22625 DUF92
Thalassiosira pseudonana

Chromosome Product Transcript Start End Strand Short Name
22625 chr_5 DUF92 534808 539809 + DUF92
Expression Profile Conditional Changes Cluster Dendrogram
Thaps_hclust_0465
hypothetical protein
0.8773
CHD
0.874
KU superfamily
0.8715
hypothetical protein
0.8705
hypothetical protein
0.8673
hypothetical protein
0.8673
COG2 superfamily
0.8634
hypothetical protein
0.862
hypothetical protein
0.8614
AAA
0.861
Name CD Accession Definition Superfamily Bitscore E-Value From - To Hit Type PSSM ID
DUF92 Integral membrane protein DUF92; Members of this family have several predicted transmembrane... cl00793 173.848 2.10E-48 26 - 224 specific 250983
DUF92 superfamily Integral membrane protein DUF92; Members of this family have several predicted transmembrane... - 173.848 2.10E-48 26 - 224 superfamily 260625
T. pseudonana P. tricornutum P. tricornutum DiatomCyc F. cylindrus Pseudo-nitzschia multiseries E. huxleyi C. reinhardtii A. thaliana P. sojae
Not available PHATRDRAFT_38754 PHATRDRAFT_38754 180348 165865 Not available Cre02.g118200.t1.2 Not available Not available
KEGG description KEGG Pathway
Not available Not available
GO:0005524 GO:0015986 GO:0016469 GO:0046933 GO:0046961 -

ATP binding

Details: 
Interacting selectively and non-covalently with ATP, adenosine 5'-triphosphate, a universally important coenzyme and enzyme regulator.
GO Category: 
MF

ATP synthesis coupled proton transport

Details: 
The transport of protons across a membrane to generate an electrochemical gradient (proton-motive force) that powers ATP synthesis.
GO Category: 
BP

proton-transporting two-sector ATPase complex

Details: 
A large protein complex that catalyzes the synthesis or hydrolysis of ATP by a rotational mechanism, coupled to the transport of protons across a membrane. The complex comprises a membrane sector (F0, V0, or A0) that carries out proton transport and a cytoplasmic compartment sector (F1, V1, or A1) that catalyzes ATP synthesis or hydrolysis. Two major types have been characterized: V-type ATPases couple ATP hydrolysis to the transport of protons across a concentration gradient, whereas F-type ATPases, also known as ATP synthases, normally run in the reverse direction to utilize energy from a proton concentration or electrochemical gradient to synthesize ATP. A third type, A-type ATPases have been found in archaea, and are closely related to eukaryotic V-type ATPases but are reversible.
GO Category: 
CC

proton-transporting ATP synthase activity, rotational mechanism

Details: 
Catalysis of the transfer of protons from one side of a membrane to the other according to the reaction: ADP + H2O + phosphate + H+(in) = ATP + H+(out), by a rotational mechanism.
GO Category: 
MF

proton-transporting ATPase activity, rotational mechanism

Details: 
Catalysis of the transfer of protons from one side of a membrane to the other according to the reaction: ATP + H2O + H+(in) = ADP + phosphate + H+(out), by a rotational mechanism.
GO Category: 
MF
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