AbstractTo understand the variation of protein sequences in nature, we need to reckon with evolutionary constraints that are biophysical, cellular, and ecological. Here, we show that under the global selection against protein misfolding, there exists a scaling among protein folding stability, protein cellular abundance, and effective population size. The specific scaling implies that the several-orders-of-magnitude range of protein abundances in the cell should leave imprints on extant protein structures, a prediction that is supported by our structural analysis of the yeast proteome
Proteins emerged from the evolutionary process shaped by natural selection. Insights into the evolut...
The properties of biomolecules depend both on physics and on the evolutionary process that formed th...
SummaryGenome-wide studies in Saccharomyces cerevisiae concluded that the dominant determinant of pr...
AbstractTo understand the variation of protein sequences in nature, we need to reckon with evolution...
SummaryThe consistent observation across all kingdoms of life that highly abundant proteins evolve s...
The consistent observation across all kingdoms of life that highly abundant proteins evolve slowly d...
requirement for highly expressed proteins to evolve slowly. Lastly, we predict from multiscale evolu...
The diverse array of protein functions depends upon these molecules' reliable ability to fold into t...
Much recent work has explored molecular and population-genetic constraints on the rate of protein se...
Abstract Background Despite a strong evolutionary pressure to reduce genome size, proteins vary in l...
AbstractThe rate of evolution-related mutation varies widely among proteins while the unity of the o...
AbstractExperimentally measured rates of spontaneous folding of single-domain globular proteins rang...
The availability of many genome sequences gives us abundant information, which is, however, very dif...
The rate of protein evolution varies more than 1000-fold and, for the past 30 years, it was thought ...
We investigate how a protein's structure influences the rate at which its sequence evolves. Our basi...
Proteins emerged from the evolutionary process shaped by natural selection. Insights into the evolut...
The properties of biomolecules depend both on physics and on the evolutionary process that formed th...
SummaryGenome-wide studies in Saccharomyces cerevisiae concluded that the dominant determinant of pr...
AbstractTo understand the variation of protein sequences in nature, we need to reckon with evolution...
SummaryThe consistent observation across all kingdoms of life that highly abundant proteins evolve s...
The consistent observation across all kingdoms of life that highly abundant proteins evolve slowly d...
requirement for highly expressed proteins to evolve slowly. Lastly, we predict from multiscale evolu...
The diverse array of protein functions depends upon these molecules' reliable ability to fold into t...
Much recent work has explored molecular and population-genetic constraints on the rate of protein se...
Abstract Background Despite a strong evolutionary pressure to reduce genome size, proteins vary in l...
AbstractThe rate of evolution-related mutation varies widely among proteins while the unity of the o...
AbstractExperimentally measured rates of spontaneous folding of single-domain globular proteins rang...
The availability of many genome sequences gives us abundant information, which is, however, very dif...
The rate of protein evolution varies more than 1000-fold and, for the past 30 years, it was thought ...
We investigate how a protein's structure influences the rate at which its sequence evolves. Our basi...
Proteins emerged from the evolutionary process shaped by natural selection. Insights into the evolut...
The properties of biomolecules depend both on physics and on the evolutionary process that formed th...
SummaryGenome-wide studies in Saccharomyces cerevisiae concluded that the dominant determinant of pr...