Sequence of PRDX1_HUMAN
EC Number:1.11.1.15
EC Number
Recommended Name
Accession Code
Organism
No of amino acids
Molecular Weight [Da]
Source
Reaction
Other sequences found for EC No. 1.11.1.15
General information:
Sequence
0 MSSGNAKIGH PAPNFKATAV MPDGQFKDIS LSDYKGKYVV FFFYPLDFTF VCPTEIIAFS
60 DRAEEFKKLN CQVIGASVDS HFCHLAWVNT PKKQGGLGPM NIPLVSDPKR TIAQDYGVLK
120 ADEGISFRGL FIIDDKGILR QITVNDLPVG RSVDETLRLV QAFQFTDKHG EVCPAGWKPG
180 SDTIKPDVQK SKEYFSKQK
Download this sequence
in fasta formatDownload all sequences for 1.11.1.15
in fasta format
in csv (Excel, OpenOffice) formatSequence related references
Sequence Reference
Authors
Title
Journal
Volume
Pages
Year
PubMed ID
461800
Prosperi M.T.,Ferbus D.,Karczinski I.,Goubin G.
A human cDNA corresponding to a gene overexpressed during cell proliferation encodes a product sharing homology with amoebic and bacterial proteins.
J. Biol. Chem.
268
11050-11056
1993
461801
Shau H.,Butterfield L.H.,Chiu R.,Kim A.
Cloning and sequence analysis of candidate human natural killer-enhancing factor genes.
Immunogenetics
40
129-134
1994
461805
Goshima N.,Kawamura Y.,Fukumoto A.,Miura A.,Honma R.,Satoh R.,Wakamatsu A.,Yamamoto J.,Kimura K.,Nishikawa T.,Andoh T.,Iida Y.,Ishikawa K.,Ito E.,Kagawa N.,Kaminaga C.,Kanehori K.,Kawakami B.,Kenmochi K.,Kimura R.,Kobayashi M.,Kuroita T.,Kuwayama H.,Maruyama Y.,Matsuo K.,Minami K.,Mitsubori M.,Mori M.,Morishita R.,Murase A.,Nishikawa A.,Nishikawa S.,Okamoto T.,Sakagami N.,Sakamoto Y.,Sasaki Y.,Seki T.,Sono S.,Sugiyama A.,Sumiya T.,Takayama T.,Takayama Y.,Takeda H.,Togashi T.,Yahata K.,Yamada H.,Yanagisawa Y.,Endo Y.,Imamoto F.,Kisu Y.,Tanaka S.,Isogai T.,Imai J.,Watanabe S.,Nomura N.
Human protein factory for converting the transcriptome into an in vitro-expressed proteome.
Nat. Methods
5
1011-1017
2008
461806
Gregory S.G.,Barlow K.F.,McLay K.E.,Kaul R.,Swarbreck D.,Dunham A.,Scott C.E.,Howe K.L.,Woodfine K.,Spencer C.C.A.,Jones M.C.,Gillson C.,Searle S.,Zhou Y.,Kokocinski F.,McDonald L.,Evans R.,Phillips K.,Atkinson A.,Cooper R.,Jones C.,Hall R.E.,Andrews T.D.,Lloyd C.,Ainscough R.,Almeida J.P.,Ambrose K.D.,Anderson F.,Andrew R.W.,Ashwell R.I.S.,Aubin K.,Babbage A.K.,Bagguley C.L.,Bailey J.,Beasley H.,Bethel G.,Bird C.P.,Bray-Allen S.,Brown J.Y.,Brown A.J.,Buckley D.,Burton J.,Bye J.,Carder C.,Chapman J.C.,Clark S.Y.,Clarke G.,Clee C.,Cobley V.,Collier R.E.,Corby N.,Coville G.J.,Davies J.,Deadman R.,Dunn M.,Earthrowl M.,Ellington A.G.,Errington H.,Frankish A.,Frankland J.,French L.,Garner P.,Garnett J.,Gay L.,Ghori M.R.J.,Gibson R.,Gilby L.M.,Gillett W.,Glithero R.J.,Grafham D.V.,Griffiths C.,Griffiths-Jones S.,Grocock R.,Hammond S.,Harrison E.S.I.,Hart E.,Haugen E.,Heath P.D.,Holmes S.,Holt K.,Howden P.J.,Hunt A.R.,Hunt