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Improving the predictive performance of binding affinities and poses for protein–cyclic peptide complexes through fine-tuned MM/PBSA(GBSA)-based methods

Huifeng Zhao, Jianxiang Huang, Gaoqi Weng, Dejun Jiang, Renling Hu, Yu Kang, Tingjun Hou

2025Briefings in Bioinformatics6 citationsDOIOpen Access PDF

Abstract

Cyclic peptides represent a highly promising class of biopharmaceutical scaffolds. The screening of cyclic peptides against protein targets can be greatly facilitated using computational approaches, especially molecular docking. However, it remains a crucial challenge to accurately predict protein-cyclic peptide (P-cp) interactions employing scoring functions of molecular docking. End-point approaches, such as molecular mechanics generalized Born surface area (MM/GBSA) and molecular mechanics Poisson-Boltzmann surface area (MM/PBSA), provide theoretically more robust frameworks than conventional scoring functions, but their reliability in predicting binding affinities and discriminating native-like binding poses for P-cp complexes remains poorly quantified. Herein, we comprehensively assessed the predictive abilities of MM/PBSA(GBSA) in scoring binding affinities of P-cp complexes and re-ranking their binding poses. The binding affinity scoring ability of MM/PBSA(GBSA) was assessed on a carefully curated dataset consisting of 50 complexes involving P-cp binding affinities, and their re-ranking capability was evaluated on another dataset consisting of the decoys of 81 P-cp complexes. Based on these assessments, we proposed a two-step workflow for predicting P-cp binding affinities. First, we employed the assessed optimal re-ranking method to select the top-1 binding pose; second, we estimated the binding affinity based on the selected top-1 pose using the assessed optimal scoring method. Our proposed workflow, which requires only 3 s for each prediction, achieves binding affinity predictions with a Rp of -0.732 when compared to experimental values, which is twice as high as that of AutoDock CrankPep (Rp = -0.316). This study emphasizes the necessity of using fine-tuned MM/PBSA(GBSA) methods for predicting P-cp interactions.

Topics & Concepts

Binding affinitiesAffinitiesComputational biologyMolecular mechanicsChemistryPeptideBinding siteComputer scienceMolecular dynamicsBiopharmaceuticalPlasma protein bindingMolecular descriptorMolecular bindingMolecular recognitionWorkflowMolecular modelAutoDockCombinatorial chemistryDrug discoveryBinding pocketClass (philosophy)Binding selectivityArtificial intelligenceMachine learningBiological systemReliability (semiconductor)Small moleculeComputational Drug Discovery Methodsvaccines and immunoinformatics approachesChemical Synthesis and Analysis
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