Cardiac PDK4 promotes neutrophilic PFKL methylation and drives the innate immune response in diabetic myocardial infarction

IF 9.1 2区医学 Q1 PHARMACOLOGY & PHARMACY

Pharmacological research Pub Date : 2025-04-11 DOI:10.1016/j.phrs.2025.107731

Song Yang , Longxin Yan , Lang Chen , Gaijuan Su , Long Yang , Lili Gong , Lihong Liu

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引用次数: 0

Abstract

NETosis plays a pivotal role in the innate immune response after diabetic myocardial infarction (MI), exerting a profound influence on the overall pathological process and potential recovery outcomes. The metabolism of diabetic cardiomyocyte actively creates a specialized micro environment for the innate immune response after MI. However, the mechanism by which cardiac metabolism drives NETosis remains unclear. Utilizing public databases of human MI sc-RNA datasets, we discovered that cardiomyocyte PDK4 expression mediates the intensification of glycolysis, which is strongly correlated with NETosis. Through mass spectrometry imaging and phenotype assessment, we ascertained that specific knockout of PDK4 in cardiomyocytes (PDK4^fl/flMyh6^Cre, male, 6 weeks) led to a reduction in NETosis by restraining micro environmental lactate (LA) production. In addition, the role of LA in promoting NETosis has been further corroborated by in vivo/in vitro experiments involving LA supplementation and its absence. Moreover, LA redirects neutrophil metabolic flux from glycolysis to the pentose-phosphate pathway (PPP). Mechanistically, LA triggers metabolic remodeling through the PRMT9-mediated methylation of PFKL at the R301 residue, resulting in PFKL inactivation and the consequent restriction of glycolysis. Our findings reveal the crucial role of cardiomyocyte metabolism in NETosis, shedding light on the role of LA as a vital signaling molecule in the crosstalk between cardiomyocytes and neutrophils. Importantly, we screened pitavastatin, a potential inhibitor of PDK4 among the FDA-approved drugs, and verified that it can alleviate NETosis in diabetic MI, which provides a rationale for drug selection in diabetic MI patients.

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心脏 PDK4 促进中性粒细胞 PFKL 甲基化并驱动糖尿病心肌梗死的先天性免疫反应

NETosis在糖尿病性心肌梗死（MI）后的先天免疫反应中起着关键作用，对整个病理过程和潜在的恢复结果有着深远的影响。糖尿病心肌细胞的代谢积极地为心肌梗死后的先天免疫反应创造了一个专门的微环境。然而，心脏代谢驱动NETosis的机制尚不清楚。利用人类MI sc-RNA数据集的公共数据库，我们发现心肌细胞PDK4表达介导糖酵解的增强，这与NETosis密切相关。通过质谱成像和表型评估，我们确定了心肌细胞中PDK4的特异性敲除（PDK4fl/flMyh6Cre，男性，6周）通过抑制微环境乳酸（LA）的产生导致NETosis的减少。此外，LA在促进NETosis中的作用已被补充和不补充LA的体内/体外实验进一步证实。此外，LA将中性粒细胞代谢通量从糖酵解重定向到戊糖-磷酸途径（PPP）。在机制上，LA通过prmt9介导的PFKL在R301残基上的甲基化引发代谢重塑，导致PFKL失活，从而限制糖酵解。我们的研究结果揭示了心肌细胞代谢在NETosis中的关键作用，揭示了LA在心肌细胞和中性粒细胞之间的串扰中作为重要信号分子的作用。重要的是，我们在fda批准的药物中筛选了吡伐他汀，一种潜在的PDK4抑制剂，并验证了它可以缓解糖尿病性心肌梗死的NETosis，这为糖尿病性心肌梗死患者的药物选择提供了依据。

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来源期刊

Pharmacological research 医学-药学

CiteScore

18.70

自引率

3.20%

发文量

491

审稿时长

8 days

期刊介绍： Pharmacological Research publishes cutting-edge articles in biomedical sciences to cover a broad range of topics that move the pharmacological field forward. Pharmacological research publishes articles on molecular, biochemical, translational, and clinical research (including clinical trials); it is proud of its rapid publication of accepted papers that comprises a dedicated, fast acceptance and publication track for high profile articles.