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Relationships ranging from cup changeover heat, and you can desiccation and heat threshold in Salmonella enterica

Relationships ranging from cup changeover heat, and you can desiccation and heat threshold in Salmonella enterica

Matchmaking between mug change heat, and you will desiccation as well as heat threshold within the Salmonella enterica

Pathogenic bacteria such as Salmonella enterica exhibit high desiccation tolerance, enabling long-term survival in low water activity (aw) environments. Although there are many reports on the effects of low aw on bacterial survival, the mechanism by which bacteria acquire desiccation tolerance and resistance to heat inactivation in low-aw foods remains unclear. We focused on the glass transition phenomenon, as bacteria may acquire environmental tolerance by state change due to glass transition. In this study, we determined the glass transition temperature (Tg) in S. enterica serovars under different aw conditions using thermal rheological analysis (TRA). The softening behaviour associated with the state change of bacterial cells was confirmed by TRA, and Tg was determined from the softening behaviour. Tg increased as the aw ple, while the Tg of five S. enterica serovars was determined as °C to °C at 0.87 aw, the Tg of all the five serovars increased by °C to °C at 0.43 aw. Furthermore, to verify the thermal tolerance of bacterial cells, a thermal inactivation assay was conducted at 60°C for 10 min under each aw condition. A higher survival ratio was observed as aw decreased; this represented an increase in Tg for Salmonella strains. These results suggest that the glass transition phenomenon of bacterial cells would associate with environmental tolerance.

Citation: Lee K, Shoda M, Kawai K, Koseki S (2020) Matchmaking anywhere between mug changeover heat, and you may desiccation as well as heat endurance from inside the Salmonella enterica. PLoS One 15(5): e0233638.

Copyright: © 2020 Lee ainsi que al. This can be an unbarred accessibility article distributed under the regards to new Innovative Commons Attribution Permit, hence it allows open-ended explore, shipping, and breeding in virtually any average, offered the original blogger and you may source was credited.

Funding: So it really works is supported by the brand new The japanese Area to the Campaign off Science (JSPS) KAKENHI (Grant JP 18H02148) offered to help you SK. The brand new funders had no character for the study construction, study collection and you will data, decision to share, or preparation of your own manuscript.

Introduction

Outbreaks of foodborne illnesses caused by dry foods, such as nuts [1–3], chocolate [4–8], cereals , and other foods are continuing worldwide [10–12]. Such foods have low water activity (aw) and the growth of bacteria causing foodborne illness is not observed. Therefore, microbiological hygiene control has not been regarded as important. However, cases of foodborne illness caused by dry food occur frequently, which means that pathogenic bacteria continue to survive even in a low-aw environment. Especially, various Salmonella serotypes were found in dry foods associated with outbreaks [1–12]. Indeed, several reports have shown that bacteria causing food poisoning such as enterohemorrhagic Escherichia coli (EHEC) and Salmonella, continue to survive for long periods in a low-aw environment [13–21]. On the contrary, the rate of bacterial survival decreases under high aw environments [16,22–24], and it is inferred that aw and the water content of bacteria have some influence on survival. From these previous studies, we consider that there are some associations between aw and desiccation tolerance of bacterial cells. However, the mechanism of desiccation tolerance of bacterial cells under low-aw conditions has not yet been clarified and elucidation of the cause is required.

There is a clue to elucidation of the mechanism of desiccation tolerance in other organisms. For example, extreme environment microorganisms, such as tardigrades and sleeping chironomids that utilize cryptobiosis, are resistant to various external environments such as high temperature, high pressure, as well as dry environments [25–27] blackpeoplemeet. In this study, we assume that bacterial cells would vitrify as well as extreme environmental organisms are considered to acquire environmental stress tolerance. Vitrification of bacterial cells by the glass transition phenomenon might be one of the long-term survival factors in a low-aw environment. The glass transition phenomenon refers to a state change caused by the increase or decrease in molecular movement in a substance as the temperature and moisture content change [28–30]. The state in which molecular movement is limited, due to the decrease in temperature and aw, is called a glass state and the substance shows physical properties similar to a solid. Since molecular motion is almost stopped in the glass state, the substance or organism shows high tolerance to various environmental stresses such as heat, desiccation, and pressure. In the present study, we hypothesized that bacterial cells are vitrified in low-aw environments based on the physicochemical properties of solid particles. In other words, we assumed that bacterial cells enter a glass state due to a decrease in molecular movement accompanying a decrease in aw, making it difficult for the bacteria to be influenced by external factors. This, in turn, allows for long-term survival, even in a dry environment.