Investigating the Mechanisms of Pazopanib-induced Hepatotoxicity: Insights from Network Toxicology, Microarray Analysis, and Machine Learning.

IF 3.5 4区医学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Current medicinal chemistry Pub Date : 2025-05-23 DOI:10.2174/0109298673367311250508082747

Yidong Zhu, Jun Liu, Fei Wang

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引用次数: 0

Abstract

Background: Pazopanib is an oral multi-kinase inhibitor that is effective in treating various tumors. However, it is commonly associated with hepatotoxicity, which can interrupt treatments and cause delays, thereby increasing the risk of tumor progression. The mechanisms underlying pazopanib-induced hepatotoxicity remain unclear and limit the development of effective preventive strategies. This study aimed to identify the core gene products and investigate the mechanisms associated with pazopanib-induced hepatotoxicity by integrating network toxicology, microarray analysis, and machinelearning.

Methods: Potential pazopanib targets were identified from multiple databases. Differential expression analysis was conducted using microarray data from hepatocyte-like cells treated with pazopanib and from matched control samples. Genes that overlapped between pazopanib targets and differentially expressed genes (DEGs) were considered potential pathogenic targets for hepatotoxicity. Multiple machine learning algorithms were employed for gene selection to improve accuracy and predictive capability. Molecular docking was used to evaluate the binding affinity of pazopanib to core proteins. Functional enrichment analysis was conducted to elucidate the potential toxic mechanisms.

Results: Our analysis identified 162 target genes for pazopanib and 291 DEGs, revealing seven shared genes as potential pathogenic targets for pazopanib-induced hepatotoxicity. Using machine learning, we further detected four core target proteins: CYP1A1, DDR2, FGF1, and PLK4. Molecular docking confirmed that pazopanib stably bound to these core proteins. Functional enrichment analysis indicated that the hepatotoxicity associated with pazopanib may involve p53 signaling, impaired cell cycle, and immune modulation.

Conclusion: This study enhances our understanding of the molecular mechanisms underlying pazopanib-induced hepatotoxicity, which is essential for developing protective strategies and therapeutic interventions. By integrating network toxicology, microarray analysis, and machine learning, this study provides a comprehensive framework for investigating the complex toxicological processes of specific compounds and offers insights that could improve the clinical applications and regulatory safety of targeted therapies.

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研究pazopanib诱导的肝毒性机制：来自网络毒理学、微阵列分析和机器学习的见解。

背景：帕唑帕尼是一种口服多激酶抑制剂，可有效治疗多种肿瘤。然而，它通常与肝毒性相关，可中断治疗并导致延迟，从而增加肿瘤进展的风险。帕唑帕尼诱发肝毒性的机制尚不清楚，限制了有效预防策略的发展。本研究旨在通过网络毒理学、微阵列分析和机器学习相结合的方法，鉴定核心基因产物，并探讨与pazopanib诱导的肝毒性相关的机制。方法：从多个数据库中鉴定帕唑帕尼的潜在靶点。使用微阵列数据对经pazopanib处理的肝细胞样细胞和匹配的对照样本进行差异表达分析。在pazopanib靶点和差异表达基因（DEGs）之间重叠的基因被认为是肝毒性的潜在致病靶点。采用多种机器学习算法进行基因选择，提高准确性和预测能力。采用分子对接法评价pazopanib与核心蛋白的结合亲和力。通过功能富集分析来阐明其潜在的毒性机制。结果：我们的分析鉴定了162个pazopanib靶基因和291个DEGs，揭示了7个共享基因是pazopanib诱导的肝毒性的潜在致病靶点。利用机器学习，我们进一步检测了四个核心靶蛋白：CYP1A1、DDR2、FGF1和PLK4。分子对接证实pazopanib与这些核心蛋白稳定结合。功能富集分析表明，与帕唑帕尼相关的肝毒性可能涉及p53信号传导、细胞周期受损和免疫调节。结论：本研究增强了我们对帕唑帕尼诱导肝毒性的分子机制的理解，这对制定保护策略和治疗干预措施至关重要。通过整合网络毒理学、微阵列分析和机器学习，本研究为研究特定化合物的复杂毒理学过程提供了一个全面的框架，并提供了可以改善靶向治疗的临床应用和监管安全性的见解。

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

Current medicinal chemistry 医学-生化与分子生物学

CiteScore

8.60

自引率

2.40%

发文量

468

审稿时长

3 months

期刊介绍： Aims & Scope Current Medicinal Chemistry covers all the latest and outstanding developments in medicinal chemistry and rational drug design. Each issue contains a series of timely in-depth reviews and guest edited thematic issues written by leaders in the field covering a range of the current topics in medicinal chemistry. The journal also publishes reviews on recent patents. Current Medicinal Chemistry is an essential journal for every medicinal chemist who wishes to be kept informed and up-to-date with the latest and most important developments.