The performing animal: causes and consequences of body remodeling and metabolic adjustments in red knots facing contrasting thermal environments

Using red knots ( ) as a model, we determined how changes in mass and metabolic activity of organs relate to temperature-induced variation in metabolic performance. In cold-acclimated birds, we expected large muscles and heart as well as improved oxidative capacity and lipid transport, and we predic...

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Bibliographic Details
Published in:American journal of physiology. Regulatory, integrative and comparative physiology integrative and comparative physiology, 2017-08, Vol.313 (2), p.R120-R131
Main Authors: Vézina, François, Gerson, Alexander R, Guglielmo, Christopher G, Piersma, Theunis
Format: Article
Language:English
Subjects:
Adjustment
Animals
Birds
Birds - physiology
Body Composition - physiology
Body fat
Carnitine
Catabolism
Citrate synthase
Endurance
Energy Metabolism - physiology
Heart diseases
Kidneys
Knots
Lipid metabolism
Lipids
Liver
Metabolic rate
Metabolism
Mitochondria
Muscle, Skeletal - physiology
Muscles
Organs
Temperature
Thermal environments
Thermogenesis - physiology
Thermotolerance - physiology
Transport
Variation
Viscera - physiology
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Summary:Using red knots ( ) as a model, we determined how changes in mass and metabolic activity of organs relate to temperature-induced variation in metabolic performance. In cold-acclimated birds, we expected large muscles and heart as well as improved oxidative capacity and lipid transport, and we predicted that this would explain variation in maximal thermogenic capacity (M ). We also expected larger digestive and excretory organs in these same birds and predicted that this would explain most of the variation in basal metabolic rate (BMR). Knots kept at 5°C were 20% heavier and maintained 1.5 times more body fat than individuals kept in thermoneutral conditions (25°C). The birds in the cold also had a BMR up to 32% higher and a M 16% higher than birds at 25°C. Organs were larger in the cold, with muscles and heart being 9-20% heavier and digestive and excretory organs being 21-36% larger than at thermoneutrality. Rather than the predicted digestive and excretory organs, the cold-induced increase in BMR correlated with changes in mass of the heart, pectoralis, and carcass. M varied positively with the mass of the pectoralis, supracoracoideus, and heart, highlighting the importance of muscles and cardiac function in cold endurance. Cold-acclimated knots also expressed upregulated capacity for lipid transport across mitochondrial membranes [carnitine palmitoyl transferase (CPT)] in their pectoralis and leg muscles, higher lipid catabolism capacity in their pectoralis muscles [β-hydroxyacyl CoA-dehydrogenase (HOAD)], and elevated oxidative capacity in their liver and kidney (citrate synthase). These adjustments may have contributed to BMR through changes in metabolic intensity. Positive relationships among M , CPT, and HOAD in the heart also suggest indirect constraints on thermogenic capacity through limited cardiac capacity.
ISSN:0363-6119
1522-1490
DOI:10.1152/ajpregu.00453.2016