Improvement of Acetaldehyde Production in by Engineering of Its Aerobic Metabolism

Overview

Journal Front Microbiol

Specialty Microbiology

Date 2019 Dec 5

PMID 31798541

Citations 17

Authors

Uldis Kalnenieks

Elina Balodite

Steffi Strahler

Inese Strazdina

Julia Rex

Agris Pentjuss

Katsuya Fuchino

Per Bruheim

Reinis Rutkis

Katherine M Pappas

Robert K Poole

Oliver Sawodny

Katja Bettenbrock

Affiliations

Soon will be listed here.

Abstract

Acetaldehyde is a valuable product of microbial biosynthesis, which can be used by the chemical industry as the entry point for production of various commodity chemicals. In ethanologenic microorganisms, like yeast or the bacterium , this compound is the immediate metabolic precursor of ethanol. In aerobic cultures of , it accumulates as a volatile, inhibitory byproduct, due to the withdrawal of reducing equivalents from the alcohol dehydrogenase reaction by respiration. The active respiratory chain of with its low energy-coupling efficiency is well-suited for regeneration of NAD under conditions when acetaldehyde, but not ethanol, is the desired catabolic product. In the present work, we sought to improve the capacity to synthesize acetaldehyde, based on predictions of a stoichiometric model of its central metabolism developed herein. According to the model analysis, the main objectives in the course of engineering acetaldehyde producer strains were determined to be: (i) reducing ethanol synthesis via reducing the activity of alcohol dehydrogenase (ADH), and (ii) enhancing the respiratory capacity, either by overexpression of the respiratory NADH dehydrogenase (NDH), or by mutation of other components of respiratory metabolism. Several mutants with elevated respiration rate, decreased alcohol dehydrogenase activity, or a combination of both, were obtained. They were extensively characterized by determining their growth rates, product yields, oxygen consumption rates, ADH, and NDH activities, transcription levels of key catabolic genes, as well as concentrations of central metabolites under aerobic culture conditions. Two mutant strains were selected, with acetaldehyde yield close to 70% of the theoretical maximum value, almost twice the previously published yield for . These strains can serve as a basis for further development of industrial acetaldehyde producers.

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