METTL3

METTL3 (ингл. ) — аксымы, шул ук исемдәге ген тарафыннан кодлана торган югары молекуляр органик матдә.^[34][35]

METTL3
Нинди таксонда бар	H. sapiens[d][1]
Кодирующий ген	METTL3[d][1]
Молекулярная функция	methyltransferase activity[d][2], трансферазная активность[d][2], RNA binding[d][2], RNA methyltransferase activity[d][3][4][5][…], mRNA (2'-O-methyladenosine-N6-)-methyltransferase activity[d][6][7][8][…], mRNA binding[d][9][10], S-adenosyl-L-methionine binding[d][9][10], protein heterodimerization activity[d][9][10], связывание с белками плазмы[d][11][12][13][…], mRNA (2'-O-methyladenosine-N6-)-methyltransferase activity[d][14][6][7][…], mRNA (N6-adenosine)-methyltransferase activity[d][15][16][17][…], mRNA (2'-O-methyladenosine-N6-)-methyltransferase activity[d][18][19] һәм mRNA (2'-O-methyladenosine-N6-)-methyltransferase activity[d][2]
Күзәнәк компоненты	RNA N6-methyladenosine methyltransferase complex[d][20][21][22][…], нуклеоплазма[d][2], ядерные спеклы[d][18][23], төш[18][18][20][…], цитоплазма[2], төш[2][2][24][…], ядерные спеклы[d][2][25][26] һәм RNA N6-methyladenosine methyltransferase complex[d][27][11][5][…]
Биологический процесс	ритмический процесс[d][2], mRNA processing[d][2], positive regulation of cap-independent translational initiation[d][28], stem cell population maintenance[d][2], Метилирование[d][2], mRNA methylation[d][16][29][30][…], mRNA destabilization[d][2], циркадный ритм[d][2], primary miRNA processing[d][3], adenosine to inosine editing[d][2], RNA methylation[d][7][18], mRNA splicing, via spliceosome[d][18][31][32], mRNA catabolic process[d][2], forebrain radial glial cell differentiation[d][2], cellular response to UV[d][17], gliogenesis[d][2], regulation of T cell differentiation[d][2], negative regulation of Notch signaling pathway[d][2], regulation of meiotic cell cycle[d][2], endothelial to hematopoietic transition[d][2], regulation of hematopoietic stem cell differentiation[d][2], cellular response to DNA damage stimulus[d][2][17], Сперматогенез[d][2][2], дифференцировка клеток[d][2], dosage compensation by inactivation of X chromosome[d][5], mRNA splicing, via spliceosome[d][2][29][33][…], RNA methylation[d][15][2][26] һәм процесс метаболизма РНК[d][2]

Искәрмәләр

1. UniProt
   https://wikidata.org/wiki/Track:P4616https://wikidata.org/wiki/Track:Q54837https://wikidata.org/wiki/Track:Q109496594https://wikidata.org/wiki/Track:Q905695https://wikidata.org/wiki/Track:Q3152521https://wikidata.org/wiki/Track:P352https://wikidata.org/wiki/Track:Q43984865
2. GOA
   https://wikidata.org/wiki/Track:Q109496594https://wikidata.org/wiki/Track:Q28018111
3. Goodarzi H., Halberg N. N6-methyladenosine marks primary microRNAs for processing // Nature / M. Skipper — NPG, Springer Science+Business Media, 2015. — ISSN 1476-4687; 0028-0836 — doi:10.1038/NATURE14281 — PMID:25799998
   https://wikidata.org/wiki/Track:Q52661223https://wikidata.org/wiki/Track:Q180445https://wikidata.org/wiki/Track:Q180419https://wikidata.org/wiki/Track:Q176916https://wikidata.org/wiki/Track:Q24323516https://wikidata.org/wiki/Track:Q42323130https://wikidata.org/wiki/Track:Q51924844
4. Schöller E., Weichmann F., Treiber T. et al. Interactions, localization and phosphorylation of the m6A generating METTL3-METTL14-WTAP complex. // RNA — Cold Spring Harbor Laboratory Press, 2018. — ISSN 1355-8382; 1469-9001 — doi:10.1261/RNA.064063.117 — PMID:29348140
   https://wikidata.org/wiki/Track:Q5142358https://wikidata.org/wiki/Track:Q7277164https://wikidata.org/wiki/Track:Q49954461
