Methyl-CpG-binding 2 K271 lactylation-mediated M2 macrophage polarization inhibits atherosclerosis.

IF 12.4 1区医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL Theranostics Pub Date : 2024-07-08 eCollection Date: 2024-01-01 DOI:10.7150/thno.94738

Liangqi Chen, Meiju Zhang, Xueyan Yang, Yanan Wang, Tuo Huang, Xin Li, Yunting Ban, Qifeng Li, Qingyuan Yang, Yongxiang Zhang, Yang Zheng, Di Wang, Xiaoqi Wang, Xiujie Shi, Maomao Zhang, Yong Sun, Jian Wu

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Abstract

Rationale: Posttranslational modifications of proteins have not been addressed in studies aimed at elucidating the cardioprotective effect of exercise in atherosclerotic cardiovascular disease (ASCVD). In this study, we reveal a novel mechanism by which exercise ameliorates atherosclerosis via lactylation. Methods: Using ApoE^-/- mice in an exercise model, proteomics analysis was used to identify exercise-induced specific lactylation of MeCP2 at lysine 271 (K271). Mutation of the MeCP2 K271 lactylation site in aortic plaque macrophages was achieved by recombinant adenoviral transfection. Explore the molecular mechanisms by which motility drives MeCP2 K271 lactylation to improve plaque stability using ATAC-Seq, CUT &Tag and molecular biology. Validation of the potential target RUNX1 for exercise therapy using Ro5-3335 pharmacological inhibition. Results: we showed that in ApoE^-/- mice, methyl-CpG-binding protein 2 (MeCP2) K271 lactylation was observed in aortic root plaque macrophages, promoting pro-repair M2 macrophage polarization, reducing the plaque area, shrinking necrotic cores, reducing plaque lipid deposition, and increasing collagen content. Adenoviral transfection, by introducing a mutant at lysine 271, overexpressed MeCP2 K271 lactylation, which enhanced exercise-induced M2 macrophage polarization and increased plaque stability. Mechanistically, the exercise-induced atheroprotective effect requires an interaction between MeCP2 K271 lactylation and H3K36me3, leading to increased chromatin accessibility and transcriptional repression of RUNX1. In addition, the pharmacological inhibition of the transcription factor RUNX1 exerts atheroprotective effects by promoting the polarization of plaque macrophages towards the pro-repair M2 phenotype. Conclusions: These findings reveal a novel mechanism by which exercise ameliorates atherosclerosis via MeCP2 K271 lactylation-H3K36me3/RUNX1. Interventions that enhance MeCP2 K271 lactylation have been shown to increase pro-repair M2 macrophage infiltration, thereby promoting plaque stabilization and reducing the risk of atherosclerotic cardiovascular disease. We also established RUNX1 as a potential drug target for exercise therapy, thereby providing guidance for the discovery of new targets.

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甲基-CpG结合2 K271乳化介导的M2巨噬细胞极化可抑制动脉粥样硬化。

理论依据：在旨在阐明运动对动脉粥样硬化性心血管疾病（ASCVD）的心脏保护作用的研究中，尚未涉及蛋白质的翻译后修饰。本研究揭示了运动通过乳化作用改善动脉粥样硬化的新机制。研究方法在运动模型中使用载脂蛋白E-/-小鼠，通过蛋白质组学分析确定运动诱导的MeCP2赖氨酸271（K271）特异性乳化。通过重组腺病毒转染实现了主动脉斑块巨噬细胞中 MeCP2 K271 乳化位点的突变。利用 ATAC-Seq、CUT &Tag 和分子生物学方法探索运动性驱动 MeCP2 K271 乳化以提高斑块稳定性的分子机制。利用 Ro5-3335 药理抑制剂验证运动疗法的潜在靶点 RUNX1。结果：我们发现，在载脂蛋白E-/-小鼠中，主动脉根部斑块巨噬细胞中观察到甲基-CpG结合蛋白2（MeCP2）K271乳酰化，促进促修复M2巨噬细胞极化，减少斑块面积，缩小坏死核心，减少斑块脂质沉积，增加胶原蛋白含量。腺病毒转染通过引入赖氨酸271突变体，过表达MeCP2 K271乳酸化，增强了运动诱导的M2巨噬细胞极化，提高了斑块的稳定性。从机理上讲，运动诱导的动脉粥样硬化保护作用需要 MeCP2 K271 乳化与 H3K36me3 之间的相互作用，从而导致染色质可及性增加和 RUNX1 的转录抑制。此外，药物抑制转录因子 RUNX1 还能促进斑块巨噬细胞向促进修复的 M2 表型极化，从而发挥动脉粥样硬化保护作用。结论：这些发现揭示了运动通过MeCP2 K271乳化-H3K36me3/RUNX1改善动脉粥样硬化的新机制。事实证明，增强 MeCP2 K271 乳酰化的干预措施可增加促进修复的 M2 巨噬细胞浸润，从而促进斑块稳定并降低动脉粥样硬化性心血管疾病的风险。我们还将 RUNX1 确立为运动疗法的潜在药物靶点，从而为发现新靶点提供指导。

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

Theranostics MEDICINE, RESEARCH & EXPERIMENTAL-

CiteScore

25.40

自引率

1.60%

发文量

433

审稿时长

1 months

期刊介绍： Theranostics serves as a pivotal platform for the exchange of clinical and scientific insights within the diagnostic and therapeutic molecular and nanomedicine community, along with allied professions engaged in integrating molecular imaging and therapy. As a multidisciplinary journal, Theranostics showcases innovative research articles spanning fields such as in vitro diagnostics and prognostics, in vivo molecular imaging, molecular therapeutics, image-guided therapy, biosensor technology, nanobiosensors, bioelectronics, system biology, translational medicine, point-of-care applications, and personalized medicine. Encouraging a broad spectrum of biomedical research with potential theranostic applications, the journal rigorously peer-reviews primary research, alongside publishing reviews, news, and commentary that aim to bridge the gap between the laboratory, clinic, and biotechnology industries.