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ARATH:AVP1

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Species (Taxon ID) Arabidopsis thaliana (Mouse-ear cress). (3702)
Gene Name(s) AVP1 (synonyms: AVP, AVP-3, AVP3)
Protein Name(s) Pyrophosphate-energized vacuolar membrane proton pump 1

Pyrophosphate-energized inorganic pyrophosphatase 1 H(+)-PPase 1 Vacuolar proton pyrophosphatase 1 Vacuolar proton pyrophosphatase 3

External Links
UniProt P31414
EMBL M81892
AB015138
AC034256
CP002684
AY065016
AY078953
BT002481
Z17694
Z17695
AK221989
PIR A38230
RefSeq NP_173021.1
UniGene At.21942
At.66944
At.67102
At.74973
ProteinModelPortal P31414
SMR P31414
BioGrid 23378
STRING 3702.AT1G15690.1
TCDB 3.A.10.1.1
iPTMnet P31414
SwissPalm P31414
PaxDb P31414
PRIDE P31414
EnsemblPlants AT1G15690.1
GeneID 838138
Gramene AT1G15690.1
KEGG ath:AT1G15690
Araport AT1G15690
TAIR locus:2036134
eggNOG ENOG410IFIU
COG3808
InParanoid P31414
KO K01507
OMA NWICAIS
OrthoDB EOG093603U6
PhylomeDB P31414
BioCyc ARA:AT1G15690-MONOMER
BRENDA 3.6.1.1
PRO PR:P31414
Proteomes UP000006548
ExpressionAtlas P31414
Genevisible P31414
GO GO:0009507
GO:0009941
GO:0010008
GO:0005794
GO:0016021
GO:0016020
GO:0005739
GO:0000325
GO:0009705
GO:0005886
GO:0005774
GO:0005773
GO:0009678
GO:0004427
GO:0046872
GO:0009926
GO:0010248
GO:0048366
GO:0015992
GO:0009651
GO:0009414
HAMAP MF_01129
InterPro IPR004131
PANTHER PTHR31998
Pfam PF03030
PIRSF PIRSF001265
TIGRFAMs TIGR01104

Annotations

Qualifier GO ID GO term name Reference ECO ID ECO term name with/from Aspect Extension Notes Status

involved_in

GO:0048366

leaf development

PMID:20460583[1]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

part_of

GO:0016020

membrane

PMID:17432890[2]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

part_of

GO:0010008

endosome membrane

PMID:16210544[3]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

part_of

GO:0009941

chloroplast envelope

PMID:12938931[4]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

involved_in

GO:0009926

auxin polar transport

PMID:16210544[3]

ECO:0000316

genetic interaction evidence used in manual assertion

AGI_LocusCode:AT1G73590

P

Seeded From UniProt

complete

part_of

GO:0009705

plant-type vacuole membrane

PMID:1311852[5]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

enables

GO:0009678

hydrogen-translocating pyrophosphatase activity

PMID:20605924[6]

ECO:0000314

direct assay evidence used in manual assertion

F

Seeded From UniProt

complete

enables

GO:0009678

hydrogen-translocating pyrophosphatase activity

PMID:1311852[5]

ECO:0000314

direct assay evidence used in manual assertion

F

Seeded From UniProt

complete

involved_in

GO:0009651

response to salt stress

PMID:11572991[7]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

part_of

GO:0009507

chloroplast

PMID:18431481[8]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

part_of

GO:0009507

chloroplast

PMID:15028209[9]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

involved_in

GO:0009414

response to water deprivation

PMID:11572991[7]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

part_of

GO:0005886

plasma membrane

PMID:17644812[10]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

part_of

GO:0005886

plasma membrane

PMID:17317660[11]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

part_of

GO:0005886

plasma membrane

PMID:16210544[3]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

NOT|part_of

GO:0005829

cytosol

PMID:21166475[12]