5. Patil D. P., Jaffrey S. R., Guttman M. m(6)A RNA methylation promotes XIST-mediated transcriptional repression // Nature / M. Skipper — NPG, Springer Science+Business Media, 2016. — ISSN 1476-4687; 0028-0836 — doi:10.1038/NATURE19342 — PMID:27602518
   https://wikidata.org/wiki/Track:Q176916https://wikidata.org/wiki/Track:Q180419https://wikidata.org/wiki/Track:Q180445https://wikidata.org/wiki/Track:Q59667368https://wikidata.org/wiki/Track:Q87787496https://wikidata.org/wiki/Track:Q44170041https://wikidata.org/wiki/Track:Q52661223https://wikidata.org/wiki/Track:Q33902260
6. Jambhekar A. RNA m6A methylation regulates the ultraviolet-induced DNA damage response // Nature / M. Skipper — NPG, Springer Science+Business Media, 2017. — ISSN 1476-4687; 0028-0836 — doi:10.1038/NATURE21671 — PMID:28297716
   https://wikidata.org/wiki/Track:Q64512449https://wikidata.org/wiki/Track:Q38712170https://wikidata.org/wiki/Track:Q176916https://wikidata.org/wiki/Track:Q180419https://wikidata.org/wiki/Track:Q52661223https://wikidata.org/wiki/Track:Q180445
7. Bokar J. A., Shambaugh M. E., D Polayes et al. Purification and cDNA cloning of the AdoMet-binding subunit of the human mRNA (N6-adenosine)-methyltransferase // RNA — Cold Spring Harbor Laboratory Press, 1997. — ISSN 1355-8382; 1469-9001 — PMID:9409616
   https://wikidata.org/wiki/Track:Q24315962https://wikidata.org/wiki/Track:Q7277164https://wikidata.org/wiki/Track:Q5142358
8. Schwartz S., Jacob-Hirsch J., Dominissini D. et al. Topology of the human and mouse m6A RNA methylomes revealed by m6A-seq // Nature / M. Skipper — NPG, Springer Science+Business Media, 2012. — ISSN 1476-4687; 0028-0836 — doi:10.1038/NATURE11112 — PMID:22575960
   https://wikidata.org/wiki/Track:Q24320240https://wikidata.org/wiki/Track:Q180445https://wikidata.org/wiki/Track:Q54536929https://wikidata.org/wiki/Track:Q42317798https://wikidata.org/wiki/Track:Q52661223https://wikidata.org/wiki/Track:Q57070545https://wikidata.org/wiki/Track:Q180419https://wikidata.org/wiki/Track:Q176916https://wikidata.org/wiki/Track:Q47008807
9. Liu Z., Zou T. Structural basis of N(6)-adenosine methylation by the METTL3-METTL14 complex // Nature / M. Skipper — NPG, Springer Science+Business Media, 2016. — ISSN 1476-4687; 0028-0836 — doi:10.1038/NATURE18298 — PMID:27281194
   https://wikidata.org/wiki/Track:Q180419https://wikidata.org/wiki/Track:Q180445https://wikidata.org/wiki/Track:Q57021198https://wikidata.org/wiki/Track:Q176916https://wikidata.org/wiki/Track:Q52661223https://wikidata.org/wiki/Track:Q87157305https://wikidata.org/wiki/Track:Q27709350
10. Wang P., Doxtader K. A., Nam Y. Structural Basis for Cooperative Function of Mettl3 and Mettl14 Methyltransferases // Mol. Cell — Cell Press, Elsevier BV, 2016. — ISSN 1097-2765; 1097-4164 — doi:10.1016/J.MOLCEL.2016.05.041 — PMID:27373337
    https://wikidata.org/wiki/Track:Q746413https://wikidata.org/wiki/Track:Q28117995https://wikidata.org/wiki/Track:Q5058164https://wikidata.org/wiki/Track:Q3319468
11. Luo G., He C., Liu J. VIRMA mediates preferential m6A mRNA methylation in 3'UTR and near stop codon and associates with alternative polyadenylation // Cell discovery — NPG, 2018. — ISSN 2056-5968 — doi:10.1038/S41421-018-0019-0 — PMID:29507755
    https://wikidata.org/wiki/Track:Q27726611https://wikidata.org/wiki/Track:Q20740944https://wikidata.org/wiki/Track:Q180419https://wikidata.org/wiki/Track:Q68691789https://wikidata.org/wiki/Track:Q59830250https://wikidata.org/wiki/Track:Q52366303
