Hasin Rehana, Nur Bengisu Çam, Mert Basmaci, Jie Zheng, Christianah Jemiyo, Yongqun He, Arzucan Özgür, Junguk Hur
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引用次数: 0
摘要
动机检测蛋白质-蛋白质相互作用(PPIs)对于了解遗传机制、疾病发病机理和药物设计至关重要。随着生物医学文献的快速增长,人们越来越需要自动、准确地提取这些相互作用,以促进科学发现。在自然语言处理任务中,预训练语言模型,如生成式预训练变换器和来自变换器的双向编码器表示,已经显示出良好的效果:我们评估了使用基于转换器的多种模型在三个人工策划的黄金标准语料库中进行 PPI 识别的性能:这些语料库包括:在逻辑中学习语言(77 个句子中包含 164 次交互)、人类蛋白质参考数据库(145 个句子中包含 163 次交互)以及交互提取性能评估(486 个句子中包含 335 次交互)。基于双向编码器表征的模型取得了最佳的整体性能,其中 BioBERT 在《Learning Language in Logic》数据集上取得了 91.95% 的最高召回率和 86.84% 的 F1 分数。尽管没有针对生物医学文本进行明确的训练,GPT-4 仍然表现出值得称赞的性能,与双向编码器模型不相上下。具体来说,GPT-4 在同一数据集上取得了 88.37% 的最高精确度、85.14% 的召回率和 86.49% 的 F1 分数。这些结果表明,GPT-4 可以有效地检测文本中的蛋白质相互作用,为挖掘生物医学文献提供了有价值的应用:本研究使用的源代码和数据集可在 https://github.com/hurlab/PPI-GPT-BERT 网站上获取。
Evaluating GPT and BERT models for protein-protein interaction identification in biomedical text.
Motivation: Detecting protein-protein interactions (PPIs) is crucial for understanding genetic mechanisms, disease pathogenesis, and drug design. As biomedical literature continues to grow rapidly, there is an increasing need for automated and accurate extraction of these interactions to facilitate scientific discovery. Pretrained language models, such as generative pretrained transformers and bidirectional encoder representations from transformers, have shown promising results in natural language processing tasks.
Results: We evaluated the performance of PPI identification using multiple transformer-based models across three manually curated gold-standard corpora: Learning Language in Logic with 164 interactions in 77 sentences, Human Protein Reference Database with 163 interactions in 145 sentences, and Interaction Extraction Performance Assessment with 335 interactions in 486 sentences. Models based on bidirectional encoder representations achieved the best overall performance, with BioBERT achieving the highest recall of 91.95% and F1 score of 86.84% on the Learning Language in Logic dataset. Despite not being explicitly trained for biomedical texts, GPT-4 showed commendable performance, comparable to the bidirectional encoder models. Specifically, GPT-4 achieved the highest precision of 88.37%, a recall of 85.14%, and an F1 score of 86.49% on the same dataset. These results suggest that GPT-4 can effectively detect protein interactions from text, offering valuable applications in mining biomedical literature.
Availability and implementation: The source code and datasets used in this study are available at https://github.com/hurlab/PPI-GPT-BERT.