Grunst Andrea S, Grunst Melissa L, Grémillet David, Kato Akiko, Bustamante Paco, Albert Céline, Brisson-Curadeau Émile, Clairbaux Manon, Cruz-Flores Marta, Gentès Sophie, Perret Samuel, Ste-Marie Eric, Wojczulanis-Jakubas Katarzyna, Fort Jérôme
Littoral, Environnement et Sociétés (LIENSs), UMR 7266 CNRS-La Rochelle Université, 2 Rue Olympe de Gouges, La Rochelle FR-17000, France.
CEFE, UMR 5175, CNRS─Université de Montpellier─Université Paul-Valéry Montpellier─EPHE, Montpellier 34090, France.
Environ Sci Technol. 2023 Feb 7;57(5):2054-2063. doi: 10.1021/acs.est.2c08893. Epub 2023 Jan 18.
Combined effects of multiple, climate change-associated stressors are of mounting concern, especially in Arctic ecosystems. Elevated mercury (Hg) exposure in Arctic animals could affect behavioral responses to changes in foraging landscapes caused by climate change, generating interactive effects on behavior and population resilience. We investigated this hypothesis in little auks (), a keystone Arctic seabird. We compiled behavioral data for 44 birds across 5 years using accelerometers while also quantifying blood Hg and environmental conditions. Warm sea surface temperature (SST) and low sea ice coverage reshaped time activity budgets (TABs) and diving patterns, causing decreased resting, increased flight, and longer dives. Mercury contamination was not associated with TABs. However, highly contaminated birds lengthened interdive breaks when making long dives, suggesting Hg-induced physiological limitations. As dive durations increased with warm SST, subtle toxicological effects threaten to increasingly constrain diving and foraging efficiency as climate change progresses, with ecosystem-wide repercussions.
多种与气候变化相关的压力源的综合影响日益受到关注,尤其是在北极生态系统中。北极动物体内汞(Hg)暴露量的增加可能会影响其对气候变化导致的觅食环境变化的行为反应,从而对行为和种群恢复力产生交互影响。我们在北极小海雀(一种关键的北极海鸟)身上对这一假设进行了研究。我们使用加速度计收集了44只小海雀在5年时间里的行为数据,同时还对血液中的汞含量和环境条件进行了量化。温暖的海表面温度(SST)和低海冰覆盖率重塑了时间活动预算(TABs)和潜水模式,导致休息时间减少、飞行时间增加以及潜水时间延长。汞污染与时间活动预算无关。然而,汞含量高的鸟类在进行长时间潜水时会延长潜水间隔时间,这表明汞会导致生理限制。随着潜水时间随着温暖的海表面温度增加,随着气候变化的进展,微妙的毒理学效应可能会越来越多地限制潜水和觅食效率,并产生全生态系统的影响。
