PLoS Computational Biology (Nov 2023)

Computational design of novel Cas9 PAM-interacting domains using evolution-based modelling and structural quality assessment.

  • Cyril Malbranke,
  • William Rostain,
  • Florence Depardieu,
  • Simona Cocco,
  • Rémi Monasson,
  • David Bikard

DOI
https://doi.org/10.1371/journal.pcbi.1011621
Journal volume & issue
Vol. 19, no. 11
p. e1011621

Abstract

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We present here an approach to protein design that combines (i) scarce functional information such as experimental data (ii) evolutionary information learned from a natural sequence variants and (iii) physics-grounded modeling. Using a Restricted Boltzmann Machine (RBM), we learn a sequence model of a protein family. We use semi-supervision to leverage available functional information during the RBM training. We then propose a strategy to explore the protein representation space that can be informed by external models such as an empirical force-field method (FoldX). Our approach is applied to a domain of the Cas9 protein responsible for recognition of a short DNA motif. We experimentally assess the functionality of 71 variants generated to explore a range of RBM and FoldX energies. Sequences with as many as 50 differences (20% of the protein domain) to the wild-type retained functionality. Overall, 21/71 sequences designed with our method were functional. Interestingly, 6/71 sequences showed an improved activity in comparison with the original wild-type protein sequence. These results demonstrate the interest in further exploring the synergies between machine-learning of protein sequence representations and physics grounded modeling strategies informed by structural information.