Mitophagy as a guardian against cellular aging.

Tetsushi Kataura, Niall Wilson, Gailing Ma, Viktor I Korolchuk
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Abstract

Mitophagy, the selective autophagic clearance of damaged mitochondria, is considered vital for maintaining mitochondrial quality and cellular homeostasis; however, its molecular mechanisms, particularly under basal conditions, and its role in cellular physiology remain poorly characterized. We recently demonstrated that basal mitophagy is a key feature of primary human cells and is downregulated by immortalization, suggesting its dependence on the primary cell state. Mechanistically, we demonstrated that the PINK1-PRKN-SQSTM1 pathway regulates basal mitophagy, with SQSTM1 sensing superoxide-enriched mitochondria through its redox-sensitive cysteine residues, which mediate SQSTM1 oligomerization and mitophagy activation. We developed STOCK1N-57534, a small molecule that targets and promotes this SQSTM1 activation mechanism. Treatment with STOCK1N-57534 reactivates mitophagy downregulated in senescent and naturally aged donor-derived primary cells, improving cellular senescence(-like) phenotypes. Our findings highlight that basal mitophagy is protective against cellular senescence and aging, positioning its pharmacological reactivation as a promising anti-aging strategy.Abbreviation: IR: ionizing radiation; ROS: reactive oxygen species; SARs: selective autophagy receptors.

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防止细胞老化的卫士--丝裂噬。
有丝分裂是对受损线粒体的选择性自噬清除,被认为是维持线粒体质量和细胞平衡的关键;然而,其分子机制(尤其是在基础条件下)及其在细胞生理学中的作用仍鲜为人知。我们最近证明,基础有丝分裂是原代人类细胞的一个关键特征,并且会因永生化而下调,这表明它依赖于原代细胞状态。从机理上讲,我们证明了 PINK1-PRKN-SQSTM1 通路调节基础有丝分裂,SQSTM1 通过其对氧化还原敏感的半胱氨酸残基感知富含超氧化物的线粒体,从而介导 SQSTM1 的寡聚化和有丝分裂的激活。我们开发了一种小分子 STOCK1N-57534,它能靶向并促进这种 SQSTM1 激活机制。用 STOCK1N-57534 治疗可重新激活衰老和自然衰老供体衍生原代细胞中下调的有丝分裂,改善细胞衰老(类)表型。我们的研究结果突出表明,基础有丝分裂对细胞衰老和老化具有保护作用,因此将其药物再激活定位为一种有前景的抗衰老策略:缩写:IR:电离辐射;ROS:活性氧;SARs:选择性自噬受体。
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