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Tree Search-Based Evolutionary Bandits for Protein Sequence Optimization

Biomolecules 2024-01-15 v1 Machine Learning

Abstract

While modern biotechnologies allow synthesizing new proteins and function measurements at scale, efficiently exploring a protein sequence space and engineering it remains a daunting task due to the vast sequence space of any given protein. Protein engineering is typically conducted through an iterative process of adding mutations to the wild-type or lead sequences, recombination of mutations, and running new rounds of screening. To enhance the efficiency of such a process, we propose a tree search-based bandit learning method, which expands a tree starting from the initial sequence with the guidance of a bandit machine learning model. Under simplified assumptions and a Gaussian Process prior, we provide theoretical analysis and a Bayesian regret bound, demonstrating that the combination of local search and bandit learning method can efficiently discover a near-optimal design. The full algorithm is compatible with a suite of randomized tree search heuristics, machine learning models, pre-trained embeddings, and bandit techniques. We test various instances of the algorithm across benchmark protein datasets using simulated screens. Experiment results demonstrate that the algorithm is both sample-efficient and able to find top designs using reasonably small mutation counts.

Keywords

Cite

@article{arxiv.2401.06173,
  title  = {Tree Search-Based Evolutionary Bandits for Protein Sequence Optimization},
  author = {Jiahao Qiu and Hui Yuan and Jinghong Zhang and Wentao Chen and Huazheng Wang and Mengdi Wang},
  journal= {arXiv preprint arXiv:2401.06173},
  year   = {2024}
}

Comments

AAAI 2024

R2 v1 2026-06-28T14:14:39.168Z