The first complete genomic structure of Butyrivibrio fibrisolvens and its chromid.

TitleThe first complete genomic structure of Butyrivibrio fibrisolvens and its chromid.
Publication TypeJournal Article
Year of Publication2018
AuthorsHernáez, JRodríguez, Cucchi, MEsperanza, Cravero, S, Martinez, MCarolina, Gonzalez, S, Puebla, A, Dopazo, J, Farber, M, Paniego, N, Rivarola, M
JournalMicrob Genom
Date Published2018 10
KeywordsAnimals; Butyrivibrio fibrisolvens; Cattle; Genome, Bacterial; Genomics; Humans; Milk; Rumen; Sequence Analysis, DNA

Butyrivibrio fibrisolvens forms part of the gastrointestinal microbiome of ruminants and other mammals, including humans. Indeed, it is one of the most common bacteria found in the rumen and plays an important role in ruminal fermentation of polysaccharides, yet, to date, there is no closed reference genome published for this species in any ruminant animal. We successfully assembled the nearly complete genome sequence of B. fibrisolvens strain INBov1 isolated from cow rumen using Illumina paired-end reads, 454 Roche single-end and mate pair sequencing technology. Additionally, we constructed an optical restriction map of this strain to aid in scaffold ordering and positioning, and completed the first genomic structure of this species. Moreover, we identified and assembled the first chromid of this species (pINBov266). The INBov1 genome encodes a large set of genes involved in the cellulolytic process but lacks key genes. This seems to indicate that B. fibrisolvens plays an important role in ruminal cellulolytic processes, but does not have autonomous cellulolytic capacity. When searching for genes involved in the biohydrogenation of unsaturated fatty acids, no linoleate isomerase gene was found in this strain. INBov1 does encode oleate hydratase genes known to participate in the hydrogenation of oleic acids. Furthermore, INBov1 contains an enolase gene, which has been recently determined to participate in the synthesis of conjugated linoleic acids. This work confirms the presence of a novel chromid in B. fibrisolvens and provides a new potential reference genome sequence for this species, providing new insight into its role in biohydrogenation and carbohydrate degradation.

Alternate JournalMicrob Genom
PubMed ID30216146
PubMed Central IDPMC6249431