What does this research mean for the field?

Engineered potyviral proteases outperform commercially available tobacco etch virus protease in terms of efficiency and substrate specificity. Novelty: ClaimNovelty.NOVEL_FINDING. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This research aims to improve the efficiency and specificity of potyviral proteases through co-evolutionary modeling.

February 28, 2026Open Access

Identification and engineering of highly functional potyviral proteases in cells using co-evolutionary models

Key Points

This research aims to improve the efficiency and specificity of potyviral proteases through co-evolutionary modeling.
Developed a co-evolutionary model to predict protease function
Validated predictions at single amino-acid resolution
Engineered proteases that surpass commercial options
Demonstrated crosstalk to trigger synthetic cell death in human cells.
Identified several engineered proteases with superior performance
Engineered proteases successfully triggered a cell-death program
Proved the effectiveness of co-evolutionary models for protease engineering.

Abstract

Abstract Efficiency and substrate specificity of proteases in the Potyviridae family have not been comprehensively profiled. Here we develop a model that learns co-evolutionary features to accurately predict and experimentally validate protease performance at single amino-acid resolution. We identify and engineer several proteases that perform better than the commercially available tobacco etch virus protease. To demonstrate the resolving power of our methods, we engineer protease crosstalk to selectively trigger a synthetic cell-death program in human cells.

Identification and engineering of highly functional potyviral proteases in cells using co-evolutionary models

Key Points

Abstract

Cite This Study