Your search keyword '"Audrey Le Pogam"' showing total 6 results

1. Early life neonicotinoid exposure results in proximal benefits and ultimate carryover effects

Author

Olivier Chastel, Lyette Régimbald, François Vézina, Louise Prouteau, Hélène Budzinski, Oliver P. Love, Thomas Zgirski, Audrey Le Pogam, Pierre Legagneux, Université du Québec à Rimouski (UQAR), Rimouski, QC, G5L 3A1, Canada, Centre de la Science de la Biodiversité du Québec (QCBS), Montréal, QC, Canada, Université Laval, Quebec, QC, G1V 0A6, Canada, Centre d’Etudes Biologiques de Chizé (CEBC), UMR 7372 CNRS - La Rochelle Université, France, 79360, Villiers-en-Bois, France, Centre d’Études Nordiques (CEN), Quebec, QC, Canada, Equipe LPTC - Laboratoire EPOC (CNRS/université de Bordeaux) - Bordeaux, France, Groupe de recherche sur les environnements nordiques (BORÉAS), Rimouski, QC, Canada, and University of Windsor, Windsor, ON, N9B 3P4, Canada

Subjects

Science, Ecophysiology, Marine Biology, Growth disorders, 010501 environmental sciences, Biology, 01 natural sciences, Adult age, Article, Songbirds, 03 medical and health sciences, chemistry.chemical_compound, Neonicotinoids, Animal science, Imidacloprid, Reduced fat, parasitic diseases, Animals, [CHIM]Chemical Sciences, Compensatory growth (organism), Biochemistry, Biophysics, and Structural Biology, 030304 developmental biology, 0105 earth and related environmental sciences, 0303 health sciences, Multidisciplinary, Neonicotinoid, Life Sciences, Biodiversity, Early life, Metabolism, chemistry, Basal metabolic rate, Lean body mass, Medicine

Abstract

Neonicotinoids are insecticides widely used as seed treatments that appear to have multiple negative effects on birds at a diversity of biological scales. Adult birds exposed to a low dose of imidacloprid, one of the most commonly used neonicotinoids, presented reduced fat stores, delayed migration and potentially altered orientation. However, little is known on the effect of imidacloprid on birds growth rate despite studies that have documented disruptive effects of low imidacloprid doses on thyroid gland communication. We performed a $$2 \times 2$$ 2 × 2 factorial design experiment in Zebra finches, in which nestling birds were exposed to a very low dose (0.205 mg kg body $$\hbox {mass}^{-1}$$ mass - 1 ) of imidacloprid combined with food restriction during posthatch development. During the early developmental period, imidacloprid exposure resulted in an improvement of body condition index in treated nestlings relative to controls. Imidacloprid also led to compensatory growth in food restricted nestlings. This early life neonicotinoid exposure also carried over to adult age, with exposed birds showing higher lean mass and basal metabolic rate than controls at ages of 90–800 days. This study presents the first evidence that very low-dose neonicotinoid exposure during early life can permanently alter adult phenotype in birds.

Published

2021

2. Snow Buntings Maintain Winter-Level Cold Endurance While Migrating to the High Arctic

Author

Audrey Le Pogam, Ryan S. O’Connor, Oliver P. Love, Justine Drolet, Lyette Régimbald, Gabrielle Roy, Marie-Pier Laplante, Dominique Berteaux, Andrew Tam, and François Vézina

Subjects

Muscle size, Evolution, Bunting, Zoology, Marine Biology, migration, Acclimatization, QH359-425, Biology, Biochemistry, Biophysics, and Structural Biology, Ecology, Evolution, Behavior and Systematics, QH540-549.5, Arctic bird, body composition, phenotypic flexibility, cold acclimatization, biology, Ecology, summit metabolic rate, Life Sciences, Biodiversity, Snow, biology.organism_classification, Arctic breeding, The arctic, Arctic, Basal metabolic rate, basal metabolic rate, Plectrophenax

Abstract

Arctic breeding songbirds migrate early in the spring and can face winter environments requiring cold endurance throughout their journey. One such species, the snow bunting (Plectrophenax nivalis), is known for its significant thermogenic capacity. Empirical studies suggest that buntings can indeed maintain winter cold acclimatization into the migratory and breeding phenotypes when kept captive on their wintering grounds. This capacity could be advantageous not only for migrating in a cold environment, but also for facing unpredictable Arctic weather on arrival and during preparation for breeding. However, migration also typically leads to declines in the sizes of several body components linked to metabolic performance. As such, buntings could also experience some loss of cold endurance as they migrate. Here, we aimed to determine whether free-living snow buntings maintain a cold acclimatized phenotype during spring migration. Using a multi-year dataset, we compared body composition (body mass, fat stores, and pectoralis muscle thickness), oxygen carrying capacity (hematocrit) and metabolic performance (thermogenic capacity – Msum and maintenance energy expenditure – BMR) of birds captured on their wintering grounds (January–February, Rimouski, QC, 48°N) and during pre-breeding (April–May) in the Arctic (Alert, NU, 82°). Our results show that body mass, fat stores and Msum were similar between the two stages, while hematocrit and pectoralis muscle thickness were lower in pre-breeding birds than in wintering individuals. These results suggest that although tissue degradation during migration may affect flight muscle size, buntings are able to maintain cold endurance (i.e., Msum) up to their Arctic breeding grounds. However, BMR was higher during pre-breeding than during winter, suggesting higher maintenance costs in the Arctic.

