Your search keyword '"Anesio, Alexandre M."' showing total 6 results

1. Giant viral signatures on the Greenland ice sheet.

Author

Perini, Laura, Sipes, Katie, Zervas, Athanasios, Bellas, Christopher, Lutz, Stefanie, Moniruzzaman, Mohammad, Mourot, Rey, Benning, Liane G., Tranter, Martyn, and Anesio, Alexandre M.

Subjects

GREENLAND ice, ICE sheets, ALGAL communities, METAGENOMICS, TUNDRAS, VIRAL genomes, ALGAL populations, VIRAL genes

Abstract

Background: Dark pigmented snow and glacier ice algae on glaciers and ice sheets contribute to accelerating melt. The biological controls on these algae, particularly the role of viruses, remain poorly understood. Giant viruses, classified under the nucleocytoplasmic large DNA viruses (NCLDV) supergroup (phylum Nucleocytoviricota), are diverse and globally distributed. NCLDVs are known to infect eukaryotic cells in marine and freshwater environments, providing a biological control on the algal population in these ecosystems. However, there is very limited information on the diversity and ecosystem function of NCLDVs in terrestrial icy habitats. Results: In this study, we investigate for the first time giant viruses and their host connections on ice and snow habitats, such as cryoconite, dark ice, ice core, red and green snow, and genomic assemblies of five cultivated Chlorophyta snow algae. Giant virus marker genes were present in almost all samples; the highest abundances were recovered from red snow and the snow algae genomic assemblies, followed by green snow and dark ice. The variety of active algae and protists in these GrIS habitats containing NCLDV marker genes suggests that infection can occur on a range of eukaryotic hosts. Metagenomic data from red and green snow contained evidence of giant virus metagenome-assembled genomes from the orders Imitervirales, Asfuvirales, and Algavirales. Conclusion: Our study highlights NCLDV family signatures in snow and ice samples from the Greenland ice sheet. Giant virus metagenome-assembled genomes (GVMAGs) were found in red snow samples, and related NCLDV marker genes were identified for the first time in snow algal culture genomic assemblies; implying a relationship between the NCLDVs and snow algae. Metatranscriptomic viral genes also aligned with metagenomic sequences, suggesting that NCLDVs are an active component of the microbial community and are potential "top-down" controls of the eukaryotic algal and protistan members. This study reveals the unprecedented presence of a diverse community of NCLDVs in a variety of glacial habitats dominated by algae. [ABSTRACT FROM AUTHOR]

Published

2024

2. The exometabolome of microbial communities inhabiting bare ice surfaces on the southern Greenland Ice Sheet.

Author

Doting, Eva L., Jensen, Marie B., Peter, Elisa K., Ellegaard‐Jensen, Lea, Tranter, Martyn, Benning, Liane G., Hansen, Martin, and Anesio, Alexandre M.

Subjects

GREENLAND ice, ICE sheets, MELTWATER, MICROBIAL communities, GLACIERS, MULTIVARIATE analysis, ALGAL communities, FREEZE-thaw cycles

Abstract

Microbial blooms colonize the Greenland Ice Sheet bare ice surface during the ablation season and significantly reduce its albedo. On the ice surface, microbes are exposed to high levels of irradiance, freeze–thaw cycles, and low nutrient concentrations. It is well known that microorganisms secrete metabolites to maintain homeostasis, communicate with other microorganisms, and defend themselves. Yet, the exometabolome of supraglacial microbial blooms, dominated by the pigmented glacier ice algae Ancylonema alaskanum and Ancylonema nordenskiöldii, remains thus far unstudied. Here, we use a high‐resolution mass spectrometry‐based untargeted metabolomics workflow to identify metabolites in the exometabolome of microbial blooms on the surface of the southern tip of the Greenland Ice Sheet. Samples were collected every 6 h across two diurnal cycles at 5 replicate sampling sites with high similarity in community composition, in terms of orders and phyla present. Time of sampling explained 46% (permutational multivariate analysis of variance [PERMANOVA], pseudo‐F = 3.7771, p = 0.001) and 27% (PERMANOVA, pseudo‐F = 1.8705, p = 0.001) of variance in the exometabolome across the two diurnal cycles. Annotated metabolites included riboflavin, lumichrome, tryptophan, and azelaic acid, all of which have demonstrated roles in microbe–microbe interactions in other ecosystems and should be tested for potential roles in the development of microbial blooms on bare ice surfaces. [ABSTRACT FROM AUTHOR]

