细菌芽孢的耐热性与含水量、湿密度以及原生质体/芽孢体体积比相关。

Bacterial spore heat resistance correlated with water content, wet density, and protoplast/sporoplast volume ratio.

作者信息

Beaman T C, Greenamyre J T, Corner T R, Pankratz H S, Gerhardt P

出版信息

J Bacteriol. 1982 May;150(2):870-7. doi: 10.1128/jb.150.2.870-877.1982.

DOI:10.1128/jb.150.2.870-877.1982

PMID:6802802

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC216440/

Abstract

Five types of dormant Bacillus spores, between and within species, were selected representing a 600-fold range in moist-heat resistance determined as a D100 value. The wet and dry density and the solids and water content of the entire spore and isolated integument of each type were determined directly from gram masses of material, with correction for interstitial water. The ratio between the volume occupied by the protoplast (the structures bounded by the inner pericytoplasm membrane) and the volume occupied by the sporoplast (the structures bounded by the outer pericortex membrane) was calculated from measurements made on electron micrographs of medially thin-sectioned spores. Among the various spore types, an exponential increase in the heat resistance correlated directly with the wet density and inversely with the water content and with the protoplast/sporoplast volume ratio. Altogether with results supported a hypothesis that the extent of heat resistance is based in whole or in part on the extent of dehydration and diminution of the protoplast in the dormant spore, without implications about physiological mechanisms for attaining this state.

摘要

在种间和种内选择了五种休眠芽孢杆菌孢子，它们的耐热性（以D100值衡量）相差600倍。直接根据材料的克质量测定每种类型的整个孢子和分离的皮层的湿密度和干密度以及固体和水分含量，并对间隙水进行校正。原生质体（由内膜周质膜界定的结构）所占体积与芽孢体（由外皮层膜界定的结构）所占体积之比，是根据对经中间薄切片的孢子的电子显微照片测量得出的。在各种孢子类型中，耐热性呈指数增加，这与湿密度直接相关，与水分含量和原生质体/芽孢体体积比呈反比。所有这些结果支持了一个假设，即耐热程度全部或部分基于休眠孢子中原生质体脱水和缩小的程度，而与达到这种状态的生理机制无关。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6cb6/216440/dfbb05463661/jbacter00258-0444-a.jpg

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细菌芽孢的耐热性与含水量、湿密度以及原生质体/芽孢体体积比相关。

Bacterial spore heat resistance correlated with water content, wet density, and protoplast/sporoplast volume ratio.

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