Winter in water: differential responses and the maintenance of biodiversity

Winter in water: differential responses and the maintenance of biodiversity

The ecological consequences of winter in freshwater systems are an understudied but rapidly emerging research area. Here, we argue that winter periods of reduced temperature and light (and potentially oxygen and resources) could play an underappreciated role in mediating the coexistence of species....

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Veröffentlicht in:Ecology letters 2020-06, Vol.23 (6), p.922-938
Hauptverfasser: McMeans, Bailey C., McCann, Kevin S., Guzzo, Matthew M., Bartley, Timothy J., Bieg, Carling, Blanchfield, Paul J., Fernandes, Timothy, Giacomini, Henrique C., Middel, Trevor, Rennie, Michael D., Ridgway, Mark S., Shuter, Brian J., Donohue, Ian
Format: Artikel
Sprache:eng
Schlagworte:
Animals
Behaviour
Biodiversity
biotic interactions
Climate change
Coexistence
environmental variation
fish
freshwater
Freshwater fish
Ice Cover
lake
Lakes
Light effects
Niches
physiology
season
Seasonal variations
Seasons
Species
Thermal environments
Water
Winter
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container_end_page 938
container_issue 6
container_start_page 922
container_title Ecology letters
container_volume 23
creator McMeans, Bailey C.
McCann, Kevin S.
Guzzo, Matthew M.
Bartley, Timothy J.
Bieg, Carling
Blanchfield, Paul J.
Fernandes, Timothy
Giacomini, Henrique C.
Middel, Trevor
Rennie, Michael D.
Ridgway, Mark S.
Shuter, Brian J.
Donohue, Ian
description The ecological consequences of winter in freshwater systems are an understudied but rapidly emerging research area. Here, we argue that winter periods of reduced temperature and light (and potentially oxygen and resources) could play an underappreciated role in mediating the coexistence of species. This may be especially true for temperate and subarctic lakes, where seasonal changes in the thermal environment might fundamentally structure species interactions. With climate change already shortening ice‐covered periods on temperate and polar lakes, consideration of how winter conditions shape biotic interactions is urgently needed. Using freshwater fishes in northern temperate lakes as a case study, we demonstrate how physiological trait differences (e.g. thermal preference, light sensitivity) drive differential behavioural responses to winter among competing species. Specifically, some species have a higher capacity for winter activity than others. Existing and new theory is presented to argue that such differential responses to winter can promote species coexistence. Importantly, if winter is a driver of niche differences that weaken competition between, relative to within species, then shrinking winter periods could threaten coexistence by tipping the scales in favour of certain sets of species over others. Northern temperate freshwater fish species with colder thermal preferences have a higher capacity for activity during dark, cold winters compared to species with warmer thermal preferences (a, b). Higher performance during winter could trade‐off with reduced performance during brighter, warmer seasons (c), setting the stage for winter‐mediated species coexistence in Northern temperate lakes (d).
doi_str_mv 10.1111/ele.13504
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subjects Animals
Behaviour
Biodiversity
biotic interactions
Climate change
Coexistence
environmental variation
fish
freshwater
Freshwater fish
Ice Cover
lake
Lakes
Light effects
Niches
physiology
season
Seasonal variations
Seasons
Species
Thermal environments
Water
Winter
title Winter in water: differential responses and the maintenance of biodiversity
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