# Distinct bacterial community structures with abundant carbon degradation and sulfur metabolisms found in different sea-ice types from the Central Arctic Ocean

**Authors:** Siddarthan Venkatachalam, Mats A. Granskog, Rafael Gonçalves‐Araujo, Dmitry V. Divine, Puthiya Veettil Vipindas, Thajudeen Jabir, Ahammed Shereef, Anand Jain

PMC · DOI: 10.1128/spectrum.01291-25 · 2025-10-08

## TL;DR

This study explores how different types of sea ice in the Central Arctic Ocean host unique bacterial communities with distinct roles in carbon and sulfur metabolism.

## Contribution

The study provides the first high-resolution, species-level analysis of bacterial communities and their metabolic functions across different sea-ice types in the Central Arctic Ocean.

## Key findings

- Bacterial communities in SYI/MYI and FYI sea ice show marked differences in composition and vertical structuring.
- Sulfur cycling and carbon degradation processes are prevalent in Central Arctic sea-ice bacterial communities.
- Novel genomes from the genus Aquiluna were identified and analyzed for their ecological roles.

## Abstract

The rapid decline of sea ice in the relatively understudied Central Arctic Ocean has a significant impact on bacterial biodiversity and the ecological functions they support. We investigated the bacterial community composition and the associated metabolic functions from three geographically distinct sea-ice floes: first-year ice (FYI) at the North Pole and western Nansen Basin and second-year or multi-year ice (SYI/MYI) in the western Amundsen Basin. We resolved the sea-ice bacterial community diversity at species-level precision using a long-read amplicon (n = 18) and metagenomic (n = 3) sequencing approach. The amplicon sequencing highlighted marked differences in bacterial community structure driven by ice age, floe origin, and environmental factors, demonstrating pronounced vertical structuring among ice horizons. Bacterial taxa like Paraglaciecola psychrophila, Hydrogenophaga crassostreae, Octadecabacter arcticus, and Polaribacter irgensii mainly dominated the bottom layers of SYI/MYI, whereas species Actimicrobium antarcticum, Polaromonas cryoconiti, O. antarcticus, and Rhodoferax sp. dominated the FYI. Similarly, notable taxonomic differences were observed in bacterial taxa inhabiting the surface and interior layers of FYI and SYI/MYI (e.g., F. frigoris and Hydrogenophaga sp.). The metagenomic analysis showed the prevalence of sulfur cycling-associated (assimilatory and dissimilatory sulfur metabolism) and complex carbon degradation processes in sea ice. We also elucidated the potential ecological role of novel metagenome-assembled genomes belonging to the genus Aquiluna through phylogenomic and pangenomic analyses. Overall, our findings revealed novel insights on the distinct bacterial communities that inhabit ice horizons and their associated ecological functions correlating with sea-ice type, origin, and habitat characteristics in the Central Arctic Ocean.

The Arctic region is warming nearly four times faster than the global average, leading to the continuous replacement of its thick multi-year sea ice with thinner first-year ice. The reduction in Arctic sea-ice cover was previously shown to have cascading effects on sea-ice-associated microbial communities and their role in the functioning of the ecosystem. This study provides the first high-resolution, species-level insight into the bacterial community composition and metabolic potential across different sea-ice types in the Central Arctic Ocean—an understudied yet rapidly changing environment. By combining long-read amplicon and metagenomic sequencing, we uncover distinct bacterial assemblages and functional metabolic roles that were shaped by the ice age and other physicochemical properties. Our findings highlight the ecological importance of sea-ice associated bacterial communities and the prevalence of sulfur metabolism and carbon degradation processes in different sea-ice types found in the central Arctic Ocean through genome-resolved metagenomics.

## Linked entities

- **Species:** Paraglaciecola psychrophila (taxon 326544), Hydrogenophaga crassostreae (taxon 1763535), Octadecabacter arcticus (taxon 53946), Polaribacter irgensii (taxon 531), Actimicrobium antarcticum (taxon 1051899), Polaromonas cryoconiti (taxon 866565), Rhodoferax sp. (taxon 50421), Hydrogenophaga sp. (taxon 1904254), Aquiluna (taxon 529881)

## Full-text entities

- **Chemicals:** sulfur (MESH:D013455), carbon (MESH:D002244)
- **Species:** Octadecabacter arcticus (species) [taxon 53946], Actimicrobium antarcticum (species) [taxon 1051899], Paraglaciecola psychrophila (species) [taxon 326544], Polaromonas cryoconiti (species) [taxon 866565], Rhodoferax sp. (species) [taxon 50421], Octadecabacter antarcticus (species) [taxon 1217908], Flavobacterium frigoris (species) [taxon 229204], Hydrogenophaga sp. (species) [taxon 1904254], Polaribacter irgensii (species) [taxon 531], Hydrogenophaga crassostreae (species) [taxon 1763535]

## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12584769/full.md

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Source: https://tomesphere.com/paper/PMC12584769