Unique biodiversity in Arctic marine forests is shaped by diverse recolonization pathways and far northern glacial refugia

The Arctic is experiencing a rapid shift toward warmer regimes, calling for a need to understand levels of biodiversity and ecosystem responses to climate cycles. This study presents genetic data for 109 Arctic marine forest species (seaweeds), which revealed contiguous populations extending from th...

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Published inProceedings of the National Academy of Sciences - PNAS Vol. 117; no. 36; pp. 22590 - 22596
Main Authors Bringloe, Trevor T., Verbruggen, Heroen, Saunders, Gary W.
Format Journal Article
LanguageEnglish
Published United States National Academy of Sciences 08.09.2020
Subjects
Algae
Aquatic Organisms
Arctic Regions
Biodiversity
Biological Sciences
Cenozoic
Coastal ecology
Ecosystem
Ecosystem resilience
Forests
Genetic diversity
Glaciation
Glaciers
Glaciology
Global cooling
Ice Cover
Pleistocene
Polar environments
Polar waters
Recolonization
Refugia
Refugium
Seaweeds
Species
Species diversity
Arctic Regions
Arctic region
Last Glacial Maximum
species-pump
endemism
species distribution models
Pleistocene glaciation
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Summary:The Arctic is experiencing a rapid shift toward warmer regimes, calling for a need to understand levels of biodiversity and ecosystem responses to climate cycles. This study presents genetic data for 109 Arctic marine forest species (seaweeds), which revealed contiguous populations extending from the Bering Sea to the northwest Atlantic, with high levels of genetic diversity in the east Canadian Arctic. One-fifth of the species sampled appeared restricted to Arctic waters. Further supported by hindcasted species distributions during the Last Glacial Maximum, we hypothesize that Arctic coastal systems were recolonized from many geographically disparate refugia leading to enriched diversity levels in the east Canadian Arctic, with important contributions stemming from northerly refugia likely centered along southern Greenland. Our results suggest Arctic marine biomes persisted through cycles of glaciation, leading to unique assemblages in polar waters, rather than being entirely derived from southerly (temperate) areas following glaciation. As such, Arctic marine species are potentially born from selective pressures during Cenozoic global cooling and eventual ice conditions beginning in the Pleistocene. Arctic endemic diversity was likely additionally driven by repeated isolations into globally disparate refugia during glaciation. This study highlights the need to take stock of unique Arctic marine biodiversity. Amplification of warming and loss of perennial ice cover are set to dramatically alter available Arctic coastal habitat, with the potential loss of diversity and decline in ecosystem resilience.
Bibliography:Edited by Jeremy B. C. Jackson, American Museum of Natural History, New York, NY, and approved August 4, 2020 (received for review February 12, 2020)
Author contributions: T.T.B., H.V., and G.W.S. designed research; T.T.B. and G.W.S. performed research; T.T.B. analyzed data; and T.T.B., H.V., and G.W.S. wrote the paper.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.2002753117