Redirecting Electron Flow in Acetobacterium Woodii Enables Growth on CO and Improves Growth on Formate

Overview

Journal Nat Commun

Specialty Biology

Date 2024 Jun 26

PMID 38926344

Authors

Jimyung Moon

Anja Poehlein

Rolf Daniel

Volker Muller

Affiliations

Soon will be listed here.

Abstract

Anaerobic, acetogenic bacteria are well known for their ability to convert various one-carbon compounds, promising feedstocks for a future, sustainable biotechnology, to products such as acetate and biofuels. The model acetogen Acetobacterium woodii can grow on CO, formate or methanol, but not on carbon monoxide, an important industrial waste product. Since hydrogenases are targets of CO inhibition, here, we genetically delete the two [FeFe] hydrogenases HydA2 and HydBA in A. woodii. We show that the ∆hydBA/hydA2 mutant indeed grows on CO and produces acetate, but only after a long adaptation period. SNP analyzes of CO-adapted cells reveal a mutation in the HycB2 subunit of the HydA2/HydB2/HydB3/Fdh-containing hydrogen-dependent CO reductase (HDCR). We observe an increase in ferredoxin-dependent CO reduction and vice versa by the HDCR in the absence of the HydA2 module and speculate that this is caused by the mutation in HycB2. In addition, the CO-adapted ∆hydBA/hydA2 mutant growing on formate has a final biomass twice of that of the wild type.

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