Hydric status influences salinity-dependent water selection in frogs from coastal wetlands

•Coastal areas are submitted to salinity fluctuations, inducing osmotic constrains.•Coastal frogs assessed water salinity before having access to water.•Frogs selected for salinity according to their hydric state.•Behavioural osmoregulation allowed salinity-dependant water selection. The environment...

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Bibliographic Details
Published in:Physiology & behavior 2022-05, Vol.249, p.113775-113775, Article 113775
Main Authors: Lorrain-Soligon, Léa, Robin, Frédéric, Brischoux, François
Format: Article
Language:English
Subjects:
Activity
Amphibian
Animals
Anura
Dehydration
Environmental Sciences
Fresh Water
Habitat selection
Humans
Osmotic status
Salinity
Water
Wetlands
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Summary:•Coastal areas are submitted to salinity fluctuations, inducing osmotic constrains.•Coastal frogs assessed water salinity before having access to water.•Frogs selected for salinity according to their hydric state.•Behavioural osmoregulation allowed salinity-dependant water selection. The environment is heterogeneous across spatial and temporal scales, and the behavioural responses required to adjust individuals’ needs to resource availability across such variable environments should be under selective pressure. Coastal wetlands are characterized by a diversity of habitats ranging from fresh- to salt water; and individuals occurring in such complex habitats need to adjust their habitat use based on their osmotic status. In this study, we experimentally tested whether an amphibian species (Pelophylax sp.) occurring in coastal wetlands was able to discriminate and select between different salinity concentrations (0, 4, 8 and 12 g.l−1) and whether hydric status (hydrated versus dehydrated) influenced salinity-dependent water selection. We found that frogs selected water based on salinity differentially between hydrated and dehydrated individuals, with the later favoring lower salinities likely to improve their osmotic status. Interestingly, we highlighted the ability of frogs to select lower salinity before having access to water, suggesting that frogs can assess water salinity without actual contact. In coastal wetlands where salinity of water bodies can dynamically vary through space and time, such behavioural osmoregulation process is potentially a key factor affecting individual movements, habitat choice and thus species distribution. Our study further highlights the importance of salinity-dependent habitat heterogeneity and especially the presence of freshwater environments as structuring factors for the amphibian community. [Display omitted]
ISSN:0031-9384
1873-507X
DOI:10.1016/j.physbeh.2022.113775