AKT2-mediated lysosomal dysfunction promotes secretory autophagy in retinal pigment epithelium (RPE) cells.

Sayan Ghosh, Stacey Hose, Debasish Sinha
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Abstract

Age-related macular degeneration (AMD) is the leading cause of blindness in the elderly, with the non-neovascular or atrophic form being the most common. Current treatment options are limited, emphasizing the urgent need for new therapeutic strategies. Our key finding is that increased levels of AKT2 in the RPE cells impair lysosomal function and trigger secretory autophagy; a non-canonical macroautophagy/autophagy pathway where cellular materials are released via the plasma membrane rather than being degraded by lysosomes. We showed that this process involves a protein complex, AKT2-SYTL1-TRIM16-SNAP23, releasing factors contributing to drusen biogenesis, a clinical hallmark of AMD development. Importantly, SIRT5 can inhibit this pathway, potentially offering a protective effect. Understanding mechanisms by which this non-canonical autophagy pathway promotes extracellular waste accumulation could provide new insights into drusen biogenesis. Future therapies for atrophic AMD could focus on regulating secretory autophagy or manipulating proteins involved in this process.

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AKT2- 介导的溶酶体功能障碍会促进视网膜色素上皮细胞(RPE)的分泌性自噬。
老年性黄斑变性(AMD)是导致老年人失明的主要原因,其中最常见的是非血管性或萎缩性黄斑变性。目前的治疗方案有限,因此迫切需要新的治疗策略。我们的主要发现是,RPE 细胞中的 AKT2 水平升高会损害溶酶体功能,引发分泌性自噬;这是一种非经典的大自噬/自噬途径,细胞物质通过质膜释放,而不是由溶酶体降解。我们的研究表明,这一过程涉及到一个蛋白复合物,即 AKT2-SYTL1-TRIM16-SNAP23 蛋白复合物,该蛋白复合物可释放有助于黑斑生物生成的因子,而黑斑生物生成是老年性黄斑变性的临床特征。重要的是,SIRT5 可以抑制这一途径,从而起到潜在的保护作用。了解这种非经典自噬途径促进细胞外废物积累的机制,可以为了解葡萄色素的生物生成提供新的视角。未来治疗萎缩性黄斑变性的方法可以侧重于调节分泌性自噬或操纵参与这一过程的蛋白质。
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