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利用 ToxCast 数据、化学结构和生物医学文献对腭裂毒物进行特征描述。

Characterizing cleft palate toxicants using ToxCast data, chemical structure, and the biomedical literature.

机构信息

Leidos, Research Triangle Park, North Carolina.

NIEHS Division of the National Toxicology Program, Research Triangle Park, North Carolina.

出版信息

Birth Defects Res. 2020 Jan 1;112(1):19-39. doi: 10.1002/bdr2.1581. Epub 2019 Aug 30.

DOI:10.1002/bdr2.1581
PMID:31471948
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8454266/
Abstract

Cleft palate has been linked to both genetic and environmental factors that perturb key events during palatal morphogenesis. As a developmental outcome, it presents a challenging, mechanistically complex endpoint for predictive modeling. A data set of 500 chemicals evaluated for their ability to induce cleft palate in animal prenatal developmental studies was compiled from Toxicity Reference Database and the biomedical literature, which included 63 cleft palate active and 437 inactive chemicals. To characterize the potential molecular targets for chemical-induced cleft palate, we mined the ToxCast high-throughput screening database for patterns and linkages in bioactivity profiles and chemical structural descriptors. ToxCast assay results were filtered for cytotoxicity and grouped by target gene activity to produce a "gene score." Following unsuccessful attempts to derive a global prediction model using structural and gene score descriptors, hierarchical clustering was applied to the set of 63 cleft palate positives to extract local structure-bioactivity clusters for follow-up study. Patterns of enrichment were confirmed on the complete data set, that is, including cleft palate inactives, and putative molecular initiating events identified. The clusters corresponded to ToxCast assays for cytochrome P450s, G-protein coupled receptors, retinoic acid receptors, the glucocorticoid receptor, and tyrosine kinases/phosphatases. These patterns and linkages were organized into preliminary decision trees and the resulting inferences were mapped to a putative adverse outcome pathway framework for cleft palate supported by literature evidence of current mechanistic understanding. This general data-driven approach offers a promising avenue for mining chemical-bioassay drivers of complex developmental endpoints where data are often limited.

摘要

腭裂与干扰腭部形态发生关键事件的遗传和环境因素有关。作为一种发育结果,它呈现出具有挑战性的、机制复杂的预测模型终点。从毒性参考数据库和生物医学文献中编译了一个评估 500 种化学物质诱导动物产前发育研究中腭裂能力的数据集,其中包括 63 种腭裂活性化学物质和 437 种非活性化学物质。为了表征化学物质诱导腭裂的潜在分子靶标,我们从 ToxCast 高通量筛选数据库中挖掘了生物活性谱和化学结构描述符中的模式和联系。对 ToxCast 测定结果进行了细胞毒性过滤,并按靶基因活性进行分组,以产生“基因评分”。在使用结构和基因评分描述符未能成功得出全局预测模型后,应用层次聚类对 63 种腭裂阳性物进行分组,以提取后续研究的局部结构-生物活性聚类。在完整数据集上(包括腭裂非活性物)证实了富集模式,并且确定了潜在的分子起始事件。聚类对应于细胞色素 P450、G 蛋白偶联受体、视黄酸受体、糖皮质激素受体和酪氨酸激酶/磷酸酶的 ToxCast 测定。这些模式和联系被组织成初步决策树,并将得出的推论映射到支持当前机制理解的文献证据的腭裂不良结局途径框架。这种基于数据的通用方法为挖掘复杂发育终点的化学-生物测定驱动因素提供了有希望的途径,而这些数据通常是有限的。

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