Single-cell imaging reveals efficient nutrient uptake and growth of microalgae darkening the Greenland Ice Sheet

Laura Halbach; Katharina Kitzinger; Martin Hansen; Sten Littmann; Liane G.  Benning; James A.  Bradley; Martin J. Whitehouse; Malin Olofsson; Rey Mourot; Martyn Tranter; Marcel M M Kuypers; Lea Ellegaard-Jensen; Alexandre M. Anesio

doi:10.1038/s41467-025-56664-6

Single-cell imaging reveals efficient nutrient uptake and growth of microalgae darkening the Greenland Ice Sheet

Laura Halbach (Corresponding author), Katharina Kitzinger, Martin Hansen, Sten Littmann, Liane G. Benning, James A. Bradley, Martin J. Whitehouse, Malin Olofsson, Rey Mourot, Martyn Tranter, Marcel M M Kuypers, Lea Ellegaard-Jensen, Alexandre M. Anesio (Corresponding author)

Department of Microbiology and Ecosystem Science

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

Blooms of dark pigmented microalgae accelerate glacier and ice sheet melting by reducing the surface albedo. However, the role of nutrient availability in regulating algal growth on the ice remains poorly understood. Here, we investigate glacier ice algae on the Greenland Ice Sheet, providing single-cell measurements of carbon:nitrogen:phosphorus (C:N:P) ratios and assimilation rates of dissolved inorganic carbon (DIC), ammonium and nitrate following nutrient amendments. The single-cell analyses reveal high C:N and C:P atomic ratios in algal biomass as well as intracellular P storage. DIC assimilation rates are not enhanced by ammonium, nitrate, or phosphate addition. Our combined results demonstrate that glacier ice algae can optimise nutrient uptake, facilitating the potential colonization of newly exposed bare ice surfaces without the need for additional nutrient inputs. This adaptive strategy is particularly important given accelerated climate warming and the expansion of melt areas on the Greenland Ice Sheet.

Original language	German
Article number	1521
Number of pages	14
Journal	Nature Communications
Volume	16
DOIs	https://doi.org/10.1038/s41467-025-56664-6
Publication status	Published - 19 Feb 2025

Austrian Fields of Science 2012

105128 Geomicrobiology
105907 Polar research
106022 Microbiology

Keywords

single-cell imaging
nutrient uptake
microalgae
Greenland
Ice sheet

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1038/s41467-025-56664-6

Cite this

Halbach, L., Kitzinger, K., Hansen, M., Littmann, S., Benning, L. G., Bradley, J. A., Whitehouse, M. J., Olofsson, M., Mourot, R., Tranter, M., Kuypers, M. M. M., Ellegaard-Jensen, L., & Anesio, A. M. (2025). Single-cell imaging reveals efficient nutrient uptake and growth of microalgae darkening the Greenland Ice Sheet. Nature Communications, 16, Article 1521. https://doi.org/10.1038/s41467-025-56664-6

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title = "Single-cell imaging reveals efficient nutrient uptake and growth of microalgae darkening the Greenland Ice Sheet",

abstract = "Blooms of dark pigmented microalgae accelerate glacier and ice sheet melting by reducing the surface albedo. However, the role of nutrient availability in regulating algal growth on the ice remains poorly understood. Here, we investigate glacier ice algae on the Greenland Ice Sheet, providing single-cell measurements of carbon:nitrogen:phosphorus (C:N:P) ratios and assimilation rates of dissolved inorganic carbon (DIC), ammonium and nitrate following nutrient amendments. The single-cell analyses reveal high C:N and C:P atomic ratios in algal biomass as well as intracellular P storage. DIC assimilation rates are not enhanced by ammonium, nitrate, or phosphate addition. Our combined results demonstrate that glacier ice algae can optimise nutrient uptake, facilitating the potential colonization of newly exposed bare ice surfaces without the need for additional nutrient inputs. This adaptive strategy is particularly important given accelerated climate warming and the expansion of melt areas on the Greenland Ice Sheet.",

keywords = "single-cell imaging, nutrient uptake, microalgae, Greenland, Ice sheet",

author = "Laura Halbach and Katharina Kitzinger and Martin Hansen and Sten Littmann and Benning, {Liane G.} and Bradley, {James A.} and Whitehouse, {Martin J.} and Malin Olofsson and Rey Mourot and Martyn Tranter and Kuypers, {Marcel M M} and Lea Ellegaard-Jensen and Anesio, {Alexandre M.}",

