Declining fungal diversity in Arctic freshwaters along a permafrost thaw gradient

Climate change-driven permafrost thaw has a strong influence on pan-Arctic regions, via, for example, the formation of thermokarst ponds. These ponds are hotspots of microbial carbon cycling and greenhouse gas production, and efforts have been put on disentangling the role of bacteria and archaea in...

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Bibliographic Details
Main Authors: Kluge, Mariana, Wauthy, Maxime, Engelbrecht Clemmensen, Karina, Wurzbacher, Christian, Hawkes, Jeffrey A., Einarsdottir, Karolina, Rautio, Milla, Stenlid, Jan, Peura, Sari
Format: Article in Journal/Newspaper
Language:English
Published: 2021
Subjects:
Climate Research
Ecology
Arctic
Canada
Greenland
Climate change
permafrost
Thermokarst
Alaska
Siberia
Online Access:https://pub.epsilon.slu.se/25936/
https://pub.epsilon.slu.se/25936/1/kluge_m_et_al_211025.pdf
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Summary:Climate change-driven permafrost thaw has a strong influence on pan-Arctic regions, via, for example, the formation of thermokarst ponds. These ponds are hotspots of microbial carbon cycling and greenhouse gas production, and efforts have been put on disentangling the role of bacteria and archaea in recycling the increasing amounts of carbon arriving to the ponds from degrading watersheds. However, despite the well-established role of fungi in carbon cycling in the terrestrial environments, the interactions between permafrost thaw and fungal communities in Arctic freshwaters have remained unknown. We integrated data from 60 ponds in Arctic hydro-ecosystems, representing a gradient of permafrost integrity and spanning over five regions, namely Alaska, Greenland, Canada, Sweden, and Western Siberia. The results revealed that differences in pH and organic matter quality and availability were linked to distinct fungal community compositions and that a large fraction of the community represented unknown fungal phyla. Results display a 16%-19% decrease in fungal diversity, assessed by beta diversity, across ponds in landscapes with more degraded permafrost. At the same time, sites with similar carbon quality shared more species, aligning a shift in species composition with the quality and availability of terrestrial dissolved organic matter. We demonstrate that the degradation of permafrost has a strong negative impact on aquatic fungal diversity, likely via interactions with the carbon pool released from ancient deposits. This is expected to have implications for carbon cycling and climate feedback loops in the rapidly warming Arctic.

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