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赖氨酸收获是一种抗氧化策略,并触发地下多胺代谢。

Lysine harvesting is an antioxidant strategy and triggers underground polyamine metabolism.

机构信息

Department of Biochemistry, University of Cambridge, Cambridge, UK.

Department of Nutrition Physiology, Instituto Nacional de Ciencias Médicas y Nutrición Salvador Zubirán, Mexico City, Mexico.

出版信息

Nature. 2019 Aug;572(7768):249-253. doi: 10.1038/s41586-019-1442-6. Epub 2019 Jul 31.

DOI:10.1038/s41586-019-1442-6
PMID:31367038
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6774798/
Abstract

Both single and multicellular organisms depend on anti-stress mechanisms that enable them to deal with sudden changes in the environment, including exposure to heat and oxidants. Central to the stress response are dynamic changes in metabolism, such as the transition from the glycolysis to the pentose phosphate pathway-a conserved first-line response to oxidative insults. Here we report a second metabolic adaptation that protects microbial cells in stress situations. The role of the yeast polyamine transporter Tpo1p in maintaining oxidant resistance is unknown. However, a proteomic time-course experiment suggests a link to lysine metabolism. We reveal a connection between polyamine and lysine metabolism during stress situations, in the form of a promiscuous enzymatic reaction in which the first enzyme of the polyamine pathway, Spe1p, decarboxylates lysine and forms an alternative polyamine, cadaverine. The reaction proceeds in the presence of extracellular lysine, which is taken up by cells to reach concentrations up to one hundred times higher than those required for growth. Such extensive harvest is not observed for the other amino acids, is dependent on the polyamine pathway and triggers a reprogramming of redox metabolism. As a result, NADPH-which would otherwise be required for lysine biosynthesis-is channelled into glutathione metabolism, leading to a large increase in glutathione concentrations, lower levels of reactive oxygen species and increased oxidant tolerance. Our results show that nutrient uptake occurs not only to enable cell growth, but when the nutrient availability is favourable it also enables cells to reconfigure their metabolism to preventatively mount stress protection.

摘要

单细胞和多细胞生物都依赖于抗应激机制,使它们能够应对环境的突然变化,包括暴露在热和氧化剂中。应激反应的核心是代谢的动态变化,例如从糖酵解到戊糖磷酸途径的转变——这是对氧化损伤的保守的一线反应。在这里,我们报告了第二种代谢适应机制,可以保护微生物细胞在应激情况下免受伤害。酵母多胺转运蛋白 Tpo1p 在维持抗氧化能力方面的作用尚不清楚。然而,一项蛋白质组时间进程实验表明它与赖氨酸代谢有关。我们揭示了应激情况下多胺和赖氨酸代谢之间的联系,形式是多胺途径中的第一个酶 Spe1p 脱羧赖氨酸并形成另一种多胺腐胺的混杂酶反应。该反应在细胞外赖氨酸存在的情况下进行,细胞摄取赖氨酸以达到比生长所需浓度高 100 倍的浓度。这种广泛的摄取在其他氨基酸中观察不到,依赖于多胺途径,并触发氧化还原代谢的重新编程。结果,NADPH——否则是赖氨酸生物合成所必需的——被引导到谷胱甘肽代谢中,导致谷胱甘肽浓度大幅增加、活性氧水平降低和抗氧化剂耐受性增加。我们的结果表明,营养物质的摄取不仅是为了促进细胞生长,而且当营养物质供应有利时,它还使细胞能够重新配置其代谢,以预防性地启动应激保护。

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2
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3
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4
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5
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6
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