The fitness cost and benefit of phase separated protein deposits

Abstract

ABSTRACTPhase separation of soluble proteins into insoluble deposits is associated with numerous diseases. However, protein deposits can also function as membrane-less compartments for many cellular processes. What are the fitness costs and benefits of forming such deposits in different conditions? Using a model protein that phase separates into deposits, we distinguish and quantify the fitness contribution due to the loss or gain of protein function and deposit formation in yeast. The environmental condition and the cellular demand for the protein function emerge as key determinants of fitness. Protein deposit formation can lead to cell-to-cell differences in free protein abundance between individuals. This results in variable manifestation of protein function and a continuous range of phenotypes in a cell population, favoring survival of some individuals in certain environments. Thus, protein deposit formation by phase separation might be a mechanism to sense protein concentration in cells and to generate phenotypic variability. The selectable phenotypic variability, previously described for prions, could be a general property of proteins that can form phase separated assemblies and may influence cell fitness.Stand-first textUsing a model protein that phase separates into deposits, we distinguish and quantify the fitness contribution due to the loss or gain of protein function and deposit formation in yeast.Bullet pointsThe presented approach identifies and quantifies different fitness effects associated with protein deposit formation due to phase separationThe environmental condition and the cellular demand for the protein function emerge as key determinants of fitness upon protein deposit formationVariability in protein deposit formation can lead to cell-to-cell differences in free protein abundance between individualsProtein phase separation can generate a continuous range of phenotypes in a cell population