S.E.,Hunter G.,Isherwood J.,James R.,Johnson C.,Johnson D.,Joy A.,Kay M.,Kershaw J.K.,Kibukawa M.,Kimberley A.M.,King A.,Knights A.J.,Lad H.,Laird G.,Lawlor S.,Leongamornlert D.A.,Lloyd D.M.,Loveland J.,Lovell J.,Lush M.J.,Lyne R.,Martin S.,Mashreghi-Mohammadi M.,Matthews L.,Matthews N.S.W.,McLaren S.,Milne S.,Mistry S.,Moore M.J.F.,Nickerson T.,O'Dell C.N.,Oliver K.,Palmeiri A.,Palmer S.A.,Parker A.,Patel D.,Pearce A.V.,Peck A.I.,Pelan S.,Phelps K.,Phillimore B.J.,Plumb R.,Rajan J.,Raymond C.,Rouse G.,Saenphimmachak C.,Sehra H.K.,Sheridan E.,Shownkeen R.,Sims S.,Skuce C.D.,Smith M.,Steward C.,Subramanian S.,Sycamore N.,Tracey A.,Tromans A.,Van Helmond Z.,Wall M.,Wallis J.M.,White S.,Whitehead S.L.,Wilkinson J.E.,Willey D.L.,Williams H.,Wilming L.,Wray P.W.,Wu Z.,Coulson A.,Vaudin M.,Sulston J.E.,Durbin R.M.,Hubbard T.,Wooster R.,Dunham I.,Carter N.P.,McVean G.,Ross M.T.,Harrow J.,Olson M.V.,Beck S.,Rogers J.,Bentley D.R.
The DNA sequence and biological annotation of human chromosome 1.
Nature
441
315-321
2006
461808
The status, quality, and expansion of the NIH full-length cDNA project: the Mammalian Gene Collection (MGC).
Genome Res.
14
2121-2127
2004
461810
Kang S.W.,Chae H.Z.,Seo M.S.,Kim K.,Baines I.C.,Rhee S.G.
Mammalian peroxiredoxin isoforms can reduce hydrogen peroxide generated in response to growth factors and tumor necrosis factor-alpha.
J. Biol. Chem.
273
6297-6302
1998
461811
Wagner E.,Luche S.,Penna L.,Chevallet M.,van Dorsselaer A.,Leize-Wagner E.,Rabilloud T.
A method for detection of overoxidation of cysteines: peroxiredoxins are oxidized in vivo at the active-site cysteine during oxidative stress.
Biochem. J.
366
777-785
2002
461812
Chang T.-S.,Jeong W.,Choi S.Y.,Yu S.,Kang S.W.,Rhee S.G.
Regulation of peroxiredoxin I activity by Cdc2-mediated phosphorylation.
J. Biol. Chem.
277
25370-25376
2002
461813
Yang K.S.,Kang S.W.,Woo H.A.,Hwang S.C.,Chae H.Z.,Kim K.,Rhee S.G.
Inactivation of human peroxiredoxin I during catalysis as the result of the oxidation of the catalytic site cysteine to cysteine-sulfinic acid.
J. Biol. Chem.
277
38029-38036
2002
461814
Chevallet M.,Wagner E.,Luche S.,van Dorsselaer A.,Leize-Wagner E.,Rabilloud T.
Regeneration of peroxiredoxins during recovery after oxidative stress: only some overoxidized peroxiredoxins can be reduced during recovery after oxidative stress.
J. Biol. Chem.
278
37146-37153
2003
461815
Andersen J.S.,Wilkinson C.J.,Mayor T.,Mortensen P.,Nigg E.A.,Mann M.
Proteomic characterization of the human centrosome by protein correlation profiling.
Nature
426
570-574
2003
461816
Woo H.A.,Chae H.Z.,Hwang S.C.,Yang K.S.,Kang S.W.,Kim K.,Rhee S.G.
Reversing the inactivation of peroxiredoxins caused by cysteine sulfinic acid formation.
