Nonenzymatic lysine d-lactylation induced by glyoxalase II substrate SLG dampens inflammatory immune responses

IF 28.1 1区生物学 Q1 CELL BIOLOGY

Cell Research Pub Date : 2025-01-06 DOI:10.1038/s41422-024-01060-w

Qihang Zhao, Qiang Wang, Qinghua Yao, Zhengdong Yang, Wenfang Li, Xiaojie Cheng, Yingling Wen, Rong Chen, Junfang Xu, Xuanying Wang, Dexiang Qin, Shuyang Zhu, Liujie He, Nan Li, Yanfeng Wu, Yizhi Yu, Xuetao Cao, Pin Wang

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Abstract

Immunometabolism is critical in the regulation of immunity and inflammation; however, the mechanism of preventing aberrant activation-induced immunopathology remains largely unclear. Here, we report that glyoxalase II (GLO2) in the glycolysis branching pathway is specifically downregulated by NF-κB signaling during innate immune activation via tristetraprolin (TTP)-mediated mRNA decay. As a result, its substrate S-D-lactoylglutathione (SLG) accumulates in the cytosol and directly induces d-lactyllysine modification of proteins. This nonenzymatic lactylation by SLG is greatly facilitated by a nearby cysteine residue, as it initially reacts with SLG to form a reversible S-lactylated thiol intermediate, followed by SN-transfer of the lactyl moiety to a proximal lysine. Lactylome profiling identifies 2255 lactylation sites mostly in cytosolic proteins of activated macrophages, and global protein structure analysis suggests that proximity to a cysteine residue determines the susceptibility of lysine to SLG-mediated d-lactylation. Furthermore, lactylation is preferentially enriched in proteins involved in immune activation and inflammatory pathways, and d-lactylation at lysine 310 (K310) of RelA attenuates inflammatory signaling and NF-κB transcriptional activity to restore immune homeostasis. Accordingly, TTP-binding site mutation or overexpression of GLO2 in vivo blocks this feedback lactylation in innate immune cells and promotes inflammation, whereas genetic deficiency or pharmacological inhibition of GLO2 restricts immune activation and attenuates inflammatory immunopathology both in vitro and in vivo. Importantly, dysregulation of the GLO2/SLG/d-lactylation regulatory axis is closely associated with human inflammatory phenotypes. Overall, our findings uncover an immunometabolic feedback loop of SLG-induced nonenzymatic d-lactylation and implicate GLO2 as a promising target for combating clinical inflammatory disorders.

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乙草醛酶II底物SLG诱导的非酶促赖氨酸d-乳酸化抑制炎症免疫反应

免疫代谢在免疫和炎症的调节中至关重要；然而，预防异常激活诱导的免疫病理的机制在很大程度上仍不清楚。在这里，我们报道了糖酵解分支通路中的glyoxalase II （GLO2）在先天免疫激活过程中通过三戊三酚（TTP）介导的mRNA衰变被NF-κB信号特异性下调。因此，其底物s - d-乳酸谷胱甘肽（SLG）在细胞质中积累，并直接诱导d-乳酸赖氨酸修饰蛋白质。SLG的这种非酶促乳酸化被附近的半胱氨酸残基极大地促进，因为它最初与SLG反应形成可逆的s -乳酸化硫醇中间体，随后将乳酸基部分sn转移到近端赖氨酸。在活化的巨噬细胞的胞质蛋白中鉴定出2255个乳酸化位点，整体蛋白结构分析表明，接近半胱氨酸残基决定了赖氨酸对slg介导的d-乳酸化的易感性。此外，参与免疫激活和炎症途径的蛋白优先富集乳酸化，而RelA赖氨酸310 （K310）的d-乳酸化可减弱炎症信号和NF-κB转录活性，从而恢复免疫稳态。因此，体内ttp结合位点突变或GLO2的过表达阻断了先天免疫细胞的反馈乳酸化并促进炎症，而GLO2的遗传缺陷或药理抑制限制了免疫激活并减轻了体外和体内的炎症免疫病理。重要的是，GLO2/SLG/d-乳酸化调节轴的失调与人类炎症表型密切相关。总的来说，我们的发现揭示了slg诱导的非酶促d-乳酸化的免疫代谢反馈回路，并暗示GLO2是对抗临床炎症疾病的有希望的靶点。

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来源期刊

Cell Research 生物-细胞生物学

CiteScore

53.90

自引率

0.70%

发文量

2420

审稿时长

2.3 months

期刊介绍： Cell Research (CR) is an international journal published by Springer Nature in partnership with the Center for Excellence in Molecular Cell Science, Chinese Academy of Sciences (CAS). It focuses on publishing original research articles and reviews in various areas of life sciences, particularly those related to molecular and cell biology. The journal covers a broad range of topics including cell growth, differentiation, and apoptosis; signal transduction; stem cell biology and development; chromatin, epigenetics, and transcription; RNA biology; structural and molecular biology; cancer biology and metabolism; immunity and molecular pathogenesis; molecular and cellular neuroscience; plant molecular and cell biology; and omics, system biology, and synthetic biology. CR is recognized as China's best international journal in life sciences and is part of Springer Nature's prestigious family of Molecular Cell Biology journals.