A Single-Nucleotide Insertion in a Drug Transporter Gene Induces a Thermotolerance Phenotype in Gluconobacter frateurii by Increasing the NADPH/NADP + Ratio via Metabolic Change

Thermotolerant microorganisms are beneficial to the fermentation industry because they reduce the need for cooling and offer other operational advantages. Previously, we obtained a thermally adapted strain by experimental evolution. In the present study, we found only a single G insertion in the ada...

Full description

Saved in:
Bibliographic Details
Published in:Applied and environmental microbiology 2018-05, Vol.84 (10), p.e00354-18
Main Authors: Matsumoto, Nami, Hattori, Hiromi, Matsutani, Minenosuke, Matayoshi, Chihiro, Toyama, Hirohide, Kataoka, Naoya, Yakushi, Toshiharu, Matsushita, Kazunobu
Format: Article
Language:English
Subjects:
Acetic acid
Efflux
Fermentation
High temperature
Insertion
Metabolic flux
Metabolites
Microorganisms
Mutation
NADP
Pentose
Pentose phosphate pathway
Phenotypes
Physiology
Reactive oxygen species
Sorbose
Strains (organisms)
Trehalose
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Thermotolerant microorganisms are beneficial to the fermentation industry because they reduce the need for cooling and offer other operational advantages. Previously, we obtained a thermally adapted strain by experimental evolution. In the present study, we found only a single G insertion in the adapted strain, which causes a frameshift in a gene encoding a putative drug transporter. A mutant derivative strain with the single G insertion in the transporter gene (Wild-G) was constructed from the wild-type strain and showed increased thermotolerance. We found that the thermotolerant strains accumulated substantial intracellular trehalose and manifested a defect in sorbose assimilation, suggesting that the transporter is partly involved in trehalose efflux and sorbose uptake and that the defect in the transporter can improve thermotolerance. The Δ strain, constructed by elimination of the trehalose synthesis gene in the wild type, showed no trehalose production but, unexpectedly, much better growth than the adapted strain at high temperatures. The Δ mutant produced more acetate as the final metabolite than the wild-type strain did. We hypothesized that trehalose does not contribute to thermotolerance directly; rather, a metabolic change including increased carbon flux to the pentose phosphate pathway may be the key factor. The NADPH/NADP ratio was higher in strain Wild-G, and much higher in the Δ strain, than in the wild-type strain. Levels of reactive oxygen species (ROS) were lower in the thermotolerant strains. We propose that the defect of the transporter causes the metabolic flux to generate more NADPH, which may enhance thermotolerance in The biorefinery industry has to ensure that microorganisms are robust and retain their viability and function at high temperatures. Here we show that , an industrially important member of the acetic acid bacteria, exhibited enhanced thermotolerance through the reduction of trehalose excretion after thermal adaptation. Although intracellular trehalose may play a key role in thermotolerance, the molecular mechanisms of action of trehalose in thermotolerance are a matter of debate. Our mutated strain that was defective in trehalose synthase genes, producing no trehalose but a larger amount of acetic acid as the end metabolite instead, unexpectedly showed higher thermotolerance than the wild type. Our adapted and mutated thermotolerant strains showed increased NADPH/NADP ratios and reductions in ROS levels. We concluded th
ISSN:0099-2240
1098-5336
DOI:10.1128/AEM.00354-18