Evolutionary pressures on microbial metabolic strategies in the chemostat
نویسندگان
چکیده
Protein expression is shaped by evolutionary processes that tune microbial fitness. The limited biosynthetic capacity of a cell constrains protein expression and forces the cell to carefully manage its protein economy. In a chemostat, the physiology of the cell feeds back on the growth conditions, hindering intuitive understanding of how changes in protein concentration affect fitness. Here, we aim to provide a theoretical framework that addresses the selective pressures and optimal evolutionary-strategies in the chemostat. We show that the optimal enzyme levels are the result of a trade-off between the cost of their production and the benefit of their catalytic function. We also show that deviations from optimal enzyme levels are directly related to selection coefficients. The maximal fitness strategy for an organism in the chemostat is to express a well-defined metabolic subsystem known as an elementary flux mode. Using a coarse-grained, kinetic model of Saccharomyces cerevisiae's metabolism and growth, we illustrate that the dynamics and outcome of evolution in a chemostat can be very counter-intuitive: Strictly-respiring and strictly-fermenting strains can evolve from a common ancestor. This work provides a theoretical framework that relates a kinetic, mechanistic view on metabolism with cellular physiology and evolutionary dynamics in the chemostat.
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The chemostat Evolutionary pressures on microbial metabolic strategies in the chemostat In collaboration with :
Protein expression is shaped by evolutionary pressures. Due to limitations in biosynthetic capacity, the costs and benefits of enzyme production are important determinants of fitness. While these processes are well understood in batch conditions, in chemostats, which are extensively used to study microbial evolution in a laboratory setting, a feedback of the microbial physiology on the conditio...
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