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The migratory movements undertaken by birds are among the most energetically demanding behaviours observed in nature. Mitochondria are the source of aerobic energy production on which migration depends, but a key component of mitochondrial function, mitochondrial remodelling, has not been investigated in the context of bird migration. We measured markers of mitochondrial remodelling in the skeletal muscles of the Gambel’s (migratory) and Nuttall’s (non-migratory) white-crowned sparrows within and outside migratory periods. Gambel’s were collected in (i) a non-migration period (baseline), (ii) preparation to depart for spring migration (pre-migration) and (iii) active autumn migration (mid-migration). Nuttall’s were collected at timepoints corresponding to baseline and mid-migration in Gambel’s. Across all sampling periods, we found that migratory birds had greater mitochondrial remodelling compared with non-migratory birds. Furthermore, birds from the migratory population also displayed flexibility, increasing several markers of mitochondrial remodelling (e.g. NRF1, OPA1 and Drp1) pre- and during migration. Further, the greater levels of mitochondrial remodelling and its upregulation during migration were specific to the pectoralis muscle used in flapping flight. Our study is the first to show that mitochondrial remodelling supports migration in Gambel’s white-crowned sparrows, indicating a highly specific and efficient phenotype supporting the increased energetic demands of migration. 

Abstract Migration is one of the most energy-demanding behaviors observed in birds. Mitochondria are the primary source of energy used to support these long-distance movements, yet how mitochondria meet the energetic demands of migration is scarcely studied. We quantified changes in mitochondrial respiratory performance in the White-crowned Sparrow (Zonotrichia leucophrys), which has a migratory and non-migratory subspecies. We hypothesized that the long-distance migratory Gambel’s subspecies (Z. l. gambelii) would show higher mitochondrial respiratory performance compared to the non-migratory Nuttall’s subspecies (Z. l. nuttalli). We sampled Gambel’s individuals during spring pre-migration, active fall migration, and a period with no migration or breeding (winter). We sampled Nuttall’s individuals during periods coinciding with fall migration and the winter period of Gambel’s annual cycle. Overall, Gambel’s individuals had higher citrate synthase, a proxy for mitochondrial volume, than Nuttall’s individuals. This was most pronounced prior to and during migration. We found that both OXPHOS capacity (state 3) and basal respiration (state 4) of mitochondria exhibit high seasonal flexibility within Gambel’s individuals, with values highest during active migration. These values in Nuttall’s individuals were most similar to Gambel’s individuals in winter. Our observations indicate that seasonal changes in mitochondrial respiration play a vital role in migration energetics. 

ABSTRACT Considerable progress has been made in understanding the physiological basis for variation in the life‐history patterns of animals, particularly with regard to the roles of oxidative stress and hormonal regulation. However, an underappreciated and understudied area that could play a role in mediating inter‐ and intraspecific variation of life history is endoplasmic reticulum (ER) stress, and the resulting unfolded protein response (UPR^ER). ER stress response and the UPR^ERmaintain proteostasis in cells by reducing the intracellular load of secretory proteins and enhancing protein folding capacity or initiating apoptosis in cells that cannot recover. Proper modulation of the ER stress response and execution of the UPR^ERallow animals to respond to intracellular and extracellular stressors and adapt to constantly changing environments. ER stress responses are heritable and there is considerable individual variation in UPR^ERphenotype in animals, suggesting that ER stress and UPR^ERphenotype can be subjected to natural selection. The variation in UPR^ERphenotype presumably reflects the way animals respond to ER stress and environmental challenges. Most of what we know about ER stress and the UPR^ERin animals has either come from biomedical studies using cell culture or from experiments involving conventional laboratory or agriculturally important models that exhibit limited genetic diversity. Furthermore, these studies involve the assessment of experimentally induced qualitative changes in gene expression as opposed to the quantitative variations that occur in naturally existing populations. Almost all of these studies were conducted in controlled settings that are often quite different from the conditions animals experience in nature. Herein, we review studies that investigated ER stress and the UPR^ERin relation to key life‐history traits including growth and development, reproduction, bioenergetics and physical performance, and ageing and senescence. We then ask if these studies can inform us about the role of ER stress and the UPR^ERin mediating the aforementioned life‐history traits in free‐living animals. We propose that there is a need to conduct experiments pertaining to ER stress and the UPR^ERin ecologically relevant settings, to characterize variation in ER stress and the UPR^ERin free‐living animals, and to relate the observed variation to key life‐history traits. We urge others to integrate multiple physiological systems and investigate how interactions between ER stress and oxidative stress shape life‐history trade‐offs in free‐living animals.