# Genomic insights into a versatile deep-sea methanotroph constituting the rare biosphere of a Brazilian carbonate mound complex

**Authors:** Ana Carolina de Araújo Butarelli, Fernanda Mancini Nakamura, Francielli Vilela Peres, Flúvio Modolon da Silva, Amanda Gonçalves Bendia, Raissa Basti, Michel Michaelovitch de Mahiques, Paulo Yukio Gomes Sumida, Vivian Helena Pellizari

PMC · DOI: 10.1128/msystems.01311-25 · mSystems · 2025-12-23

## TL;DR

A new deep-sea methanotroph was discovered in Brazil's carbonate mounds, revealing genomic traits that help it survive in low-energy environments.

## Contribution

The discovery of Methylotuvimicrobium crucis sp. nov., a rare methanotroph with genomic adaptations for deep-sea survival.

## Key findings

- Methylotuvimicrobium crucis sp. nov. exhibits genomic features like cold-shock proteins and DNA repair systems for deep-sea survival.
- The organism has metabolic versatility with methane oxidation, nitrogen fixation, and sulfur cycling pathways.
- A shared deep-sea core genome suggests horizontal gene transfer plays a role in adaptation.

## Abstract

Recent 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 discovered Methylotuvimicrobium crucis sp. nov., a novel methanotroph representing the rare biosphere in native sediments, described in accordance with the SeqCode rules. Recent 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 discovered Methylotuvimicrobium crucis sp. nov., a novel methanotroph representing the rare biosphere in native sediments, described in accordance with the SeqCode rules. Phylogenomic analysis revealed <95% of Average Nucleotide Identity (ANI) to described species, with genomic evidence of deep-sea specialization including: (i) stress adaptation through cold-shock proteins (CspA) and DNA repair systems (UvrD/LexA), (ii) metabolic versatility via complete methane oxidation (pmoABC), nitrogen fixation (nifHDK), and sulfur cycling (sox/sqr) pathways, and (iii) niche partitioning through biofilm formation (GGDEF/EAL) and heavy metal resistance (CopZ/CzcD). Comparative genomics identified a 1,234-gene deep-sea core shared with Methylotuvimicrobium sp. wino1, enriched in mobile elements (TnpA, prophages) suggesting horizontal gene transfer drives adaptation. While undetected in situ amplicon surveys, Methylotuvimicrobium crucis exhibited enrichment under methane availability, demonstrating its role as a latent methane filter. These findings contribute to 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.

Microbial communities in deep-sea sediments play crucial roles in global biogeochemical cycles, yet they remain poorly characterized due to the challenges of sampling and culturing under extreme conditions. This study provides a comprehensive overview of microbial diversity and functional potential in carbonate-rich deep-sea sediments, with an emphasis on methane-oxidizing bacteria. By combining high-throughput metagenomics and comparative genomics, we reconstructed high-quality genomes from previously uncharacterized microbial consortia, including novel members of the genus Methylotuvimicrobium. Our findings shed light on the ecological strategies of methanotrophs in oxygen-limited environments and expand the genomic representation of key players in carbon cycling.

## Linked entities

- **Genes:** SOX (sulfite oxidase) [NCBI Gene 820118], SQOR (sulfide quinone oxidoreductase) [NCBI Gene 58472], COPZ1 (coat protein complex I subunit zeta 1) [NCBI Gene 22818], czcD (potassium/proton-divalent cation antiporter) [NCBI Gene 937630], tnpA (transposase) [NCBI Gene 929189], uvrD (DNA-dependent helicase II) [NCBI Gene 877766], lexA (LexA repressor) [NCBI Gene 879875], cspA (cold shock protein A) [NCBI Gene 885837]
- **Species:** Mus musculus (taxon 10090)

## Full-text entities

- **Genes:** COPZ1 (coat protein complex I subunit zeta 1) [NCBI Gene 22818] {aka CGI-120, COPZ, HSPC181, SCN12, zeta-COP, zeta1-COP}
- **Chemicals:** Carbonate (MESH:D002254), methane (MESH:D008697), heavy metal (MESH:D019216), carbon (MESH:D002244), oxygen (MESH:D010100), sulfur (MESH:D013455), nitrogen (MESH:D009584)

## Full text

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## Figures

3 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12911358/full.md

## References

56 references — full list in the complete paper: https://tomesphere.com/paper/PMC12911358/full.md

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Source: https://tomesphere.com/paper/PMC12911358