高通量成像和多参数代谢谱的结合揭示了替诺福韦毒性的线粒体机制。

IF 5.1 Q2 CELL BIOLOGY
Adam Pearson, Dominik Haenni, Jamal Bouitbir, Matthew Hunt, Brendan A I Payne, Ashwin Sachdeva, Rachel K Y Hung, Frank A Post, John Connolly, Stellor Nlandu-Khodo, Nevena Jankovic, Milica Bugarski, Andrew M Hall
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引用次数: 2

摘要

肾毒性是肾脏疾病和药物开发失败的主要原因,但对细胞机制的了解有限,强调需要更好的实验模型和方法方法。大多数肾毒素损害近端小管(PT),引起溶质重吸收功能障碍和全身代谢并发症。抗病毒药物富马酸替诺福韦二氧吡酯(TDF)是一种典型的肾毒素,可引起线粒体异常和尿溶质浪费,原因此前尚不清楚。在这里,我们开发了一种自动化的高通量成像管道,以筛选TDF对人源性RPTEC/TERT1细胞中溶质转运和线粒体形态的影响,并利用它来生成功能毒性的真实模型。通过应用多参数代谢谱-包括耗氧量测量,代谢组学和转录组学-我们阐明了TDF暴露的高度稳健的分子指纹。至关重要的是,我们发现活性代谢物抑制复合体V (ATP合成酶),TDF治疗导致复合体V活性和表达的快速、剂量依赖性丧失。此外,我们在TDF中毒患者的肾脏活检中发现了复合V抑制的证据。因此,我们展示了一种有效和方便的实验方法来筛选体外肾细胞中与疾病相关的功能缺陷,并揭示了一个新的范式来理解肾毒性的一个重要原因的发病机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Integration of High-Throughput Imaging and Multiparametric Metabolic Profiling Reveals a Mitochondrial Mechanism of Tenofovir Toxicity.

Integration of High-Throughput Imaging and Multiparametric Metabolic Profiling Reveals a Mitochondrial Mechanism of Tenofovir Toxicity.

Integration of High-Throughput Imaging and Multiparametric Metabolic Profiling Reveals a Mitochondrial Mechanism of Tenofovir Toxicity.

Integration of High-Throughput Imaging and Multiparametric Metabolic Profiling Reveals a Mitochondrial Mechanism of Tenofovir Toxicity.

Nephrotoxicity is a major cause of kidney disease and failure in drug development, but understanding of cellular mechanisms is limited, highlighting the need for better experimental models and methodological approaches. Most nephrotoxins damage the proximal tubule (PT), causing functional impairment of solute reabsorption and systemic metabolic complications. The antiviral drug tenofovir disoproxil fumarate (TDF) is an archetypal nephrotoxin, inducing mitochondrial abnormalities and urinary solute wasting, for reasons that were previously unclear. Here, we developed an automated, high-throughput imaging pipeline to screen the effects of TDF on solute transport and mitochondrial morphology in human-derived RPTEC/TERT1 cells, and leveraged this to generate realistic models of functional toxicity. By applying multiparametric metabolic profiling-including oxygen consumption measurements, metabolomics, and transcriptomics-we elucidated a highly robust molecular fingerprint of TDF exposure. Crucially, we identified that the active metabolite inhibits complex V (ATP synthase), and that TDF treatment causes rapid, dose-dependent loss of complex V activity and expression. Moreover, we found evidence of complex V suppression in kidney biopsies from humans with TDF toxicity. Thus, we demonstrate an effective and convenient experimental approach to screen for disease relevant functional defects in kidney cells in vitro, and reveal a new paradigm for understanding the pathogenesis of a substantial cause of nephrotoxicity.

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CiteScore
5.70
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