STRINGSTRING
AOK51517.1 AOK51517.1 AOK52136.1 AOK52136.1 AOK52538.1 AOK52538.1 AOK53140.1 AOK53140.1 nuoN nuoN AOK53316.1 AOK53316.1 AOK53317.1 AOK53317.1 nuoK nuoK AOK53319.1 AOK53319.1 nuoI nuoI AOK53322.1 AOK53322.1 nuoF nuoF nuoD nuoD nuoC nuoC nuoB nuoB nuoA nuoA AOK54643.1 AOK54643.1 AOK54731.1 AOK54731.1 AOK54808.1 AOK54808.1 AOK54811.1 AOK54811.1 AOK54812.1 AOK54812.1 AOK54813.1 AOK54813.1 AOK56397.1 AOK56397.1 AOK57226.1 AOK57226.1
Nodes:
Network nodes represent proteins
splice isoforms or post-translational modifications are collapsed, i.e. each node represents all the proteins produced by a single, protein-coding gene locus.
Node Color
colored nodes:
query proteins and first shell of interactors
white nodes:
second shell of interactors
Node Content
empty nodes:
proteins of unknown 3D structure
filled nodes:
a 3D structure is known or predicted
Edges:
Edges represent protein-protein associations
associations are meant to be specific and meaningful, i.e. proteins jointly contribute to a shared function; this does not necessarily mean they are physically binding to each other.
Known Interactions
from curated databases
experimentally determined
Predicted Interactions
gene neighborhood
gene fusions
gene co-occurrence
Others
textmining
co-expression
protein homology
Your Input:
AOK51517.1NADPH-dependent FMN reductase; Derived by automated computational analysis using gene prediction method: Protein Homology. (190 aa)
AOK52136.1Formate dehydrogenase; Derived by automated computational analysis using gene prediction method: Protein Homology. (525 aa)
AOK52538.1NAD(P)H-quinone oxidoreductase; Derived by automated computational analysis using gene prediction method: Protein Homology; Belongs to the WrbA family. (204 aa)
AOK53140.1NADH:ubiquinone oxidoreductase subunit M; Catalyzes the transfer of electrons from NADH to quinone; Derived by automated computational analysis using gene prediction method: Protein Homology. (510 aa)
nuoNNADH:ubiquinone oxidoreductase subunit N; NDH-1 shuttles electrons from NADH, via FMN and iron-sulfur (Fe-S) centers, to quinones in the respiratory chain. The immediate electron acceptor for the enzyme in this species is believed to be ubiquinone. Couples the redox reaction to proton translocation (for every two electrons transferred, four hydrogen ions are translocated across the cytoplasmic membrane), and thus conserves the redox energy in a proton gradient; Belongs to the complex I subunit 2 family. (484 aa)
AOK53316.1NADH:ubiquinone oxidoreductase subunit M; Catalyzes the transfer of electrons from NADH to quinone; Derived by automated computational analysis using gene prediction method: Protein Homology. (496 aa)
AOK53317.1NADH:ubiquinone oxidoreductase subunit L; Derived by automated computational analysis using gene prediction method: Protein Homology. (684 aa)
nuoKNADH-quinone oxidoreductase subunit K; NDH-1 shuttles electrons from NADH, via FMN and iron-sulfur (Fe-S) centers, to quinones in the respiratory chain. The immediate electron acceptor for the enzyme in this species is believed to be ubiquinone. Couples the redox reaction to proton translocation (for every two electrons transferred, four hydrogen ions are translocated across the cytoplasmic membrane), and thus conserves the redox energy in a proton gradient; Belongs to the complex I subunit 4L family. (101 aa)
AOK53319.1NADH:ubiquinone oxidoreductase subunit J; NDH-1 shuttles electrons from NADH, via FMN and iron-sulfur (Fe-S) centers, to quinones in the respiratory chain. Couples the redox reaction to proton translocation (for every two electrons transferred, four hydrogen ions are translocated across the cytoplasmic membrane), and thus conserves the redox energy in a proton gradient. (217 aa)
nuoINADH dehydrogenase; NDH-1 shuttles electrons from NADH, via FMN and iron-sulfur (Fe-S) centers, to quinones in the respiratory chain. The immediate electron acceptor for the enzyme in this species is believed to be ubiquinone. Couples the redox reaction to proton translocation (for every two electrons transferred, four hydrogen ions are translocated across the cytoplasmic membrane), and thus conserves the redox energy in a proton gradient. (162 aa)
AOK53322.1NADH dehydrogenase; NDH-1 shuttles electrons from NADH, via FMN and iron-sulfur (Fe-S) centers, to quinones in the respiratory chain. Couples the redox reaction to proton translocation (for every two electrons transferred, four hydrogen ions are translocated across the cytoplasmic membrane), and thus conserves the redox energy in a proton gradient. Belongs to the complex I 75 kDa subunit family. (776 aa)
nuoFNADH dehydrogenase; NDH-1 shuttles electrons from NADH, via FMN and iron-sulfur (Fe-S) centers, to quinones in the respiratory chain. Belongs to the complex I 51 kDa subunit family. (436 aa)
