37509 (VAT3) vATP-synt_AC39 superfamily
Thalassiosira pseudonana

Chromosome Product Transcript Start End Strand Short Name
37509 chr_14 (VAT3) vATP-synt_AC39 superfamily 293012 294580 + vATP-synt_AC39 superfamily
NCBI ID Ensembl Genomes exon ID
7450857 Thaps37509.1, Thaps37509.2
Expression Profile Conditional Changes Cluster Dendrogram
Thaps_hclust_0078
Normalized Mean Residue
Thaps_bicluster_0271
0.35
Rab
0.8848
vATP-synt_E
0.8819
V-ATPase_C superfamily
0.8792
ATP-synt_F superfamily
0.8719
ATP-synt_D
0.8717
hypothetical protein
0.8709
ATP-synt_C
0.8694
(VAT1) V-ATPase_V1_B
0.8692
ATP-synt_C superfamily
0.8654
S_TKc
0.8645
Name CD Accession Definition Superfamily Bitscore E-Value From - To Hit Type PSSM ID
vATP-synt_AC39 superfamily ATP synthase (C/AC39) subunit; This family includes the AC39 subunit from vacuolar ATP synthase,... - 211.833 9.06E-65 24 - 379 superfamily 260557
NtpC Archaeal/vacuolar-type H+-ATPase subunit C [Energy production and conversion] - 159.051 1.20E-44 27 - 380 multi-dom 224444
T. pseudonana P. tricornutum P. tricornutum DiatomCyc F. cylindrus Pseudo-nitzschia multiseries E. huxleyi C. reinhardtii A. thaliana P. sojae
Not available PHATR_21030 PHATR_21030 278320 260538 413949 Cre03.g176250.t1.2 AT3G28710.1 351065
KEGG description KEGG Pathway
Phagosome map04145
GO:0015986 GO:0016469 GO:0046933 GO:0046961 GO:0003936 -

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

NA

Details: 
NA
GO Category: 
NA
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