Publications

4372

Abstract Background Rare species, especially of the marine sedimentary biosphere, have long been overlooked owing to the complexity of sediment microbial communities, their sporadic temporal and patchy spatial abundance, and challenges in cultivating environmental microorganisms. In this study, we combined enrichments, targeted metagenomic sequencing, and extensive data mining to uncover uncultivated members of the archaeal rare biosphere in marine sediments. Results In protein-amended enrichments, we detected the ecologically and metabolically uncharacterized class Candidatus Penumbrarchaeia within the phylum Thermoplasmatota. By screening more than 8000 metagenomic runs and 11,479 published genome assemblies, we expanded the phylogeny of Ca. Penumbrarchaeia by 3 novel orders. All six identified families of this class show low abundance in environmental samples characteristic of rare biosphere members. Members of the class Ca. Penumbrarchaeia were predicted to be involved in organic matter degradation in anoxic, carbon-rich habitats. All Ca. Penumbrarchaeia families contain high numbers of taxon-specific orthologous genes, highlighting their environmental adaptations and habitat specificity. Besides, members of this group exhibit the highest proportion of unknown genes within the entire phylum Thermoplasmatota, suggesting a high degree of functional novelty in this class. Conclusions In this study, we emphasize the necessity of targeted, data-integrative approaches to deepen our understanding of the rare biosphere and uncover the functions and metabolic potential hidden within these understudied taxa.

Ticks spread pathogens that affect both human and animal health and often cause significant economic losses to the livestock industry. However, there is limited data on the distribution of ticks and tick-borne pathogens, particularly those affecting cattle in Cameroon. In this study, ticks were collected from cattle in Buea, the capital of the South West Region of Cameroon, to determine their diversity and identify tick-borne pathogens through PCR and sequencing. The tick samples were screened for pathogens using assays that target the rOmpA gene (ompA) of Rickettsia, the ssrRNA gene of Babesia and Theileria and the Ehrlichia genus 16SrRNA gene. A total of 458 ticks were collected with Rhipicephalus annulatus (65.6%) as the predominant species. From 68 tick pools screened, 26 (38.2%) were positive for pathogen/ symbiont DNA. The pathogen identified was Rickettsia africae (22.1%). This study reports the first molecular detection of the symbiont Candidatus Midichloria mitochondrii (22.1%) in the sampled tick species. It was observed that male ticks were significantly more likely to test positive for R. africae (OR = 208, 95% CI = 28.6 - 4553, p<0.001). Animal handlers may face the risk of these zoonotic infections and as such, there is a need to employ protective measures to prevent or reduce pathogen spread.

Abstract The CRISPR–Cas (clustered regularly interspaced short palindromic repeats and CRISPR-associated protein) systems are adaptive immune mechanisms that play critical roles in defending archaea and bacteria against invading entities. These systems can be divided into two classes, with class 2 comprising three types (II, V, and VI). Because of their ability to cleave double-stranded DNA, many class 2 CRISPR–Cas proteins have been harnessed as genome editing tools. Unlike the well-studied type II Cas9 proteins, the structural studies of the type V-B Cas12b proteins are limited, hindering their engineering and broader application. Here, we report four complex structures of ChCas12b, which reveal many unique structural features. The folding of the single guide RNA (sgRNA) of ChCas12b is distinct from that of AacCas12b and BthCas12b. Notably, many of these unique features are involved in ChCas12b–sgRNA interaction, suggesting that they are co-evolved. While ChCas12b shares a conserved two-cation-assisted catalytic mechanism with its homologs, it recognizes a longer guide:target heteroduplex, potentially offering higher fidelity in DNA editing. Altogether, our studies suggested that Cas12b family proteins exhibit significant diversity in their folding, sgRNA and target DNA binding. In the future, it is worth characterizing more representative proteins to identify CRISPR–Cas proteins with higher gene editing ability and fidelity.

