The primary technical focus of the project has been on developing methods for evolving and engineering allosteric protein switches using phage-assisted evolution, a key objective of this ERC project. We successfully created a robust phage-assisted evolution pipeline to evolve switchable proteins, optimizing plasmid-based positive and negative selection circuits to monitor effector protein activity under specific stimuli. In parallel, we established a scalable method to generate and screen receptor insertion libraries in effector proteins in E. coli (Mathony et al., Advanced Science 10:28, 2023;
https://doi.org/10.1002/advs.202303496(öffnet in neuem Fenster)). Building on this groundwork, we performed iterative evolution on effector-receptor hybrid proteins, notably evolving an AraC-LOV2 hybrid transcription factor. These efforts yielded optimized switchable proteins whose activity levels surpassed the parental proteins by orders of magnitude, demonstrating the robustness and efficiency of our evolution strategies (manuscript in preparation).
We significantly expanded the phage-assisted evolution capabilities by integrating a retron-based indel mutagenesis method, allowing exploration of not only point mutations but also insertions and deletions, thereby dramatically broadening the accessible fitness landscape.
On the computational side, we developed ProDomino, a machine learning model that predicts viable insertion sites for domain insertion-based allosteric control. Trained on semi-synthetic datasets and refined using experimental data from Objective 1, ProDomino enables accurate inference of insertion points and allosteric sites across diverse protein families (Wolf et al., bioRxiv, 2024;
https://www.biorxiv.org/content/10.1101/2024.12.04.626757v1(öffnet in neuem Fenster)). Early applications of the model, including successful validation in complex effectors such as CRISPR-Cas9 and Cas12a, have demonstrated its versatility and significant potential for rational, scalable protein engineering.
Finally, we initiated preparatory steps for creating switchable mammalian transcription factors. We engineered highly potent light-switchable synthetic transcription factors (Gal4-VP64 and dCas9-VPR) using LOV2 domain fusions, establishing a strong technological basis for Objective 3 (Münch et al., originally posted on bioRxiv and now published in Nucleic Acids Research;
https://pubmed.ncbi.nlm.nih.gov/39676667/(öffnet in neuem Fenster)). These achievements lay the foundation for engineering switchable Yamanaka factors to enable inducible cellular reprogramming, extending the scope of the project toward therapeutic and regenerative applications.