ECO:0000245

automatically integrated combinatorial evidence used in manual assertion

C

Seeded From UniProt

complete

part_of

GO:0005794

Golgi apparatus

PMID:22430844[13]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

part_of

GO:0005774

vacuolar membrane

PMID:17151019[14]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

part_of

GO:0005774

vacuolar membrane

PMID:16618929[15]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

part_of

GO:0005773

vacuole

PMID:22923678[16]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

part_of

GO:0005773

vacuole

PMID:15539469[17]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

part_of

GO:0005773

vacuole

PMID:15215502[18]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

part_of

GO:0005773

vacuole

PMID:14760709[19]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

part_of

GO:0005739

mitochondrion

PMID:14671022[20]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

part_of

GO:0000325

plant-type vacuole

PMID:16618929[15]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

enables

GO:0004427

inorganic diphosphatase activity

GO_REF:0000002

ECO:0000256

match to sequence model evidence used in automatic assertion

InterPro:IPR004131

F

Seeded From UniProt

complete

enables

GO:0009678

hydrogen-translocating pyrophosphatase activity

GO_REF:0000002

ECO:0000256

match to sequence model evidence used in automatic assertion

InterPro:IPR004131

F

Seeded From UniProt

complete

part_of

GO:0016020

membrane

GO_REF:0000002

ECO:0000256

match to sequence model evidence used in automatic assertion

InterPro:IPR004131

C

Seeded From UniProt

complete

involved_in

GO:1902600

proton transmembrane transport

GO_REF:0000002

ECO:0000256

match to sequence model evidence used in automatic assertion

InterPro:IPR004131

P

Seeded From UniProt

complete

involved_in

GO:0010248

establishment or maintenance of transmembrane electrochemical gradient

PMID:1311852[5]

ECO:0000304

author statement supported by traceable reference used in manual assertion

P

Seeded From UniProt

complete

part_of

GO:0016021

integral component of membrane

GO_REF:0000037

ECO:0000322

imported manually asserted information used in automatic assertion

UniProtKB-KW:KW-0812

C

Seeded From UniProt

complete

involved_in

GO:0006811

ion transport

GO_REF:0000037

ECO:0000322

imported manually asserted information used in automatic assertion

UniProtKB-KW:KW-0406

P

Seeded From UniProt

complete

part_of

GO:0005768

endosome

GO_REF:0000037

ECO:0000322

imported manually asserted information used in automatic assertion

UniProtKB-KW:KW-0967

C

Seeded From UniProt

complete

part_of

GO:0005773

vacuole

GO_REF:0000037

ECO:0000322

imported manually asserted information used in automatic assertion

UniProtKB-KW:KW-0926

C

Seeded From UniProt

complete

enables

GO:0046872

metal ion binding

GO_REF:0000037

ECO:0000322

imported manually asserted information used in automatic assertion

UniProtKB-KW:KW-0479

F

Seeded From UniProt

complete

part_of

GO:0005886

plasma membrane

GO_REF:0000037
GO_REF:0000039

ECO:0000322

imported manually asserted information used in automatic assertion

UniProtKB-KW:KW-1003
UniProtKB-SubCell:SL-0039

C

Seeded From UniProt

complete

part_of

GO:0016020

membrane

GO_REF:0000037

ECO:0000322

imported manually asserted information used in automatic assertion

UniProtKB-KW:KW-0472

C

Seeded From UniProt

complete

part_of

GO:0010008

endosome membrane

GO_REF:0000039

ECO:0000322

imported manually asserted information used in automatic assertion

UniProtKB-SubCell:SL-0100

C

Seeded From UniProt

complete

part_of

GO:0005774

vacuolar membrane

GO_REF:0000039

ECO:0000322

imported manually asserted information used in automatic assertion

UniProtKB-SubCell:SL-0271

C

Seeded From UniProt

complete

Notes

References

See Help:References for how to manage references in GONUTS.

