Gene Ontology — View

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GO:0045263

Overview

Field	Value
Namespace	Cellular component
Short description	Proton-transporting ATP synthase complex, coupling factor F(o)
Full defintion	All non-F1 subunits of a hydrogen-transporting ATP synthase, including integral and peripheral membrane proteins.
Subterm of	GO:0033177 GO:0044424

Relationships

The relationship of GO:0045263 with other GO terms.

Relationship type	GO terms
Is a	GO:0033177 GO:0044424
Regulates	n.a.
Part of	GO:0045259
Positively regulates	n.a.
Negatively regulates	n.a.

Ancestor tree

A force layout showing the ancestor tree for GO:0045263, and its immediate children. If you wish to explore the tree dynamically, please use the GO Explorer.

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Additional data

This table contains additional metadata associated with the GO entry's definition field.

Field	Value
PMID	Insights into ATP synthase assembly and function through the molecular genetic manipulation of subunits of the yeast mitochondrial enzyme complex.Devenish RJ, Prescott M, Roucou X, Nagley P Biochim Biophys Acta. 2000 May 31; 1458 (2-3): 428–42.PMID: 10838056 Development of an increasingly detailed understanding of the eucaryotic mitochondrial ATP synthase requires a detailed knowledge of the stoichiometry, structure and function of F(0) sector subunits in the contexts of the proton channel and the stator stalk. Still to be resolved are the precise locations and roles of other supernumerary subunits present in mitochondrial ATP synthase complexes, but not found in the bacterial or chloroplast enzymes. The highly developed system of molecular genetic manipulation available in the yeast Saccharomyces cerevisiae, a unicellular eucaryote, permits testing for gene function based on the effects of gene disruption or deletion. In addition, the genes encoding ATP synthase subunits can be manipulated to introduce specific amino acids at desired positions within a subunit, or to add epitope or affinity tags at the C-terminus, enabling questions of stoichiometry, structure and function to be addressed. Newly emerging technologies, such as fusions of subunits with GFP are being applied to probe the dynamic interactions within mitochondrial ATP synthase, between ATP synthase complexes, and between ATP synthase and other mitochondrial enzyme complexes.

Field

Value

PMID

Insights into ATP synthase assembly and function through the molecular genetic manipulation of subunits of the yeast mitochondrial enzyme complex.Devenish RJ, Prescott M, Roucou X, Nagley P
Biochim Biophys Acta. 2000 May 31; 1458 (2-3): 428–42.PMID: 10838056

Development of an increasingly detailed understanding of the eucaryotic mitochondrial ATP synthase requires a detailed knowledge of the stoichiometry, structure and function of F(0) sector subunits in the contexts of the proton channel and the stator stalk. Still to be resolved are the precise locations and roles of other supernumerary subunits present in mitochondrial ATP synthase complexes, but not found in the bacterial or chloroplast enzymes. The highly developed system of molecular genetic manipulation available in the yeast Saccharomyces cerevisiae, a unicellular eucaryote, permits testing for gene function based on the effects of gene disruption or deletion. In addition, the genes encoding ATP synthase subunits can be manipulated to introduce specific amino acids at desired positions within a subunit, or to add epitope or affinity tags at the C-terminus, enabling questions of stoichiometry, structure and function to be addressed. Newly emerging technologies, such as fusions of subunits with GFP are being applied to probe the dynamic interactions within mitochondrial ATP synthase, between ATP synthase complexes, and between ATP synthase and other mitochondrial enzyme complexes.

Associated Lotus transcripts 8

GO predictions are based solely on the InterPro-to-GO mappings published by EMBL-EBI, which are in turn based on the mapping of predicted domains to the InterPro dataset. The InterPro-to-GO mapping was last updated on April 27, 2020, while the GO metadata was last updated on April 27, 2020.

Transcript	Name	Description	GO terms	GO count
Lj0g3v0002079.1 View transcript LORE1 insertions in MG20 v3.0 Genome browser Expression Atlas (ExpAt)	–	AtpI, partial (chloroplast) [Ixonanthes sp]. CCD-2012] gi\|408904962\|gb\|AFU97029.1\|	GO terms View details of GO:0015078 View details of GO:0015986 View details of GO:0045263	3
Lj0g3v0088839.1 View transcript LORE1 insertions in MG20 v3.0 Genome browser Expression Atlas (ExpAt)	–	PREDICTED: ATP synthase subunit a-like [Glycine max] gi\|356577936\|ref\|XP_003557077.1\|	GO terms View details of GO:0015078 View details of GO:0015986 View details of GO:0045263	3
Lj0g3v0295119.1 View transcript LORE1 insertions in MG20 v3.0 Genome browser Expression Atlas (ExpAt)	–	AtpH (chloroplast) [Trithuria inconspicua] gi\|456330977\|ref\|YP_007476338.1\|	GO terms View details of GO:0015078 View details of GO:0015986 View details of GO:0045263	3
Ljchlorog3v0000420.1 View transcript LORE1 insertions in MG20 v3.0 Genome browser Expression Atlas (ExpAt)	–	ATP synthase CF0 A subunit [Lotus japonicus] gi\|13518440\|ref\|NP_084800.1\|	GO terms View details of GO:0015078 View details of GO:0015986 View details of GO:0045263	3
Ljchlorog3v0000430.1 View transcript LORE1 insertions in MG20 v3.0 Genome browser Expression Atlas (ExpAt)	–	AtpH (chloroplast) [Trithuria inconspicua] gi\|456330977\|ref\|YP_007476338.1\|	GO terms View details of GO:0015078 View details of GO:0015986 View details of GO:0045263	3
Ljmitog3v0000190.1 View transcript LORE1 insertions in MG20 v3.0 Genome browser Expression Atlas (ExpAt)	–	PREDICTED: ATP synthase subunit a-like [Glycine max] gi\|356577936\|ref\|XP_003557077.1\|	GO terms View details of GO:0015078 View details of GO:0015986 View details of GO:0045263	3
Ljmitog3v0000550.1 View transcript LORE1 insertions in MG20 v3.0 Genome browser Expression Atlas (ExpAt)	–	PREDICTED: ATP synthase subunit a-like [Glycine max] gi\|356577936\|ref\|XP_003557077.1\|	GO terms View details of GO:0015078 View details of GO:0015986 View details of GO:0045263	3
LotjaGi1g1v0382500.1 View transcript LORE1 insertions in MG20 v3.0 Genome browser Expression Atlas (ExpAt)	–	ATP synthase subunit b; TAIR: AT4G32260.1 ATPase, F0 complex, subunit B/B', bacterial/chloroplast; Swiss-Prot: sp\|P31853\|ATPX_SPIOL ATP synthase subunit b', chloroplastic; TrEMBL-Plants: tr\|A0A1J7H2B0\|A0A1J7H2B0_LUPAN Uncharacterized protein; Found in the gene: LotjaGi1g1v0382500	GO terms View details of GO:0015078 View details of GO:0015986 View details of GO:0045263	3

Co-occuring GO terms 1

A list of co-occurring GO terms within the L. japonicus gene space:

GO term	Namespace	Name	Observations	Saturation (%)
GO:0045263 View details of GO:0045263 AmiGO InterPro QuickGO	Cellular component	Proton-transporting ATP synthase complex, coupling factor F(o)	1	12.50