增加饮食中的胆固醇可增强黑腹果蝇的耐寒性。

Increased dietary cholesterol enhances cold tolerance in Drosophila melanogaster.

作者信息

Shreve Scott M, Yi Shu-Xia, Lee Richard E

机构信息

Department of Zoology, Miami University, Oxford, Ohio 45056, USA.

出版信息

Cryo Letters. 2007 Jan-Feb;28(1):33-7.

PMID:17369960

Abstract

For many years, non-freezing cold shock injury has been associated with damage to the cell membrane. In this study, we enhanced membrane cholesterol levels of Drosophila melanogaster by raising larvae on a cholesterol-augmented diet. Diet augmentation significantly increased the amount of cholesterol in the cell membranes of the adult flies (1.57+/-0.17 nmol per mg vs. 0.93+/-0.11 nmol per mg). Flies on the cholesterol-augmented diet exhibited a greater intrinsic cold tolerance: this group had a higher survival rate after a 2-h cold shock of -5 degree C than did the control group (71.0+/-6.6 percent vs 36.0+/-8.1 percent). Cholesterol-augmented flies also had a significantly greater capacity to rapidly cold-harden to -7 degree C (36.7+/-4.4 percent) compared to flies on a control diet (20.0+/-2.9 percent). These results suggest a mechanistic link between protection from chilling or cold shock injury and modifications to the cellular membrane.

摘要

多年来，非冻伤性冷休克损伤一直与细胞膜损伤有关。在本研究中，我们通过用富含胆固醇的饮食饲养幼虫来提高黑腹果蝇细胞膜胆固醇水平。饮食强化显著增加了成年果蝇细胞膜中的胆固醇含量（每毫克1.57±0.17纳摩尔，而对照组为每毫克0.93±0.11纳摩尔）。食用富含胆固醇饮食的果蝇表现出更强的内在耐寒性：在-5℃冷休克2小时后，该组的存活率高于对照组（71.0±6.6%对36.0±8.1%）。与食用对照饮食的果蝇相比，富含胆固醇的果蝇快速冷适应至-7℃的能力也显著更强（36.7±4.4%对20.0±2.9%）。这些结果表明免受寒冷或冷休克损伤的保护与细胞膜修饰之间存在机制联系。

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增加饮食中的胆固醇可增强黑腹果蝇的耐寒性。

Increased dietary cholesterol enhances cold tolerance in Drosophila melanogaster.

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