Avian pectoral muscle size rapidly tracks body mass changes during flight, fasting and fuelling

We used ultrasonic imaging to monitor short-term changes in the pectoral muscle size of captive red knots Calidris canutus. Pectoral muscle thickness changed rapidly and consistently in parallel with body mass changes caused by flight, fasting;and fuelling. Four knots hew repeatedly for 10h periods...

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Bibliographic Details
Main Authors: Lindström, Åke, Kvist, A, Piersma, T, Dekinga, A, Dietz, M W
Format: Article in Journal/Newspaper
Language:English
Published: 2000
Subjects:
flight
pectoral muscle
migration
phenotypic flexibility
exercise
power training
ultrasonic imaging
wind tunnel
red knot
Calidris canutus
BIRDS
HYPERTROPHY
FAT
ADAPTATIONS
DIET
Red Knot
Online Access:https://hdl.handle.net/11370/6f311c00-0b14-401b-a9cd-d1900314fa67
https://research.rug.nl/en/publications/6f311c00-0b14-401b-a9cd-d1900314fa67
https://pure.rug.nl/ws/files/6659883/2000JExpBiolLindstrom.pdf
Description
Summary:We used ultrasonic imaging to monitor short-term changes in the pectoral muscle size of captive red knots Calidris canutus. Pectoral muscle thickness changed rapidly and consistently in parallel with body mass changes caused by flight, fasting;and fuelling. Four knots hew repeatedly for 10h periods in a wind tunnel. Over this period, pectoral muscle thickness decreased in parallel with the decrease in body mass. The change in pectoral muscle thickness during flight wats indistinguishable from that during periods of natural and experimental fasting and fuelling, The body-mass-related variation in pectoral muscle thickness between and within individuals was not related to the amount of Right, indicating that changes in avian muscle do not require power-training as in mammals. Our study suggests that it is possible for birds to consume and replace their flight muscles on a time scale short enough to allow these muscles to be used as part of the energy supply for migratory flight. The adaptive significance of the changes in pectoral muscle mass cannot be explained by reproductive needs since our knots were in the early winter phase of their annual cycle. Instead, pectoral muscle mass changes may reflect (i) the breakdown of protein during heavy exercise and its subsequent restoration, (ii) the regulation of flight capacity to maintain optimal flight performance when body mass varies, or (iii) the need for a particular protein:fat ratio in winter survival stores.

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