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Enhancing kinase-inhibitor activity and selectivity prediction through contrastive learning.

Yanan Tian1,2, Ruiqiang Lu1, Xiaoqing Gong1

  • 1Faculty of Applied Sciences, Macao Polytechnic University, Macao, China.

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MMCLKin accurately predicts kinase-inhibitor activity and selectivity using a novel deep learning framework. This tool aids in discovering potent and selective kinase inhibitors, overcoming challenges in drug development.

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Area of Science:

  • Biochemistry
  • Computational Biology
  • Drug Discovery

Background:

  • Developing selective kinase inhibitors is difficult due to conserved protein structures and expensive screening.
  • Accurate prediction of kinase-inhibitor affinity and specificity is crucial for efficient drug development.

Purpose of the Study:

  • To present MMCLKin, a deep learning framework for predicting kinase-inhibitor activity and selectivity.
  • To demonstrate MMCLKin's superior performance and generalizability compared to existing methods.

Main Methods:

  • Developed MMCLKin, an attention consistency-guided contrastive learning framework.
  • Integrated geometric graph and sequence networks with multi-head attention and multimodal, multiscale contrastive learning.
  • Validated MMCLKin on multiple 3D kinase-drug, protein-drug, and mutation-aware datasets.

Main Results:

  • MMCLKin outperformed existing methods across diverse datasets.
  • The framework demonstrated strong generalizability on known and unknown kinase structures.
  • Attention analysis identified key residues and functional groups for kinase-inhibitor binding.
  • Experimental validation confirmed MMCLKin's ability to identify potent inhibitors, including against the LRRK2 G2019S mutant.

Conclusions:

  • MMCLKin provides accurate and interpretable predictions of kinase-inhibitor interactions.
  • The framework effectively screens for potent and selective kinase inhibitors.
  • MMCLKin is a valuable tool for advancing kinase inhibitor drug discovery.