Phenotypic and genotypic adaptation of Escherichia coli to thermal stress is contingent on genetic background.
Tiffany N BatarsehSarah N BatarsehAlejandra Rodríguez-VerdugoBrandon S GautPublished in: Molecular biology and evolution (2023)
Evolution can be contingent on history, but we do not yet have a clear understanding of the processes and dynamics that govern contingency. Here we performed the second phase of a two-phase evolution experiment to investigate features of contingency. The first phase of the experiment was based on Escherichia coli clones that had evolved at the stressful temperature of 42.2°C. The Phase 1 lines generally evolved through two adaptive pathways: mutations of rpoB, which encodes the beta subunit of RNA polymerase, or through rho, a transcriptional terminator. We hypothesized that epistatic interactions within the two pathways constrained their future adaptative potential, thus affecting patterns of historical contingency. Using 10 different E. coli Founders representing both adaptive pathways, we performed a second phase of evolution at 19.0°C to investigate how prior genetic divergence or adaptive pathway (rpoB vs. rho) affects evolutionary outcomes. We found that phenotype, as measured by relative fitness, was contingent on founder genotypes and pathways. This finding extended to genotypes, because E. coli from different Phase 1 histories evolved by adaptive mutations in distinct sets of genes. Our results suggest that evolution depends critically on genetic history, likely due to idiosyncratic epistatic interactions within and between evolutionary modules.