Ruegeria pomeroyi DSS-3 is a model Roseobacter marine bacterium, particularly regarding its catabolism of dimethylsulfoniopropionate (DMSP), an abundant anti-stress molecule made by marine phytoplankton. We found a novel gene, dddW, which encodes a DMSP lyase that cleaves DMSP into acrylate plus the environmentally important volatile dimethyl sulfide (DMS). Mutations in dddW reduced, but did not abolish DMS production. Transcription of dddW was greatly enhanced by pre-growth of cells with DMSP, via a LysR-type regulator. Close DddW homologs occur in only one other Roseobacter species, and there are no close homologs and only a few related sequences in metagenomes of marine bacteria. In addition to DddW, R. pomeroyi DSS-3 had been shown to have two other, different, DMSP lyases, DddP and DddQ, plus an enzyme that demethylates DMSP, emphasizing the importance of this substrate for this model bacterium.
Ruegeria (previously Silicibacter) pomeroyi DSS-3, a marine roseobacter, can catabolize dimethylsulfoniopropionate (DMSP), a compatible solute that is made in large amounts by marine plankton and algae. This strain was known to demethylate DMSP via a demethylase, encoded by the dmdA gene, and it can also cleave DMSP, releasing the environmentally important volatile dimethyl sulfide (DMS) in the process. We found that this strain has two different genes, dddP and dddQ, which encode enzymes that cleave DMSP, generating DMS plus acrylate. DddP had earlier been found in other roseobacters and is a member of the M24 family of peptidases. The newly discovered DddQ polypeptide contains a predicted cupin metal-binding pocket, but has no other similarity to any other polypeptide with known function. DddP(-) and DddQ(-) mutants each produced DMS at significantly reduced levels compared with wild-type R. pomeroyi DSS-3, and transcription of the corresponding ddd genes was enhanced when cells were pre-grown with DMSP. Ruegeria pomeroyi DSS-3 also has a gene product that is homologous to DddD, a previously identified enzyme that cleaves DMSP, but which forms DMS plus 3-OH-propionate as the initial catabolites. However, mutations in this dddD-like gene did not affect DMS production, and it was not transcribed under our conditions. Another roseobacter strain, Roseovarius nubinhibens ISM, also contains dddP and has two functional copies of dddQ, encoded by adjacent genes. Judged by their frequencies in the Global Ocean Sampling metagenomic databases, DddP and DddQ are relatively abundant among marine bacteria compared with the previously identified DddL and DddD enzymes.
Salmonella enterica serotype Typhimurium (S. Typhimurium) is a leading cause of gastroenteritis and bacteraemia worldwide, and a model organism for the study of host-pathogen interactions. Two S. Typhimurium strains (SL1344 and ATCC14028) are widely used to study host-pathogen interactions, yet genotypic variation results in strains with diverse host range, pathogenicity and risk to food safety. The population structure of diverse strains of S. Typhimurium revealed a major phylogroup of predominantly sequence type 19 (ST19) and a minor phylogroup of ST36. The major phylogroup had a population structure with two high order clades (α and β) and multiple subclades on extended internal branches, that exhibited distinct signatures of host adaptation and anthropogenic selection. Clade α contained a number of subclades composed of strains from well characterized epidemics in domesticated animals, while clade β contained multiple subclades associated with wild avian species. The contrasting epidemiology of strains in clade α and β was reflected by the distinct distribution of antimicrobial resistance (AMR) genes, accumulation of hypothetically disrupted coding sequences (HDCS), and signatures of functional diversification. These observations were consistent with elevated anthropogenic selection of clade α lineages from adaptation to circulation in populations of domesticated livestock, and the predisposition of clade β lineages to undergo adaptation to an invasive lifestyle by a process of convergent evolution with of host adapted Salmonella serotypes. Gene flux was predominantly driven by acquisition and recombination of prophage and associated cargo genes, with only occasional loss of these elements. The acquisition of large chromosomally-encoded genetic islands was limited, but notably, a feature of two recent pandemic clones (DT104 and monophasic S. Typhimurium ST34) of clade α (SGI-1 and SGI-4).
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