Abstract
AIMS: Methanogens are methane-producing archaea that are present in the human gut. Yet, their adaptation to diverse human lifestyles remains poorly understood. Here, we report the isolation of Methanobrevibacter intestini G0370_i3 from the stool of a healthy adult from Southern Gabon, Africa, where inhabitants maintain traditional subsistence lifestyles with diets distinct from industrialized populations. MATERIALS AND METHODS: M. intestini was enriched from human stool, phenotypically characterized, and sequenced. RESULTS: G0370_i3 growth relied on the presence of H(2) and CO(2) and could also grow on formate, in contrast to reports for the type strain. The genome encoded pathways for amino acid biosynthesis, cofactor metabolism, and secondary metabolite production. We identified 23 mobile genetic elements and five defense systems, indicating horizontal gene transfer and antiviral defense. No prophage regions were detected.The genome also encoded uridine diphosphate (UDP)-sugar metabolism pathways, indicating capacity for energy storage and cell wall adaptability. Genes encoding adhesin-like proteins suggest capabilities for host interaction. Phenotypically, G0370_i3 is a coccobacillus, grows optimally at 37°C, and tolerates antibiotics, salt, and oxygen stress. CONCLUSIONS: These findings highlight the stress resilience and selective metabolic capabilities of M. intestini and underscore the importance of representing African populations in microbiome research.