三氯醇致人神经毒性机制的计算机分析

IF 2.6 3区医学 Q3 NEUROSCIENCES

Neurotoxicology and teratology Pub Date : 2025-03-30 DOI:10.1016/j.ntt.2025.107447

Fuat Karakuş , Burak Kuzu

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引用次数: 0

摘要

三氯醇（DCF）是一种有机氯农药，近年来被认为是一种持久性有机污染物。本研究首先通过计算机工具研究DCF及其代谢物的神经毒性。随后，通过网络毒理学、多层次生物信息学方法和分子对接分析，探讨了dcf诱导人类神经毒性的分子机制和关键靶点。预测结果表明，DCF及其代谢物均可穿过血脑屏障，穿透中枢神经系统，引起神经毒性。一项彻底的分析已经确定了56个与dcf引起的神经毒性有关的潜在目标。基因本体富集分析显示，与钠离子跨膜转运、钠/钾交换atp酶复合物和p型钙转运蛋白活性相关的途径存在显著关联。途径富集分析表明，dcf诱导的神经毒性是由通过p型atp酶的离子运输中断引起的。进一步研究基因-基因和蛋白质-蛋白质相互作用，以及中心性分析，确定了11个枢纽靶点，包括ATP1A1， ATP1A2, ATP1A3, ATP1A4, ATP1B1， ATP1B2和MAPK1，是关键角色。值得注意的是，这些靶标中有6个是Na+/K+- atp酶（一种p型atp酶）的亚基。分子对接结果表明，DCF与ATP1A3-ATP1B1蛋白复合物的结合比其天然配体ATP更有效。这些发现提示DCF可能通过ATP1A3抑制Na+/K+- atp酶，导致钠钾梯度失衡，最终导致神经毒性。

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An in silico analysis of dicofol-induced neurotoxicity mechanisms in humans

Dicofol (DCF) is an organochlorine pesticide that has recently been recognized as a persistent organic pollutant. This study begins by investigating the neurotoxicity of DCF and its metabolites through in silico tools. It subsequently explores the molecular mechanisms and key targets associated with DCF-induced neurotoxicity in humans by employing network toxicology, multi-level bioinformatics approaches, and molecular docking analyses. The prediction results indicate that both DCF and its metabolites can traverse the blood-brain barrier, penetrating the central nervous system, and inducing neurotoxicity. A thorough analysis has identified 56 potential targets linked to DCF-induced neurotoxicity. Gene Ontology enrichment analysis revealed significant associations with pathways related to sodium ion transmembrane transport, sodium/potassium-exchanging ATPase complexes, and P-type calcium transporter activity. Pathway enrichment analysis suggests that DCF-induced neurotoxicity arises from disruptions in ion transport via P-type ATPases. Further examination of gene-gene and protein-protein interactions, along with centrality analysis, identified 11 hub targets, including ATP1A1, ATP1A2, ATP1A3, ATP1A4, ATP1B1, ATP1B2, and MAPK1, as key players. Notably, six of these targets are subunits of the Na⁺/K⁺-ATPase, a P-type ATPase. Molecular docking results demonstrated that DCF binds more effectively to the ATP1A3-ATP1B1 protein complex than to its natural ligand, ATP. These findings suggest that DCF may inhibit Na⁺/K⁺-ATPase through ATP1A3, resulting in an imbalance of sodium and potassium gradients and ultimately leading to neurotoxicity.

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来源期刊

Neurotoxicology and teratology 医学-毒理学

CiteScore

5.60

自引率

10.30%

发文量

审稿时长

58 days

期刊介绍： Neurotoxicology and Teratology provides a forum for publishing new information regarding the effects of chemical and physical agents on the developing, adult or aging nervous system. In this context, the fields of neurotoxicology and teratology include studies of agent-induced alterations of nervous system function, with a focus on behavioral outcomes and their underlying physiological and neurochemical mechanisms. The Journal publishes original, peer-reviewed Research Reports of experimental, clinical, and epidemiological studies that address the neurotoxicity and/or functional teratology of pesticides, solvents, heavy metals, nanomaterials, organometals, industrial compounds, mixtures, drugs of abuse, pharmaceuticals, animal and plant toxins, atmospheric reaction products, and physical agents such as radiation and noise. These reports include traditional mammalian neurotoxicology experiments, human studies, studies using non-mammalian animal models, and mechanistic studies in vivo or in vitro. Special Issues, Reviews, Commentaries, Meeting Reports, and Symposium Papers provide timely updates on areas that have reached a critical point of synthesis, on aspects of a scientific field undergoing rapid change, or on areas that present special methodological or interpretive problems. Theoretical Articles address concepts and potential mechanisms underlying actions of agents of interest in the nervous system. The Journal also publishes Brief Communications that concisely describe a new method, technique, apparatus, or experimental result.