Data from: Large-brained birds suffer less oxidative damage

Large brains (relative to body size) might confer fitness benefits to animals. Although the putative costs of well-developed brains can constrain the majority of species to modest brain sizes, these costs are still poorly understood. Given that the neural tissue is energetically expensive and demand...

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Bibliographic Details
Main Authors: Vágási, Csongor I., Vincze, Orsolya, Pătraș, Laura, Osváth, Gergely, Marton, Attila, Bărbos, Lőrinc, Sol, Daniel, Pap, Péter L.
Format: Dataset
Language:unknown
Published: 2021
Subjects:
Life sciences
medicine and health care
Anthus spinoletta
Merops apiaster
Luscinia megarhynchos
Luscinia luscinia
Locustella luscinioides
Periparus ater
Sylvia atricapilla
Passer montanus
Muscicapa striata
Phasianus colchicus
Cuculus canorus
Acrocephalus palustris
Anthus campestris
Cinclus cinclus
Linaria cannabina
Turdus philomelos
Phylloscopus trochilus
Tachymarptis melba
Poecile palustris
Anthus trivialis
Passer hispaniolensis
Sitta europaea
Aegithalos caudatus
Pica pica
Upupa epops
Troglodytes troglodytes
Ixobrychus minutus
lipid peroxidation
Acrocephalus arundinaceus
Passer domesticus
Emberiza citrinella
Turdus merula
Corvus cornix
Bombycilla garrulus
Streptopelia decaocto
Falco vespertinus
Panurus biarmicus
Coracias garrulus
Sylvia borin
Fringilla coelebs
Alauda arvensis
Phylloscopus sibilatrix
Sylvia curruca
Acrocephalus scirpaceus
Phoenicurus ochruros
Asio otus
Online Access:https://doi.org/10.5061/dryad.3836f
Description
Summary:Large brains (relative to body size) might confer fitness benefits to animals. Although the putative costs of well-developed brains can constrain the majority of species to modest brain sizes, these costs are still poorly understood. Given that the neural tissue is energetically expensive and demands antioxidants, one potential cost of developing and maintaining large brains is increased oxidative stress (‘oxidation exposure’ hypothesis). Alternatively, because large-brained species exhibit slow-paced life histories, they are expected to invest more into self-maintenance such as an efficacious antioxidative defence machinery (‘oxidation avoidance’ hypothesis). We predict decreased antioxidant levels and/or increased oxidative damage in large-brained species in case of oxidation exposure, and the contrary in case of oxidation avoidance. We address these contrasting hypotheses for the first time by means of a phylogenetic comparative approach based on an unprecedented dataset of 4 redox state markers from 85 European bird species. Large-brained birds suffered less oxidative damage to lipids (measured as malondialdehyde levels) and exhibited higher total non-enzymatic antioxidant capacity than small-brained birds, while uric acid and glutathione levels were independent of brain size. These results were not altered by potentially confounding variables and did not depend on how relative brain size was quantified. Our findings partially support the ‘oxidation avoidance’ hypothesis and provide a physiological explanation for the linkage of large brains with slow-paced life histories: reduced oxidative stress of large-brained birds can secure brain functionality and healthy lifespan, which are integral to their lifetime fitness and slow-paced life history. Oxidative state data for 85 European bird speciesData for: Vágási et al. 2016. Large-brained birds suffer less oxidative damage. Journal of Evolutionary Biology. Data provided: four oxidative state markers (total antioxidant status, uric acid, total glutathione and ...

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