Abstract
Formate oxidation to carbon dioxide is a key reaction in one-carbon compound metabolism, and its reverse reaction represents the first step in carbon assimilation in the acetogenic and methanogenic branches of many anaerobic organisms. The molybdenum-containing dehydrogenase FdsABG is a soluble NAD+-dependent formate dehydrogenase and a member of the NADH dehydrogenase superfamily. Here, we present the first structure of the FdsBG subcomplex of the cytosolic FdsABG formate dehydrogenase from the hydrogen-oxidizing bacterium Cupriavidus necator H16 both with and without bound NADH. The structures revealed that the two iron-sulfur clusters, Fe4S4 in FdsB and Fe2S2 in FdsG, are closer to the FMN than they are in other NADH dehydrogenases. Rapid kinetic studies and EPR measurements of rapid freeze-quenched samples of the NADH reduction of FdsBG identified a neutral flavin semiquinone, FMNH•, not previously observed to participate in NADH-mediated reduction of the FdsABG holoenzyme. We found that this semiquinone forms through the transfer of one electron from the fully reduced FMNH-, initially formed via NADH-mediated reduction, to the Fe2S2 cluster. This Fe2S2 cluster is not part of the on-path chain of iron-sulfur clusters connecting the FMN of FdsB with the active-site molybdenum center of FdsA. According to the NADH-bound structure, the nicotinamide ring stacks onto the re-face of the FMN. However, NADH binding significantly reduced the electron density for the isoalloxazine ring of FMN and induced a conformational change in residues of the FMN-binding pocket that display peptide-bond flipping upon NAD+ binding in proper NADH dehydrogenases.
Highlights
Formate oxidation to carbon dioxide is a key reaction in onecarbon compound metabolism, and its reverse reaction represents the first step in carbon assimilation in the acetogenic and methanogenic branches of many anaerobic organisms
The physiological function of FdsABG is to oxidize formate to CO2 by reducing NADϩ to NADH [3,4,5,6], the enzyme has been shown to be fully capable of catalyzing the reverse reaction, the reduction of CO2 to formate, using NADH as an electron source with steady-state kinetic parameters that conform to the required Haldane relationship [7]
A similar observation was reported for the expression of Rhodobacter capsulatus FdsABG holoenzyme [17]
Summary
Formate oxidation to carbon dioxide is a key reaction in onecarbon compound metabolism, and its reverse reaction represents the first step in carbon assimilation in the acetogenic and methanogenic branches of many anaerobic organisms. Rapid kinetic studies and EPR measurements of rapid freeze-quenched samples of the NADH reduction of FdsBG identified a neutral flavin semiquinone, FMNH1⁄7, not previously observed to participate in NADH-mediated reduction of the FdsABG holoenzyme We found that this semiquinone forms through the transfer of one electron from the fully reduced FMNH؊, initially formed via NADH-mediated reduction, to the Fe2S2 cluster. Formate dehydrogenase FdsABG forms a dimer of heterotrimers, (␣␥), with the 105-kDa FdsA subunit containing the active site molybdenum center and five iron-sulfur clusters, one Fe2S2 and four Fe4S4 clusters; the 55-kDa FdsB containing an Fe4S4 cluster, FMN, and a binding site for NADH/NADϩ; and the 19-kDa FdsG subunit containing one Fe2S2 cluster. The physiological function of FdsABG is to oxidize formate to CO2 by reducing NADϩ to NADH [3,4,5,6], the enzyme has been shown to be fully capable of catalyzing the reverse reaction, the reduction of CO2 to formate, using NADH as an electron source with steady-state kinetic parameters that conform to the required Haldane relationship [7]
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