EMD-15452
Cryo-EM structure of the nitrogen-fixation associated NADH:ferredoxin oxidoreductase RNF from Azotobacter vinelandii
EMD-15452
Single-particle3.11 Å
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Map released: 01/11/2023
Last modified: 16/10/2024
Sample Organism:
Azotobacter vinelandii DJ
Sample: Heptameric complex of NADH:ferredoxin oxidoreductase RNF
Fitted models: 8ahx (Avg. Q-score: 0.513)
Deposition Authors: Zhang L
,
Einsle O
Sample: Heptameric complex of NADH:ferredoxin oxidoreductase RNF
Fitted models: 8ahx (Avg. Q-score: 0.513)
Deposition Authors: Zhang L
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Architecture of the RNF1 complex that drives biological nitrogen fixation.
Abstract:
Biological nitrogen fixation requires substantial metabolic energy in form of ATP as well as low-potential electrons that must derive from central metabolism. During aerobic growth, the free-living soil diazotroph Azotobacter vinelandii transfers electrons from the key metabolite NADH to the low-potential ferredoxin FdxA that serves as a direct electron donor to the dinitrogenase reductases. This process is mediated by the RNF complex that exploits the proton motive force over the cytoplasmic membrane to lower the midpoint potential of the transferred electron. Here we report the cryogenic electron microscopy structure of the nitrogenase-associated RNF complex of A. vinelandii, a seven-subunit membrane protein assembly that contains four flavin cofactors and six iron-sulfur centers. Its function requires the strict coupling of electron and proton transfer but also involves major conformational changes within the assembly that can be traced with a combination of electron microscopy and modeling.
Biological nitrogen fixation requires substantial metabolic energy in form of ATP as well as low-potential electrons that must derive from central metabolism. During aerobic growth, the free-living soil diazotroph Azotobacter vinelandii transfers electrons from the key metabolite NADH to the low-potential ferredoxin FdxA that serves as a direct electron donor to the dinitrogenase reductases. This process is mediated by the RNF complex that exploits the proton motive force over the cytoplasmic membrane to lower the midpoint potential of the transferred electron. Here we report the cryogenic electron microscopy structure of the nitrogenase-associated RNF complex of A. vinelandii, a seven-subunit membrane protein assembly that contains four flavin cofactors and six iron-sulfur centers. Its function requires the strict coupling of electron and proton transfer but also involves major conformational changes within the assembly that can be traced with a combination of electron microscopy and modeling.