SeqCode Logo SeqCode Registry
cognitis nomina
  • About
  • Search
  • •
  • Login
  • Register
Authors Guy

JSON
See as cards

Guy, Lionel


Publications
3

CitationNamesAbstract
The genome of Rhizobiales bacteria in predatory ants reveals urease gene functions but no genes for nitrogen fixation Neuvonen et al. (2016). Scientific Reports 6 (1) “Tokpelaia” “Tokpelaia hoelldobleri”
Text
Single-cell genomics of a rare environmental alphaproteobacterium provides unique insights into Rickettsiaceae evolution Martijn et al. (2015). The ISME Journal 9 (11) “Arcanibacter lacustris” “Arcanobacter lacustris”
Text
Complex archaea that bridge the gap between prokaryotes and eukaryotes Spang et al. (2015). Nature 521 (7551) Asgardarchaeota “Lokiarchaeota”

The genome of Rhizobiales bacteria in predatory ants reveals urease gene functions but no genes for nitrogen fixation
AbstractGut-associated microbiota of ants include Rhizobiales bacteria with affiliation to the genus Bartonella. These bacteria may enable the ants to fix atmospheric nitrogen, but no genomes have been sequenced yet to test the hypothesis. Sequence reads from a member of the Rhizobiales were identified in the data collected in a genome project of the ant Harpegnathos saltator. We present an analysis of the closed 1.86 Mb genome of the ant-associated bacterium, for which we suggest the species name Candidatus Tokpelaia hoelldoblerii. A phylogenetic analysis reveals a relationship to Bartonella and Brucella, which infect mammals. Novel gene acquisitions include a gene for a putative extracellular protein of more than 6,000 amino acids secreted by the type I secretion system, which may be involved in attachment to the gut epithelium. No genes for nitrogen fixation could be identified, but genes for a multi-subunit urease protein complex are present in the genome. The urease genes are also present in Brucella, which has a fecal-oral transmission pathway, but not in Bartonella, which use blood-borne transmission pathways. We hypothesize that the gain and loss of the urease function is related to transmission strategies and lifestyle changes in the host-associated members of the Rhizobiales.
Single-cell genomics of a rare environmental alphaproteobacterium provides unique insights into Rickettsiaceae evolution
Abstract The bacterial family Rickettsiaceae includes a group of well-known etiological agents of many human and vertebrate diseases, including epidemic typhus-causing pathogen Rickettsia prowazekii. Owing to their medical relevance, rickettsiae have attracted a great deal of attention and their host-pathogen interactions have been thoroughly investigated. All known members display obligate intracellular lifestyles, and the best-studied genera, Rickettsia and Orientia, include species that are hosted by terrestrial arthropods. Their obligate intracellular lifestyle and host adaptation is reflected in the small size of their genomes, a general feature shared with all other families of the Rickettsiales. Yet, despite that the Rickettsiaceae and other Rickettsiales families have been extensively studied for decades, many details of the origin and evolution of their obligate host-association remain elusive. Here we report the discovery and single-cell sequencing of ‘Candidatus Arcanobacter lacustris’, a rare environmental alphaproteobacterium that was sampled from Damariscotta Lake that represents a deeply rooting sister lineage of the Rickettsiaceae. Intriguingly, phylogenomic and comparative analysis of the partial ‘Candidatus Arcanobacter lacustris’ genome revealed the presence chemotaxis genes and vertically inherited flagellar genes, a novelty in sequenced Rickettsiaceae, as well as several host-associated features. This finding suggests that the ancestor of the Rickettsiaceae might have had a facultative intracellular lifestyle. Our study underlines the efficacy of single-cell genomics for studying microbial diversity and evolution in general, and for rare microbial cells in particular.
Search