Active and dormant microorganisms on glacier surfaces

Bradley, James A.; Trivedi, Christopher B.; Winkel, Matthias; Mourot, Rey; Lutz, Stefanie; Larose, Catherine; Keuschnig, Christoph; Doting, Eva L.; Halbach, Laura; Zervas, Athanasios; Anesio, Alexandre M.; Benning, Liane G.

doi:10.1111/gbi.12535

Cited by 14 publications

(10 citation statements)

References 149 publications

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“…Previous work has also identified that a subset of taxa in Greenlandic seasonal supraglacial snowpacks and meltwater channels are potentially active whereas others are translationally quiescent (Gokul et al, 2019). There is recent evidence that at least half of the cells in glacier surface habitats are translationally active within typical summer conditions, and can rapidly resume activity upon defrosting, well within the likely residence time of meltwater within the weathering crust (Bradley et al, 2023; Stevens et al, 2018). Furthermore, our finding that the exported community from the glacier surface is dominated by Polaromonas concurs with RNA‐based studies of fluvial export from Canadian Arctic watersheds which show Polaromonas as a key constituent of the potentially active exported microbiome (Comte et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

The distinctive weathering crust habitat of a High Arctic glacier comprises discrete microbial micro‐habitats

Rassner,

Cook,

Mitchell

et al. 2024

Environmental Microbiology

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Sunlight penetrates the ice surfaces of glaciers and ice sheets, forming a water‐bearing porous ice matrix known as the weathering crust. This crust is home to a significant microbial community. Despite the potential implications of microbial processes in the weathering crust for glacial melting, biogeochemical cycles, and downstream ecosystems, there have been few explorations of its microbial communities. In our study, we used 16S rRNA gene sequencing and shotgun metagenomics of a Svalbard glacier surface catchment to characterise the microbial communities within the weathering crust, their origins and destinies, and the functional potential of the weathering crust metagenome. Our findings reveal that the bacterial community in the weathering crust is distinct from those in upstream and downstream habitats. However, it comprises two separate micro‐habitats, each with different taxa and functional categories. The interstitial porewater is dominated by Polaromonas, influenced by the transfer of snowmelt, and exported via meltwater channels. In contrast, the ice matrix is dominated by Hymenobacter, and its metagenome exhibits a diverse range of functional adaptations. Given that the global weathering crust area and the subsequent release of microbes from it are strongly responsive to climate projections for the rest of the century, our results underscore the pressing need to integrate the microbiome of the weathering crust with other communities and processes in glacial ecosystems.

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Section: Discussionmentioning

confidence: 99%

The distinctive weathering crust habitat of a High Arctic glacier comprises discrete microbial micro‐habitats

Rassner,

Cook,

Mitchell

et al. 2024

Environmental Microbiology

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“…The standing theory for inoculation of the supraglacial environments by bacteria is that they are delivered through aerial deposition (Šantl-Temkiv et al 2018 , Cameron et al 2020 ). Once on the ice sheet, a significant portion of glacier surface microbes are subsequently found to be metabolically inactive (Bradley et al 2022 ). This means certain taxa of microbes observed in this study through culturing might spring from transient cells in the sample they were captured from, rather than settled and thriving colonies.…”

Section: Discussionmentioning

confidence: 99%

Exploring microbial diversity in Greenland Ice Sheet supraglacial habitats through culturing-dependent and -independent approaches

Jaarsma,

Sipes,

Zervas

et al. 2023

FEMS Microbiology Ecology

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The microbiome of Greenland Ice Sheet supraglacial habitats is still under-investigated, and as a result there is a lack of representative genomes from these environments. In this study, we investigated the supraglacial microbiome through a combination of culturing-dependent and -independent approaches. We explored ice, cryoconite, biofilm, and snow biodiversity to answer: 1) how microbial diversity differs between supraglacial habitats, 2) if obtained bacterial genomes reflect dominant community members, and 3) how culturing versus high throughput sequencing changes our observations of microbial diversity in supraglacial habitats. Genomes acquired through metagenomic sequencing (133 high-quality MAGs) and whole genome sequencing (73 bacterial isolates) were compared to the metagenome assemblies to investigate abundance within the total environmental DNA. Isolates obtained in this study were not dominant taxa in the habitat they were sampled from, in contrast to the obtained MAGs. We demonstrate here the advantages of using metagenome SSU rRNA genes to reflect whole-community diversity. Additionally, we demonstrate a proof-of-concept of the application of in situ culturing in a supraglacial setting.

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“…Supraglacial and subglacial microbial communities have been widely studied and characterized in the last few decades, with many studies showing how biotic and abiotic processes in these systems are linked to global biogeochemical cycles [ 4 , 34 , 35 ]. It is also common knowledge that climate warming affects the interconnectivity among glacial hydrology, microbial community, and geochemistry and that increases in meltwater discharge from glaciers and ice sheets impact the proglacial systems [ 20 , 198 , 199 , 200 , 201 ]. Therefore, whereas it is clear that climate warming affects and will affect dynamics within glaciers and ice sheets and in their out-stream environments, little information is present on how glacial microbial communities will be impacted.…”

Section: Discussionmentioning

confidence: 99%

“…In the supraglacial environment, organic and inorganic nutrients and carbon are often available in dissolved forms released by the biochemical weathering of deposited particles [ 13 , 126 ]. With the onset of the ablation season, nutrients and carbon deposited during the accumulation season progressively percolate through the snowpack into the weathering crust, cryoconite holes, and glacial ponds (ablation zone) [ 12 , 55 ], and microorganisms are able to resume metabolic activity shortly after thawing [ 20 ] ( Figure 1 ).…”

Section: Hydrology Influences On Glacial Nutrients and Microbial Comm...mentioning

confidence: 99%

“…For example, the microbial communities on the glacial surface are dominated by photoautotrophs and nitrogen fixers, whereas microbial communities in the subglacial waters can be dominated by iron reducers, sulfide oxidizers, sulfate reducers and methanogens [ 17 , 18 ]. Which metabolisms are most active at a specific time and in a specific glacial compartment highly depends on the state of the ice body [ 19 , 20 ]. Such data clearly indicate that glaciers and ice sheets are not inert masses, placing them as integral components of global biogeochemical cycling.…”

Section: Introductionmentioning

confidence: 99%

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Glacial Water: A Dynamic Microbial Medium

et al. 2023

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Microbial communities and nutrient dynamics in glaciers and ice sheets continuously change as the hydrological conditions within and on the ice change. Glaciers and ice sheets can be considered bioreactors as microbiomes transform nutrients that enter these icy systems and alter the meltwater chemistry. Global warming is increasing meltwater discharge, affecting nutrient and cell export, and altering proglacial systems. In this review, we integrate the current understanding of glacial hydrology, microbial activity, and nutrient and carbon dynamics to highlight their interdependence and variability on daily and seasonal time scales, as well as their impact on proglacial environments.

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Active and dormant microorganisms on glacier surfaces

Abstract: This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

Cited by 14 publications

References 149 publications

The distinctive weathering crust habitat of a High Arctic glacier comprises discrete microbial micro‐habitats

The distinctive weathering crust habitat of a High Arctic glacier comprises discrete microbial micro‐habitats

Exploring microbial diversity in Greenland Ice Sheet supraglacial habitats through culturing-dependent and -independent approaches

Glacial Water: A Dynamic Microbial Medium

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