Sequence of SKI2_YEAST
EC Number:3.6.4.13
EC Number
Recommended Name
Accession Code
Organism
No of amino acids
Molecular Weight [Da]
Source
Reaction
a nucleoside triphosphate + H2O = a nucleoside diphosphate + phosphate
Other sequences found for EC No. 3.6.4.13
General information:
Sequence
0 MSEGFSSSSI QELYQSLKEI TNNADVELFE DRITKLDFES TDEPKHANDI IKDRFLRPSN
60 ALPWSLLDMV QDVPHTSSPE DCSGKLDYKE LLKVPDPINR TSYQFKRTGL EGKISGYKEE
120 VDLKEVANAN ASNSLSITRS INHNQNSVRG STAQLPFTPG GIPMKSVKTD SEQNGSSTMA
180 NATKLLHKDG QGLFDIPEGM NRGIKPMDSP AENEDQNGQF KELKQLNEID NELDIRIEAN
240 EAKLKEEEKS AKSISEEIME EATEETTADN ADDAEIDELL PIGIDFGRTK PVSKSVPVKK
300 EWAHVVDLNH KIENFDELIP NPARSWPFEL DTFQKEAVYH LEQGDSVFVA AHTSAGKTVV
360 AEYAIAMAHR NMTKTIYTSP IKALSNQKFR DFKETFDDVN IGLITGDVQI NPDANCLIMT
420 TEILRSMLYR GADLIRDVEF VIFDEVHYVN DQDRGVVWEE VIIMLPQHVK FILLSATVPN
480 TYEFANWIGR TKQKNIYVIS TPKRPVPLEI NIWAKKELIP VINQNSEFLE ANFRKHKEIL
540 NGESAKGAPS KTDNGRGGST ARGGRGGSNT RDGRGGRGNS TRGGANRGGS RGAGAIGSNK
600 RKFFTQDGPS KKTWPEIVNY LRKRELLPMV VFVFSKKRCE EYADWLEGIN FCNNKEKSQI
660 HMFIEKSITR LKKEDRDLPQ ILKTRSLLER GIAVHHGGLL PIVKELIEIL FSKGFIKVLF
720 ATETFAMGLN LPTRTVIFSS IRKHDGNGLR ELTPGEFTQM AGRAGRRGLD STGTVIVMAY
780 NSPLSIATFK EVTMGVPTRL QSQFRLTYNM ILNLLRIEAL RVEEMIKYSF SENAKETLQP
840 EHEKQIKVLQ EELQTIEYKS CEICDNDIEK FLELMLAYKE ATVNLMQEMV KSPSILHILK
900 EGRLVAFRDP NDCLKLGFVF KVSLKDAVCV IMTFTKPYKL PNGEPNHLIY FPKADGYRRR
960 NFPKFQKTDF YMEEVPVTAI EVITKRKFAA PLGKVIKKDV AALNEFNAET NNILDGKTLK
1020 EAINIEKQGL KIHQILLDRT NIRDEIFKLK SIKCPNLSQH IVPKFKAHVI KKKIEELYHL
1080 MSDQNLSLLP DYEKRLAVLK DTEFIDQNHN VLLKGRVACE INSGYELVLT ELILDNFLGS
1140 FEPEEIVALL SVFVYEGKTR EEEPPIVTPR LAKGKQRIEE IYKKMLCVFN THQIPLTQDE
1200 AEFLDRKRFA MMNVVYEWAR GLSFKEIMEM SPEAEGTVVR VITWLDEICR EVKTASIIIG
1260 NSTLHMKMSR AQELIKRDIV FAASLYL
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Sequence Reference
Authors
Title
Journal
Volume
Pages
Year
PubMed ID
100093
Widner W.R.,Wickner R.B.
Evidence that the SKI antiviral system of Saccharomyces cerevisiae acts by blocking expression of viral mRNA.
Mol. Cell. Biol.
13
4331-4341
1993
100094
Johnston M.,Hillier L.W.,Riles L.,Albermann K.,Andre B.,Ansorge W.,Benes V.,Brueckner M.,Delius H.,Dubois E.,Duesterhoeft A.,Entian K.-D.,Floeth M.,Goffeau A.,Hebling U.,Heumann K.,Heuss-Neitzel D.,Hilbert H.,Hilger F.,Kleine K.,Koetter P.,Louis E.J.,Messenguy F.,Mewes H.-W.,Miosga T.,Moestl D.,Mueller-Auer S.,Nentwich U.,Obermaier B.,Piravandi E.,Pohl T.M.,Portetelle D.,Purnelle B.,Rechmann S.,Rieger M.,Rinke M.,Rose M.,Scharfe M.,Scherens B.,Scholler P.,Schwager C.,Schwarz S.,Underwood A.P.,Urrestarazu L.A.,Vandenbol M.,Verhasselt P.,Vierendeels F.,Voet M.,Volckaert G.,Voss H.,Wambutt R.,Wedler E.,Wedler H.,Zimmermann F.K.,Zollner A.,Hani J.,Hoheisel J.D.
The nucleotide sequence of Saccharomyces cerevisiae chromosome XII.
Nature
387
87-90
1997
100095
Engel S.R.,Dietrich F.S.,Fisk D.G.,Binkley G.,Balakrishnan R.,Costanzo M.C.,Dwight S.S.,Hitz B.C.,Karra K.,Nash R.S.,Weng S.,Wong E.D.,Lloyd P.,Skrzypek M.S.,Miyasato S.R.,Simison M.,Cherry J.M.
