Long-run bacteria-phage coexistence dynamics under natural habitat conditions in an environmental biotechnology system

Abstract

AbstractBacterial viruses are widespread and abundant across natural and engineered habitats. They influence ecosystem functioning through interactions with their hosts. Laboratory studies of phage-host pairs have advanced our understanding of phenotypic and genetic diversification in bacteria and phages. However, the dynamics of phage-host interactions has been seldom recorded in complex natural environments. We conducted an observational metagenomic study of the dynamics of interaction between Gordonia and their phages using a three-year data series of samples collected from a full-scale wastewater treatment plant. The aim was to obtain a comprehensive picture of the coevolution dynamics in naturally evolving populations at relatively high time resolution. Co-evolution was followed by monitoring changes over time in the CRISPR loci of Gordonia metagenome-assembled genome, and reciprocal changes in the viral genome. Genome-wide analysis indicated low strain variability of Gordonia, and almost clonal conservation of the trailer-end of the CRISPR loci. Incorporation of newer spacers gave rise to multiple coexisting bacterial populations. A host population containing a CRISPR array variant, which did not contain spacers against the coexisting phages, accounted for more than half of the total host abundance in the majority of samples. Phages genome co-evolved by introducing directional changes, with no preference for mutations within the protospacer and PAM regions. Metagenomic reconstruction of time-resolved variants of host and virus genomes revealed how selection operates at the population level. In activated sludge, it differed from the arms-race observed in nutrient rich media and resembled the fluctuating selection dynamics observed in natural environments.