Season, anthocyanin supplementation, and flight training have mixed effects on the antioxidant system of migratory European Starlings

Frawley, Abigail E.; DeMoranville, Kristen J.; Carbeck, Katherine; Trost, Lisa; Bryła, Amadeusz; Dzialo, Maciej; Sadowska, Edyta T.; Bauchinger, Ulf; Pierce, Barbara J.; McWilliams, Scott R.

doi:10.1093/ornithology/ukab023

Cited by 8 publications

(14 citation statements)

References 60 publications

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“…In contrast, flight duration (range: 65-205 min) was not related to d-ROMs levels in Northern Bald Ibis on a managed migration (Geronticus eremita; Bairlein et al, 2015). Similarly, several wind-tunnel studies on starlings (S. vulgaris) that involved weeks of flight training leading to long final flights up to 6 h have not found any change in d-ROMs associated with flight, either within individuals preand post-flight or between individuals that were either flown or not flown (McWilliams et al, 2020;Frawley et al, 2021). In contrast, starlings involved in a similar 2-week wind-tunnel flight training decreased d-ROMs after flight compared to pre-flight indicating a potential hormetic response (DeMoranville, 2020).…”

Section: Does Flight Elevate Oxidative Damage?mentioning

confidence: 91%

“…European Starlings also reduced OXY (and oxidative damage, noted above) immediately after flights in a wind tunnel, and the extent of this change was more apparent in birds that expended more energy during their longest flights (DeMoranville, 2020). OXY also changed in European Starlings immediately after flights, although the direction and extent of the change depended on season (fall vs. spring migration) and whether diets were supplemented with antioxidants (Frawley et al, 2021).…”

Section: Does Flight Deplete Antioxidant Capacity?mentioning

confidence: 97%

“…For example, European Robins caught during nocturnal migratory flight had higher GPx activity compared to birds on stopover (Jenni-Eiermann et al, 2014), and Yellow-rumped Warblers flown in a wind tunnel had higher SOD after flight than individuals at rest (Dick and Guglielmo, 2019). The response of enzymatic antioxidants in flight-trained European Starlings to an approximately 3-h flight in a wind tunnel depended on availability of dietary antioxidants (Frawley et al, 2021). Specifically, starlings fed a diet not supplemented with anthocyanin, a dietary antioxidant, had decreased GPx activity immediately after flight, whereas GPx activity did not change after flight for starlings fed a diet supplemented with anthocyanins (Frawley et al, 2021).…”

Section: Does Flight Deplete Antioxidant Capacity?mentioning

confidence: 99%

“…The response of enzymatic antioxidants in flight-trained European Starlings to an approximately 3-h flight in a wind tunnel depended on availability of dietary antioxidants (Frawley et al, 2021). Specifically, starlings fed a diet not supplemented with anthocyanin, a dietary antioxidant, had decreased GPx activity immediately after flight, whereas GPx activity did not change after flight for starlings fed a diet supplemented with anthocyanins (Frawley et al, 2021). Furthermore, Zebra Finches flown for short bursts had similar serum GPx, CAT, and SOD activity after flight compared to unflown control birds (Costantini et al, 2013).…”

Section: Does Flight Deplete Antioxidant Capacity?mentioning

confidence: 99%

“…Uric acid, a byproduct of protein catabolism and a powerful antioxidant, has been found to consistently increase after flight in several field and lab studies. European Starlings flown in wind tunnels had elevated serum uric acid immediately after up to 6 h of flight (Carter et al, 2020;McWilliams et al, 2020;Frawley et al, 2021). Whitecrowned Sparrows (Zonotrichia leucophrys) that were flown at high speeds in a hop/hover wheel (Tsahar et al, 2006) and pigeons flown for 4 h (Gannes et al, 2001) also had increased uric acid concentrations after flight.…”