Published

2024

3. Pigment signatures of algal communities and their implications for glacier surface darkening.

Author

Halbach, Laura, Chevrollier, Lou-Anne, Doting, Eva L., Cook, Joseph M., Jensen, Marie B., Benning, Liane G., Bradley, James A., Hansen, Martin, Lund-Hansen, Lars C., Markager, Stiig, Sorrell, Brian K., Tranter, Martyn, Trivedi, Christopher B., Winkel, Matthias, and Anesio, Alexandre M.

Subjects

ALGAL communities, ASTAXANTHIN, DISSOLVED organic matter, GLACIERS, ICE sheets, SNOWMELT, BIOMASS energy

Abstract

Blooms of pigmented algae darken the surface of glaciers and ice sheets, thereby enhancing solar energy absorption and amplifying ice and snow melt. The impacts of algal pigment and community composition on surface darkening are still poorly understood. Here, we characterise glacier ice and snow algal pigment signatures on snow and bare ice surfaces and study their role in photophysiology and energy absorption on three glaciers in Southeast Greenland. Purpurogallin and astaxanthin esters dominated the glacier ice and snow algal pigment pools (mass ratios to chlorophyll a of 32 and 56, respectively). Algal biomass and pigments impacted chromophoric dissolved organic matter concentrations. Despite the effective absorption of astaxanthin esters at wavelengths where incoming irradiance peaks, the cellular energy absorption of snow algae was 95% lower than anticipated from their pigmentation, due to pigment packaging. The energy absorption of glacier ice algae was consequently ~ 5 × higher. On bare ice, snow algae may have locally contributed up to 13% to total biological radiative forcing, despite contributing 44% to total biomass. Our results give new insights into the impact of algal community composition on bare ice energy absorption and biomass accumulation during snow melt. [ABSTRACT FROM AUTHOR]

Published

2022

4. Similar heterotrophic communities but distinct interactions supported by red and green‐snow algae in the Antarctic Peninsula.

Author

Ji, Mukan, Kong, Weidong, Jia, Hongzeng, Ding, Chen, Anesio, Alexandre M., Wang, Yanfen, and Zhu, Yong‐Guan

Subjects

FUNGAL communities, HETEROTROPHIC bacteria, POLAR climate, ALGAL communities, COLONIAL birds, PENINSULAS, NUCLEOTIDE sequencing

Abstract

Summary: Snow algae are predicted to expand in polar regions due to climate warming, which can accelerate snowmelt by reducing albedo. Green snow frequently occurs near penguin colonies, and red snow distributes widely along ocean shores. However, the mechanisms underpinning the assemblage of algae and heterotrophs in colored snow remain poorly characterized.We investigated algal, bacterial, and fungal communities and their interactions in red and green snows in the Antarctic Peninsula using a high‐throughput sequencing method.We found distinct algal community structure in red and green snows, and the relative abundance of dominant taxa varied, potentially due to nutrient status differences. Contrastingly, red and green snows exhibited similar heterotrophic communities (bacteria and fungi), whereas the relative abundance of fungal pathogens was substantially higher in red snow by 3.8‐fold. Red snow exhibited a higher network complexity, indicated by a higher number of nodes and edges. Red snow exhibited a higher proportion of negative correlations among heterotrophs (62.2% vs 3.4%) and stronger network stability, suggesting the red‐snow network is more resistant to external disturbance.Our study revealed that the red snow microbiome exhibits a more stable microbial network than the green snow microbiome. [ABSTRACT FROM AUTHOR]