12. Mansfeld J., Hein M. Y., Hyman A. A. et al. A human interactome in three quantitative dimensions organized by stoichiometries and abundances // Cell — Cell Press, Elsevier BV, 2015. — ISSN 0092-8674; 1097-4172 — doi:10.1016/J.CELL.2015.09.053 — PMID:26496610
    https://wikidata.org/wiki/Track:Q746413https://wikidata.org/wiki/Track:Q5058164https://wikidata.org/wiki/Track:Q655814https://wikidata.org/wiki/Track:Q1443007https://wikidata.org/wiki/Track:Q55137389https://wikidata.org/wiki/Track:Q55137390https://wikidata.org/wiki/Track:Q573389https://wikidata.org/wiki/Track:Q27936244
13. Wang Y., Li Y., Toth J. I. et al. N6-methyladenosine modification destabilizes developmental regulators in embryonic stem cells // Nat. Cell Biol. — NPG, 2014. — ISSN 1465-7392; 1476-4679 — doi:10.1038/NCB2902 — PMID:24394384
    https://wikidata.org/wiki/Track:Q1574111https://wikidata.org/wiki/Track:Q28585513https://wikidata.org/wiki/Track:Q180419
14. Parisien M. N6-methyladenosine-dependent regulation of messenger RNA stability // Nature / M. Skipper — NPG, Springer Science+Business Media, 2014. — ISSN 1476-4687; 0028-0836 — doi:10.1038/NATURE12730 — PMID:24284625
    https://wikidata.org/wiki/Track:Q42754877https://wikidata.org/wiki/Track:Q180445https://wikidata.org/wiki/Track:Q176916https://wikidata.org/wiki/Track:Q180419https://wikidata.org/wiki/Track:Q52661223https://wikidata.org/wiki/Track:Q24310545
15. Bokar J. A., Shambaugh M. E., D Polayes et al. Purification and cDNA cloning of the AdoMet-binding subunit of the human mRNA (N6-adenosine)-methyltransferase // RNA — Cold Spring Harbor Laboratory Press, 1997. — ISSN 1355-8382; 1469-9001 — PMID:9409616
    https://wikidata.org/wiki/Track:Q24315962https://wikidata.org/wiki/Track:Q7277164https://wikidata.org/wiki/Track:Q5142358
16. Schwartz S., Jacob-Hirsch J., Dominissini D. et al. Topology of the human and mouse m6A RNA methylomes revealed by m6A-seq // Nature / M. Skipper — NPG, Springer Science+Business Media, 2012. — ISSN 1476-4687; 0028-0836 — doi:10.1038/NATURE11112 — PMID:22575960
    https://wikidata.org/wiki/Track:Q24320240https://wikidata.org/wiki/Track:Q180445https://wikidata.org/wiki/Track:Q54536929https://wikidata.org/wiki/Track:Q42317798https://wikidata.org/wiki/Track:Q52661223https://wikidata.org/wiki/Track:Q57070545https://wikidata.org/wiki/Track:Q180419https://wikidata.org/wiki/Track:Q176916https://wikidata.org/wiki/Track:Q47008807
17. Jambhekar A. RNA m6A methylation regulates the ultraviolet-induced DNA damage response // Nature / M. Skipper — NPG, Springer Science+Business Media, 2017. — ISSN 1476-4687; 0028-0836 — doi:10.1038/NATURE21671 — PMID:28297716
    https://wikidata.org/wiki/Track:Q64512449https://wikidata.org/wiki/Track:Q38712170https://wikidata.org/wiki/Track:Q176916https://wikidata.org/wiki/Track:Q180419https://wikidata.org/wiki/Track:Q52661223https://wikidata.org/wiki/Track:Q180445
18. GOA
    https://wikidata.org/wiki/Track:Q109496594https://wikidata.org/wiki/Track:Q28018111
19. Livstone M. S., Thomas P. D., Lewis S. E. et al. Phylogenetic-based propagation of functional annotations within the Gene Ontology consortium // Brief. Bioinform. — OUP, 2011. — ISSN 1467-5463; 1477-4054 — doi:10.1093/BIB/BBR042 — PMID:21873635
    https://wikidata.org/wiki/Track:Q73104530https://wikidata.org/wiki/Track:Q61770112https://wikidata.org/wiki/Track:Q34211397https://wikidata.org/wiki/Track:Q217595https://wikidata.org/wiki/Track:Q30032484https://wikidata.org/wiki/Track:Q4967031https://wikidata.org/wiki/Track:Q7650732
20. Liu J., Yue Y., Han D. et al. A METTL3-METTL14 complex mediates mammalian nuclear RNA N6-adenosine methylation // Nature Chemical Biology — NPG, 2014. — ISSN 1552-4450; 1552-4469 — doi:10.1038/NCHEMBIO.1432 — PMID:24316715
