EZH2-mediated H3K27me3 links microbial inosine loss to depression: a gut-brain epigenetic switch.

IF 13.3 1区医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL

Theranostics Pub Date : 2025-09-12 eCollection Date: 2025-01-01 DOI:10.7150/thno.120824

Sen Zhu, Xuan Li, Ying Yu, Xiaoyi Han, Fang Yang, Mengxi Lu, Gaole Dai, Liang Guo, Dan Xu

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Abstract

Background: Depression, the second most prevalent neurological disorder globally, affects over 300 million people and presents an urgent public health challenge. While gut microbiota dysbiosis is increasingly recognized as a key contributor to depression, the molecular mechanisms linking microbial imbalance to brain dysfunction remain poorly defined. Methods: We investigated the role of EZH2 in gut microbiota-induced depressive behaviors in mice using the chronic unpredictable mild stress (CUMS), fecal microbiota transplantation, and conditional knockout of EZH2. CUT&Tag sequencing was employed to analyze EZH2-mediated H3K27me3 epigenetic reprogramming. Untargeted metabolomics and luciferase reporter assays were used to identify metabolites that upregulate EZH2 expression. 16S rRNA sequencing combined with metabolic tracing was conducted to trace the microbial origin of inosine. Additionally, natural compound screening identified coumaric acid (CA) as a novel EZH2-targeting degrader. Results: Conditional knockout of neuronal Ezh2 abolishes microbiota-induced depressive behaviors and neuronal apoptosis. Mechanistically, reduced abundance of specific microbiota (f_Lachnospiraceae, f_Oscillospiraceae, and f_Erysipelotricaceae) leads to inosine depletion. This depletion subsequently elevates EZH2 transcriptional activity by increasing H3K9ac modification at its locus, mediated through attenuation of the A2aR-cAMP-PKA-CREB-HDAC3 signaling axis. Subsequently, EZH2 silences serotonergic synapse-related genes (e.g., Tph2, Htr2a, Htr6) via H3K27me3 reprogramming, ultimately driving depressive behaviors and neuronal apoptosis in mice. Importantly, CA is identified as a first-in-class EZH2 degrader that binds lysine residues K623/K646 and recruits UBE3A for proteasomal degradation. CA treatment restores synaptic integrity and reverses depressive behaviors with minimal toxicity. Conclusions: Collectively, these findings define a novel "microbiota-inosine-EZH2" axis in depression pathogenesis and highlight EZH2 degradation as a promising therapeutic strategy for microbiota-associated neuropsychiatric disorders.

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ezh2介导的H3K27me3将微生物肌苷损失与抑郁症联系起来：肠-脑表观遗传开关。

背景：抑郁症是全球第二大最常见的神经系统疾病，影响着3亿多人，是一项紧迫的公共卫生挑战。虽然肠道微生物群失调越来越被认为是抑郁症的关键因素，但将微生物失衡与大脑功能障碍联系起来的分子机制仍不明确。方法：我们通过慢性不可预测轻度应激（CUMS）、粪便微生物群移植和条件敲除EZH2来研究EZH2在肠道微生物诱导的小鼠抑郁行为中的作用。采用CUT&Tag测序分析ezh2介导的H3K27me3表观遗传重编程。非靶向代谢组学和荧光素酶报告基因检测用于鉴定上调EZH2表达的代谢物。采用16S rRNA测序结合代谢示踪法对肌苷的微生物来源进行追踪。此外，天然化合物筛选发现香豆酸（CA）是一种新的ezh2靶向降解剂。结果：条件敲除神经元Ezh2可消除微生物诱导的抑郁行为和神经元凋亡。机制上，特定微生物群（f_Lachnospiraceae， f_Oscillospiraceae和f_丹毒菌科）丰度的降低导致肌苷耗竭。这种缺失随后通过A2aR-cAMP-PKA-CREB-HDAC3信号轴的衰减，通过增加其位点的H3K9ac修饰，从而提高EZH2的转录活性。随后，EZH2通过H3K27me3重编程使5 -羟色胺能突触相关基因（如Tph2、Htr2a、Htr6）沉默，最终导致小鼠抑郁行为和神经元凋亡。重要的是，CA被鉴定为一流的EZH2降解物，它结合赖氨酸残基K623/K646并招募UBE3A进行蛋白酶体降解。CA治疗恢复突触完整性，以最小的毒性逆转抑郁行为。结论：总的来说，这些发现在抑郁症发病机制中定义了一个新的“微生物群-肌苷-EZH2”轴，并强调了EZH2降解是一种有希望的治疗微生物群相关神经精神疾病的策略。

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.