Knock-down of FOXO3, GATA2, NFE2L2 and AHR promotes doxorubicin-induced cardiotoxicity in human cardiomyocytes

IF 4.8 3区医学 Q1 PHARMACOLOGY & PHARMACY

Toxicology Pub Date : 2024-10-18 DOI:10.1016/j.tox.2024.153977

J.G. Faber, J. Ochoteco Asensio, F. Caiment, T. van den Beucken

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引用次数: 0

Abstract

Recent advances in cancer therapy have substantially increased survival rates among patients, yet the prolonged effect of current treatment regimens with anthracyclines (ACs) often include severe long-term complications, notably in the form of anthracycline-induced cardiotoxicity (AIC). Despite known associations between AC treatment and AIC, a comprehensive understanding of the underlying molecular pathways remains elusive. This gap is highlighted by the scarcity of reliable therapeutic interventions, with dexrazoxane being the sole FDA-approved drug to mitigate AIC risks. This study aims at elucidating the transcriptional response of human cardiomyocytes (hCMs) to AC exposure by analyzing a previously generated RNA-sequencing dataset of cardiac spheroids subjected to clinically relevant doses of ACs. The analysis revealed a robust transcriptional response identified across various time points. We aimed at identifying important transcription factors (TFs) mediating AIC by employing predictive algorithms to highlight key TFs for further experimental validation. Using shRNA constructs, we further assessed the impact of these TFs on hCM response to doxorubicin (DOX) and revealed that these TFs had a notable impact on hCM survival upon DOX exposure. TFs FOXO3, GATA2, AHR and NFE2L2 were further investigated for their role in AIC including cell viability, DOX uptake, DNA damage repair and induction of apoptosis through Cleaved-Caspase 3. Our study demonstrated that eliminating FOXO3 and GATA2 made hCMs more vulnerable to DOX and the lack of GATA2, NFE2L2 and AHR led to significantly higher intracellular levels of DOX. Additionally, FOXO3 played a role in the repair of hCM DNA damage as we observed markedly enhanced levels of CDKN1A. We also noted significant increases in DNA damage through COMET-assays when FOXO3, GATA2, NFE2L2 and AHR were absent. Furthermore, we investigated the clinical relevance by comparing our results with those from a study based on hiPSC-CMs derived from patients with doxorubicin-induced cardiotoxicity, identifying overlapping TFs and their regulatory roles in critical cellular processes like the cell cycle and DNA repair. This approach not only advances the understanding of the molecular mechanisms behind AIC but also opens possible windows for new therapeutic approaches to mitigate the negative side-effects from patient AC treatment.

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敲除 FOXO3、GATA2、NFE2L2 和 AHR 会促进多柔比星诱导的人类心肌细胞心脏毒性。

癌症治疗的最新进展大大提高了患者的生存率，但目前使用蒽环类药物（ACs）进行治疗的长期效果往往包括严重的长期并发症，特别是蒽环类药物诱发的心脏毒性（AIC）。尽管已知蒽环类药物治疗与 AIC 之间存在关联，但对其潜在分子通路的全面了解仍然遥遥无期。缺乏可靠的治疗干预措施凸显了这一空白，而右雷佐生是美国食品及药物管理局批准的唯一一种缓解 AIC 风险的药物。本研究旨在通过分析之前生成的、受临床相关剂量AC影响的心脏球体RNA测序数据集，阐明人心肌细胞（hCMs）对AC暴露的转录反应。分析结果显示，不同时间点的转录反应都很强。我们的目的是通过采用预测算法来识别介导 AIC 的重要转录因子 (TF)，从而突出关键 TF，进行进一步的实验验证。利用 shRNA 构建物，我们进一步评估了这些转录因子对 hCM 对多柔比星（DOX）反应的影响，结果发现这些转录因子对 hCM 暴露于 DOX 时的存活有显著影响。我们进一步研究了 FOXO3、GATA2、AHR 和 NFE2L2 等因子在 AIC 中的作用，包括细胞活力、DOX 吸收、DNA 损伤修复以及通过裂解-Caspase 3 诱导细胞凋亡。我们的研究表明，消除 FOXO3 和 GATA2 会使 hCMs 更容易受到 DOX 的伤害，缺乏 GATA2、NFE2L2 和 AHR 会导致细胞内 DOX 水平显著升高。此外，FOXO3 还在 hCM DNA 损伤的修复过程中发挥作用，因为我们观察到 CDKN1A 水平明显升高。我们还通过 COMET 分析发现，当 FOXO3、GATA2、NFE2L2 和 AHR 缺失时，DNA 损伤会明显增加。此外，我们还将我们的研究结果与一项基于多柔比星诱导的心脏毒性患者的 hiPSC-CMs 的研究结果进行了比较，确定了重叠的 TFs 及其在细胞周期和 DNA 修复等关键细胞过程中的调控作用，从而研究了两者的临床相关性。这种方法不仅加深了人们对 AIC 背后的分子机制的理解，还为新的治疗方法打开了可能的窗口，以减轻患者 AC 治疗的负面副作用。

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

Toxicology 医学-毒理学

CiteScore

7.80

自引率

4.40%

发文量

222

审稿时长

23 days

期刊介绍： Toxicology is an international, peer-reviewed journal that publishes only the highest quality original scientific research and critical reviews describing hypothesis-based investigations into mechanisms of toxicity associated with exposures to xenobiotic chemicals, particularly as it relates to human health. In this respect "mechanisms" is defined on both the macro (e.g. physiological, biological, kinetic, species, sex, etc.) and molecular (genomic, transcriptomic, metabolic, etc.) scale. Emphasis is placed on findings that identify novel hazards and that can be extrapolated to exposures and mechanisms that are relevant to estimating human risk. Toxicology also publishes brief communications, personal commentaries and opinion articles, as well as concise expert reviews on contemporary topics. All research and review articles published in Toxicology are subject to rigorous peer review. Authors are asked to contact the Editor-in-Chief prior to submitting review articles or commentaries for consideration for publication in Toxicology.