    https://wikidata.org/wiki/Track:Q904026https://wikidata.org/wiki/Track:Q180419https://wikidata.org/wiki/Track:Q24311871
21. Patil D. P., Jaffrey S. R., Guttman M. m(6)A RNA methylation promotes XIST-mediated transcriptional repression // Nature / M. Skipper — NPG, Springer Science+Business Media, 2016. — ISSN 1476-4687; 0028-0836 — doi:10.1038/NATURE19342 — PMID:27602518
    https://wikidata.org/wiki/Track:Q176916https://wikidata.org/wiki/Track:Q180419https://wikidata.org/wiki/Track:Q180445https://wikidata.org/wiki/Track:Q59667368https://wikidata.org/wiki/Track:Q87787496https://wikidata.org/wiki/Track:Q44170041https://wikidata.org/wiki/Track:Q52661223https://wikidata.org/wiki/Track:Q33902260
22. Luo G., He C., Liu J. VIRMA mediates preferential m6A mRNA methylation in 3'UTR and near stop codon and associates with alternative polyadenylation // Cell discovery — NPG, 2018. — ISSN 2056-5968 — doi:10.1038/S41421-018-0019-0 — PMID:29507755
    https://wikidata.org/wiki/Track:Q27726611https://wikidata.org/wiki/Track:Q20740944https://wikidata.org/wiki/Track:Q180419https://wikidata.org/wiki/Track:Q68691789https://wikidata.org/wiki/Track:Q59830250https://wikidata.org/wiki/Track:Q52366303
23. Dahal U., Liu F. Mammalian WTAP is a regulatory subunit of the RNA N6-methyladenosine methyltransferase // Cell Res. — NPG, Springer Nature, Springer Science+Business Media, 2014. — ISSN 1001-0602; 1748-7838 — doi:10.1038/CR.2014.3 — PMID:24407421
    https://wikidata.org/wiki/Track:Q24318728https://wikidata.org/wiki/Track:Q1524018https://wikidata.org/wiki/Track:Q41582191https://wikidata.org/wiki/Track:Q176916https://wikidata.org/wiki/Track:Q21096327https://wikidata.org/wiki/Track:Q180419https://wikidata.org/wiki/Track:Q56557378
24. Jaffrey S. R. Dynamic m(6)A mRNA methylation directs translational control of heat shock response // Nature / M. Skipper — NPG, Springer Science+Business Media, 2015. — ISSN 1476-4687; 0028-0836 — doi:10.1038/NATURE15377 — PMID:26458103
    https://wikidata.org/wiki/Track:Q180445https://wikidata.org/wiki/Track:Q176916https://wikidata.org/wiki/Track:Q87787496https://wikidata.org/wiki/Track:Q180419https://wikidata.org/wiki/Track:Q52661223https://wikidata.org/wiki/Track:Q28118495
25. Dahal U., Liu F. Mammalian WTAP is a regulatory subunit of the RNA N6-methyladenosine methyltransferase // Cell Res. — NPG, Springer Nature, Springer Science+Business Media, 2014. — ISSN 1001-0602; 1748-7838 — doi:10.1038/CR.2014.3 — PMID:24407421
    https://wikidata.org/wiki/Track:Q24318728https://wikidata.org/wiki/Track:Q1524018https://wikidata.org/wiki/Track:Q41582191https://wikidata.org/wiki/Track:Q176916https://wikidata.org/wiki/Track:Q21096327https://wikidata.org/wiki/Track:Q180419https://wikidata.org/wiki/Track:Q56557378
26. Livstone M. S., Thomas P. D., Lewis S. E. et al. Phylogenetic-based propagation of functional annotations within the Gene Ontology consortium // Brief. Bioinform. — OUP, 2011. — ISSN 1467-5463; 1477-4054 — doi:10.1093/BIB/BBR042 — PMID:21873635
    https://wikidata.org/wiki/Track:Q73104530https://wikidata.org/wiki/Track:Q61770112https://wikidata.org/wiki/Track:Q34211397https://wikidata.org/wiki/Track:Q217595https://wikidata.org/wiki/Track:Q30032484https://wikidata.org/wiki/Track:Q4967031https://wikidata.org/wiki/Track:Q7650732
27. Jínek M., Sledź P. Structural insights into the molecular mechanism of the m(6)A writer complex // eLife / M. B. Eisen — eLife Sciences Publications Ltd, 2016. — ISSN 2050-084X — doi:10.7554/ELIFE.18434 — PMID:27627798