The reference genome sequence of Saccharomyces cerevisiae: Then and now.
G3 (Bethesda)
4
389-398
2014
100096
Lygerou Z.,Conesa C.,Lesage P.,Swanson R.N.,Ruet A.,Carlson M.,Sentenac A.,Seraphin B.
The yeast BDF1 gene encodes a transcription factor involved in the expression of a broad class of genes including snRNAs.
Nucleic Acids Res.
22
5332-5340
1994
100097
Toh-e A.,Guerry P.,Wickner R.B.
Chromosomal superkiller mutants of Saccharomyces cerevisiae.
J. Bacteriol.
136
1002-1007
1978
100098
Ridley S.P.,Sommer S.S.,Wickner R.B.
Superkiller mutations in Saccharomyces cerevisiae suppress exclusion of M2 double-stranded RNA by L-A-HN and confer cold sensitivity in the presence of M and L-A-HN.
Mol. Cell. Biol.
4
761-770
1984
100099
Johnson A.W.,Kolodner R.D.
Synthetic lethality of sep1 (xrn1) ski2 and sep1 (xrn1) ski3 mutants of Saccharomyces cerevisiae is independent of killer virus and suggests a general role for these genes in translation control.
Mol. Cell. Biol.
15
2719-2727
1995
100100
Masison D.C.,Blanc A.,Ribas J.C.,Carroll K.,Sonenberg N.,Wickner R.B.
Decoying the cap- mRNA degradation system by a double-stranded RNA virus and poly(A)- mRNA surveillance by a yeast antiviral system.
Mol. Cell. Biol.
15
2763-2771
1995
100101
Anderson J.S.J.,Parker R.P.
The 3' to 5' degradation of yeast mRNAs is a general mechanism for mRNA turnover that requires the SKI2 DEVH box protein and 3' to 5' exonucleases of the exosome complex.
EMBO J.
17
1497-1506
1998
100102
van Hoof A.,Lennertz P.,Parker R.
Yeast exosome mutants accumulate 3'-extended polyadenylated forms of U4 small nuclear RNA and small nucleolar RNAs.
Mol. Cell. Biol.
20
441-452
2000
100103
Brown J.T.,Bai X.,Johnson A.W.
The yeast antiviral proteins Ski2p, Ski3p, and Ski8p exist as a complex in vivo.
RNA
6
449-457
2000
100104
Searfoss A.M.,Wickner R.B.
3' poly(A) is dispensable for translation.
Proc. Natl. Acad. Sci. U.S.A.
97
9133-9137
2000
100105
Araki Y.,Takahashi S.,Kobayashi T.,Kajiho H.,Hoshino S.,Katada T.
Ski7p G protein interacts with the exosome and the Ski complex for 3'-to-5' mRNA decay in yeast.
EMBO J.
20
4684-4693
2001
100106
Brown J.T.,Johnson A.W.
A cis-acting element known to block 3' mRNA degradation enhances expression of polyA-minus mRNA in wild-type yeast cells and phenocopies a ski mutant.
RNA
7
1566-1577
2001
100107
Mitchell P.,Tollervey D.
An NMD pathway in yeast involving accelerated deadenylation and exosome-mediated 3'-->5' degradation.
Mol. Cell
11
1405-1413
2003
100108
Huh W.-K.,Falvo J.V.,Gerke L.C.,Carroll A.S.,Howson R.W.,Weissman J.S.,O'Shea E.K.
Global analysis of protein localization in budding yeast.
Nature
425
686-691
2003
100109
Ghaemmaghami S.,Huh W.-K.,Bower K.,Howson R.W.,Belle A.,Dephoure N.,O'Shea E.K.,Weissman J.S.
Global analysis of protein expression in yeast.
Nature
425
737-741
2003
100110
Kushner D.B.,Lindenbach B.D.,Grdzelishvili V.Z.,Noueiry A.O.,Paul S.M.,Ahlquist P.
Systematic, genome-wide identification of host genes affecting replication of a positive-strand RNA virus.
Proc. Natl. Acad. Sci. U.S.A.
100
15764-15769
2003
100111
Li X.,Gerber S.A.,Rudner A.D.,Beausoleil S.A.,Haas W.,Villen J.,Elias J.E.,Gygi S.P.
Large-scale phosphorylation analysis of alpha-factor-arrested Saccharomyces cerevisiae.
J. Proteome Res.
6
1190-1197
2007
100112
Albuquerque C.P.,Smolka M.B.,Payne S.H.,Bafna V.,Eng J.,Zhou H.
A multidimensional chromatography technology for in-depth phosphoproteome analysis.
Mol. Cell. Proteomics
7
1389-1396
2008
100113
Holt L.J.,Tuch B.B.,Villen J.,Johnson A.D.,Gygi S.P.,Morgan D.O.
Global analysis of Cdk1 substrate phosphorylation sites provides insights into evolution.
Science
325
1682-1686
2009
100114
Aloy P.,Boettcher B.,Ceulemans H.,Leutwein C.,Mellwig C.,Fischer S.,Gavin A.-C.,Bork P.,Superti-Furga G.,Serrano L.,Russell R.B.
Structure-based assembly of protein complexes in yeast.
Science
303
2026-2029
2004