Published

2021

3. Coping with the worst of both worlds: Phenotypic adjustments for cold acclimatization benefit northward migration and arrival in the cold in an Arctic-breeding songbird

Author

Magali Petit, Audrey Le Pogam, Lyette Régimbald, François Vézina, Ryan S. O'Connor, and Oliver P. Love

Subjects

Coping (psychology), body composition, cold acclimatization, Ecology, fattening, Life Sciences, Marine Biology, Biodiversity, Biology, biology.organism_classification, migration, Acclimatization, carryover, Songbird, Arctic, M sum, BMR, Ecology, Evolution, Behavior and Systematics, Arctic bird, Biochemistry, Biophysics, and Structural Biology

Abstract

Cold acclimatization (phenotypic adjustments to cope with cold conditions) is an imperative requirement for birds living at high latitudes during the cold depths of winter. Despite the significant remodelling of key phenotypic traits and energetic costs associated with elevating cold endurance, winter cold acclimatization can also provide further carryover benefits to subsequent stages in species wintering, migrating and breeding in cold environments (e.g. the Arctic). We tested this beneficial carryover hypothesis using outdoor captive Arctic-breeding snow buntings Plectrophenax nivalis, a cold specialist known for its impressive wintering thermogenic capabilities. We compared changes in phenotypic traits supporting cold acclimatization—body composition (body, fat, lean mass, pectoral muscle thickness), oxygen carrying capacity (haematocrit), thermogenic capacity and endurance (Msum, time to Msum), cold tolerance (Ta at Msum) and maintenance energy expenditure (BMR)—between the wintering, migratory and arrival/summer stages. Body mass (+31%), fat mass (+226%) and BMR (+13%) increased relative to the winter phenotype, likely to support the added costs of migration—that is the migratory upregulation hypothesis. In contrast, lean mass, pectoral muscle thickness, haematocrit and thermogenic capacity remained high and stable at winter level across stages in support of the thermal carryover hypothesis. The maintenance of these traits likely offers spare capacity for unpredictable cold environments expected during migration and breeding in the Arctic. Our results thus suggest that birds can extend the long-term advantages of winter phenotypic adjustments through additional benefits to thermogenic capacity during subsequent life-history stages. These benefits likely make it possible for Arctic-breeding birds to maximize success across diverse life-history stages in the face of extreme cold conditions.

Published

2021

4. Snow buntings preparing for migration increase muscle fiber size and myonuclear domain in parallel with a major gain in fat mass

Author

Oliver P. Love, Ryan S. O'Connor, François Vézina, Ana Gabriela Jimenez, Aliyah D. De Jesus, and Audrey Le Pogam

Subjects

Muscle ultrastructure, phenotypic flexibility, cold acclimatization, fattening, Life Sciences, Marine Biology, Biodiversity, Biology, Snow, migration, muscle ultrastructure, Fat mass, Domain (software engineering), Biophysics, Animal Science and Zoology, Muscle fibre, Ecology, Evolution, Behavior and Systematics, Biochemistry, Biophysics, and Structural Biology

Abstract

In long-distance migrants, preparation for migration is typically associated with increases in fat and body mass, and with an enlargement of pectoralis muscle mass that likely improves flight performance. Although changes in muscle mass or size have been well described in migratory birds, potential changes in muscle ultrastructure during this transition still deserves scrutiny. Using outdoor captive snow buntings (Plectrophenax nivalis n = 15) measured during their transition into a spring migratory phenotype as a model system, we studied changes in pectoralis muscle ultrastructure and predicted that muscle fiber diameter could increase in parallel with the gain in body mass. We also expected that larger fibers could either recruit satellite cells to support cellular maintenance and protein turnover, increase myonuclear domain (cytoplasm per nuclei) with a potential increase in protein turnover load per myonucleus, or existing myonuclei could undergo endoreduplication. Buntings increased body mass by 46% within a month, largely due to a > 6-fold increase in body fat. However, this increase in body mass was also associated with a 36% increase in muscle fiber diameter. Both pectoralis muscle mass (r2 = 0.57–0.77) and fiber diameter (r2 = 0.32) correlated with total body mass, without any change in the number of nuclei per fiber. Consequently, variation in myonuclear domain (i.e. the amount of cytoplasm per nucleus), was also positively associated with body mass (r2 = 0.51). Therefore, buntings preparing for migration may experience an increase in muscle contraction force due to larger muscle fibers, but this is also coupled with increases in myonuclear domain, which may force these cells to increase protein production to safeguard satellite cells.

