Host recognition strategies and evolution in phages infecting the marine bacterium Alteromonas sp.

Abstract

Viruses constitute the vast majority of all biological entities in the biosphere and represent one of the biggest reservoirs of undetected genetic diversity on Earth. Of all the viral particles inhabiting the ocean, phages are the most abundant and can affect the overall microbial composition of marine ecosystems and the dynamics of global biogeochemical cycles. The interaction between prokaryotic cells and their phages is among the oldest and most intertwined host-parasite relationships on the planet. It has been extensively studied by culture, molecular biology, and experimental evolution. However, due to the difficulties of culture with environmental samples, only a few studies have analyzed the mechanisms of phage-host interaction in the marine environment. Here, we have studied the genes involved in viral host recognition and their evolutionary dynamics by focusing on two species of the marine copiotrophic bacterium Alteromonas and several phages infecting them. We described the genomic and morphological characterization of the first Alteromonas phage belonging to the Myoviridae family (Alteromonas myovirus V22) that was isolated in coastal waters of the Mediterranean Sea, and we identified its receptor-binding protein (RBP) used for host recognition by combining fluorescence microscopy and spectrometry. In addition, using size-exclusion chromatography, we showed how this protein required co-expression with a downstream protein to be functional, which later was identified as a new type of intermolecular chaperone crucial for RBP maturation. We also identified a conserved host recognition module in V22 and other unrelated alterophages belonging to different viral families and with completely different morphologies, suggesting horizontal gene transfer between the ancestors of these phages. Furthermore, we described the first coevolution study of a host-parasite system performed with Alteromonas using a metagenomics-like approach. Finally, we analyzed the micro- and macrodiversity of an alterophage population that was able to survive over a long period of time and showed remarkable genomic stability, indicating stable interactions over time between phage-host recognition structures. Overall, this study has contributed to extend the knowledge of known phage-host recognition mechanisms present in the marine ecosystem and has provided a first glimpse of the evolutionary dynamics in phages infecting Alteromonas.