Science
300
653-656
2003
461817
Budanov A.V.,Sablina A.A.,Feinstein E.,Koonin E.V.,Chumakov P.M.
Regeneration of peroxiredoxins by p53-regulated sestrins, homologs of bacterial AhpD.
Science
304
596-600
2004
461818
Chi A.,Valencia J.C.,Hu Z.-Z.,Watabe H.,Yamaguchi H.,Mangini N.J.,Huang H.,Canfield V.A.,Cheng K.C.,Yang F.,Abe R.,Yamagishi S.,Shabanowitz J.,Hearing V.J.,Wu C.,Appella E.,Hunt D.F.
Proteomic and bioinformatic characterization of the biogenesis and function of melanosomes.
J. Proteome Res.
5
3135-3144
2006
461819
Choudhary C.,Kumar C.,Gnad F.,Nielsen M.L.,Rehman M.,Walther T.C.,Olsen J.V.,Mann M.
Lysine acetylation targets protein complexes and co-regulates major cellular functions.
Science
325
834-840
2009
461820
Burkard T.R.,Planyavsky M.,Kaupe I.,Breitwieser F.P.,Buerckstuemmer T.,Bennett K.L.,Superti-Furga G.,Colinge J.
Initial characterization of the human central proteome.
BMC Syst. Biol.
5
17-17
2011
461821
Schmidt M.V.,Schuelke J.P.,Liebl C.,Stiess M.,Avrabos C.,Bock J.,Wochnik G.M.,Davies H.A.,Zimmermann N.,Scharf S.H.,Truembach D.,Wurst W.,Zieglgaensberger W.,Turck C.,Holsboer F.,Stewart M.G.,Bradke F.,Eder M.,Mueller M.B.,Rein T.
Tumor suppressor down-regulated in renal cell carcinoma 1 (DRR1) is a stress-induced actin bundling factor that modulates synaptic efficacy and cognition.
Proc. Natl. Acad. Sci. U.S.A.
108
17213-17218
2011
461822
Rosenow A.,Noben J.P.,Jocken J.,Kallendrusch S.,Fischer-Posovszky P.,Mariman E.C.,Renes J.
Resveratrol-induced changes of the human adipocyte secretion profile.
J. Proteome Res.
11
4733-4743
2012
461823
Zhou H.,Di Palma S.,Preisinger C.,Peng M.,Polat A.N.,Heck A.J.,Mohammed S.
Toward a comprehensive characterization of a human cancer cell phosphoproteome.
J. Proteome Res.
12
260-271
2013
461824
Bian Y.,Song C.,Cheng K.,Dong M.,Wang F.,Huang J.,Sun D.,Wang L.,Ye M.,Zou H.
An enzyme assisted RP-RPLC approach for in-depth analysis of human liver phosphoproteome.
J. Proteomics
96
253-262
2014
461825
Impens F.,Radoshevich L.,Cossart P.,Ribet D.
Mapping of SUMO sites and analysis of SUMOylation changes induced by external stimuli.
Proc. Natl. Acad. Sci. U.S.A.
111
12432-12437
2014
461826
Vaca Jacome A.S.,Rabilloud T.,Schaeffer-Reiss C.,Rompais M.,Ayoub D.,Lane L.,Bairoch A.,Van Dorsselaer A.,Carapito C.
N-terminome analysis of the human mitochondrial proteome.
Proteomics
15
2519-2524
2015
461827
Hendriks I.A.,Lyon D.,Young C.,Jensen L.J.,Vertegaal A.C.,Nielsen M.L.
Site-specific mapping of the human SUMO proteome reveals co-modification with phosphorylation.
Nat. Struct. Mol. Biol.
24
325-336
2017
461828
Joensson T.J.,Johnson L.C.,Lowther W.T.
Structure of the sulphiredoxin-peroxiredoxin complex reveals an essential repair embrace.
Nature
451
98-101
2008
461829
Joensson T.J.,Johnson L.C.,Lowther W.T.
Protein engineering of the quaternary sulfiredoxin.peroxiredoxin enzyme.substrate complex reveals the molecular basis for cysteine sulfinic acid phosphorylation.
J. Biol. Chem.
284
33305-33310
2009