Published

2021

5. Wintering snow buntings elevate cold hardiness to extreme levels but show no changes in maintenance costs

Author

Fanny Hallot, Myriam Milbergue, Ryan S. O'Connor, Magali Petit, François Vézina, Oliver P. Love, Lyette Régimbald, Karine Dubois, and Audrey Le Pogam

Subjects

Male, Physiology, 030310 physiology, Acclimatization, Marine Biology, Biochemistry, 03 medical and health sciences, Animal science, biology.animal, Temperate climate, Basal metabolic rate (BMR), Animals, Passeriformes, Biology, Cold acclimatization, Biochemistry, Biophysics, and Structural Biology, 0303 health sciences, biology, Fat mass, Winter, Oxygen transport, Lean mass, Life Sciences, Thermogenesis, Biodiversity, biology.organism_classification, Passerine, Cold Temperature, Hematocrit, Basal metabolic rate, Lean body mass, Body Composition, Animal Science and Zoology, Basal Metabolism, Seasons, Summit metabolic rate (M ) sum, Hardiness (plants), Plectrophenax, Thermal Acclimatization, Snow bunting

Abstract

Resident temperate passerines adjust their phenotypes to cope with winter constraints, with peak performance in metabolic traits typically occurring during the coldest months. However, it is sparsely known whether cold-adapted northern species make similar adjustments when faced with variable seasonal environments. Life in near-constant cold could be associated with limited flexibility in traits underlying cold endurance. We investigated this by tracking individual physiological changes over five consecutive winters in snow buntings (Plectrophenax nivalis), an Arctic-breeding migratory passerine typically confronted with nearly constant cold. Buntings were held in an outdoor aviary and exposed to seasonal temperature variation typical of temperate zone climates. We measured phenotypic changes in body composition (body, fat, and lean mass, pectoralis muscle thickness), oxygen transport capacity (hematocrit), metabolic performance (basal metabolic rate [BMR] and summit metabolic rate [Msum]), thermogenic endurance (time to reach Msum), and cold tolerance (temperature at Msum). Snow buntings showed flexibility in functions underlying thermogenic capacity and cold endurance comparable to that observed in temperate resident passerines wintering at similar latitudes. Specifically, they increased body mass (13%), fat mass (246%), hematocrit (23%), pectoralis muscle thickness (8%), and Msum (27%). We also found remarkable cold tolerance in these birds, with individuals reaching Msum in helox at temperatures equivalent to less than -90°C in air. However, in contrast with resident temperate passerines, lean mass decreased by 12%, and there was no clear increase in maintenance costs (BMR). Our results show that the flexibility of traits underlying thermal acclimatization in a cold-adapted northern species is comparable to that of temperate resident species living at lower latitudes and is therefore not limited by life in near-constant cold.

Published

2020

6. Consequences of being phenotypically mismatched with the environment: Rapid muscle ultrastructural changes in cold-shocked black-capped chickadees (Poecile atricapillus)

Author

Oliver P. Love, François Vézina, Ana Gabriela Jimenez, Lyette Régimbald, Erin S. O'Connor, Audrey Le Pogam, and Emily Cornelius Ruhs

Subjects

030110 physiology, 0106 biological sciences, 0301 basic medicine, Muscle ultrastructure, Physiology, Zoology, Marine Biology, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Physiology (medical), Capillaries per fiber area, Phenotypic mismatch, Myonuclear domain, Biology, Biochemistry, Biophysics, and Structural Biology, biology, Life Sciences, Phenotypic trait, Biodiversity, biology.organism_classification, Muscle fiber diameter, Cold shock response, 13. Climate action, Poecile, Ultrastructure

Abstract

Phenotypic flexibility has received considerable attention in the last decade; however, whereas many studies have reported amplitude of variation in phenotypic traits, much less attention has focused on the rate at which traits can adjust in response to sudden changes in the environment. We investigated whole animal and muscle phenotypic changes occurring in black-capped chickadees ( Poecile atricapillus) acclimated to cold (−5°C) and warm (20°C) temperatures in the first 3 h following a 15°C temperature drop (over 3 h). Before the temperature change, cold-acclimated birds were consuming 95% more food, were carrying twice as much body fat, and had 23% larger pectoralis muscle fiber diameters than individuals kept at 20°C. In the 3 h following the temperature drop, these same birds altered their pectoralis muscle ultrastructure by increasing the number of capillaries per fiber area and the number of nuclei per millimeter of fiber by 22%, consequently leading to a 22% decrease in myonuclear domain (amount of cytoplasm serviced per nucleus), whereas no such changes were observed in the warm-acclimated birds. To our knowledge, this is the first demonstration of such a rapid adjustment in muscle fiber ultrastructure in vertebrates. These results support the hypothesis that chickadees maintaining a cold phenotype are better prepared than warm-phenotype individuals to respond to a sudden decline in temperature, such as what may be experienced in their natural wintering environment.

Published

2020