Adaptive Mutations that Prevent Crosstalk Enable the Expansion of Paralogous Signaling Protein Families

Orthologous proteins often harbor numerous substitutions, but whether these differences result from neutral or adaptive processes is usually unclear. To tackle this challenge, we examined the divergent evolution of a model bacterial signaling pathway comprising the kinase PhoR and its cognate substr...

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Bibliographic Details
Published in:Cell 2012-07, Vol.150 (1), p.222-232
Main Authors: Capra, Emily J., Perchuk, Barrett S., Skerker, Jeffrey M., Laub, Michael T.
Format: Article
Language:English
Subjects:
alpha-Proteobacteria
Alphaproteobacteria - genetics
Alphaproteobacteria - metabolism
Bacterial Proteins - genetics
divergent evolution
Evolution, Molecular
insulating materials
Mutation
Phylogeny
proteins
Selection, Genetic
Signal Transduction
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Summary:Orthologous proteins often harbor numerous substitutions, but whether these differences result from neutral or adaptive processes is usually unclear. To tackle this challenge, we examined the divergent evolution of a model bacterial signaling pathway comprising the kinase PhoR and its cognate substrate PhoB. We show that the specificity-determining residues of these proteins are typically under purifying selection but have, in α-proteobacteria, undergone a burst of diversification followed by extended stasis. By reversing mutations that accumulated in an α-proteobacterial PhoR, we demonstrate that these substitutions were adaptive, enabling PhoR to avoid crosstalk with a paralogous pathway that arose specifically in α-proteobacteria. Our findings demonstrate that duplication and the subsequent need to avoid crosstalk strongly influence signaling protein evolution. These results provide a concrete example of how system-wide insulation can be achieved postduplication through a surprisingly limited number of mutations. Our work may help explain the apparent ease with which paralogous protein families expanded in all organisms. [Display omitted] ► The prevention of crosstalk constrains the evolution of signaling proteins ► Unless duplicated, the specificity residues of signaling proteins rarely change ► Avoiding crosstalk between pathways after duplication is a major selective pressure ► Insulating duplicated signaling proteins requires changes in specificity residues Following gene duplication, selective pressure to avoid signaling crosstalk drives gene divergence, promoting a burst of mutations in specificity determining residues.
ISSN:0092-8674
1097-4172
DOI:10.1016/j.cell.2012.05.033