# Machine learning-assisted directed protein evolution with combinatorial   libraries

**Authors:** Zachary Wu, S. B. Jennifer Kan, Russell D. Lewis, Bruce J. Wittmann,, Frances H. Arnold

arXiv: 1902.07231 · 2020-01-07

## TL;DR

This paper demonstrates how machine learning can accelerate directed protein evolution by efficiently exploring combinatorial sequence space, leading to higher fitness variants and enabling stereodivergent enzyme evolution with high enantioselectivity.

## Contribution

It introduces a machine learning-guided approach for directed protein evolution that improves efficiency and success rate over traditional methods.

## Key findings

- Machine learning models successfully predicted high-fitness protein variants.
- The approach identified enzyme variants with 93% and 79% enantiomeric excess.
- Machine learning increased throughput and diversity in protein engineering.

## Abstract

To reduce experimental effort associated with directed protein evolution and to explore the sequence space encoded by mutating multiple positions simultaneously, we incorporate machine learning in the directed evolution workflow. Combinatorial sequence space can be quite expensive to sample experimentally, but machine learning models trained on tested variants provide a fast method for testing sequence space computationally. We validate this approach on a large published empirical fitness landscape for human GB1 binding protein, demonstrating that machine learning-guided directed evolution finds variants with higher fitness than those found by other directed evolution approaches. We then provide an example application in evolving an enzyme to produce each of the two possible product enantiomers (stereodivergence) of a new-to-nature carbene Si-H insertion reaction. The approach predicted libraries enriched in functional enzymes and fixed seven mutations in two rounds of evolution to identify variants for selective catalysis with 93% and 79% ee. By greatly increasing throughput with in silico modeling, machine learning enhances the quality and diversity of sequence solutions for a protein engineering problem.

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Source: https://tomesphere.com/paper/1902.07231