Predicting the target landscape of kinase inhibitors using 3D convolutional neural networks.

IF 4.3 2区生物学

PLoS Computational Biology Pub Date : 2023-09-05 eCollection Date: 2023-09-01 DOI:10.1371/journal.pcbi.1011301

Georgi K Kanev, Yaran Zhang, Albert J Kooistra, Andreas Bender, Rob Leurs, David Bailey, Thomas Würdinger, Chris de Graaf, Iwan J P de Esch, Bart A Westerman

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引用次数: 0

Abstract

Many therapies in clinical trials are based on single drug-single target relationships. To further extend this concept to multi-target approaches using multi-targeted drugs, we developed a machine learning pipeline to unravel the target landscape of kinase inhibitors. This pipeline, which we call 3D-KINEssence, uses a new type of protein fingerprints (3D FP) based on the structure of kinases generated through a 3D convolutional neural network (3D-CNN). These 3D-CNN kinase fingerprints were matched to molecular Morgan fingerprints to predict the targets of each respective kinase inhibitor based on available bioactivity data. The performance of the pipeline was evaluated on two test sets: a sparse drug-target set where each drug is matched in most cases to a single target and also on a densely-covered drug-target set where each drug is matched to most if not all targets. This latter set is more challenging to train, given its non-exclusive character. Our model's root-mean-square error (RMSE) based on the two datasets was 0.68 and 0.8, respectively. These results indicate that 3D FP can predict the target landscape of kinase inhibitors at around 0.8 log units of bioactivity. Our strategy can be utilized in proteochemometric or chemogenomic workflows by consolidating the target landscape of kinase inhibitors.

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使用3D卷积神经网络预测激酶抑制剂的靶向格局。

临床试验中的许多疗法都是基于单药单靶点关系。为了进一步将这一概念扩展到使用多靶向药物的多靶点方法，我们开发了一个机器学习管道来揭示激酶抑制剂的靶点景观。这个管道，我们称之为3D KINSense，使用了一种基于通过3D卷积神经网络（3D-CNN）生成的激酶结构的新型蛋白质指纹（3DFP）。将这些3D-CNN激酶指纹与分子Morgan指纹相匹配，以基于可用的生物活性数据预测每个相应激酶抑制剂的靶标。管道的性能在两个测试集上进行了评估：一个是稀疏药物靶点集，在大多数情况下，每种药物都与单个靶点匹配；另一个是密集药物靶点集中，每种药都与大多数（如果不是所有的话）靶点匹配。后一组训练更具挑战性，因为它具有非排他性。基于这两个数据集，我们的模型的均方根误差（RMSE）分别为0.68和0.8。这些结果表明，3D-FP可以在约0.8 log单位的生物活性下预测激酶抑制剂的靶向景观。我们的策略可以通过巩固激酶抑制剂的靶向格局，用于蛋白化学计量学或化学基因组工作流程。

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

PLoS Computational Biology 生物-生化研究方法

CiteScore

7.10

自引率

4.70%

发文量

820

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