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Sedimentary ancient DNA reveals local vegetation changes driven by glacial activity and climate

Sedimentary ancient DNA reveals local vegetation changes driven by glacial activity and climate
Sedimentary ancient DNA reveals local vegetation changes driven by glacial activity and climate
Disentangling the effects of glaciers and climate on vegetation is complicated by the confounding role that climate plays in both systems. We reconstructed changes in vegetation occurring over the Holocene at Jøkelvatnet, a lake located directly downstream from the Langfjordjøkel glacier in northern Norway. We used a sedimentary ancient DNA (sedaDNA) metabarcoding dataset of 38 samples from a lake sediment core spanning 10,400 years using primers targeting the P6 loop of the trnL (UAA) intron. A total of 193 plant taxa were identified revealing a pattern of continually increasing richness over the time period. Vegetation surveys conducted around Jøkelvatnet show a high concordance with the taxa identified through sedaDNA metabarcoding. We identified four distinct vegetation assemblage zones with transitions at ca. 9.7, 8.4 and 4.3 ka with the first and last mirroring climatic shifts recorded by the Langfjordjøkel glacier. Soil disturbance trait values of the vegetation increased with glacial activity, suggesting that the glacier had a direct impact on plants growing in the catchment. Temperature optimum and moisture trait values correlated with both glacial activity and reconstructed climatic variables showing direct and indirect effects of climate change on the vegetation. In contrast to other catchments without an active glacier, the vegetation at Jøkelvatnet has displayed an increased sensitivity to climate change throughout the Middle and Late Holocene. Beyond the direct impact of climate change on arctic and alpine vegetation, our results suggest the ongoing disappearance of glaciers will have an additional effect on plant communities.
climate change, glaciers, sedaDNA, vegetation reconstruction, Norway, Holocene
2571-550X
1
Elliott, Lucas
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Rijal, Dilli
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Brown, Antony
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Bakke, Jostein
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Topstad, Lasse
34e2b154-927a-411c-a90a-75b56feffbc8
Heintzman, Peter
1a2cd02d-1a70-4e28-9cab-11378964a326
Alsos, Inger
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Elliott, Lucas
8e01ee27-6228-4a0c-9cf7-d320f92ef882
Rijal, Dilli
5c2fb168-b2e6-41c7-8da2-35c282132702
Brown, Antony
c51f9d3e-02b0-47da-a483-41c354e78fab
Bakke, Jostein
9e645ed5-4e79-4ee8-838c-77f1d91340eb
Topstad, Lasse
34e2b154-927a-411c-a90a-75b56feffbc8
Heintzman, Peter
1a2cd02d-1a70-4e28-9cab-11378964a326
Alsos, Inger
a0d63fcd-b038-4556-b900-22a540f80b88

Elliott, Lucas, Rijal, Dilli, Brown, Antony, Bakke, Jostein, Topstad, Lasse, Heintzman, Peter and Alsos, Inger (2023) Sedimentary ancient DNA reveals local vegetation changes driven by glacial activity and climate. Quaternary, 6 (1), 1, [7]. (doi:10.3390/quat6010007).

Record type: Article

Abstract

Disentangling the effects of glaciers and climate on vegetation is complicated by the confounding role that climate plays in both systems. We reconstructed changes in vegetation occurring over the Holocene at Jøkelvatnet, a lake located directly downstream from the Langfjordjøkel glacier in northern Norway. We used a sedimentary ancient DNA (sedaDNA) metabarcoding dataset of 38 samples from a lake sediment core spanning 10,400 years using primers targeting the P6 loop of the trnL (UAA) intron. A total of 193 plant taxa were identified revealing a pattern of continually increasing richness over the time period. Vegetation surveys conducted around Jøkelvatnet show a high concordance with the taxa identified through sedaDNA metabarcoding. We identified four distinct vegetation assemblage zones with transitions at ca. 9.7, 8.4 and 4.3 ka with the first and last mirroring climatic shifts recorded by the Langfjordjøkel glacier. Soil disturbance trait values of the vegetation increased with glacial activity, suggesting that the glacier had a direct impact on plants growing in the catchment. Temperature optimum and moisture trait values correlated with both glacial activity and reconstructed climatic variables showing direct and indirect effects of climate change on the vegetation. In contrast to other catchments without an active glacier, the vegetation at Jøkelvatnet has displayed an increased sensitivity to climate change throughout the Middle and Late Holocene. Beyond the direct impact of climate change on arctic and alpine vegetation, our results suggest the ongoing disappearance of glaciers will have an additional effect on plant communities.

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Accepted/In Press date: 20 December 2022
Published date: March 2023
Additional Information: Funding Information: This work was supported by the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation program grant agreement no. 819192 (to I.G.A. and A.G.B.; supported L.D.E and L.T.) for the IceAGenT project; Research Council of Norway grant 250963/F20 (to I.G.A) for the ECOGEN project. Publisher Copyright: © 2023 by the authors.
Keywords: climate change, glaciers, sedaDNA, vegetation reconstruction, Norway, Holocene

Identifiers

Local EPrints ID: 474875
URI: http://eprints.soton.ac.uk/id/eprint/474875
ISSN: 2571-550X
PURE UUID: 6fb79692-9b37-4b0a-b403-bebf3b96df83
ORCID for Antony Brown: ORCID iD orcid.org/0000-0002-1990-4654

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Date deposited: 06 Mar 2023 17:35
Last modified: 17 Mar 2024 03:09

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Contributors

Author: Lucas Elliott
Author: Dilli Rijal
Author: Antony Brown ORCID iD
Author: Jostein Bakke
Author: Lasse Topstad
Author: Peter Heintzman
Author: Inger Alsos

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