Table_1_Macroinvertebrate traits in Arctic streams reveal latitudinal patterns in physiology and habits that are strongly linked to climate.xlsx

Introduction Arctic freshwater ecosystems are undergoing rapid environmental transformation because of climate change, which is predicted to produce fundamental alterations in river community structure and function. Methods We explored how climate change affects benthic invertebrate communities of A...

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Bibliographic Details
Main Authors: Jennifer Lento, Danny C. P. Lau, John E. Brittain, Joseph M. Culp, Willem Goedkoop
Format: Dataset
Language:unknown
Published: 2023
Subjects:
Evolutionary Biology
Ecology
Invasive Species Ecology
Landscape Ecology
Conservation and Biodiversity
Behavioural Ecology
Community Ecology (excl. Invasive Species Ecology)
Ecological Physiology
Freshwater Ecology
Marine and Estuarine Ecology (incl. Marine Ichthyology)
Population Ecology
Terrestrial Ecology
Arctic
freshwater
functional trait
benthic macroinvertebrate
diversity
climate change
stream
temperature
Canada
Norway
Climate change
Online Access:https://doi.org/10.3389/fevo.2023.1209612.s002
https://figshare.com/articles/dataset/Table_1_Macroinvertebrate_traits_in_Arctic_streams_reveal_latitudinal_patterns_in_physiology_and_habits_that_are_strongly_linked_to_climate_xlsx/23983860
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Summary:Introduction Arctic freshwater ecosystems are undergoing rapid environmental transformation because of climate change, which is predicted to produce fundamental alterations in river community structure and function. Methods We explored how climate change affects benthic invertebrate communities of Arctic streams by examining patterns of their biological traits along latitudinal and climatic gradients in eastern North America (Canada) and northwestern Europe (Sweden, Norway). Results Despite differences in taxonomic composition between continents, we identified similarities in the functional trait niche (FTN) of predominant macroinvertebrate taxonomic groups. Trait composition differed by latitude in eastern Canada, with a predominance of cold-tolerant taxa, tubular body shape, and cased and attached habits at the highest latitudes. Differences in trait composition were evident among ecoregions in Europe, with trait dominance at the highest latitudes that was comparable to North America. There was a similar increase in the relative abundance of cold tolerance and tubular body shape and a decrease in obligate shredders and trait richness with decreasing temperatures across both continents. Discussion These patterns are indicative of FTNs that include physiological traits and habits that are advantageous for the low temperatures, short ice-free period, and low riparian vegetation cover at the highest latitudes. We predict that climate change will lead to an increase in functional diversity at high latitudes, as organisms with trait modalities that are currently only found at lower latitudes move northward. However, this change in trait composition will be mediated by the effect of spatial connectivity on dispersal ability, with slower change occurring on Arctic islands. These findings can support modelling of future change in Arctic freshwater assemblages in response to ongoing climate change.

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