计算机科学
药物靶点
药物发现
中心性
图形
编码(内存)
数据挖掘
机器学习
药品
人工智能
特征(语言学)
计算生物学
生物信息学
理论计算机科学
生物
药理学
数学
组合数学
语言学
哲学
作者
Youzhi Liu,Linlin Xing,Longbo Zhang,Hongzhen Cai,Maozu Guo
标识
DOI:10.1038/s41598-024-57879-1
摘要
Abstract Predicting the interaction affinity between drugs and target proteins is crucial for rapid and accurate drug discovery and repositioning. Therefore, more accurate prediction of DTA has become a key area of research in the field of drug discovery and drug repositioning. However, traditional experimental methods have disadvantages such as long operation cycles, high manpower requirements, and high economic costs, making it difficult to predict specific interactions between drugs and target proteins quickly and accurately. Some methods mainly use the SMILES sequence of drugs and the primary structure of proteins as inputs, ignoring the graph information such as bond encoding, degree centrality encoding, spatial encoding of drug molecule graphs, and the structural information of proteins such as secondary structure and accessible surface area. Moreover, previous methods were based on protein sequences to learn feature representations, neglecting the completeness of information. To address the completeness of drug and protein structure information, we propose a Transformer graph-based early fusion research approach for drug-target affinity prediction (GEFormerDTA). Our method reduces prediction errors caused by insufficient feature learning. Experimental results on Davis and KIBA datasets showed a better prediction of drugtarget affinity than existing affinity prediction methods.
科研通智能强力驱动
Strongly Powered by AbleSci AI