Phenotypic compromise in the face of conflicting ecological demands:an example in red knots Calidris canutus

Phenotypic flexibility is a phenomenon where physiological functions in animals are reversibly adjusted in response to ecological constraints. Research usually focuses on effects of single constraints, but under natural conditions animals face a multitude of restrictions acting simultaneously, and p...

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Bibliographic Details
Published in:Journal of Avian Biology
Main Authors: Vezina, Francois, Dekinga, Anne, Piersma, Theunis
Format: Article in Journal/Newspaper
Language:English
Published: 2010
Subjects:
COST-BENEFIT-ANALYSIS
PECTORAL MUSCLE MASS
BODY-MASS
ORGAN SIZE
COLD-EXPOSURE
ANNUAL CYCLE
BIRDS
SHOREBIRDS
LACTATION
WINTER
Calidris canutus
Red Knot
Online Access:https://hdl.handle.net/11370/0952e38d-135a-43a2-9b5f-c35f090aa1c1
https://research.rug.nl/en/publications/0952e38d-135a-43a2-9b5f-c35f090aa1c1
https://doi.org/10.1111/j.1600-048X.2009.04763.x
https://pure.rug.nl/ws/files/6742347/2010JAvianBiolVezina.pdf
Description
Summary:Phenotypic flexibility is a phenomenon where physiological functions in animals are reversibly adjusted in response to ecological constraints. Research usually focuses on effects of single constraints, but under natural conditions animals face a multitude of restrictions acting simultaneously, and potentially generating conflicting demands on the phenotype. We investigated the conflicting demands of low temperatures and a low quality diet on the phenotype of a shorebird, the red knot Calidris canutus. We tested the effects of switching diet from a high quality trout food to low quality hard-shelled bivalves in captive birds acclimated to temperatures reflecting natural winter conditions. Feeding on bivalves generated a digestive constraint forcing the birds to increase the height and width of their gizzard by 66% and 71%, respectively, over 30 days. The change in gizzard size was associated with an initial 15% loss of body mass and a reduction in size of the pectoral muscles by 11%. Because pectoral muscle size determines summit metabolic rate (M(sum), an indicator of cold endurance), measured M(sum) declined by 9%. Therefore, although the birds were acclimated to cold, gizzard growth led to a loss of cold endurance. We propose that cold-acclimated knots facing a digestive constraint made a phenotypic compromise by giving-up cold hardiness for digestive capacity. Field studies suggest that phenotypic compromises occur in free-living red knots as well and help improve survival.

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