大肠杆菌的脂肪酸组成作为最低生长温度的一个可能控制因素

Fatty Acid Composition of Escherichia coli as a Possible Controlling Factor of the Minimal Growth Temperature.

作者信息

Shaw M K, Ingraham J L

机构信息

Department of Bacteriology, University of California, Davis, California.

出版信息

J Bacteriol. 1965 Jul;90(1):141-6. doi: 10.1128/jb.90.1.141-146.1965.

DOI:10.1128/jb.90.1.141-146.1965

PMID:16562009

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC315606/

Abstract

Shaw, Maxwell K. (University of California, Davis), and John L. Ingraham. Fatty acid composition of Escherichia coli as a possible controlling factor of the minimal growth temperature. J. Bacteriol. 90:141-146. 1965.-If Escherichia coli ML30 is shifted from 37 to 10 C during exponential growth in glucose minimal medium, a 4.5-hr lag results. During this lag, the proportion of unsaturated fatty acids increases in the cellular lipids. However, the adjustment of the fatty acid composition does not appear to be prerequisite to growth at 10 C. If shifts are made to 10 C into minimal medium containing glucose after starvation for glucose at 37 C for 0.5 and 16 hr, the lag periods at 10 C are 4.5 and 6 hr, respectively. Withholding glucose during the lag periods does not affect the duration of the lag periods, but no change in fatty acid composition occurs if glucose is not present. Supplementing the medium with glucose after the lag period permits immediate growth at 10 C; however, the fatty acid composition is still typical of cells grown at 37 C. It is concluded that the fatty acid composition of cells does not determine the minimal temperature of growth.

摘要

肖，马克斯韦尔·K.（加利福尼亚大学戴维斯分校），以及约翰·L.英格拉姆。大肠杆菌的脂肪酸组成作为最低生长温度的一个可能控制因素。《细菌学杂志》90:141 - 146。1965年。——如果在葡萄糖基本培养基中指数生长期间，将大肠杆菌ML30从37℃转移到10℃，会出现4.5小时的延迟期。在这个延迟期内，细胞脂质中不饱和脂肪酸的比例增加。然而，脂肪酸组成的调整似乎不是在10℃生长的先决条件。如果在37℃饥饿葡萄糖0.5小时和16小时后转移到含有葡萄糖的基本培养基中至10℃，在10℃的延迟期分别为4.5小时和6小时。在延迟期内不提供葡萄糖不会影响延迟期的持续时间，但如果没有葡萄糖，脂肪酸组成不会发生变化。在延迟期后向培养基中添加葡萄糖可使细胞在10℃立即生长；然而，脂肪酸组成仍然是在37℃生长的细胞的典型组成。得出的结论是，细胞的脂肪酸组成并不决定最低生长温度。

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Can J Biochem Physiol. 1962 Sep;40:1213-27.

cis-9,10-Methylene hexadecanoic acid from the phospholipids of Escherichia coli.

J Biol Chem. 1961 Oct;236:2615-9.

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大肠杆菌的脂肪酸组成作为最低生长温度的一个可能控制因素

Fatty Acid Composition of Escherichia coli as a Possible Controlling Factor of the Minimal Growth Temperature.

作者信息

Shaw M K, Ingraham J L

机构信息

Department of Bacteriology, University of California, Davis, California.

出版信息

J Bacteriol. 1965 Jul;90(1):141-6. doi: 10.1128/jb.90.1.141-146.1965.

DOI:10.1128/jb.90.1.141-146.1965

PMID:16562009

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC315606/

Abstract

摘要

大肠杆菌的脂肪酸组成作为最低生长温度的一个可能控制因素

Fatty Acid Composition of Escherichia coli as a Possible Controlling Factor of the Minimal Growth Temperature.

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大肠杆菌的脂肪酸组成作为最低生长温度的一个可能控制因素

Fatty Acid Composition of Escherichia coli as a Possible Controlling Factor of the Minimal Growth Temperature.

作者信息

机构信息

出版信息