Sedimentary ancient DNA reveals local vegetation changes driven by glacial activity and climate.
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https://hdl.handle.net/10037/28744Date
2023-01-07Type
Journal articleTidsskriftartikkel
Peer reviewed
Author
Elliott, Lucas Dane; Rijal, Dilli Prasad; Brown, Antony; Bakke, Jostein; Topstad, Lasse; Heintzman, Peter D.; Alsos, Inger GreveAbstract
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.
Is part of
Elliott, L.D. (2024). Unlocking the potential of sedimentary ancient DNA. (Doctoral thesis). https://hdl.handle.net/10037/35339Publisher
MDPICitation
Elliott LD, Rijal DP, Brown A, Bakke JB, Topstad L, Heintzman PD, Alsos IGA. Sedimentary ancient DNA reveals local vegetation changes driven by glacial activity and climate. . Quaternary. 2023;6Metadata
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