计算机科学
生物信息学
注释
计算生物学
人工智能
序列(生物学)
相似性(几何)
功能(生物学)
限制
蛋白质测序
排名(信息检索)
自然语言处理
自然语言
机器学习
语言模型
自然语言理解
蛋白质结构数据库
点(几何)
语义相似性
蛋白质超家族
源代码
计算语言学
蛋白质功能
情报检索
序列标记
生物
序列比对
数据挖掘
蛋白质-蛋白质相互作用
鉴定(生物学)
语义学(计算机科学)
统计模型
作者
Edo Dotan,Iris Lyubman,Marcelo Ehrlich,Eran Bacharach,Tal Pupko,Yonatan Belinkov
标识
DOI:10.1073/pnas.2537345123
摘要
Deciphering protein function is fundamental to advancements in medicine and biotechnology. However, conventional experimental characterization remains resource-intensive. Public large language models (LLMs), though proficient in natural language processing, often fail to accurately interpret and predict the functional and structural properties of proteins, limiting their utility in bioinformatics. To address this gap, we introduce BetaDescribe, designed to generate detailed and rich textual descriptions of proteins, including their function, catalytic activity, involvement in specific metabolic pathways, subcellular localizations, and the presence of specific domains. The trained BetaDescribe model receives protein sequences as input and outputs a textual description of these properties. BetaDescribe starting point was the LLAMA2 model, which was trained on trillions of tokens. Our model was next trained on datasets containing both biological and English text, which allowed the incorporation of biological knowledge. In addition to the description generator, BetaDescribe comprises multiple validator models and a judge, which together enable accurate ranking of alternative generated descriptions. We demonstrate the utility of BetaDescribe by providing descriptions for proteins that share little to no sequence similarity to proteins with functional descriptions in public datasets. Using in silico mutagenesis, we further show that BetaDescribe relies on functionally important regions, as part of its prediction, suggesting that the model identifies regions of importance for the protein functionality without needing homologous sequence. BetaDescribe offers a powerful tool to explore protein functionality, augmenting existing approaches such as annotation transfer based on sequence or structure similarity.
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