Abstract
Many birds undertake long migrations when they are only a few months of age. Although they are typically of adult body size, their performance and survival are often poor compared to adults. This differential performance could be due to lack of experience, selection against poor-performing cohort members, or inherent constraints of continuing physiological and morphological maturation of juveniles. Limited evidence suggests that digestive and muscle physiology of juveniles during their first migration may differ from that of adults. We compared body composition, metabolic rate, and digestive physiology between juvenile and adult passerines during fall migration. First, we measured fat and lean masses by quantitative magnetic resonance, and organ and muscle masses of salvaged carcasses of fall migrants from four passerine species. In general, juveniles had more lean mass and heavier digestive organs (especially liver) than adults in hermit thrushes (Catharus guttatus), Swainson’s thrushes (Catharus ustulatus), ovenbirds (Seiurus aurocapilla), and white-throated sparrows (Zonotrichia albicollis). Principal components analysis of all organs and muscles revealed that juveniles for three of four species had overall larger digestive components and smaller flight muscles than adults. We then used open-flow respirometry to measure basal metabolic rates (BMRs) of juvenile and adult Swainson’s thrushes and white-throated sparrows captured in fall at a migratory stopover site. Controlling for a significant effect of body mass, juveniles had 6% higher BMRs than adults in both species. We then conducted total collection mass balance feeding trials with fall migratory Swainson’s thrushes and white-throated sparrows. Juvenile thrushes had greater metabolizable energy intake than adults, which was achieved through higher food intake rather than greater utilization efficiency. Age classes of white-throated sparrows did not differ in these measures of digestive performance, although juveniles had greater food intake capacity at low lean body masses. We propose that age-related differences in foraging ecology, diet composition and energy requirements may be responsible for larger digestive organs of juvenile migrants. Larger guts may allow juveniles to consume more food or a more dilute diet, but may contribute to higher BMRs.
Highlights
Piersma and van Gils (2011) described the morphology and physiology of animal bodies as expressions of their ecologies
Our objective was to investigate whether adult and juvenile birds differ in body composition, basal metabolic rates (BMRs), and digestive performance during fall migration
Larger digestive organs of juvenile migrants can both result from and enable higher food intake, while larger organs can contribute to higher maintenance metabolic rates
Summary
Piersma and van Gils (2011) described the morphology and physiology of animal bodies as expressions of their ecologies. Animal bodies are not static; changes during development transform phenotype and performance capacity, and some animals maintain an ability to reversibly alter phenotype even when fully mature to cope with changes in workload associated with environmental variation or life history stages (Secor and Diamond, 1995; Piersma and Lindström, 1997; Piersma and Drent, 2003). During migration, animals such as birds face greatly elevated physiological demands and may experience a variety of environmental conditions as they move between breeding and wintering areas. The amount of time and energy spent at stopover sites can limit overall migration speed (Alerstam and Lindström, 1990)
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