nuoDNADH dehydrogenase; NDH-1 shuttles electrons from NADH, via FMN and iron-sulfur (Fe-S) centers, to quinones in the respiratory chain. The immediate electron acceptor for the enzyme in this species is believed to be ubiquinone. Couples the redox reaction to proton translocation (for every two electrons transferred, four hydrogen ions are translocated across the cytoplasmic membrane), and thus conserves the redox energy in a proton gradient; Belongs to the complex I 49 kDa subunit family. (417 aa)
nuoCNADH dehydrogenase; NDH-1 shuttles electrons from NADH, via FMN and iron-sulfur (Fe-S) centers, to quinones in the respiratory chain. The immediate electron acceptor for the enzyme in this species is believed to be ubiquinone. Couples the redox reaction to proton translocation (for every two electrons transferred, four hydrogen ions are translocated across the cytoplasmic membrane), and thus conserves the redox energy in a proton gradient; Belongs to the complex I 30 kDa subunit family. (200 aa)
nuoBNADH dehydrogenase; NDH-1 shuttles electrons from NADH, via FMN and iron-sulfur (Fe-S) centers, to quinones in the respiratory chain. The immediate electron acceptor for the enzyme in this species is believed to be ubiquinone. Couples the redox reaction to proton translocation (for every two electrons transferred, four hydrogen ions are translocated across the cytoplasmic membrane), and thus conserves the redox energy in a proton gradient. (159 aa)
nuoANADH-quinone oxidoreductase subunit A; NDH-1 shuttles electrons from NADH, via FMN and iron-sulfur (Fe-S) centers, to quinones in the respiratory chain. The immediate electron acceptor for the enzyme in this species is believed to be ubiquinone. Couples the redox reaction to proton translocation (for every two electrons transferred, four hydrogen ions are translocated across the cytoplasmic membrane), and thus conserves the redox energy in a proton gradient; Belongs to the complex I subunit 3 family. (119 aa)
AOK54643.1Flavodoxin; Derived by automated computational analysis using gene prediction method: Protein Homology. (163 aa)
AOK54731.1NAD(FAD)-dependent dehydrogenase; Derived by automated computational analysis using gene prediction method: Protein Homology. (124 aa)
AOK54808.1Formate hydrogenlyase; Derived by automated computational analysis using gene prediction method: Protein Homology. (668 aa)
AOK54811.1Hydrogenase 4 subunit F; Derived by automated computational analysis using gene prediction method: Protein Homology. (487 aa)
AOK54812.1Hydrogenase; Derived by automated computational analysis using gene prediction method: Protein Homology. (519 aa)
AOK54813.1Formate hydrogenlyase; Derived by automated computational analysis using gene prediction method: Protein Homology. (169 aa)
AOK56397.1NADH dehydrogenase; Derived by automated computational analysis using gene prediction method: Protein Homology. (483 aa)
AOK57226.1NADPH-dependent FMN reductase; Derived by automated computational analysis using gene prediction method: Protein Homology. (187 aa)
Your Current Organism:
Burkholderia stagnalis
NCBI taxonomy Id: 1503054
Other names: B. stagnalis, Burkholderia sp. Bp6893, Burkholderia sp. Bp6916, Burkholderia sp. Bp7118, Burkholderia sp. Bp7119, Burkholderia sp. Bp7120, Burkholderia sp. Bp7137, Burkholderia sp. Bp7139, Burkholderia sp. Bp7142, Burkholderia sp. Bp7143, Burkholderia sp. Bp7145, Burkholderia sp. Bp7260, Burkholderia sp. Bp7266, Burkholderia sp. Bp7278, Burkholderia sp. Bp7280, Burkholderia sp. Bp7282, Burkholderia sp. Bp7288, Burkholderia sp. Bp7466, Burkholderia sp. Bp7469, Burkholderia sp. Bp7471, Burkholderia sp. Bp7483, Burkholderia sp. Bp7485, Burkholderia sp. Bp7491, Burkholderia sp. Bp7519, Burkholderia sp. Bp7520, Burkholderia sp. Bp7521, Burkholderia sp. Bp7554, Burkholderia sp. Bp7555, Burkholderia sp. Bp7571, Burkholderia sp. Bp7572, Burkholderia sp. Bp7635, Burkholderia sp. Bp7636, Burkholderia sp. Bp7639, Burkholderia sp. Bp7640, Burkholderia sp. Bp7641, Burkholderia sp. Bp7642, Burkholderia sp. Bp7643, Burkholderia sp. Bp7644, Burkholderia sp. Bp7645, Burkholderia sp. Bp7651, Burkholderia sp. Bp7656, Burkholderia sp. Bp7657, Burkholderia sp. Bp7658, Burkholderia sp. Bp7663, Burkholderia sp. Bp7665, Burkholderia sp. Bp7666, Burkholderia sp. Bp7667, Burkholderia sp. Bp7670, Burkholderia sp. Bp7671, Burkholderia sp. Bp7673, Burkholderia sp. Bp7681, Burkholderia sp. Bp7682, Burkholderia sp. Bp7684, Burkholderia sp. Bp7685, Burkholderia sp. Bp7686, Burkholderia sp. Bp7687, Burkholderia sp. Bp7690, Burkholderia sp. Bp7692, Burkholderia sp. Bp7693, Burkholderia sp. Bp7694, Burkholderia sp. Bp7697, Burkholderia sp. Bp7698, Burkholderia sp. Bp7699, Burkholderia sp. Bp7705, Burkholderia sp. Bp7707, Burkholderia sp. LMG 28156, Burkholderia sp. LMG 28157, Burkholderia sp. R-52095, Burkholderia sp. R-52096, Burkholderia sp. R-52235, Burkholderia sp. R-52237, Burkholderia sp. R-52238, Burkholderia sp. R-52240, Burkholderia stagnalis De Smet et al. 2015, CCUG 65686, LMG 28156, LMG:28156
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