Leveraging a large language model to predict protein phase transition: A physical, multiscale, and interpretable approach

Frank, Mor; Ni, Pengyu; Jensen, Matthew; Gerstein, Mark B.

doi:10.1073/pnas.2320510121

Proc. Natl. Acad. Sci. U.S.A.

2024

DOI: 10.1073/pnas.2320510121

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Leveraging a large language model to predict protein phase transition: A physical, multiscale, and interpretable approach

Mor Frank,

Pengyu Ni,

Matthew Jensen

et al.

Abstract: Protein phase transitions (PPTs) from the soluble state to a dense liquid phase (forming droplets via liquid–liquid phase separation) or to solid aggregates (such as amyloids) play key roles in pathological processes associated with age-related diseases such as Alzheimer’s disease. Several computational frameworks are capable of separately predicting the formation of droplets or amyloid aggregates based on protein sequences, yet none have tackled the prediction of both within a unified framework. Recently, lar… Show more

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Cited by 2 publications

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Efficient Inference, Training, and Fine-tuning of Protein Language Models

Çelik,

Xie

2024

Preprint

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Protein language models have shown great promise in predicting protein structure, function, and the effects of missense variants on protein fitness. However, their use has been limited by the substantial computational resources required. In this work, we focus on improving the computational efficiency of protein language models (PLMs), specifically the Evolutionary Scale Modeling (ESM) family, to increase the accessibility of PLMs. By implementing optimizations such as FlashAttention and Partition-Attention, a novel technique designed to handle proteins of variable length, we achieved a 16-fold speedup in inference time and reduced memory usage by 3 to 14 times for long proteins. Additionally, 4-bit quantization applied to billion-parameter models led to a 2 to 3 times reduction in memory consumption with minimal performance loss in the missense variant effect prediction task. Training efficiency was also improved, with a 6-fold reduction in runtime achieved through activation checkpointing and the DeepSpeed Zero-Offload strategy. For fine-tuning, we employed parameter-efficient methods, enabling state-of-the-art predictions of protein properties and functions by training only the model head or a small fraction of adapter weights. For instance, we achieved a Spearman's correlation coefficient of 70% in melting point prediction and an 87% area under the precision-recall curve (AU-PRC) for transcription factor prediction. Our efficient ESM (ESME) implementation significantly lowers the barrier to using these powerful models, making them accessible to academic laboratories with limited computational resources. The ESME implementation is available on PyPI (pypi.org/project/esm-efficient) and GitHub (github.com/uci-cbcl/esm-efficient).

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Efficient Inference, Training, and Fine-tuning of Protein Language Models

Çelik,

Xie

2024

Preprint

View full text Add to dashboard Cite

show abstract

PSTP: Decoding Latent Sequence Grammar for Protein Phase Separation through Transfer Learning and Attention

Feng,

Liu,

Xian

et al. 2024

Preprint

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Phase separation (PS) is essential in various biological processes, necessitating high-accuracy predictive algorithms to study numerous uncharacterized sequences and accelerate experimental validation. However, many recent prediction methods face challenges in generalizability due to their reliance on engineered features, and accurately identifying protein regions involved in PS remains difficult. We propose PSTP, which employs a dual-language model embedding strategy and a lightweight attention model. PSTP achieves identification of 84% of PS regions in PhaSePro and demonstrates ~50% improvement in correlation coefficient over existing models. It shows robust performance across different types of PS proteins, and shows the potential for predicting artificial proteins. By analyzing 160,000 variants, PSTP characterizes the link between the incidence of pathogenic variants and residue-level PS propensities. PSTP's predictive power and broad applicability make it a valuable tool for accelerating our understanding of biomolecular condensates, and their mechanisms underlying disease development.

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Leveraging a large language model to predict protein phase transition: A physical, multiscale, and interpretable approach

Cited by 2 publications

References 51 publications

Efficient Inference, Training, and Fine-tuning of Protein Language Models

Efficient Inference, Training, and Fine-tuning of Protein Language Models

PSTP: Decoding Latent Sequence Grammar for Protein Phase Separation through Transfer Learning and Attention

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