Drp1 acetylation mediated by CDK5-AMPK-GCN5L1 axis promotes cerebral ischemic injury via facilitating mitochondrial fission.

IF 6 2区医学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY

Molecular Medicine Pub Date : 2024-10-10 DOI:10.1186/s10020-024-00948-y

Jiejie Zhang, Shan Wang, Haitao Zhang, Xiaotong Yang, Xin Ren, Lei Wang, Yihan Yang, Yi Yang, Ya Wen

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引用次数: 0

Abstract

The aberrant acetylation of mitochondrial proteins is involved in the pathogenesis of multiple diseases including neurodegenerative diseases and cerebral ischemic injury. Previous studies have shown that depletion of mitochondrial NAD+, which is necessary for mitochondrial deacetylase activity, leads to decreased activity of mitochondrial deacetylase and thus causes hyperacetylation of mitochondrial proteins in ischemic brain tissues, which results in altered mitochondrial dynamics. However, it remains largely unknown about how mitochondrial dynamics-related protein Drp1 is acetylated in ischemic neuronal cells and brain tissues. Here, we showed that Drp1 and GCN5L1 expression was up-regulated in OGD-treated neuronal cells and ischemic brain tissues induced by dMCAO, accompanied by the increased mitochondrial fission, mtROS accumulation, and cell apoptosis. Further, we confirmed that ischemia/hypoxia promoted Drp1 interaction with GCN5L1 in neuronal cells and brain tissues. GCN5L1 knockdown attenuated, while its overexpression enhanced Drp1 acetylation and mitochondrial fission, indicating that GCN5L1 plays a crucial role in ischemia/hypoxia-induced mitochondrial fission by acetylating Drp1. Mechanistically, ischemia/hypoxia induced Drp1 phosphorylation by CDK5 upregulation-mediated activation of AMPK in neuronal cells, which in turn facilitated the interaction of GCN5L1 with Drp1, thus enhancing Drp1 acetylation and mitochondrial fission. Accordingly, inhibition of AMPK alleviated ischemia/hypoxia- induced Drp1 acetylation and mitochondrial fission and protected brain tissues from ischemic damage. These findings provide a novel insight into the functional roles of GCN5L1 in regulating Drp1 acetylation and identify a previously unrecognized CDK5-AMPK-GCN5L1 pathway that mediates the acetylation of Drp1 in ischemic brain tissues.

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CDK5-AMPK-GCN5L1轴介导的Drp1乙酰化通过促进线粒体裂变促进脑缺血损伤。

线粒体蛋白的乙酰化异常与神经退行性疾病和脑缺血损伤等多种疾病的发病机制有关。先前的研究表明，线粒体脱乙酰化酶活性所必需的线粒体 NAD+ 的耗竭会导致线粒体脱乙酰化酶活性降低，从而引起缺血性脑组织中线粒体蛋白的高乙酰化，导致线粒体动力学改变。然而，线粒体动力学相关蛋白Drp1在缺血性神经元细胞和脑组织中如何发生乙酰化，目前仍是一个未知数。在这里，我们发现，Drp1和GCN5L1在OGD处理的神经元细胞和dMCAO诱导的缺血脑组织中表达上调，并伴随线粒体裂变、mtROS积累和细胞凋亡的增加。此外，我们还证实缺血/缺氧促进了神经元细胞和脑组织中 Drp1 与 GCN5L1 的相互作用。GCN5L1敲除可减轻Drp1的乙酰化，而过表达则可增强Drp1的乙酰化和线粒体裂解，这表明GCN5L1通过乙酰化Drp1在缺血缺氧诱导的线粒体裂解中起着关键作用。从机理上讲，缺血/缺氧通过CDK5上调激活AMPK诱导神经细胞中的Drp1磷酸化，进而促进GCN5L1与Drp1的相互作用，从而增强Drp1乙酰化和线粒体裂解。因此，抑制 AMPK 可缓解缺血/缺氧诱导的 Drp1 乙酰化和线粒体分裂，保护脑组织免受缺血损伤。这些发现为了解 GCN5L1 在调控 Drp1 乙酰化中的功能作用提供了新的视角，并确定了一种之前未被认识的 CDK5-AMPK-GCN5L1 通路，该通路介导缺血脑组织中 Drp1 的乙酰化。

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来源期刊

Molecular Medicine 医学-生化与分子生物学

CiteScore

8.60

自引率

0.00%

发文量

137

审稿时长

1 months

期刊介绍： Molecular Medicine is an open access journal that focuses on publishing recent findings related to disease pathogenesis at the molecular or physiological level. These insights can potentially contribute to the development of specific tools for disease diagnosis, treatment, or prevention. The journal considers manuscripts that present material pertinent to the genetic, molecular, or cellular underpinnings of critical physiological or disease processes. Submissions to Molecular Medicine are expected to elucidate the broader implications of the research findings for human disease and medicine in a manner that is accessible to a wide audience.