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SES-Adapter enhances protein language models (PLMs) by integrating structural information, improving downstream task performance and accelerating convergence. This method offers significant gains even with low-quality structural data.

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Area of Science:

  • Computational Biology
  • Bioinformatics
  • Machine Learning

Background:

  • Fine-tuning pretrained protein language models (PLMs) is crucial for downstream prediction tasks.
  • Parameter-efficient fine-tuning techniques from natural language processing show promise but face challenges in life sciences.
  • Adapting these techniques requires addressing differences in training strategies and data formats.

Purpose of the Study:

  • To introduce SES-Adapter, a novel method for enhancing PLM representation learning in life sciences.
  • To create structure-aware protein representations by combining PLM embeddings with structural sequence embeddings.
  • To demonstrate the efficiency and scalability of SES-Adapter across various PLM architectures and tasks.

Main Methods:

  • Developed SES-Adapter, a parameter-efficient fine-tuning method.
  • Integrated protein language model embeddings with structural sequence embeddings.
  • Evaluated SES-Adapter on diverse downstream tasks using 9 benchmark datasets and 2 types of folding structures.

Main Results:

  • SES-Adapter improved downstream task performance by an average of 3% and up to 11% compared to vanilla PLMs.
  • Achieved significant acceleration in convergence speed, averaging 362% and up to 1034%.
  • Demonstrated improved training efficiency (approximately 2x) and robustness with low-quality predicted structures.

Conclusions:

  • SES-Adapter is a compatible and effective method for enhancing PLMs across different architectures and tasks.
  • The approach significantly boosts performance, accelerates convergence, and improves training efficiency.
  • SES-Adapter shows promise for advancing protein representation learning, even with imperfect structural data.