Reversible Hydrogenase Activity Confers Flexibility to Balance Intracellular Redox in

Overview

Journal Front Microbiol

Specialty Microbiology

Date 2022 May 31

PMID 35633713

Authors

Shunsuke Kobayashi

Junya Kato

Keisuke Wada

Kaisei Takemura

Setsu Kato

Tatsuya Fujii

Yuki Iwasaki

Yoshiteru Aoi

Tomotake Morita

Akinori Matsushika

Katsuji Murakami

Yutaka Nakashimada

Affiliations

Soon will be listed here.

Abstract

Hydrogen (H) converted to reducing equivalents is used by acetogens to fix and metabolize carbon dioxide (CO) to acetate. The utilization of H enables not only autotrophic growth, but also mixotrophic metabolism in acetogens, enhancing carbon utilization. This feature seems useful, especially when the carbon utilization efficiency of organic carbon sources is lowered by metabolic engineering to produce reduced chemicals, such as ethanol. The potential advantage was tested using engineered strains of that produce ethanol. By adding H to the fructose-supplied culture, the engineered strains produced increased levels of acetate, and a slight increase in ethanol was observed. The utilization of a knockout strain of the major acetate production pathway, aimed at increasing the carbon flux to ethanol, was unexpectedly hindered by H-mediated growth inhibition in a dose-dependent manner. Metabolomic analysis showed a significant increase in intracellular NADH levels due to H in the ethanol-producing strain. Higher NADH level was shown to be the cause of growth inhibition because the decrease in NADH level by dimethyl sulfoxide (DMSO) reduction recovered the growth. When H was not supplemented, the intracellular NADH level was balanced by the reversible electron transfer from NADH oxidation to H production in the ethanol-producing strain. Therefore, reversible hydrogenase activity confers the ability and flexibility to balance the intracellular redox state of . Tuning of the redox balance is required in order to benefit from H-supplemented mixotrophy, which was confirmed by engineering to produce acetone.

Citing Articles

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