Selection of a Promiscuous Minimalist CAMP Phosphodiesterase from a Library of De Novo Designed Proteins

Overview

Journal Nat Chem

Specialty Chemistry

Date 2024 May 3

PMID 38702405

Authors

J David Schnettler

Michael S Wang

Maximilian Gantz

H Adrian Bunzel

Christina Karas

Florian Hollfelder

Michael H Hecht

Affiliations

Soon will be listed here.

Abstract

The ability of unevolved amino acid sequences to become biological catalysts was key to the emergence of life on Earth. However, billions of years of evolution separate complex modern enzymes from their simpler early ancestors. To probe how unevolved sequences can develop new functions, we use ultrahigh-throughput droplet microfluidics to screen for phosphoesterase activity amidst a library of more than one million sequences based on a de novo designed 4-helix bundle. Characterization of hits revealed that acquisition of function involved a large jump in sequence space enriching for truncations that removed >40% of the protein chain. Biophysical characterization of a catalytically active truncated protein revealed that it dimerizes into an α-helical structure, with the gain of function accompanied by increased structural dynamics. The identified phosphodiesterase is a manganese-dependent metalloenzyme that hydrolyses a range of phosphodiesters. It is most active towards cyclic AMP, with a rate acceleration of ~10 and a catalytic proficiency of >10 M, comparable to larger enzymes shaped by billions of years of evolution.

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