计算机科学
概率逻辑
序列(生物学)
机器学习
人工智能
任务(项目管理)
生成语法
数据挖掘
算法
生物
遗传学
经济
管理
作者
Jun Zhang,Sirui Liu,Mengyun Chen,Haotian Chu,Min Wang,Zidong Wang,Jialiang Yu,Ningxi Ni,Yu Fan,Dechin Chen,Yi Yang,Boxin Xue,Lijiang Yang,Yuan Liu,Yi Qin Gao
标识
DOI:10.1021/acs.jctc.3c00528
摘要
Data-driven predictive methods that can efficiently and accurately transform protein sequences into biologically active structures are highly valuable for scientific research and medical development. Determining an accurate folding landscape using coevolutionary information is fundamental to the success of modern protein structure prediction methods. As the state of the art, AlphaFold2 has dramatically raised the accuracy without performing explicit coevolutionary analysis. Nevertheless, its performance still shows strong dependence on available sequence homologues. Based on the interrogation on the cause of such dependence, we presented EvoGen, a meta generative model, to remedy the underperformance of AlphaFold2 for poor MSA targets. By prompting the model with calibrated or virtually generated homologue sequences, EvoGen helps AlphaFold2 fold accurately in the low-data regime and even achieve encouraging performance with single-sequence predictions. Being able to make accurate predictions with few-shot MSA not only generalizes AlphaFold2 better for orphan sequences but also democratizes its use for high-throughput applications. Besides, EvoGen combined with AlphaFold2 yields a probabilistic structure generation method that could explore alternative conformations of protein sequences, and the task-aware differentiable algorithm for sequence generation will benefit other related tasks including protein design.
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