  1. Gonzalez, N et al. (2010) Increased leaf size: different means to an end. Plant Physiol. 153 1261-79 PubMed GONUTS page
  2. Mitra, SK et al. (2007) Membrane proteomic analysis of Arabidopsis thaliana using alternative solubilization techniques. J. Proteome Res. 6 1933-50 PubMed GONUTS page
  3. 3.0 3.1 3.2 Li, J et al. (2005) Arabidopsis H+-PPase AVP1 regulates auxin-mediated organ development. Science 310 121-5 PubMed GONUTS page
  4. Froehlich, JE et al. () Proteomic study of the Arabidopsis thaliana chloroplastic envelope membrane utilizing alternatives to traditional two-dimensional electrophoresis. J. Proteome Res. 2 413-25 PubMed GONUTS page
  5. 5.0 5.1 5.2 Sarafian, V et al. (1992) Molecular cloning and sequence of cDNA encoding the pyrophosphate-energized vacuolar membrane proton pump of Arabidopsis thaliana. Proc. Natl. Acad. Sci. U.S.A. 89 1775-9 PubMed GONUTS page
  6. Segami, S et al. (2010) Quantification, organ-specific accumulation and intracellular localization of type II H(+)-pyrophosphatase in Arabidopsis thaliana. Plant Cell Physiol. 51 1350-60 PubMed GONUTS page
  7. 7.0 7.1 Gaxiola, RA et al. (2001) Drought- and salt-tolerant plants result from overexpression of the AVP1 H+-pump. Proc. Natl. Acad. Sci. U.S.A. 98 11444-9 PubMed GONUTS page
  8. Zybailov, B et al. (2008) Sorting signals, N-terminal modifications and abundance of the chloroplast proteome. PLoS ONE 3 e1994 PubMed GONUTS page
  9. Kleffmann, T et al. (2004) The Arabidopsis thaliana chloroplast proteome reveals pathway abundance and novel protein functions. Curr. Biol. 14 354-62 PubMed GONUTS page
  10. Marmagne, A et al. (2007) A high content in lipid-modified peripheral proteins and integral receptor kinases features in the arabidopsis plasma membrane proteome. Mol. Cell Proteomics 6 1980-96 PubMed GONUTS page
  11. Benschop, JJ et al. (2007) Quantitative phosphoproteomics of early elicitor signaling in Arabidopsis. Mol. Cell Proteomics 6 1198-214 PubMed GONUTS page
  12. Ito, J et al. (2011) Analysis of the Arabidopsis cytosolic proteome highlights subcellular partitioning of central plant metabolism. J. Proteome Res. 10 1571-82 PubMed GONUTS page
  13. Parsons, HT et al. (2012) Isolation and proteomic characterization of the Arabidopsis Golgi defines functional and novel components involved in plant cell wall biosynthesis. Plant Physiol. 159 12-26 PubMed GONUTS page
  14. Jaquinod, M et al. (2007) A proteomics dissection of Arabidopsis thaliana vacuoles isolated from cell culture. Mol. Cell Proteomics 6 394-412 PubMed GONUTS page
  15. 15.0 15.1 Dunkley, TP et al. (2006) Mapping the Arabidopsis organelle proteome. Proc. Natl. Acad. Sci. U.S.A. 103 6518-23 PubMed GONUTS page
  16. Nikolovski, N et al. (2012) Putative glycosyltransferases and other plant Golgi apparatus proteins are revealed by LOPIT proteomics. Plant Physiol. 160 1037-51 PubMed GONUTS page
  17. Carter, C et al. (2004) The vegetative vacuole proteome of Arabidopsis thaliana reveals predicted and unexpected proteins. Plant Cell 16 3285-303 PubMed GONUTS page
  18. Shimaoka, T et al. (2004) Isolation of intact vacuoles and proteomic analysis of tonoplast from suspension-cultured cells of Arabidopsis thaliana. Plant Cell Physiol. 45 672-83 PubMed GONUTS page
  19. Szponarski, W et al. (2004) Large-scale characterization of integral proteins from Arabidopsis vacuolar membrane by two-dimensional liquid chromatography. Proteomics 4 397-406 PubMed GONUTS page
  20. Heazlewood, JL et al. (2004) Experimental analysis of the Arabidopsis mitochondrial proteome highlights signaling and regulatory components, provides assessment of targeting prediction programs, and indicates plant-specific mitochondrial proteins. Plant Cell 16 241-56 PubMed GONUTS page