Section: Does Flight Deplete Antioxidant Capacity?mentioning

confidence: 99%

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How Birds During Migration Maintain (Oxidative) Balance

et al. 2021

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Animals dynamically adjust their physiology and behavior to survive in changing environments, and seasonal migration is one life stage that demonstrates these dynamic adjustments. As birds migrate between breeding and wintering areas, they incur physiological demands that challenge their antioxidant system. Migrating birds presumably respond to these oxidative challenges by up-regulating protective endogenous systems or accumulating dietary antioxidants at stopover sites, although our understanding of the pre-migration preparations and mid-migration responses of birds to such oxidative challenges is as yet incomplete. Here we review evidence from field and captive-bird studies that address the following questions: (1) Do migratory birds build antioxidant capacity as they build fat stores in preparation for long flights? (2) Is oxidative damage an inevitable consequence of oxidative challenges such as flight, and, if so, how is the extent of damage affected by factors such as the response of the antioxidant system, the level of energetic challenge, and the availability of dietary antioxidants? (3) Do migratory birds ‘recover’ from the oxidative damage accrued during long-duration flights, and, if so, does the pace of this rebalancing of oxidative status depend on the quality of the stopover site? The answer to all these questions is a qualified ‘yes’ although ecological factors (e.g., diet and habitat quality, geographic barriers to migration, and weather) affect how the antioxidant system responds. Furthermore, the pace of this dynamic physiological response remains an open question, despite its potential importance for shaping outcomes on timescales ranging from single flights to migratory journeys. In sum, the antioxidant system of birds during migration is impressively dynamic and responsive to environmental conditions, and thus provides ample opportunities to study how the physiology of migratory birds responds to a changing and challenging world.

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Section: Does Flight Elevate Oxidative Damage?mentioning

confidence: 91%

Section: Does Flight Deplete Antioxidant Capacity?mentioning

confidence: 97%

Section: Does Flight Deplete Antioxidant Capacity?mentioning

confidence: 99%

Section: Does Flight Deplete Antioxidant Capacity?mentioning

confidence: 99%

Section: Does Flight Deplete Antioxidant Capacity?mentioning

confidence: 99%

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How Birds During Migration Maintain (Oxidative) Balance

et al. 2021

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Physiological challenges of migration

McWilliams

Ramenofsky

Pierce

2022

Sturkie's Avian Physiology

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Flight and Dietary Antioxidants Influence Antioxidant Expression and Activity in a Migratory Bird

DeMoranville

Carter

Pierce

et al. 2021

Integrative Organismal Biology

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Ecologically-relevant factors such as exercise and diet quality can directly influence how physiological systems work including those involved in maintaining oxidative balance; however, to our knowledge, no studies to date have focused on how such factors directly affect expression of key components of the endogenous antioxidant system (i.e., transcription factors, select antioxidant genes, and corresponding antioxidant enzymes) in several metabolically active tissues of a migratory songbird. We conducted a 3-factor experiment that tested the following hypotheses: (H1) Daily flying over several weeks increases the expression of transcription factors NRF2 and PPARs as well as endogenous antioxidant genes (i.e., CAT, SOD1, SOD2, GPX1, GPX4), and upregulates endogenous antioxidant enzyme activities (i.e., CAT, SOD, GPx). (H2) Songbirds fed diets composed of more 18:2n-6 PUFA are more susceptible to oxidative damage and thus upregulate their endogenous antioxidant system compared to when fed diets with less PUFA. (H3) Songbirds fed dietary anthocyanins gain additional antioxidant protection and thus upregulate their endogenous antioxidant system less compared to songbirds not fed anthocyanins. Flight training increased the expression of 3 of the 6 antioxidant genes and transcription factors measured in the liver, consistent with H1, but for only one gene (SOD2) in the pectoralis. Dietary fat quality had no effect on antioxidant pathways (H2) whereas dietary anthocyanins increased the expression of select antioxidant enzymes in the pectoralis, but not in the liver (H3). These tissue-specific differences in response to flying and dietary antioxidants are likely explained by functional differences between tissues as well as fundamental differences in their turnover rates. The consumption of dietary antioxidants along with regular flying enables birds during migration to stimulate the expression of genes involved in antioxidant protection likely through increasing the transcriptional activity of NRF2 and PPARs, and thereby demonstrates for the first time that these relevant ecological factors affect the regulation of key antioxidant pathways in wild birds. What remains to be demonstrated is how the extent of these ecological factors (i.e., intensity or duration of flight, amounts of dietary antioxidants) influences the regulation of these antioxidant pathways and thus oxidative balance.

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Season, anthocyanin supplementation, and flight training have mixed effects on the antioxidant system of migratory European Starlings

Cited by 8 publications

References 60 publications

How Birds During Migration Maintain (Oxidative) Balance

How Birds During Migration Maintain (Oxidative) Balance

Physiological challenges of migration

Flight and Dietary Antioxidants Influence Antioxidant Expression and Activity in a Migratory Bird

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