超级休眠孢子作为基于温和萌发-灭活的孢子控制策略的一个障碍

Superdormant Spores as a Hurdle for Gentle Germination-Inactivation Based Spore Control Strategies.

作者信息

Zhang Yifan, Mathys Alexander

机构信息

Sustainable Food Processing Laboratory, Institute of Food, Nutrition and Health, Department of Health Science and Technology, ETH Zurich, Zurich, Switzerland.

出版信息

Front Microbiol. 2019 Jan 4;9:3163. doi: 10.3389/fmicb.2018.03163. eCollection 2018.

DOI:10.3389/fmicb.2018.03163

PMID:30662433

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6328458/

Abstract

Bacterial spore control strategies based on the germination-inactivation principle can lower the thermal load needed to inactivate bacterial spores and thus preserve food quality better. However, the success of this strategy highly depends on the germination of spores, and a subpopulation of spores that fail to germinate or germinate extremely slowly hinders the application of this strategy. This subpopulation of spores is termed 'superdormant (SD) spores.' Depending on the source of the germination stimulus, SD spores are categorized as nutrient-SD spores, Ca-dipicolinic acid SD spores, dodecylamine-SD spores, and high pressure SD spores. In recent decades, research has been done to isolate these different groups of SD spores and unravel the cause of their germination deficiency as well as their germination capacities. This review summarizes the challenges caused by SD spores, their isolation and characterization, the underlying mechanisms of their germination deficiency, and the future research directions needed to tackle this topic in further depth.

摘要

基于萌发-灭活原理的细菌芽孢控制策略可以降低灭活细菌芽孢所需的热负荷，从而更好地保持食品质量。然而，该策略的成功高度依赖于芽孢的萌发，而一小部分未能萌发或萌发极其缓慢的芽孢会阻碍该策略的应用。这部分芽孢被称为“超级休眠（SD）芽孢”。根据萌发刺激源的不同，SD芽孢可分为营养型SD芽孢、吡啶二羧酸钙SD芽孢、十二烷基胺SD芽孢和高压SD芽孢。近几十年来，人们开展了相关研究来分离这些不同类型的SD芽孢，并揭示其萌发缺陷的原因及其萌发能力。本综述总结了SD芽孢带来的挑战、它们的分离与表征、萌发缺陷的潜在机制，以及进一步深入研究该主题所需的未来研究方向。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/f281/6328458/3a8ce129b3d8/fmicb-09-03163-g001.jpg

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超级休眠孢子作为基于温和萌发-灭活的孢子控制策略的一个障碍

Superdormant Spores as a Hurdle for Gentle Germination-Inactivation Based Spore Control Strategies.

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