Characterization of Hsp17, a Novel Small Heat Shock Protein, in Sphingomonas Melonis TY Under Heat Stress

Overview

Journal Microbiol Spectr

Specialty Microbiology

Date 2023 Jul 12

PMID 37436164

Authors

Yihan Wang

Xiaoyu Wang

Hao Wu

Lvjing Wang

Haixia Wang

Zhenmei Lu

Affiliations

Soon will be listed here.

Abstract

Bacteria are constantly exposed to a variety of environmental stresses. Temperature is considered one of the most important environmental factors affecting microbial growth and survival. As ubiquitous environmental microorganisms, species play essential roles in the biodegradation of organic contaminants, plant protection, and environmental remediation. Understanding the mechanism by which they respond to heat shock will help further improve cell resistance by applying synthetic biological strategies. Here, we assessed the transcriptomic and proteomic responses of Sphingomonas melonis TY to heat shock and found that stressful conditions caused significant changes in functional genes related to protein synthesis at the transcriptional level. The most notable changes observed were increases in the transcription (1,857-fold) and protein expression (11-fold) of Hsp17, which belongs to the small heat shock protein family, and the function of Hsp17 in heat stress was further investigated in this study. We found that the deletion of reduced the capacity of the cells to tolerate high temperatures, whereas the overexpression of significantly enhanced the ability of the cells to withstand high temperatures. Moreover, the heterologous expression of in Escherichia coli DH5α conferred to the bacterium the ability to resist heat stress. Interestingly, its cells were elongated and formed connected cells following the increase in temperature, while overexpression restored their normal morphology under high temperature. In general, these results indicate that the novel small heat shock protein Hsp17 greatly contributes to maintaining cell viability and morphology under stress conditions. Temperature is generally considered the most important factor affecting metabolic functions and the survival of microbes. As molecular chaperones, small heat shock proteins can prevent damaged protein aggregation during abiotic stress, especially heat stress. species are widely distributed in nature, and they can frequently be found in various extreme environments. However, the role of small heat shock proteins in under high-temperature stress has not been elucidated. This study greatly enhances our understanding of a novel identified protein, Hsp17, in TY in terms of its ability to resist heat stress and maintain cell morphology under high temperature, leading to a broader understanding of how microbes adapt to environmental extremes. Furthermore, our study will provide potential heat resistance elements for further enhancing cellular resistance as well as the synthetic biological applications of .

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