TeM-DTBA: time-efficient drug target binding affinity prediction using multiple modalities with Lasso feature selection

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2023-09-30 DOI:10.1007/s10822-023-00533-1
Tanya Liyaqat, Tanvir Ahmad, Chandni Saxena
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Abstract

Drug discovery, especially virtual screening and drug repositioning, can be accelerated through deeper understanding and prediction of Drug Target Interactions (DTIs). The advancement of deep learning as well as the time and financial costs associated with conventional wet-lab experiments have made computational methods for DTI prediction more popular. However, the majority of these computational methods handle the DTI problem as a binary classification task, ignoring the quantitative binding affinity that determines the drug efficacy to their target proteins. Moreover, computational space as well as execution time of the model is often ignored over accuracy. To address these challenges, we introduce a novel method, called Time-efficient Multimodal Drug Target Binding Affinity (TeM-DTBA), which predicts the binding affinity between drugs and targets by fusing different modalities based on compound structures and target sequences. We employ the Lasso feature selection method, which lowers the dimensionality of feature vectors and speeds up the proposed model training time by more than 50%. The results from two benchmark datasets demonstrate that our method outperforms state-of-the-art methods in terms of performance. The mean squared errors of 18.8% and 23.19%, achieved on the KIBA and Davis datasets, respectively, suggest that our method is more accurate in predicting drug-target binding affinity.

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TeM-DTBA:使用Lasso特征选择的多种模式进行时效性药物靶标结合亲和力预测。
药物发现,特别是虚拟筛选和药物重新定位,可以通过更深入地了解和预测药物靶标相互作用(DTI)来加速。深度学习的进步以及与传统湿实验室实验相关的时间和财务成本使DTI预测的计算方法更加流行。然而,这些计算方法中的大多数将DTI问题作为二元分类任务来处理,忽略了决定药物对靶蛋白疗效的定量结合亲和力。此外,模型的计算空间和执行时间往往被忽略,而忽略了准确性。为了应对这些挑战,我们引入了一种新的方法,称为时效多模式药物靶标结合亲和力(TeM-DTBA),该方法通过基于化合物结构和靶标序列融合不同模式来预测药物和靶标之间的结合亲和力。我们采用了Lasso特征选择方法,该方法降低了特征向量的维数,并将所提出的模型训练时间加快了50%以上。来自两个基准数据集的结果表明,我们的方法在性能方面优于最先进的方法。在KIBA和Davis数据集上分别获得18.8%和23.19%的均方误差,表明我们的方法在预测药物靶标结合亲和力方面更准确。
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CiteScore
7.20
自引率
4.30%
发文量
567
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