The complete genome of a new marine Thaumarchaea strain contains evidence of previous virus infection and a possible defense mechanism from infection

While marine viruses have been isolated from several marine bacterial phyla, no reported viruses have been isolated from mesophilic marine archaea. There is growing evidence for viruses that infect marine Thaumarchaea, an abundant phylum of mesophilic archaea that are important in C and N cycles in the ocean. We have recently sequenced the complete genome of new Thaumarchaeota strain, SPOT01, that contains evidence of viral infection. Two independent virus finding programs, VirSorter and phiSpy, indicate the genome contains a ~ 20 kb region that is likely viral in origin. Manual inspection of this region, including comparison to known viral proteins, also supports that this region contains viral genes. It is unclear if this region is a viable prophage or the remnants of a previous lytic infection. Next to this region are genes for a newly recognized form of DNA modification, phosphorothioation (PT), and an adjacent operon that likely encodes a restriction endonuclease (RE). PT genes are found in a variety of bacteria and archaea, but this is the first example of PT genes in a marine achaeon. PT and adjacent RE genes in Salmonella enterica have been shown to function as a restriction modification system—non PT-modified DNA is degraded by the PT system RE such that the host is protected from invasion of foreign DNA. The discovery of both PT and adjacent RE genes in SPOT01 is novel among marine microbes, and we hypothesize that they act to restrict infection by degrading non PT-modified viral DNA. Recruitment of metagenomes from a near-shore site off California indicates that the putative virus and PT regions are found in roughly 25% and 2% respectively of Thaumarchaea in the field. Results from PacBio sequencing will be presented on which genomic sites are PT modified. This new genome provides compelling evidence that marine Thaumarchaea are susceptible to viral infection and possess a potential new mechanism for defense from infection.