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乙醇和己醇对大肠杆菌细胞膜的不同作用

Differential effects of ethanol and hexanol on the Escherichia coli cell envelope.

作者信息

Ingram L O, Vreeland N S

出版信息

J Bacteriol. 1980 Nov;144(2):481-8. doi: 10.1128/jb.144.2.481-488.1980.

DOI:10.1128/jb.144.2.481-488.1980
PMID:7000746
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC294694/
Abstract

Both ethanol and hexanol inhibited the growth of Escherichia coli, but their effects on the organization and composition of the cell envelope were quite different. Hexanol (7.8 x 10(-3) mM) increased membrane fluidity, whereas ethanol (0.67 M) had little effect. During growth in the presence of ethanol, the proportion of unsaturated fatty acids increased. The opposite change was induced by hexanol. Unlike hexanol, growth in the presence of ethanol resulted in the production of un-cross-linked peptidoglycan with subsequent lysis. Salt (0.3 M) protected cells against ethanol-induced lysis but potentiated growth inhibition by hexanol. Mutants isolated for resistance to ethanol-induced lysis synthesized cross-linked peptidoglycan during growth in the presence of ethanol but remained sensitive to hexanol. A general hypothesis was presented to explain the differential effects of ethanol and hexanol. All alcohols are viewed as similar in having both an apolar chain capable of interacting with hydrophobic environments and a hydroxyl function capable of hydrogen bonding. The differential effects of short-chain alcohols may represent effects due to the high molar concentrations of hydrogen bonding groups with an apolar end within the environment. These may replace bound water in some cases. With longer-chain alcohols such as hexanol, the effects of the acyl chain would dominate, and limitations of solubility and cellular integrity would mask these hydroxyl effects.

摘要

乙醇和己醇都能抑制大肠杆菌的生长,但它们对细胞包膜的组织结构和组成的影响却大不相同。己醇(7.8×10⁻³ mM)可增加膜流动性,而乙醇(0.67 M)的影响则很小。在乙醇存在下生长时,不饱和脂肪酸的比例会增加。己醇则会引发相反的变化。与己醇不同,在乙醇存在下生长会导致产生未交联的肽聚糖并随后发生裂解。盐(0.3 M)可保护细胞免受乙醇诱导的裂解,但会增强己醇对生长的抑制作用。分离出的对乙醇诱导裂解具有抗性的突变体在乙醇存在下生长时会合成交联的肽聚糖,但对己醇仍敏感。本文提出了一个一般性假设来解释乙醇和己醇的不同作用。所有醇类都被认为具有相似性,即都有一个能够与疏水环境相互作用的非极性链和一个能够形成氢键的羟基官能团。短链醇的不同作用可能是由于环境中具有非极性末端的氢键基团的高摩尔浓度所导致的影响。在某些情况下,这些基团可能会取代结合水。对于像己醇这样的长链醇,酰基链的作用将占主导地位,而溶解度和细胞完整性的限制会掩盖这些羟基的作用。

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