Proteins–molecular machines that underpin all biological life–are of significant therapeutic and industrial value. Directed evolution is a high-throughput experimental approach for improving protein function, but has difficulty escaping local maxima in the fitness landscape. Here, we investigate how supervised learning in a closed loop with DNA synthesis and high-throughput screening can be used to improve protein design. Using the green fluorescent protein (GFP) as an illustrative example, we demonstrate the opportunities and challenges of generating training datasets conducive to selecting strongly generalizing models. With prospectively designed wet lab experiments, we then validate that these models can generalize to unseen regions of the fitness landscape, even when constrained to explore combinations of non-trivial mutations. Taken together, this suggests a hybrid optimization strategy for protein design in which a predictive model is used to explore difficult-to-access but promising regions of the fitness landscape that directed evolution can then exploit at scale.
@article{biswas2018toward, year = {2018}, title = {Toward machine-guided design of proteins}, author = {Biswas, Surojit and Kuznetsov, Gleb and Ogden, Pierce J and Conway, Nicholas J and Adams, Ryan P and Church, George M}, journal = {BioRxiv}, pages = {337154}, publisher = {Cold Spring Harbor Laboratory} }