Nicolas Deutschmann , Aurelien Pelissier , Anna Weber , Shuaijun Gao , Jasmina Bogojeska , María Rodríguez Martínez
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引用次数: 0
Abstract
Deciphering the antigen recognition capabilities by T-cell and B-cell receptors (antibodies) is essential for advancing our understanding of adaptive immune system responses. In recent years, the development of protein language models (PLMs) has facilitated the development of bioinformatic pipelines where complex amino acid sequences are transformed into vectorized embeddings, which are then applied to a range of downstream analytical tasks. With their success, we have witnessed the emergence of domain-specific PLMs tailored to specific proteins, such as immune receptors. Domain-specific models are often assumed to possess enhanced representation capabilities for targeted applications, however, this assumption has not been thoroughly evaluated. In this manuscript, we assess the efficacy of both generalist and domain-specific transformer-based embeddings in characterizing B and T-cell receptors. Specifically, we assess the accuracy of models that leverage these embeddings to predict antigen specificity and elucidate the evolutionary changes that B cells undergo during an immune response. We demonstrate that the prevailing notion of domain-specific models outperforming general models requires a more nuanced examination. We also observe remarkable differences between generalist and domain-specific PLMs, not only in terms of performance but also in the manner they encode information. Finally, we observe that the choice of the size and the embedding layer in PLMs are essential model hyperparameters in different tasks. Overall, our analyzes reveal the promising potential of PLMs in modeling protein function while providing insights into their information-handling capabilities. We also discuss the crucial factors that should be taken into account when selecting a PLM tailored to a particular task.
破译 T 细胞和 B 细胞受体(抗体)的抗原识别能力对于加深我们对适应性免疫系统反应的理解至关重要。近年来,蛋白质语言模型(PLM)的发展促进了生物信息学管道的发展,复杂的氨基酸序列被转化为矢量化嵌入,然后应用于一系列下游分析任务。随着这些模型的成功,我们看到了针对特定蛋白质(如免疫受体)的领域特异性 PLM 的出现。领域特异性模型通常被认为具有更强的表示能力,可用于有针对性的应用,但这一假设尚未得到全面评估。在本手稿中,我们评估了基于通用和特定领域变换器的嵌入在表征 B 细胞和 T 细胞受体方面的功效。具体来说,我们评估了利用这些嵌入来预测抗原特异性的模型的准确性,并阐明了 B 细胞在免疫反应过程中所经历的进化变化。我们证明,目前流行的领域特异性模型优于通用模型的概念需要更细致的研究。我们还观察到通用和特定领域 PLM 之间的显著差异,这不仅体现在性能上,还体现在它们编码信息的方式上。最后,我们观察到,在不同的任务中,选择 PLM 的大小和嵌入层是至关重要的模型超参数。总之,我们的分析揭示了 PLM 在蛋白质功能建模方面的巨大潜力,同时也提供了对其信息处理能力的深入了解。我们还讨论了在选择适合特定任务的 PLM 时应考虑的关键因素。