通过生殖毒性的跨物种不良后果途径网络,在同一健康视角下缩小人类毒理学与生态毒理学之间的差距。

IF 3.6 4区 环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES
Elizabeth Dufourcq Sekatcheff, Jaeseong Jeong, Jinhee Choi
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引用次数: 0

摘要

虽然生态毒理学和毒理学风险评估是分开进行的,但最近这两个学科都在努力减少动物试验,转而开发预测方法,例如通过保守的分子标记、体外和硅学方法。其中,不利结果途径(AOPs)的提出有助于在更大的生物尺度上预测分子毒性效应。因此,更多的毒理学数据可用于为生态毒理学风险提供信息,反之亦然。以前曾开发过一种 AOP,用于预测纳米银粒子通过氧化应激对线虫 Caenorhabditis elegans(AOPwiki ID 207)的生殖毒性。继之前的研究之后,本研究旨在扩展 AOP 207 的生物合理分类适用域(tDOA)。我们从以前的研究中收集了各种类型的数据,包括体外人体细胞、体内和分子到个体的数据,并将其构建成一个跨物种 AOP 网络,为人类毒理学和生态毒理学风险评估提供信息。第一步是收集和分析文献数据,以符合 AOP 标准并建立第一个 AOP 网络。然后,使用贝叶斯网络建模方法对关键事件关系进行评估,使我们对整个 AOP 网络更有信心。最后,利用硅学方法(基因到路径物种保护分析和序列比对预测跨物种易感性)扩展了生物学上可信的 tDOA,从而将我们的 AOP 网络推断到 100 多个分类群。我们的方法表明,各种类型的数据都可以整合到 AOP 框架中,从而有助于获取知识和预测毒性机制,而无需进一步的动物试验。环境毒物化学 2024;00:1-14。© 2024 作者。环境毒理学与化学》由 Wiley Periodicals LLC 代表 SETAC 出版。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Bridging the Gap Between Human Toxicology and Ecotoxicology Under One Health Perspective by a Cross-Species Adverse Outcome Pathway Network for Reproductive Toxicity.

Although ecotoxicological and toxicological risk assessments are performed separately from each other, recent efforts have been made in both disciplines to reduce animal testing and develop predictive approaches instead, for example, via conserved molecular markers, and in vitro and in silico approaches. Among them, adverse outcome pathways (AOPs) have been proposed to facilitate the prediction of molecular toxic effects at larger biological scales. Thus, more toxicological data are used to inform on ecotoxicological risks and vice versa. An AOP has been previously developed to predict reproductive toxicity of silver nanoparticles via oxidative stress on the nematode Caenorhabditis elegans (AOPwiki ID 207). Following this previous study, our present study aims to extend the biologically plausible taxonomic domain of applicability (tDOA) of AOP 207. Various types of data, including in vitro human cells, in vivo, and molecular to individual, from previous studies have been collected and structured into a cross-species AOP network that can inform both human toxicology and ecotoxicology risk assessments. The first step was the collection and analysis of literature data to fit the AOP criteria and build a first AOP network. Then, key event relationships were assessed using a Bayesian network modeling approach, which gave more confidence in our overall AOP network. Finally, the biologically plausible tDOA was extended using in silico approaches (Genes-to-Pathways Species Conservation Analysis and Sequence Alignment to Predict Across Species Susceptibility), which led to the extrapolation of our AOP network across over 100 taxonomic groups. Our approach shows that various types of data can be integrated into an AOP framework, and thus facilitates access to knowledge and prediction of toxic mechanisms without the need for further animal testing. Environ Toxicol Chem 2024;00:1-14. © 2024 The Authors. Environmental Toxicology and Chemistry published by Wiley Periodicals LLC on behalf of SETAC.

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来源期刊
CiteScore
7.40
自引率
9.80%
发文量
265
审稿时长
3.4 months
期刊介绍: The Society of Environmental Toxicology and Chemistry (SETAC) publishes two journals: Environmental Toxicology and Chemistry (ET&C) and Integrated Environmental Assessment and Management (IEAM). Environmental Toxicology and Chemistry is dedicated to furthering scientific knowledge and disseminating information on environmental toxicology and chemistry, including the application of these sciences to risk assessment.[...] Environmental Toxicology and Chemistry is interdisciplinary in scope and integrates the fields of environmental toxicology; environmental, analytical, and molecular chemistry; ecology; physiology; biochemistry; microbiology; genetics; genomics; environmental engineering; chemical, environmental, and biological modeling; epidemiology; and earth sciences. ET&C seeks to publish papers describing original experimental or theoretical work that significantly advances understanding in the area of environmental toxicology, environmental chemistry and hazard/risk assessment. Emphasis is given to papers that enhance capabilities for the prediction, measurement, and assessment of the fate and effects of chemicals in the environment, rather than simply providing additional data. The scientific impact of papers is judged in terms of the breadth and depth of the findings and the expected influence on existing or future scientific practice. Methodological papers must make clear not only how the work differs from existing practice, but the significance of these differences to the field. Site-based research or monitoring must have regional or global implications beyond the particular site, such as evaluating processes, mechanisms, or theory under a natural environmental setting.
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