Published

2022

5. Over Winter Microbial Processes in a Svalbard Snow Pack: An Experimental Approach.

Author

Holland, Alexandra T., Bergk Pinto, Benoît, Layton, Rose, Williamson, Christopher J., Anesio, Alexandre M., Vogel, Timothy M., Larose, Catherine, and Tranter, Martyn

Subjects

SNOW, NUTRIENT cycles, SNOW cover, SURFACE of the earth, PHOSPHORUS cycle (Biogeochemistry), ALGAL communities, MICROBIAL communities

Abstract

Snow packs cover large expanses of Earth's land surface, making them integral components of the cryosphere in terms of past climate and atmospheric proxies, surface albedo regulators, insulators for other Arctic environments and habitats for diverse microbial communities such as algae, bacteria and fungi. Yet, most of our current understanding of snow pack environments, specifically microbial activity and community interaction, is limited to the main microbial growing season during spring ablation. At present, little is known about microbial activity and its influence on nutrient cycling during the subfreezing temperatures and 24-h darkness of the polar winter. Here, we examined microbial dynamics in a simulated cold (−5°C), dark snow pack to determine polar winter season microbial activity and its dependence on critical nutrients. Snow collected from Ny-Ålesund, Svalbard was incubated in the dark over a 5-week period with four different nutrient additions, including glacial mineral particles, dissolved inorganic nitrogen (DIN), dissolved inorganic phosphorus (DIP) and a combined treatment of DIN plus DIP. Data indicate a consumption of dissolved inorganic nutrients, particularly DIN, by heterotrophic communities, suggesting a potential nitrogen limitation, contradictory to phosphorus limitations found in most aquatic environments. 16S amplicon sequencing also reveal a clear difference in microbial community composition in the particulate mineral treatment compared to dissolved nutrient treatments and controls, suggesting that certain species of heterotrophs living within the snow pack are more likely to associate with particulates. Particulate phosphorus analyses indicate a potential ability of heterotrophic communities to access particulate sources of phosphorous, possibly explaining the lack of phosphorus limitation. These findings have importance for understanding microbial activity during the polar winter season and its potential influences on the abundance and bioavailability of nutrients released to surface ice and downstream environments during the ablation season. [ABSTRACT FROM AUTHOR]

Published

2020

6. Variations of algal communities cause darkening of a Greenland glacier.

Author

Lutz, Stefanie, Anesio, Alexandre M., Jorge Villar, Susana E., and Benning, Liane G.

Subjects

*BIOLOGICAL variation, *ALGAL communities, *GLACIERS, *MICROBIAL ecology, *MELTING, *HABITATS

Abstract

We have assessed the microbial ecology on the surface of Mittivakkat glacier in SE-Greenland during the exceptional high melting season in July 2012 when the so far most extreme melting rate for the Greenland Ice Sheet has been recorded. By employing a complementary and multi-disciplinary field sampling and analytical approach, we quantified the dramatic changes in the different microbial surface habitats (green snow, red snow, biofilms, grey ice, cryoconite holes). The observed clear change in dominant algal community and their rapidly changing cryo-organic adaptation inventory was linked to the high melting rate. The changes in carbon and nutrient fluxes between different microbial pools (from snow to ice, cryoconite holes and glacial forefronts) revealed that snow and ice algae dominate the net primary production at the onset of melting, and that they have the potential to support the cryoconite hole communities as carbon and nutrient sources. A large proportion of algal cells is retained on the glacial surface and temporal and spatial changes in pigmentation contribute to the darkening of the snow and ice surfaces. This implies that the fast, melt-induced algal growth has a high albedo reduction potential, and this may lead to a positive feedback speeding up melting processes. [ABSTRACT FROM AUTHOR]

Published

2014