The genus Moraxella (Moraxellaceae, Pseudomonadales) comprises a diverse group of bacteria inhabiting human and animal mucosa, as well as environmental niches such as water, soil and food. While some species are clinically significant pathogens, others play ecological or biotechnological roles. Despite previous taxonomic revisions, Moraxella remains polyphyletic, necessitating a refined classification. In this study, we conducted comprehensive taxogenomic analyses integrating core protein phylogeny, average amino acid identity and the percentage of conserved proteins, along with 16S rRNA similarities and inferred phylogeny. Our results revealed three distinct phylogenetic clusters within Moraxella. The core group, comprising Moraxella lacunata NBRC 102154T and closely related species, exhibited strong genomic cohesion. A second cluster, consisting of Moraxella boevrei DSM 14165T, Moraxella osloensis CCUG 350T and Moraxella atlantae NBRC 14588T, showed greater genetic affinity to Faucicola mancuniensis GVCNT2T, supporting their reassignment to the genus Faucicola. The third group, represented by Moraxella lincolnii CCUG 9405T, was phylogenetically distinct, occupying a basal position relative to Psychrobacter, indicating the need for its classification within a novel genus within the family Moraxellaceae, for which we propose the name Lwoffella lincolnii gen. nov., comb. nov. Phenotypic data compiled from the original published descriptions of the respective species, including fatty acid composition and enzymatic profiles, further corroborated these genomic findings. This study refines Moraxella taxonomy by clarifying genus boundaries and evolutionary relationships, with implications for ecology and clinical microbiology.

Despite their large environmental impact and multiple independent emergences, the processes leading to the evolution of anaerobic methanotrophic archaea (ANME) remain unclear. This work uses comparative metagenomics of a recently evolved but understudied ANME group, “ Candidatus Methanovorans” (ANME-3), to identify evolutionary processes and innovations at work in ANME, which may be obscured in earlier evolved lineages. We identified horizontal transfer of hdrA homologs and convergent evolution in carbon and energy metabolic genes as potential early steps in Methanovorans evolution. We also identified the erosion of genes required for methylotrophic methanogenesis along with horizontal acquisition of multiheme cytochromes and other loci uniquely associated with ANME. The assembly and comparative analysis of multiple Methanovorans genomes offers important functional context for understanding the niche-defining metabolic differences between methane-oxidizing ANME and their methanogen relatives. Furthermore, this work illustrates the multiple evolutionary modes at play in the transition to a globally important metabolic niche.

The actinobacterial family Microbacteriaceae comprises a diverse group of Gram-positive bacteria with high G+C content and complex taxonomic challenges. Traditional polyphasic approaches, based on 16S rRNA phylogeny and phenotypic traits, have in some instances resulted in polyphyletic taxonomic groupings, necessitating genome-wide methodologies to better resolve evolutionary relationships. This study employs a taxogenomic approach – incorporating 16S rRNA gene sequencing, core protein phylogeny, average amino acid identity and percentage of conserved proteins – to reassess the genera Leifsonia, Salinibacterium, Homoserinimonas, Glaciibacter, Antiquaquibacter and Diaminobutyricibacter. The findings reveal significant polyphyly in Leifsonia, Glaciibacter and Salinibacterium, indicating ecological convergence rather than shared ancestry. Proposed taxonomic revisions include the reclassification of Salinibacterium soli and Salinibacterium metalliresistens into Antiquaquibacter, Salinibacterium hongtaonis and Salinibacterium sedimenticola into Homoserinimonas, and Leifsonia psychrotolerans and Leifsonia kafniensis into Glaciibacter. Diaminobutyricibacter tongyongensis should be incorporated into Leifsonia. Additionally, Leifsonia rubra is reassigned to Salinibacterium. Two new genera were also proposed to encompass “Leifsonia flava” and Glaciibacter flavus, named Orlajensenia gen. nov. and another to encompass Leifsonia bigeumensis, named Leifsonella gen. nov. These genome-based insights provide a refined framework for the taxonomy of Microbacteriaceae, enhancing our understanding of their evolutionary and ecological roles.

ABSTRACT Ca . Babelota is a phylum of strictly intracellular bacteria whose representatives are commonly detected in various environments through metagenomics, though their presence, ecology, and biology have never been addressed so far. As a group of strict intracellular, we hypothesize that their presence, occurrence, and abundance heavily depend on their hosts, which are known as heterotrophic protists, based on few described isolates. Here, we conducted a sampling campaign allowing to characterize protists and associated bacterial communities, using high-throughput sequencing. In parallel, a systematic enrichment of protists from samples was performed to attempt characterization and isolation of new Ca . Babelota within native hosts. We found that Ca . Babelota are among the most widespread phylum among the rare ones. Protist enrichments are allowed in certain cases to enrich as well for Ca . Babelota, which could be visualized in vivo infecting protist cells. Though cosmopolitan, Ca . Babelota diversity was highly site-specific. Cooccurrence analyses allowed to retrieve well-known as well as new putative associations involving numerous protists of various trophic regimes. The combination of approaches developed in this study enhances our understanding of Ca . Babelota ecology and biology, while paving the way for future isolation of new members of this elusive phylum, which could have huge impact on protists—and ecosystems—functioning. IMPORTANCE Our understanding of microbial diversity surrounding us and colonizing the environment has been dramatically impacted by the advent of DNA-based analyses. Such progress helped shine a new light on numerous lineages of yet-to-be-characterized microbes, whose ecology and biology are basically unknown. Among those uncharacterized clades is the Candidatus Babelota, a bacterial phylum for which parasitism seems to be an ancestral trait. All known Ca. Babelota thrive by infecting phagotrophic protist hosts, thereby impacting this basal link of the trophic chain. The Ca. Babelota constitutes a model that stands out, as phylum-wide conserved parasitism has only been described in one previous occurrence for Bacteria, with the Chlamydiota. Thus, exploring the intricate interplay between Ca. Babelota and their protist hosts will advance our knowledge of bacterial diversity, their ecology, and global impact on ecosystem functioning.

