about
ATM serine/threonine kinaseAtaxia telangiectasia mutatedUPF1 RNA helicase and ATPaseTerminal nucleotidyltransferase 2LSM1 homolog, mRNA degradation associatedMitochondrial poly(A) polymeraseExosome component 4Terminal nucleotidyltransferase 4ATerminal nucleotidyltransferase 4BTerminal uridylyl transferase 1, U6 snRNA-specificExoribonuclease 1Terminal uridylyl transferase 4Terminal uridylyl transferase 7Decapping mRNA 25'-3' exoribonuclease 1Decapping mRNA 2Exoribonuclease 1Exosome component 10Terminal nucleotidyltransferase 2LSM1 homolog, mRNA degradation associatedTerminal nucleotidyltransferase 4BTerminal nucleotidyltransferase 4AMitochondrial poly(A) polymeraseTerminal uridylyl transferase 1, U6 snRNA-specificTerminal uridylyl transferase 4Terminal uridylyl transferase 7UPF1 regulator of nonsense transcripts homolog (yeast)5'-3' exoribonuclease 1Exosome component 4Non-canonical poly(A) polymerase PAP2 YOL115WNon-canonical poly(A) polymerase TRF5 YNL299WExosome nuclease subunit RRP6 YOR001WTerminal nucleotidyltransferase 2Terminal uridylyl transferase 1, U6 snRNA-specificExoribonuclease 15'-3' exoribonuclease 1Terminal nucleotidyltransferase 4AExosome component 10LSM1 homolog, mRNA degradation associatedExosome component 4
P682
Degradation of histone mRNA requires oligouridylation followed by decapping and simultaneous degradation of the mRNA both 5' to 3' and 3' to 5'Regulated degradation of replication-dependent histone mRNAs requires both ATR and Upf1Contribution of Trf4/5 and the nuclear exosome to genome stability through regulation of histone mRNA levels in Saccharomyces cerevisiae.Deletion of the nuclear exosome component RRP6 leads to continued accumulation of the histone mRNA HTB1 in S-phase of the cell cycle in Saccharomyces cerevisiae
P921
Q141591-6772FE80-651D-45D4-9348-14B27DDC641EQ14872812-A66295CD-A878-462E-BCBA-0073BD12A93DQ14872812-AE0CA242-C9D9-45AA-94B5-B1DC764309CDQ21104922-359DA639-D492-4CB3-BBC6-08738F78C770Q21111810-C96DBFA4-9F9F-47CB-973F-21F948F61ABFQ21112385-862438CF-04BA-4A5A-A7CB-4CF36D814D44Q21115407-14F3DC70-0828-43F5-8A80-EA211708ED04Q21115884-3266D960-0AD2-4DD6-AD87-B4376606662EQ21123703-C6C12D49-803B-4BA2-B2C4-9A5C6828BF89Q21123721-CAC68E69-EF65-4084-BBEB-B9C1B2CD97A3Q21127316-6E747CD5-9DAF-464F-9C95-44349442430FQ21130623-20213FE1-F6C7-4CE5-A544-9C3AD39B5F30Q21135137-70B90D28-41FA-4EF9-BE2D-FA92EE9E3E15Q21135139-35F2103B-033A-41CC-8FCB-6AE87A296EECQ21173237-465D5168-E514-41A2-AA85-0E4B49F9697DQ21245962-0B9FD883-21B3-4DD3-8FDC-1A92FF85366CQ21495170-703DE06C-15BD-4B08-BD1D-6549F25A43BAQ21495571-3EB1D696-A849-4A04-8166-B98AE2885802Q21984239-11F259AC-62EC-4E71-AFCC-84343C3FA945Q21984239-42370197-592F-48FA-806B-15A63B529DF6Q21985392-82E5DEB9-BB07-4C55-ACB1-C36F88E9579DQ21987206-2A95775E-8739-40C2-914B-CFD5AD7B3ADFQ21987832-36CD2353-FD56-4705-9D73-B0D1BC39973EQ21987832-6D8B1BDE-533A-4893-BFDF-8E5CF11D6D40Q21987834-90206227-67DB-4F0C-8EFD-930EA599FA1CQ21987838-B088CED4-89C7-46F0-9B9D-1AC2345261E6Q21990664-C4ACB3DC-B5EB-43AF-A768-7532ACF33223Q21990775-AC6F298F-0FAA-4426-8F06-8C4262C4D228Q21990779-DAA09042-B546-4F4D-A8A4-FC0341133C31Q21990947-1B2D1C6D-9D23-4144-8056-A740A2153A07Q21992743-47744D28-36A6-4648-9036-0852FF4E4AD7Q22677818-72D4B4AB-21CD-4ABD-ACCF-6D24596DCB48Q27549284-9F1BD83B-50EF-4DD9-A505-2A8A5E6CF270Q27549284-B551E029-B31C-4758-8CF6-6E623C3218BFQ27549407-9A36C74D-C33A-4773-BC69-08A7B049A280Q27549407-A2A88583-5995-4AB1-A120-10FB81746EA1Q27551691-7FA4F642-7C74-4029-9676-72246D77283DQ27551691-E32EB3D6-B5AA-40BF-8FA1-48965E0969E5Q28559451-EC2A59B0-7AC0-4645-8AA2-0D845E2B934EQ28560203-87A70EBB-A94A-4937-8A7F-28AE9E1220F5
P682
description
The chemical reactions and pat ...... histone messenger RNA (mRNA).
@en
biologisch proces
@nl
name
histone mRNA catabolic process
@en
type
label
histone mRNA catabolic process
@en
altLabel
GO:0071044
@en
prefLabel
histone mRNA catabolic process
@en
P2888
P686
GO:0071044