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用于药物协同作用个性化预测的通路激活模型

Pathway activation model for personalized prediction of drug synergy.

作者信息

Trac Quang Thinh, Huang Yue, Erkers Tom, Östling Päivi, Bohlin Anna, Osterroos Albin, Vesterlund Mattias, Jafari Rozbeh, Siavelis Ioannis, Backvall Helena, Kiviluoto Santeri, Orre Lukas, Rantalainen Mattias, Lehtiö Janne, Lehmann Soren, Kallioniemi Olli, Pawitan Yudi, Vu Trung Nghia

机构信息

Department of Medical Epidemiology and Biostatistics, Karolinska Institutet, Stockholm, Sweden.

Department of Health Statistics, School of Public Health, Weifang Medical University, Weifang, China.

出版信息

Elife. 2025 Jun 3;13:RP100071. doi: 10.7554/eLife.100071.

DOI:10.7554/eLife.100071
PMID:40459126
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12133153/
Abstract

Targeted monotherapies for cancer often fail due to inherent or acquired drug resistance. By aiming at multiple targets simultaneously, drug combinations can produce synergistic interactions that increase drug effectiveness and reduce resistance. Computational models based on the integration of omics data have been used to identify synergistic combinations, but predicting drug synergy remains a challenge. Here, we introduce Drug synergy Interaction Prediction (DIPx), an algorithm for personalized prediction of drug synergy based on biologically motivated tumor- and drug-specific pathway activation scores (PASs). We trained and validated DIPx in the AstraZeneca-Sanger (AZS) DREAM Challenge human cell-line dataset using two separate test sets: Test Set 1 comprised the combinations already present in the training set, while Test Set 2 contained combinations absent from the training set, thus indicating the model's ability to handle novel combinations. The Spearman's correlation coefficients between predicted and observed drug synergy were 0.50 (95% CI: 0.47-0.53) in Test Set 1 and 0.26 (95% CI: 0.22-0.30) in Test Set 2, compared to 0.38 (95% CI: 0.34-0.42) and 0.18 (95% CI: 0.16-0.20), respectively, for the best performing method in the Challenge. We show evidence that higher synergy is associated with higher functional interaction between the drug targets, and this functional interaction information is captured by PAS. We illustrate the use of PAS to provide a potential biological explanation in terms of activated pathways that mediate the synergistic effects of combined drugs. In summary, DIPx can be a useful tool for personalized prediction of drug synergy and exploration of activated pathways related to the effects of combined drugs.

摘要

癌症的靶向单一疗法常常因内在或获得性耐药而失败。通过同时针对多个靶点,药物联合使用可产生协同相互作用,从而提高药物疗效并降低耐药性。基于组学数据整合的计算模型已被用于识别协同组合,但预测药物协同作用仍然是一项挑战。在此,我们介绍药物协同相互作用预测(DIPx),这是一种基于具有生物学动机的肿瘤和药物特异性通路激活分数(PAS)进行药物协同作用个性化预测的算法。我们在阿斯利康 - 桑格(AZS)DREAM挑战赛人类细胞系数据集中使用两个单独的测试集对DIPx进行了训练和验证:测试集1包含训练集中已有的组合,而测试集2包含训练集中不存在的组合,从而表明该模型处理新组合的能力。在测试集1中,预测和观察到的药物协同作用之间的斯皮尔曼相关系数为0.50(95%置信区间:0.47 - 0.53),在测试集2中为0.26(95%置信区间:0.22 - 0.30),相比之下,挑战赛中表现最佳的方法在测试集1和测试集2中的相关系数分别为0.38(95%置信区间:0.34 - 0.42)和0.18(95%置信区间:0.16 - 0.20)。我们证明了更高的协同作用与药物靶点之间更高的功能相互作用相关,并且这种功能相互作用信息由PAS捕获。我们举例说明了如何使用PAS从介导联合药物协同效应的激活通路方面提供潜在的生物学解释。总之,DIPx可以成为药物协同作用个性化预测以及探索与联合药物效应相关的激活通路的有用工具。

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