Piezo1, F-actin Remodeling, and Podocyte Survival and Regeneration.

IF 10.3 1区医学 Q1 UROLOGY & NEPHROLOGY

Journal of The American Society of Nephrology Pub Date : 2025-04-02 DOI:10.1681/ASN.0000000697

Maria Elena Melica, Giulia Antonelli, Roberto Semeraro, Gilda La Regina, Tommaso Dafichi, Camilla Fantini, Giulia Carangelo, Giuseppina Comito, Carolina Conte, Laura Maggi, Samuela Landini, Valentina Raglianti, Maria Lucia Angelotti, Alice Molli, Daniela Buonvicino, Letizia De Chiara, Elena Lazzeri, Benedetta Mazzinghi, Anna Julie Peired, Paola Romagnani, Laura Lasagni

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引用次数: 0

Abstract

Background: Podocytes and podocyte progenitors are interdependent components of the kidney's glomerular structure, with podocytes forming the glomerular filtration barrier and progenitors being key players in podocyte regeneration during pathophysiological processes. Both cell types are subjected to constant mechanical forces, whose alterations can initiate podocytopathy and worsen glomerular injury. Despite this, the specific mechanosensors and mechanotransduction pathways involved in their response to mechanical cues remain only partially explored.

Methods: We used transcriptomics, immunofluorescence, and silencing experiments on human primary podocyte progenitor cell cultures to demonstrate the expression and function of Piezo1 channels. We generated inducible podocyte- and podocyte progenitor-specific Piezo1 knockout mice to evaluate the effects of Piezo1 loss in the context of Adriamycin nephropathy and over 10 months of aging.

Results: Silencing of Piezo1 in progenitors triggered F-actin remodelling, induced cell shape modification and nuclear envelope defects with accumulation of DNA damage that led to mitotic catastrophe in differentiated podocytes. Podocyte-specific knockout of Piezo1 induced higher susceptibility to podocyte injury in Adriamycin nephropathy and led to accumulation of DNA damage and mild albuminuria starting from adult age. Podocyte progenitor-specific knockout of Piezo1 in mouse resulted in severe albuminuria during Adriamycin nephropathy, leading to the generation of defective podocytes.

Conclusions: These results demonstrated that Piezo1, thanks to its role in F-actin cytoskeleton maintenance, is essential for the survival of podocytes exposed to mechanical stress conditions and for their correct regeneration.

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Piezo1、f -肌动蛋白重塑与足细胞存活和再生。

背景：足细胞和足细胞祖细胞是肾脏肾小球结构中相互依赖的组成部分，足细胞形成肾小球滤过屏障，而祖细胞在病理生理过程中是足细胞再生的关键参与者。这两种类型的细胞都受到恒定的机械力，其改变可引发足细胞病和加重肾小球损伤。尽管如此，它们对机械信号的反应所涉及的特定机械传感器和机械转导途径仍然只是部分探索。方法：利用转录组学、免疫荧光和沉默实验对人原代足细胞祖细胞进行培养，证实Piezo1通道的表达和功能。我们产生了可诱导的足细胞和足细胞祖特异性Piezo1敲除小鼠，以评估在阿霉素肾病和超过10个月的衰老背景下Piezo1丢失的影响。结果：祖细胞中Piezo1的沉默触发f -肌动蛋白重塑，诱导细胞形状改变和核膜缺陷，DNA损伤积累导致分化足细胞有丝分裂突变。足细胞特异性敲除Piezo1导致阿霉素肾病足细胞损伤易感性增高，并导致DNA损伤的积累和从成年开始的轻度蛋白尿。小鼠足细胞祖细胞特异性敲除Piezo1导致阿霉素肾病期间严重的蛋白尿，导致足细胞缺陷的产生。结论：这些结果表明，由于其在f -肌动蛋白细胞骨架维持中的作用，Piezo1对于暴露于机械应力条件下的足细胞的存活和正确再生至关重要。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of The American Society of Nephrology 医学-泌尿学与肾脏学

CiteScore

22.40

自引率

2.90%

发文量

492

审稿时长

3-8 weeks

期刊介绍： The Journal of the American Society of Nephrology (JASN) stands as the preeminent kidney journal globally, offering an exceptional synthesis of cutting-edge basic research, clinical epidemiology, meta-analysis, and relevant editorial content. Representing a comprehensive resource, JASN encompasses clinical research, editorials distilling key findings, perspectives, and timely reviews. Editorials are skillfully crafted to elucidate the essential insights of the parent article, while JASN actively encourages the submission of Letters to the Editor discussing recently published articles. The reviews featured in JASN are consistently erudite and comprehensive, providing thorough coverage of respective fields. Since its inception in July 1990, JASN has been a monthly publication. JASN publishes original research reports and editorial content across a spectrum of basic and clinical science relevant to the broad discipline of nephrology. Topics covered include renal cell biology, developmental biology of the kidney, genetics of kidney disease, cell and transport physiology, hemodynamics and vascular regulation, mechanisms of blood pressure regulation, renal immunology, kidney pathology, pathophysiology of kidney diseases, nephrolithiasis, clinical nephrology (including dialysis and transplantation), and hypertension. Furthermore, articles addressing healthcare policy and care delivery issues relevant to nephrology are warmly welcomed.