Related papers: CreoPep: A Universal Deep Learning Framework for Target-Specific Peptide Design and Optimization

CreoPep: A Universal Deep Learning Framework for Target-Specific Peptide Design and Optimization

URL: http://arxiv.org/abs/2505.02887v1
Date: Mon, 05 May 2025 15:56:39 GMT
Title: CreoPep: A Universal Deep Learning Framework for Target-Specific Peptide Design and Optimization
Authors: Cheng Ge, Han-Shen Tae, Zhenqiang Zhang, Lu Lu, Zhijie Huang, Yilin Wang, Tao Jiang, Wenqing Cai, Shan Chang, David J. Adams, Rilei Yu,
Abstract summary: Target-specific peptides, such as conotoxins, exhibit exceptional binding affinity and selectivity toward ion channels and receptors.<n>Here, we present CreoPep, a deep learning-based conditional generative framework that integrates masked language modeling with a progressive masking scheme to design high-affinity peptide mutants.<n>We validate this approach by designing conotoxin inhibitors targeting the $alpha$7 nicotinic acetylcholine receptor, achieving submicromolar potency in electrophysiological tests.
Score: 19.795752582745397
License: http://creativecommons.org/licenses/by-nc-sa/4.0/
Abstract: Target-specific peptides, such as conotoxins, exhibit exceptional binding affinity and selectivity toward ion channels and receptors. However, their therapeutic potential remains underutilized due to the limited diversity of natural variants and the labor-intensive nature of traditional optimization strategies. Here, we present CreoPep, a deep learning-based conditional generative framework that integrates masked language modeling with a progressive masking scheme to design high-affinity peptide mutants while uncovering novel structural motifs. CreoPep employs an integrative augmentation pipeline, combining FoldX-based energy screening with temperature-controlled multinomial sampling, to generate structurally and functionally diverse peptides that retain key pharmacological properties. We validate this approach by designing conotoxin inhibitors targeting the $\alpha$7 nicotinic acetylcholine receptor, achieving submicromolar potency in electrophysiological assays. Structural analysis reveals that CreoPep-generated variants engage in both conserved and novel binding modes, including disulfide-deficient forms, thus expanding beyond conventional design paradigms. Overall, CreoPep offers a robust and generalizable platform that bridges computational peptide design with experimental validation, accelerating the discovery of next-generation peptide therapeutics.

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