ENERGETIC CONSEQUENCES OF CLUTCH TEMPERATURE AND CLUTCH SIZE FOR A UNIPARENTAL INTERMITTENT INCUBATOR: THE STARLING

ENERGETIC CONSEQUENCES OF CLUTCH TEMPERATURE AND CLUTCH SIZE FOR A UNIPARENTAL INTERMITTENT INCUBATOR: THE STARLING

In uniparental intermittent incubators, incubating parents must simultaneously regulate both the temperature of the clutch and their own energy level. To examine energetic consequences of providing different thermal environments for clutches of different sizes, a dynamic model was constructed in whi...

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Bibliographic Details
Published in:The Auk Vol. 119; no. 1; pp. 54 - 61
Main Authors: Reid, J. M, Ruxton, G. D, Monaghan, P, Hilton, G. M
Format: Journal Article
Language:English
Published: Lawrence, KS The American Ornithologists' Union 01-01-2002
Ornithological Societies North America
American Ornithological Society
Subjects:
Animal reproduction
Biological and medical sciences
Birds
Clutch size
Eggs
Energy value
Female animals
Foraging
Fundamental and applied biological sciences. Psychology
Incubation
Incubators
Intermediate and energetic metabolism
Male animals
Metabolisms and neurohumoral controls
Modeling
Ornithology
Starlings
Temperature
Vertebrates: anatomy and physiology, studies on body, several organs or systems
Parental behavior
Reproductive effort
Energy metabolism
Temperature
Brooding
Thermoregulation
Environmental factor
Clutch size
Experimental study
Breeding behavior
Energy budget
Reproduction
Vertebrata
Energetic cost
Aves
Dynamic model
Sturnus vulgaris
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Summary:In uniparental intermittent incubators, incubating parents must simultaneously regulate both the temperature of the clutch and their own energy level. To examine energetic consequences of providing different thermal environments for clutches of different sizes, a dynamic model was constructed in which energy level of an incubating European Starling (Sturnus vulgaris) and temperature of its clutch were simultaneously described. Adult energy balance after a day of incubation decreased as mean clutch temperature increased, such that the debt accrued while maintaining a clutch within the optimal developmental temperature range (36–39°C) was predicted to be prohibitively high, despite the prediction that the mean basal metabolic rate (BMR) required to maintain this temperature was <2 BMR. Thus, this model can explain our observation that starlings maintained their eggs at 32–33°C, well below the developmental optimum. Consistent with empirical studies, our model predicted that the metabolic demand of incubation increases with clutch size. That increase was predicted to affect adult energy balance and hence cost of incubation when starlings maintained their clutches at optimal temperatures, but not at the lower temperatures actually observed. Hence, clutch-size-dependent variation in incubation demands may be unlikely to influence optimal number of eggs that a starling should lay. However, exact relationship between clutch size and adult energy debt depended on the nature of the relationship between clutch size and clutch thermal properties and on mean incubation temperature. Thus, consequences of clutch size for the cost of incubation are not clearly predictable, and caution may be required when using experimental clutch enlargements to manipulate reproductive costs.
ISSN:0004-8038
1938-4254
2732-4613
DOI:10.1642/0004-8038(2002)119[0054:ECOCTA]2.0.CO;2