Bill size mediates behavioural thermoregulation in birds

Summary Bird bills have been the subject of classic evolutionary studies that demonstrate how morphological adaptations are driven by foraging ecology. As significant areas of heat loss, bills are also under selection with respect to thermoregulation, yet the ecological consequences of this function...

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Published in	Functional ecology Vol. 31; no. 4; pp. 885 - 893
Main Authors	Ryeland, Julia, Weston, Michael A., Symonds, Matthew R.E.
Format	Journal Article
Language	English
Published	London Wiley 01.04.2017 Wiley Subscription Services, Inc
Subjects	Adaptation Allen's rule Ambient temperature Animal physiological ecology Aquatic birds back rest bill size Birds Body size climate climate adaptation Comparative analysis Ecological effects Ecological monitoring Ecology environmental impact Forage foraging Foraging behavior Heat Heat loss Plumage prediction roosting behavior Species Thermoregulation Thermoregulatory behavior
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Abstract	Summary Bird bills have been the subject of classic evolutionary studies that demonstrate how morphological adaptations are driven by foraging ecology. As significant areas of heat loss, bills are also under selection with respect to thermoregulation, yet the ecological consequences of this function have been largely ignored until recently. Given the role of bills in thermoregulation is important, we predict that birds should behave to minimise heat loss through their bills at lower ambient temperatures by attempting to insulate their bill in their plumage. Our second prediction is that this thermoregulatory behaviour should be utilised more by species with relatively larger bills, because they will be more prone to heat loss. We demonstrate both these predictions to be correct using field observations and a comparative analysis of nine shorebird species. First, the placement of the bill within the back plumage while roosting (‘back rest’ behaviour), which insulates the bill, becomes more frequent at cooler temperatures. Second, species with large bills relative to their body size do indeed use back rest behaviour more frequently across a range of temperatures. Our findings show that behavioural thermoregulation can be mediated by bill size, and that bill morphology is not only relevant to foraging ecology but also influences behavioural adaptations to climate. A lay summary is available for this article. Lay Summary
AbstractList	Bird bills have been the subject of classic evolutionary studies that demonstrate how morphological adaptations are driven by foraging ecology. As significant areas of heat loss, bills are also under selection with respect to thermoregulation, yet the ecological consequences of this function have been largely ignored until recently. Given the role of bills in thermoregulation is important, we predict that birds should behave to minimise heat loss through their bills at lower ambient temperatures by attempting to insulate their bill in their plumage. Our second prediction is that this thermoregulatory behaviour should be utilised more by species with relatively larger bills, because they will be more prone to heat loss. We demonstrate both these predictions to be correct using field observations and a comparative analysis of nine shorebird species. First, the placement of the bill within the back plumage while roosting (‘back rest’ behaviour), which insulates the bill, becomes more frequent at cooler temperatures. Second, species with large bills relative to their body size do indeed use back rest behaviour more frequently across a range of temperatures. Our findings show that behavioural thermoregulation can be mediated by bill size, and that bill morphology is not only relevant to foraging ecology but also influences behavioural adaptations to climate. A lay summary is available for this article. Bird bills have been the subject of classic evolutionary studies that demonstrate how morphological adaptations are driven by foraging ecology. As significant areas of heat loss, bills are also under selection with respect to thermoregulation, yet the ecological consequences of this function have been largely ignored until recently. Given the role of bills in thermoregulation is important, we predict that birds should behave to minimise heat loss through their bills at lower ambient temperatures by attempting to insulate their bill in their plumage. Our second prediction is that this thermoregulatory behaviour should be utilised more by species with relatively larger bills, because they will be more prone to heat loss. We demonstrate both these predictions to be correct using field observations and a comparative analysis of nine shorebird species. First, the placement of the bill within the back plumage while roosting (‘back rest’ behaviour), which insulates the bill, becomes more frequent at cooler temperatures. Second, species with large bills relative to their body size do indeed use back rest behaviour more frequently across a range of temperatures. Our findings show that behavioural thermoregulation can be mediated by bill size, and that bill morphology is not only relevant to foraging ecology but also influences behavioural adaptations to climate. A lay summary is available for this article. Summary Bird bills have been the subject of classic evolutionary studies that demonstrate how morphological adaptations are driven by foraging ecology. As significant areas of heat loss, bills are also under selection with respect to thermoregulation, yet the ecological consequences of this function have been largely ignored until recently. Given the role of bills in thermoregulation is important, we predict that birds should behave to minimise heat loss through their bills at lower ambient temperatures by attempting to insulate their bill in their plumage. Our second prediction is that this thermoregulatory behaviour should be utilised more by species with relatively larger bills, because they will be more prone to heat loss. We demonstrate both these predictions to be correct using field observations and a comparative analysis of nine shorebird species. First, the placement of the bill within the back plumage while roosting (‘back rest’ behaviour), which insulates the bill, becomes more frequent at cooler temperatures. Second, species with large bills relative to their body size do indeed use back rest behaviour more frequently across a range of temperatures. Our findings show that behavioural thermoregulation can be mediated by bill size, and that bill morphology is not only relevant to foraging ecology but also influences behavioural adaptations to climate. A lay summary is available for this article. Lay Summary 1. Bird bills have been the subject of classic evolutionary studies that demonstrate how morphological adaptations are driven by foraging ecology. As significant areas of heat loss, bills are also under selection with respect to thermoregulation, yet the ecological consequences of this function have been largely ignored until recently. 2. Given the role of bills in thermoregulation is important, we predict that birds should behave to minimise heat loss through their bills at lower ambient temperatures by attempting to insulate their bill in their plumage. 3. Our second prediction is that this thermoregulatory behaviour should be utilised more by species with relatively larger bills, because they will be more prone to heat loss. 4. We demonstrate both these predictions to be correct using field observations and a comparative analysis of nine shorebird species. First, the placement of the bill within the back plumage while roosting ('back rest' behaviour), which insulates the bill, becomes more frequent at cooler temperatures. Second, species with large bills relative to their body size do indeed use back rest behaviour more frequently across a range of temperatures. 5. Our findings show that behavioural thermoregulation can be mediated by bill size, and that bill morphology is not only relevant to foraging ecology but also influences behavioural adaptations to climate. A lay summary is available for this article. Lay Summary
Author	Symonds, Matthew R.E. Weston, Michael A. Ryeland, Julia
Author_xml	– sequence: 1 givenname: Julia surname: Ryeland fullname: Ryeland, Julia – sequence: 2 givenname: Michael A. surname: Weston fullname: Weston, Michael A. – sequence: 3 givenname: Matthew R.E. surname: Symonds fullname: Symonds, Matthew R.E.
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Snippet	Summary Bird bills have been the subject of classic evolutionary studies that demonstrate how morphological adaptations are driven by foraging ecology. As... Bird bills have been the subject of classic evolutionary studies that demonstrate how morphological adaptations are driven by foraging ecology. As significant... 1. Bird bills have been the subject of classic evolutionary studies that demonstrate how morphological adaptations are driven by foraging ecology. As...
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SubjectTerms	Adaptation Allen's rule Ambient temperature Animal physiological ecology Aquatic birds back rest bill size Birds Body size climate climate adaptation Comparative analysis Ecological effects Ecological monitoring Ecology environmental impact Forage foraging Foraging behavior Heat Heat loss Plumage prediction roosting behavior Species Thermoregulation Thermoregulatory behavior
Title	Bill size mediates behavioural thermoregulation in birds
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