Abstract
The design of novel proteins with tailored functionalities presents a transformative approach to addressing pressing biomedical challenges. In this study, we propose PrefixProt, a framework for controllable protein design that employs prefix-tuning to learn virtual tokens as control tags. These virtual tokens are adaptively tailored to diverse protein properties through a data-driven manner and can be combinatorially integrated to enable multiobjective control over protein generation. The effectiveness of PrefixProt was validated through extensive experiments encompassing both protein structure design (e.g., α helix or beta-sheet topologies) and protein function design (e.g., antimicrobial or anticancer peptide activities). Benchmark results demonstrate that prefix virtual tokens efficiently guide the pretrained ProtLM by optimizing a smaller number of trainable parameters, outperforming other parameter-efficient fine-tuning methods and text-guided ProtLMs, particularly in scenarios with limited data availability. More importantly, the compositional flexibility of virtual tokens facilitates the generation of proteins with multiple target properties, substantially expanding the scope of the design possibilities. PrefixProt establishes a robust framework for de novo protein design with promising applications in drug discovery and biomedicine.