. |
| 16227571 | A human protein complex homologous to the Drosophila MSL complex is responsible for the majority of histone H4 acetylation at lysine 16. |