Avian BMR in marine and non-marine habitats: a test using shorebirds

Basal metabolic rate (BMR) is closely linked to different habitats and way of life. In birds, some studies have noted that BMR is higher in marine species compared to those inhabiting terrestrial habitats. However, the extent of such metabolic dichotomy and its underlying mechanisms are largely unkn...

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Veröffentlicht in:	PloS one 2012-07, Vol.7 (7), p.e42206-e42206
Hauptverfasser:	Gutiérrez, Jorge S, Abad-Gómez, José M, Sánchez-Guzmán, Juan M, Navedo, Juan G, Masero, José A
Format:	Artikel
Sprache:	eng
Schlagworte:	Analysis Anatomy & physiology Animal behavior Animal Migration Animals Aquatic birds Aquatic habitats Basal Metabolism Biology Birds Birds - classification Birds - metabolism Body mass Body temperature Breeding Breeding seasons Climate Coastal ecology Coasts Divergence Ecology Ecosystem Energy expenditure Evolution Foraging behavior Freshwater environments Habitats Interspecific Latitude Marine Biology Metabolic rate Metabolism Microclimate Migration Migratory birds Migratory species Phenotypic plasticity Phenotypic variations Phylogenetics Phylogeny Physiological aspects Physiology Plastic properties Plasticity Radiation (Physics) Salinity Solar radiation Species Specificity Studies Temperature effects Terrestrial environments Zoology
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description	Basal metabolic rate (BMR) is closely linked to different habitats and way of life. In birds, some studies have noted that BMR is higher in marine species compared to those inhabiting terrestrial habitats. However, the extent of such metabolic dichotomy and its underlying mechanisms are largely unknown. Migratory shorebirds (Charadriiformes) offer a particularly interesting opportunity for testing this marine-non-marine difference as they are typically divided into two broad categories in terms of their habitat occupancy outside the breeding season: 'coastal' and 'inland' shorebirds. Here, we measured BMR for 12 species of migratory shorebirds wintering in temperate inland habitats and collected additional BMR values from the literature for coastal and inland shorebirds along their migratory route to make inter- and intraspecific comparisons. We also measured the BMR of inland and coastal dunlins Calidris alpina wintering at a similar latitude to facilitate a more direct intraspecific comparison. Our interspecific analyses showed that BMR was significantly lower in inland shorebirds than in coastal shorebirds after the effects of potentially confounding climatic (latitude, temperature, solar radiation, wind conditions) and organismal (body mass, migratory status, phylogeny) factors were accounted for. This indicates that part of the variation in basal metabolism might be attributed to genotypic divergence. Intraspecific comparisons showed that the mass-specific BMR of dunlins wintering in inland freshwater habitats was 15% lower than in coastal saline habitats, suggesting that phenotypic plasticity also plays an important role in generating these metabolic differences. We propose that the absence of tidally-induced food restrictions, low salinity, and less windy microclimates associated with inland freshwater habitats may reduce the levels of energy expenditure, and hence BMR. Further research including common-garden experiments that eliminate phenotypic plasticity as a source of phenotypic variation is needed to determine to what extent these general patterns are attributable to genotypic adaptation.
doi_str_mv	10.1371/journal.pone.0042206
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In birds, some studies have noted that BMR is higher in marine species compared to those inhabiting terrestrial habitats. However, the extent of such metabolic dichotomy and its underlying mechanisms are largely unknown. Migratory shorebirds (Charadriiformes) offer a particularly interesting opportunity for testing this marine-non-marine difference as they are typically divided into two broad categories in terms of their habitat occupancy outside the breeding season: 'coastal' and 'inland' shorebirds. Here, we measured BMR for 12 species of migratory shorebirds wintering in temperate inland habitats and collected additional BMR values from the literature for coastal and inland shorebirds along their migratory route to make inter- and intraspecific comparisons. We also measured the BMR of inland and coastal dunlins Calidris alpina wintering at a similar latitude to facilitate a more direct intraspecific comparison. 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In birds, some studies have noted that BMR is higher in marine species compared to those inhabiting terrestrial habitats. However, the extent of such metabolic dichotomy and its underlying mechanisms are largely unknown. Migratory shorebirds (Charadriiformes) offer a particularly interesting opportunity for testing this marine-non-marine difference as they are typically divided into two broad categories in terms of their habitat occupancy outside the breeding season: 'coastal' and 'inland' shorebirds. Here, we measured BMR for 12 species of migratory shorebirds wintering in temperate inland habitats and collected additional BMR values from the literature for coastal and inland shorebirds along their migratory route to make inter- and intraspecific comparisons. We also measured the BMR of inland and coastal dunlins Calidris alpina wintering at a similar latitude to facilitate a more direct intraspecific comparison. Our interspecific analyses showed that BMR was significantly lower in inland shorebirds than in coastal shorebirds after the effects of potentially confounding climatic (latitude, temperature, solar radiation, wind conditions) and organismal (body mass, migratory status, phylogeny) factors were accounted for. This indicates that part of the variation in basal metabolism might be attributed to genotypic divergence. Intraspecific comparisons showed that the mass-specific BMR of dunlins wintering in inland freshwater habitats was 15% lower than in coastal saline habitats, suggesting that phenotypic plasticity also plays an important role in generating these metabolic differences. We propose that the absence of tidally-induced food restrictions, low salinity, and less windy microclimates associated with inland freshwater habitats may reduce the levels of energy expenditure, and hence BMR. Further research including common-garden experiments that eliminate phenotypic plasticity as a source of phenotypic variation is needed to determine to what extent these general patterns are attributable to genotypic adaptation.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>22860084</pmid><doi>10.1371/journal.pone.0042206</doi><tpages>e42206</tpages><oa>free_for_read</oa></addata></record>
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subjects	Analysis Anatomy & physiology Animal behavior Animal Migration Animals Aquatic birds Aquatic habitats Basal Metabolism Biology Birds Birds - classification Birds - metabolism Body mass Body temperature Breeding Breeding seasons Climate Coastal ecology Coasts Divergence Ecology Ecosystem Energy expenditure Evolution Foraging behavior Freshwater environments Habitats Interspecific Latitude Marine Biology Metabolic rate Metabolism Microclimate Migration Migratory birds Migratory species Phenotypic plasticity Phenotypic variations Phylogenetics Phylogeny Physiological aspects Physiology Plastic properties Plasticity Radiation (Physics) Salinity Solar radiation Species Specificity Studies Temperature effects Terrestrial environments Zoology
title	Avian BMR in marine and non-marine habitats: a test using shorebirds
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