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Halbach, L, Kitzinger, K, Hansen, M, Littmann, S, Benning, LG, Bradley, JA, Whitehouse, MJ, Olofsson, M, Mourot, R, Tranter, M, Kuypers, MMM, Ellegaard-Jensen, L & Anesio, AM 2025, 'Single-cell imaging reveals efficient nutrient uptake and growth of microalgae darkening the Greenland Ice Sheet', Nature Communications, vol. 16, 1521. https://doi.org/10.1038/s41467-025-56664-6

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T1 - Single-cell imaging reveals efficient nutrient uptake and growth of microalgae darkening the Greenland Ice Sheet

AU - Halbach, Laura

AU - Kitzinger, Katharina

AU - Hansen, Martin

AU - Littmann, Sten

AU - Benning, Liane G.

AU - Bradley, James A.

AU - Whitehouse, Martin J.

AU - Olofsson, Malin

AU - Mourot, Rey

AU - Tranter, Martyn

AU - Kuypers, Marcel M M

AU - Ellegaard-Jensen, Lea

AU - Anesio, Alexandre M.

PY - 2025/2/19

Y1 - 2025/2/19

N2 - Blooms of dark pigmented microalgae accelerate glacier and ice sheet melting by reducing the surface albedo. However, the role of nutrient availability in regulating algal growth on the ice remains poorly understood. Here, we investigate glacier ice algae on the Greenland Ice Sheet, providing single-cell measurements of carbon:nitrogen:phosphorus (C:N:P) ratios and assimilation rates of dissolved inorganic carbon (DIC), ammonium and nitrate following nutrient amendments. The single-cell analyses reveal high C:N and C:P atomic ratios in algal biomass as well as intracellular P storage. DIC assimilation rates are not enhanced by ammonium, nitrate, or phosphate addition. Our combined results demonstrate that glacier ice algae can optimise nutrient uptake, facilitating the potential colonization of newly exposed bare ice surfaces without the need for additional nutrient inputs. This adaptive strategy is particularly important given accelerated climate warming and the expansion of melt areas on the Greenland Ice Sheet.

AB - Blooms of dark pigmented microalgae accelerate glacier and ice sheet melting by reducing the surface albedo. However, the role of nutrient availability in regulating algal growth on the ice remains poorly understood. Here, we investigate glacier ice algae on the Greenland Ice Sheet, providing single-cell measurements of carbon:nitrogen:phosphorus (C:N:P) ratios and assimilation rates of dissolved inorganic carbon (DIC), ammonium and nitrate following nutrient amendments. The single-cell analyses reveal high C:N and C:P atomic ratios in algal biomass as well as intracellular P storage. DIC assimilation rates are not enhanced by ammonium, nitrate, or phosphate addition. Our combined results demonstrate that glacier ice algae can optimise nutrient uptake, facilitating the potential colonization of newly exposed bare ice surfaces without the need for additional nutrient inputs. This adaptive strategy is particularly important given accelerated climate warming and the expansion of melt areas on the Greenland Ice Sheet.

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KW - nutrient uptake

KW - microalgae

KW - Greenland

KW - Ice sheet

U2 - 10.1038/s41467-025-56664-6

DO - 10.1038/s41467-025-56664-6

M3 - Artikel

SN - 2041-1723

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JO - Nature Communications

JF - Nature Communications

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