AbstractRecent discoveries of aerobic methanotrophs in non-seep carbonate-rich environments in the deep sea suggest that these organisms may persist as part of the rare biosphere. Recovering rare, active methanotrophs through targeted culturing is essential for understanding their persistence under the oligotrophic non-seep conditions, and for uncovering their genomic adaptations related to the survival in energy-limited ecosystems. In our study, using metagenomic analysis of enrichment cultures from the Alpha Crucis Carbonate Ridge, we discoveredMethylotuvimicrobium crucissp. nov., a novel methanotroph representing the rare biosphere in native sediments. Phylogenomic analysis revealed <95% ANI to described species, with genomic evidence of deep-sea specialization including: (1) stress adaptation through cold-shock proteins (CspA) and DNA repair systems (UvrD/LexA), (2) metabolic versatility via complete methane oxidation(pmoABC), nitrogen fixation (nifHDK), and sulfur cycling (sox/sqr) pathways, and (3) niche partitioning through biofilm formation (GGDEF/EAL) and heavy metal resistance (CopZ/CzcD). Comparative genomics identified a 1,234-gene deep-sea core shared withM. sp. wino1, enriched in mobile elements (TnpA, prophages) suggesting horizontal gene transfer drives adaptation. While undetectedin situamplicon surveys,M. crucisexhibited rapid enrichment under methane availability, demonstrating its role as a latent methane filter. These findings contribute for the understanding of the ecological significance of aerobic methanotrophs in deep-sea systems, revealing how rare microbial taxa with genomic plasticity have the potential to influence biogeochemical cycling in deep carbonate-rich environments.

Abstract Methanol, the simplest alcohol, has long been recognized as a key energy and carbon source for soil and plant-associated bacteria and fungi, and is increasingly recognized as an important substrate for marine bacteria. Lanthanide-dependent methanol dehydrogenases (encoded by the gene xoxF) are now recognized as the key catalysts for methylotrophy in many environments, yet the identity of the most transcriptionally active methylotrophs in open ocean waters (“Clade X”) has remained elusive. Here we show that “Clade X” methylotrophs belong to the deep-branching alphaproteobacterial order TMED127, which we propose be renamed ‘Methylaequorales’; ‘methyl’ for ‘methylotrophic metabolism’ and ‘aequor’ for ‘ocean surface’, as these bacteria are most transcriptionally active near the sea surface. TMED127/Methylaequorales are present in surface waters of tropical and subtropical oceans throughout the global ocean. They have small, streamlined genomes (∼1.5 Mb), and appear to be obligate methylotrophs that use the serine cycle for carbon assimilation. They display a diel pattern of xoxF5 and glucose dehydrogenase (gdh) transcription, peaking in the late afternoon, in oligotrophic surface water of the Sargasso Sea. Several other highly transcribed genes of unknown function had no homologs outside of TMED127/Methylaequorales genomes. Our findings illuminate an overlooked marine methylotrophic bacterium and predict a diel cycle of methanol production in surface seawater by an unknown pathway. Importance Methanol metabolism is increasingly recognized as an important process in the marine carbon cycle, yet the identity and metabolism of the microorganisms mediating methylotrophy in the open ocean have remained unknown. This study reveals that bacteria in the TMED127 order of Alphaproteobacteria, proposed new name of “Methylaequorales”, abundantly transcribe the key gene for lanthanide-dependent methylotrophy in oligotrophic surface waters of the world’s oceans. TMED127/Methylaequorales likely require methanol as a carbon and energy source and display a diel pattern of transcription of key genes for methylotrophy that peaks in the late afternoon. These findings motivate future studies on the mechanisms of methanol production in surface seawater.