Authors
Maximilian R Stammnitz, Ben Lehner
Published in
Nature communications. Volume 17. Issue 1. Apr 01, 2026. Epub Apr 01, 2026.
Abstract
Many proteins function as switches, transducing the concentrations of environmental chemicals into cellular responses. It is not well understood how signal processing by switches is genetically encoded. Here, using a massively parallel approach, GluePCA, we present >40,000 measurements and a complete map of how mutations alter the quantitative activation function of a receptor switch, the plant hormone sensor PYL1. Close to 90% of missense variants tune the dose-response of the receptor, often causing correlated changes in sensitivity, basal activity, maximum response and induction steepness. Based on theory we predict and then validate the underlying latent mechanism as a change in protein stability. Beyond this, signalling parameters can be independently tuned, with large effects in interface-distal positions and a modular genetic architecture across the receptor's structure. Rare single amino acid substitutions confer phenotypic innovation, including inverted and band-stop activation functions. Our data demonstrate the feasibility of dose-response profile quantification at massive scale and reveal the remarkable evolutionary malleability of a protein switch.
PMID:
41922352
Bibliographic data and abstract were imported from PubMed on 14 Jun 2026.
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