Defensive hypervariable regions confer superinfection exclusion in microviruses.
Paul C KirchbergerZachary A MartinezLandry J LukerHoward OchmanPublished in: Proceedings of the National Academy of Sciences of the United States of America (2021)
Single-stranded DNA phages of the family Microviridae have fundamentally different evolutionary origins and dynamics than the more frequently studied double-stranded DNA phages. Despite their small size (around 5 kb), which imposes extreme constraints on genomic innovation, they have adapted to become prominent members of viromes in numerous ecosystems and hold a dominant position among viruses in the human gut. We show that multiple, divergent lineages in the family Microviridae have independently become capable of lysogenizing hosts and have convergently developed hypervariable regions in their DNA pilot protein, which is responsible for injecting the phage genome into the host. By creating microviruses with combinations of genomic segments from different phages and infecting Escherichia coli as a model system, we demonstrate that this hypervariable region confers the ability of temperate Microviridae to prevent DNA injection and infection by other microviruses. The DNA pilot protein is present in most microviruses, but has been recruited repeatedly into this additional role as microviruses altered their lifestyle by evolving the ability to integrate in bacterial genomes, which linked their survival to that of their hosts. Our results emphasize that competition between viruses is a considerable and often overlooked source of selective pressure, and by producing similar evolutionary outcomes in distinct lineages, it underlies the prevalence of hypervariable regions in the genomes of microviruses and perhaps beyond.
Keyphrases
- circulating tumor
- cell free
- single molecule
- escherichia coli
- nucleic acid
- binding protein
- climate change
- genome wide
- pseudomonas aeruginosa
- cardiovascular disease
- study protocol
- gene expression
- type diabetes
- weight loss
- metabolic syndrome
- copy number
- small molecule
- multidrug resistant
- protein protein
- dna methylation
- candida albicans