Abstract

Here, we report recent progress our laboratories have made in understanding the maturation and reaction mechanism of the cytosolic and NAD+-dependent formate dehydrogenase from Cupriavidus necator. Our recent work has established that the enzyme is fully capable of catalyzing the reverse of the physiological reaction, namely, the reduction of CO2 to formate using NADH as a source of reducing equivalents. The steady-state kinetic parameters in the forward and reverse directions are consistent with the expected Haldane relationship. The addition of an NADH-regenerating system consisting of glucose and glucose dehydrogenase increases the yield of formate approximately 10-fold. This work points to possible ways of optimizing the reverse of the enzyme’s physiological reaction with commercial potential as an effective means of CO2 remediation. New insight into the maturation of the enzyme comes from the recently reported structure of the FdhD sulfurase. In E. coli, FdhD transfers a catalytically essential sulfur to the maturing molybdenum cofactor prior to insertion into the apoenzyme of formate dehydrogenase FdhF, which has high sequence similarity to the molybdenum-containing domain of the C. necator FdsA. The FdhD structure suggests that the molybdenum cofactor may first be transferred from the sulfurase to the C-terminal cap domain of apo formate dehydrogenase, rather than being transferred directly to the body of the apoenzyme. Closing of the cap domain over the body of the enzymes delivers the Mo-cofactor into the active site, completing the maturation of formate dehydrogenase. The structural and kinetic characterization of the NADH reduction of the FdsBG subcomplex of the enzyme provides further insights in reversing of the formate dehydrogenase reaction. Most notably, we observe the transient formation of a neutral semiquinone FMNH·, a species that has not been observed previously with holoenzyme. After initial reduction of the FMN of FdsB by NADH to the hydroquinone (with a kred of 680 s−1 and Kd of 190 µM), one electron is rapidly transferred to the Fe2S2 cluster of FdsG, leaving FMNH·. The Fe4S4 cluster of FdsB does not become reduced in the process. These results provide insight into the function not only of the C. necator formate dehydrogenase but also of other members of the NADH dehydrogenase superfamily of enzymes to which it belongs.

Highlights

  • The molybdenum- and tungsten-dependent formate dehydrogenases have drawn increased attention over the past 5–10 years due to the demonstration that under the appropriate conditions, most, if not all, are able to catalyze the reverse reaction, reduction of CO2 to formate, under the appropriate conditions

  • The cytosolic and NAD+ -dependent formate dehydrogenase is fully capable of catalyzing the reduction of CO2 to formate using NADH as a source of reducing equivalents

  • The addition of an NADH-regenerating system consisting of glucose and glucose dehydrogenase increases the yield of formate approximately 10-fold, suggesting the commercial potential of the enzyme as an effective means of CO2 remediation

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Summary

Introduction

The molybdenum- and tungsten-dependent formate dehydrogenases have drawn increased attention over the past 5–10 years due to the demonstration that under the appropriate conditions, most, if not all, are able to catalyze the reverse reaction, reduction of CO2 to formate, under the appropriate conditions. Cupriavidus necator H16 (previously known as Ralstonia eutropha) has four formate dehydrogenases, of which, two are cytosolic enzymes that utilize NAD+ as oxidizing substrate [1,2]. One of these contains molybdenum and is encoded by the fdsGBACD operon, the other possesses tungsten and is encoded by the fdwAB operon (presumably enlisting additional subunits from the fds operon) [3]. Inorganics 2020, 8, x FOR PEER REVIEW operating via a ping-pong mechanism with separate sites for the reductive and oxidative half-reactions, is as follows:The Haldane relationship for these parameters for an enzyme, such as formate dehydrogenase forward. Catalysis of CO2 of reduction to formate by C. necator formate dehydrogenase

Catalysis
A comparison the structures of of FdhD andand
The Crystal Structure of FdsBG
The structure
EPR Characterization of the
Rapid-Reaction Kinetics of FdsBG Reduction by NADH
Proposed
The Thioredoxin-Like Domain of FdsB
Concluding Remarks

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