Data from: Migrating songbirds on stopover prepare for, and recover from, oxidative challenges posed by long-distance flight
Managing oxidative stress is an important physiological function for all aerobic organisms, particularly during periods of prolonged high metabolic activity, such as long-distance migration across ecological barriers. However, no previous study has investigated the oxidative status of birds at diffe...
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Zusammenfassung: | Managing oxidative stress is an important physiological function for all
aerobic organisms, particularly during periods of prolonged high metabolic
activity, such as long-distance migration across ecological barriers.
However, no previous study has investigated the oxidative status of birds
at different stages of migration and whether that oxidative status depends
on the condition of the birds. In this study, we compared (1) energy
stores and circulating oxidative status measures in (a) two species of
Neotropical migrants with differing migration strategies that were sampled
at an autumn stopover site before an ecological barrier; and (b) a species
of trans-Saharan migrant sampled at a spring stopover site after crossing
an ecological barrier; and (2) circulating oxidative measures and
indicators of fat metabolism in a trans-Saharan migrant after stopovers of
varying duration (0–8 nights), based on recapture records. We found fat
stores to be positively correlated with circulating antioxidant capacity
in Blackpoll Warblers and Red-eyed Vireos preparing for fall migration on
Block Island, USA, but uncorrelated in Garden Warblers on the island of
Ponza, Italy, after a spring crossing of the Sahara Desert and
Mediterranean Sea. In all circumstances, fat stores were positively
correlated with circulating lipid oxidation levels. Among Garden Warblers
on the island of Ponza, fat anabolism increased with stopover duration
while oxidative damage levels decreased. Our study provides evidence that
birds build antioxidant capacity as they build fat stores at stopover
sites before long flights, but does not support the idea that antioxidant
stores remain elevated in birds with high fuel levels after an ecological
barrier. Our results further suggest that lipid oxidation may be an
inescapable hazard of using fats as the primary fuel for flight. Yet, we
also show that birds on stopover are capable of recovering from the
oxidative damage they have accrued during migration, as lipid oxidation
levels decrease with time on stopover. Thus, the physiological strategy of
migrating songbirds may be to build prophylactic antioxidant capacity in
concert with fuel stores at stopover sites before a long-distance flight,
and then repair oxidative damage while refueling at stopover sites after
long-distance flight. |
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DOI: | 10.5061/dryad.sj6n2 |