Abstract
AbstractMany non-sporulating Bacterial species survive prolonged resource exhaustion, by entering a state termed long-term stationary phase (LTSP). Here, we performed LTSP evolutionary experiments on the bacteriumPseudomonas putida, followed by whole genome sequencing of evolved clones. We show thatP. putidais able to persist and adapt genetically under LTSP. We observed a gradual accumulation of mutations within the evolvingP. putidapopulations. Within each population, independently evolving lineages are established early on and persist throughout the four-month-long experiment. Mutations accumulate in a highly convergent manner, with similar loci being mutated across independently evolving populations. Across populations, mutators emerge, that due to mutations within mismatch repair genes developed a much higher rate of mutation than other clones with which they co-existed within their respective populations. While these general dynamics of the adaptive process are quite similar to those we previously observed in the model bacteriumEscherichia coli, the specific loci that are involved in adaptation only partially overlap betweenP. putidaandE. coli.Significance statementBacteria often face conditions of prolonged nutrient limitation, following periods of growth. One strategy for dealing with this challenge is entry into a state termed long-term stationary phase (LTSP), in which a small minority of cells within a population can survive and persist, by recycling the remains of their deceased brethren. Here, we broaden our understanding of adaptation under LTSP, by studying it in the bacteriumPseudomonas putida. We show that many of the dynamics of LTSP genetic adaptation are quite general, as reflected by great similarity to what was previously observed in the model bacteriumEscherichia coli. However, the specific loci that are involved in adaptation substantially vary betweenP. putidaandE. coli.
Publisher
Cold Spring Harbor Laboratory