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鸭沙门氏菌脂多糖的结构及噬菌体灭活能力随生长温度的变化

Variation in the structure and bacteriophage-inactivating capacity of Salmonella anatum lipopolysaccharide as a function of growth temperature.

作者信息

McConnell M, Wright A

出版信息

J Bacteriol. 1979 Feb;137(2):746-51. doi: 10.1128/jb.137.2.746-751.1979.

DOI:10.1128/jb.137.2.746-751.1979
PMID:422511
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC218352/
Abstract

Growth temperature affects both the structure and the phage-inactivating capacity of Salmonella anatum A1 lipopolysaccharide. Whereas S. anatum cells normally synthesize smooth lipopolysaccharide when grown at physiological temperature (37 degrees C), a partial smooth-rough transition occurs when cells are grown at low temperature (20 to 25 degrees C). The synthesis at low growth temperature of lipopolysaccharide molecules lacking O-antigen was detected both by increased sensitivity of cells to the rough-specific bacteriophage Felix O-1 and by fractionation of oligosaccharides derived from lipopolysaccharide by mild acid hydrolysis. Growth temperature-induced changes in the structure of S. anatum A1 lipopolysaccharide also affected its ability to inactivate epsilon15, a bacteriophage that binds initially to the O-antigen portion of the molecule. Purified lipopolysaccharide prepared from cells grown at low growth temperature exhibited a higher in vitro phage-inactivating capacity than did lipopolysaccharide prepared from cells grown at physiological temperature (37 degrees C).

摘要

生长温度会影响鸭沙门氏菌A1脂多糖的结构和噬菌体灭活能力。鸭沙门氏菌细胞在生理温度(37℃)下生长时通常合成光滑型脂多糖,而在低温(20至25℃)下生长时会发生部分光滑型向粗糙型的转变。通过细胞对粗糙特异性噬菌体Felix O-1的敏感性增加以及通过温和酸水解对脂多糖衍生的寡糖进行分级分离,检测到在低生长温度下缺乏O抗原的脂多糖分子的合成。生长温度诱导的鸭沙门氏菌A1脂多糖结构变化也影响了其灭活ε15的能力,ε15是一种最初结合到该分子O抗原部分的噬菌体。从在低生长温度下生长的细胞制备的纯化脂多糖比从在生理温度(37℃)下生长的细胞制备的脂多糖表现出更高的体外噬菌体灭活能力。

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