Non‐Enzymatic Lysine Lactoylation of Glycolytic Enzymes

The FASEB Journal Pub Date : 2020-04-01 DOI:10.1096/fasebj.2020.34.s1.02010

J. Galligan, Dominique O. Gaffney, E. Jennings, Colin C Anderson, John O. Marentette, Taoda Shi, Anne-Mette Schou Oxvig, Matthew D. Streeter, Mogens Johannsen, David A. Spiegel, Eli Chapman, James R. Roede

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引用次数: 1

Abstract

Post‐translational modifications (PTMs) regulate enzyme structure and function to expand the functional proteome. Many of these PTMs are derived from cellular metabolites and serve as feedback and feed‐forward mechanisms of regulation. We have identified a novel PTM that is derived from the glycolytic by‐product, methylglyoxal. This reactive metabolite is rapidly conjugated to glutathione via glyoxalase 1, generating lactoylglutathione (LGSH). LGSH is hydrolyzed by glyoxalase 2 (GLO2), cycling glutathione and generating D‐lactate. We have identified the non‐enzymatic acyl transfer of the lactate moiety from LGSH to protein Lys residues, generating a ‘LactoylLys’ modification on proteins. GLO2 knockout cells have elevated LGSH and consequently, a marked increase in LactoylLys. Using an alkyne‐tagged methylglyoxal analog, we show that these modifications are enriched on glycolytic enzymes and regulate glycolysis. Collectively, these data suggest a previously unexplored feedback mechanism that may serve to regulate glycolytic flux under hyperglycemic or Warburg‐like conditions.

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糖酵解酶的非酶赖氨酸乳酰化作用

翻译后修饰（PTM）调节酶的结构和功能，从而扩展功能蛋白质组。其中许多 PTM 来自细胞代谢产物，是一种反馈和前馈调节机制。我们发现了一种新型 PTM，它来自糖酵解副产物甲基乙二醛。这种活性代谢物通过乙二醛酶 1 与谷胱甘肽快速共轭，生成乳酰谷胱甘肽（LGSH）。LGSH 被乙二醛酶 2（GLO2）水解，循环谷胱甘肽并生成 D-乳酸。我们发现了 LGSH 中的乳酸分子与蛋白质赖氨酸残基之间的非酶酰基转移，从而在蛋白质上产生 "LactoylLys "修饰。GLO2 基因敲除细胞的 LGSH 升高，因此 LactoylLys 也明显增加。通过使用炔标记的甲基乙二酸类似物，我们发现这些修饰富集在糖酵解酶上，并能调节糖酵解。总之，这些数据表明，在高血糖或类似沃伯格的条件下，一种以前未曾探索过的反馈机制可能起到调节糖酵解通量的作用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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