    https://wikidata.org/wiki/Track:Q18746166https://wikidata.org/wiki/Track:Q41093229https://wikidata.org/wiki/Track:Q82648013https://wikidata.org/wiki/Track:Q2000008https://wikidata.org/wiki/Track:Q52636855https://wikidata.org/wiki/Track:Q3308179
28. Meyer K. D., Patil D. P. 5' UTR m(6)A Promotes Cap-Independent Translation // Cell — Cell Press, Elsevier BV, 2015. — ISSN 0092-8674; 1097-4172 — doi:10.1016/J.CELL.2015.10.012 — PMID:26593424
    https://wikidata.org/wiki/Track:Q56557434https://wikidata.org/wiki/Track:Q655814https://wikidata.org/wiki/Track:Q746413https://wikidata.org/wiki/Track:Q44170041https://wikidata.org/wiki/Track:Q5058164https://wikidata.org/wiki/Track:Q28114851
29. Liu N., Parisien M. N(6)-methyladenosine-dependent RNA structural switches regulate RNA-protein interactions // Nature / M. Skipper — NPG, Springer Science+Business Media, 2015. — ISSN 1476-4687; 0028-0836 — doi:10.1038/NATURE14234 — PMID:25719671
    https://wikidata.org/wiki/Track:Q42754877https://wikidata.org/wiki/Track:Q180445https://wikidata.org/wiki/Track:Q24320088https://wikidata.org/wiki/Track:Q176916https://wikidata.org/wiki/Track:Q56557391https://wikidata.org/wiki/Track:Q52661223https://wikidata.org/wiki/Track:Q180419
30. Parisien M. N6-methyladenosine-dependent regulation of messenger RNA stability // Nature / M. Skipper — NPG, Springer Science+Business Media, 2014. — ISSN 1476-4687; 0028-0836 — doi:10.1038/NATURE12730 — PMID:24284625
    https://wikidata.org/wiki/Track:Q42754877https://wikidata.org/wiki/Track:Q180445https://wikidata.org/wiki/Track:Q176916https://wikidata.org/wiki/Track:Q180419https://wikidata.org/wiki/Track:Q52661223https://wikidata.org/wiki/Track:Q24310545
31. Liu N., Parisien M. N(6)-methyladenosine-dependent RNA structural switches regulate RNA-protein interactions // Nature / M. Skipper — NPG, Springer Science+Business Media, 2015. — ISSN 1476-4687; 0028-0836 — doi:10.1038/NATURE14234 — PMID:25719671
    https://wikidata.org/wiki/Track:Q42754877https://wikidata.org/wiki/Track:Q180445https://wikidata.org/wiki/Track:Q24320088https://wikidata.org/wiki/Track:Q176916https://wikidata.org/wiki/Track:Q56557391https://wikidata.org/wiki/Track:Q52661223https://wikidata.org/wiki/Track:Q180419
32. Goodarzi H. HNRNPA2B1 Is a Mediator of m(6)A-Dependent Nuclear RNA Processing Events // Cell — Cell Press, Elsevier BV, 2015. — ISSN 0092-8674; 1097-4172 — doi:10.1016/J.CELL.2015.08.011 — PMID:26321680
    https://wikidata.org/wiki/Track:Q5058164https://wikidata.org/wiki/Track:Q655814https://wikidata.org/wiki/Track:Q28118781https://wikidata.org/wiki/Track:Q746413https://wikidata.org/wiki/Track:Q51924844
33. Goodarzi H. HNRNPA2B1 Is a Mediator of m(6)A-Dependent Nuclear RNA Processing Events // Cell — Cell Press, Elsevier BV, 2015. — ISSN 0092-8674; 1097-4172 — doi:10.1016/J.CELL.2015.08.011 — PMID:26321680
    https://wikidata.org/wiki/Track:Q5058164https://wikidata.org/wiki/Track:Q655814https://wikidata.org/wiki/Track:Q28118781https://wikidata.org/wiki/Track:Q746413https://wikidata.org/wiki/Track:Q51924844
34. HUGO Gene Nomenclature Commitee, HGNC:29223 (ингл.). әлеге чыганактан 2015-10-25 архивланды. 18 сентябрь, 2017 тикшерелгән.
35. UniProt, Q9ULJ7 (ингл.). 18 сентябрь, 2017 тикшерелгән.

Чыганаклар

• Степанов В.М. (2005). Молекулярная биология. Структура и функция белков. Москва: Наука. ISBN 5-211-04971-3.(рус.)
• Bruce Alberts, Alexander Johnson, Julian Lewis, Martin Raff, Keith Roberts, Peter Walter (2002). Molecular Biology of the Cell (вид. 4th). Garland. ISBN 0815332181.(ингл.)