Acetylation of proximal cysteine-lysine pairs by alcohol metabolism

IF 10.7 1区生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY

Redox Biology Pub Date : 2025-02-01 DOI:10.1016/j.redox.2024.103462

Courtney D. McGinnis, Peter S. Harris, Brenton I.M. Graham, John O. Marentette, Cole R. Michel, Laura M. Saba, Richard Reisdorph, James R. Roede, Kristofer S. Fritz

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Abstract

Alcohol consumption induces hepatocyte damage through complex processes involving oxidative stress and disrupted metabolism. These factors alter proteomic and epigenetic marks, including alcohol-induced protein acetylation, which is a key post-translational modification (PTM) that regulates hepatic metabolism and is associated with the pathogenesis of alcohol-associated liver disease (ALD). Recent evidence suggests lysine acetylation occurs when a proximal cysteine residue is within ∼15 Å of a lysine residue, referred to as a cysteine-lysine (Cys-Lys) pair. Here, acetylation can occur through the transfer of an acetyl moiety via an S → N transfer reaction. Alcohol-mediated redox stress is known to occur coincidentally with lysine acetylation, yet the biochemical mechanisms related to cysteine and lysine crosstalk within ALD remain unexplored. A murine model of ALD was employed to quantify hepatic cysteine redox changes and lysine acetylation, revealing that alcohol metabolism significantly reduced the cysteine thiol proteome and increased protein acetylation. Interrogating both cysteine redox and lysine acetylation datasets, 1280 protein structures generated by AlphaFold2 represented by a 3D spatial matrix were used to quantify the distances between 557,815 cysteine and lysine residues. Our analysis revealed that alcohol metabolism induces redox changes and acetylation selectively on proximal Cys-Lys pairs with an odds ratio of 1.88 (p < 0.0001). Key Cys-Lys redox signaling hubs were impacted in metabolic pathways associated with ALD, including lipid metabolism and the electron transport chain. Proximal Cys-Lys pairs exist as sets with four major motifs represented by the number of Cys and Lys residues that are pairing (Cys₁:Lys₁, Cys_x:Lys₁, Cys₁:Lys_x and Cys_x:Lys_x) each with a unique microenvironment. The motifs are composed of functionally relevant Cys-Ly altered within ALD, identifying potential therapeutic targets. Furthermore, these unique Cys-Lys redox signatures are translationally relevant as revealed by orthologous comparison with severe alcohol-associated hepatitis (SAH) explants, revealing numerous pathogenic thiol redox signals in these patients.

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近端半胱氨酸-赖氨酸对在酒精代谢中的乙酰化。

酒精消耗通过涉及氧化应激和代谢紊乱的复杂过程诱导肝细胞损伤。这些因素改变了蛋白质组学和表观遗传标记，包括酒精诱导的蛋白质乙酰化，这是一种关键的翻译后修饰（PTM），调节肝脏代谢，并与酒精相关性肝病（ALD）的发病机制有关。最近的证据表明，当近端半胱氨酸残基位于赖氨酸残基的~ 15 Å以内时，赖氨酸乙酰化发生，称为半胱氨酸-赖氨酸（Cys-Lys）对。在这里，乙酰化可以通过S→N转移反应发生乙酰基部分的转移。已知酒精介导的氧化还原应激与赖氨酸乙酰化同时发生，但与ALD中半胱氨酸和赖氨酸串音相关的生化机制仍未探索。采用小鼠ALD模型量化肝脏半胱氨酸氧化还原变化和赖氨酸乙酰化，发现酒精代谢显著降低了半胱氨酸硫醇蛋白质组，增加了蛋白质乙酰化。对半胱氨酸氧化还原和赖氨酸乙酰化数据集进行查询，利用AlphaFold2生成的1280个蛋白质结构用三维空间矩阵表示，量化了557,815个半胱氨酸和赖氨酸残基之间的距离。我们的分析显示，酒精代谢选择性地诱导近端Cys-Lys对的氧化还原变化和乙酰化，比值比为1.88 （p < 0.0001）。关键的Cys-Lys氧化还原信号中枢在与ALD相关的代谢途径中受到影响，包括脂质代谢和电子传递链。近端Cys-Lys对以配对的Cys和Lys残基数量表示的四个主要基序（Cys1:Lys1, Cysx:Lys1， Cys1:Lysx和Cysx:Lysx）的集合存在，每个基序都具有独特的微环境。这些基序由在ALD中改变的功能相关的Cys-Ly组成，确定了潜在的治疗靶点。此外，通过与严重酒精相关性肝炎（SAH）外植体的同源比较，这些独特的Cys-Lys氧化还原信号与翻译相关，揭示了这些患者中许多致病性硫醇氧化还原信号。

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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来源期刊

Redox Biology BIOCHEMISTRY & MOLECULAR BIOLOGY-

CiteScore

19.90

自引率

3.50%

发文量

318

审稿时长

25 days

期刊介绍： Redox Biology is the official journal of the Society for Redox Biology and Medicine and the Society for Free Radical Research-Europe. It is also affiliated with the International Society for Free Radical Research (SFRRI). This journal serves as a platform for publishing pioneering research, innovative methods, and comprehensive review articles in the field of redox biology, encompassing both health and disease. Redox Biology welcomes various forms of contributions, including research articles (short or full communications), methods, mini-reviews, and commentaries. Through its diverse range of published content, Redox Biology aims to foster advancements and insights in the understanding of redox biology and its implications.