灵活性(工程)
计算机科学
构象集合
序列(生物学)
蛋白质结构
变构调节
生物系统
人工智能
分子动力学
结构线形
情态动词
算法
蛋白质折叠
扩散
蛋白质动力学
噪音(视频)
财产(哲学)
统计物理学
嵌入
蛋白质设计
蛋白质结构预测
理论计算机科学
蛋白质测序
作者
Baoli wang,Chenglin Wang,Jingyang Chen,Danlin Liu,Changzhi Sun,Jie Zhang,Kai Zhang,Honglin Li
标识
DOI:10.1038/s42256-026-01198-9
摘要
Recent advances in artificial intelligence have enabled accurate prediction of a protein’s stable structure solely based on its amino acid sequence. However, capturing the complete conformational landscape of a protein and its dynamic flexibility remains challenging. Here we developed modal-aligned conditional diffusion (Mac-Diff), a score-based diffusion model for generating the conformational ensembles for unseen proteins. Central to Mac-Diff is an attention module that enforces a delicate, locality-aware alignment between the conditional view (protein sequence) and the target view (residue pair geometry) to compute highly contextualized features for effective structural denoising and generation. Furthermore, Mac-Diff leverages semantically rich sequence embedding from protein language models such as ESM-2 in enforcing the protein sequence condition that captures evolutionary, structural and functional information. Mac-Diff showed promising results in generating realistic and diverse protein structures. It successfully recovered conformational distributions of fast-folding proteins, captured multiple meta-stable conformations that were observed only in long MD simulation trajectories and efficiently predicted alternative conformations for allosteric proteins. We believe that Mac-Diff offers a useful tool to improve understanding of protein dynamics and structural variability, with broad implications for structural biology, structure-based drug design and protein engineering. Wang et al. introduce Mac-Diff, a conditional diffusion model with locality-aware attention across modalities, to generate diverse conformational ensembles for unseen proteins, capturing both dynamic flexibility and structural heterogeneity.
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