通过结合人类诱导多能干细胞衍生心肌细胞的转录组和功能数据,为环境化学品的危害识别和风险特征描述提供信息。

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-08-19 Epub Date: 2024-07-24 DOI:10.1021/acs.chemrestox.4c00193
Han-Hsuan D Tsai, Lucie C Ford, Sarah D Burnett, Allison N Dickey, Fred A Wright, Weihsueh A Chiu, Ivan Rusyn
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引用次数: 0

摘要

环境中的化学物质可能会加重全球心血管疾病的负担,但目前还缺乏实验数据来确定哪些物质的风险最大。人类诱导多能干细胞(iPSC)衍生的心肌细胞是一种高通量的心脏毒性模型,被广泛用于测试药物和化学品;然而,大多数研究侧重于探索电生理读数。基因表达数据可提供更多的分子信息,用于机理解释和剂量反应分析。因此,我们假设人类 iPSC 衍生心肌细胞中的转录组和功能数据可作为一种综合筛选工具,用于识别化学品的潜在心脏毒性危害和风险。为了验证这一假设,我们对 12 类 464 种化学物质(包括药物和非药物物质)进行了浓度-反应分析。我们评估了功能效应(心跳频率、QT 延长和心搏骤停)、细胞毒性和整个转录组反应。从表型和转录组数据中得出出发点,并进行了风险特征描述。总体而言,有 244 种(53%)药物在至少一种表型中具有活性;不出所料,具有已知心脏毒性的药物最为活跃。正向时相是被最多受测化学物质激活的功能表型。没有哪一类化学物质特别容易对心肌细胞造成潜在危害;每一类中都有不同比例(10-44%)的物质对心肌细胞产生影响。转录组数据显示,69 种物质(15%)引起了基因表达的显著变化;大多数受干扰的途径与已知的人类心脏毒性物质的主要特征高度相关。生物活性与暴露比率表明,基于表型和转录组的 POD 风险特征描述结果相似。总之,我们的研究结果表明,综合利用来自 iPSC 衍生心肌细胞的体外转录组和表型数据,不仅能为危害和风险优先排序提供互补方法,还能对体外测试结果进行机理解释,从而提高决策的可信度。
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Informing Hazard Identification and Risk Characterization of Environmental Chemicals by Combining Transcriptomic and Functional Data from Human-Induced Pluripotent Stem-Cell-Derived Cardiomyocytes.

Environmental chemicals may contribute to the global burden of cardiovascular disease, but experimental data are lacking to determine which substances pose the greatest risk. Human-induced pluripotent stem cell (iPSC)-derived cardiomyocytes are a high-throughput cardiotoxicity model that is widely used to test drugs and chemicals; however, most studies focus on exploring electro-physiological readouts. Gene expression data may provide additional molecular insights to be used for both mechanistic interpretation and dose-response analyses. Therefore, we hypothesized that both transcriptomic and functional data in human iPSC-derived cardiomyocytes may be used as a comprehensive screening tool to identify potential cardiotoxicity hazards and risks of the chemicals. To test this hypothesis, we performed concentration-response analysis of 464 chemicals from 12 classes, including both pharmaceuticals and nonpharmaceutical substances. Functional effects (beat frequency, QT prolongation, and asystole), cytotoxicity, and whole transcriptome response were evaluated. Points of departure were derived from phenotypic and transcriptomic data, and risk characterization was performed. Overall, 244 (53%) substances were active in at least one phenotype; as expected, pharmaceuticals with known cardiac liabilities were the most active. Positive chronotropy was the functional phenotype activated by the largest number of tested chemicals. No chemical class was particularly prone to pose a potential hazard to cardiomyocytes; a varying proportion (10-44%) of substances in each class had effects on cardiomyocytes. Transcriptomic data showed that 69 (15%) substances elicited significant gene expression changes; most perturbed pathways were highly relevant to known key characteristics of human cardiotoxicants. The bioactivity-to-exposure ratios showed that phenotypic- and transcriptomic-based POD led to similar results for risk characterization. Overall, our findings demonstrate how the integrative use of in vitro transcriptomic and phenotypic data from iPSC-derived cardiomyocytes not only offers a complementary approach for hazard and risk prioritization, but also enables mechanistic interpretation of the in vitro test results to increase confidence in decision-making.

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