Impacts of spring environmental conditions on energetic demand in an Arctic-breeding seabird
Type of Proposal
Visual Presentation (Poster, Installation, Demonstration)
Faculty
Faculty of Science
Faculty Sponsor
Dr. Oliver P. Love
Proposal
Life-history investment theory predicts that some individuals may be better at using physiological and behavioural mechanisms to meet the energetic demands imposed by environmental challenges to maximize breeding success. However, field-testing these seemingly straightforward predictions is complicated by the extreme challenge of quantifying environmentally induced flexibility in mechanisms before breeding investment. Nonetheless, these questions are especially vital to answer in places such as the Arctic, which is experiencing climate change rates 3-4 times the global average. Here we use a 16-year dataset from Canada’s largest colony of Arctic-breeding common eiders (Somateria mollissima), located at East Bay Island, Nunavut, to field-test these investment decision predictions. Specifically, from 2006-2023 (missing 2020-21 due to COVID-19), we captured almost 3000 pre-laying females following their arrival on the breeding grounds and collected physiological data on energetic demand (baseline corticosterone) and fattening rates (plasma triglycerides). We then followed individuals to assess two key reproductive decisions known to impact breeding success: whether birds invested in reproduction, and if so, when they initiated laying. Our goal is to use this dataset to examine whether individuals with certain physiological phenotypes can better overcome spring environment challenges (i.e., low ambient temperatures) to not only invest in breeding in a given year, but lay as early as possible to maximize lifetime breeding success in these highly seasonal environments. Filling in these challenging life history gaps is vital for predicting whether individuals and the populations they make up can persist and succeed in the face of rapidly increasing change in the north.
Impacts of spring environmental conditions on energetic demand in an Arctic-breeding seabird
Life-history investment theory predicts that some individuals may be better at using physiological and behavioural mechanisms to meet the energetic demands imposed by environmental challenges to maximize breeding success. However, field-testing these seemingly straightforward predictions is complicated by the extreme challenge of quantifying environmentally induced flexibility in mechanisms before breeding investment. Nonetheless, these questions are especially vital to answer in places such as the Arctic, which is experiencing climate change rates 3-4 times the global average. Here we use a 16-year dataset from Canada’s largest colony of Arctic-breeding common eiders (Somateria mollissima), located at East Bay Island, Nunavut, to field-test these investment decision predictions. Specifically, from 2006-2023 (missing 2020-21 due to COVID-19), we captured almost 3000 pre-laying females following their arrival on the breeding grounds and collected physiological data on energetic demand (baseline corticosterone) and fattening rates (plasma triglycerides). We then followed individuals to assess two key reproductive decisions known to impact breeding success: whether birds invested in reproduction, and if so, when they initiated laying. Our goal is to use this dataset to examine whether individuals with certain physiological phenotypes can better overcome spring environment challenges (i.e., low ambient temperatures) to not only invest in breeding in a given year, but lay as early as possible to maximize lifetime breeding success in these highly seasonal environments. Filling in these challenging life history gaps is vital for predicting whether individuals and the populations they make up can persist and succeed in the face of rapidly increasing change in the north.