Aquatic Ecology and Contaminant Accumulation in Northern Lakes: Understanding and Predicting Change

北部湖泊的水生生态和污染物积累：理解和预测变化

• 批准号: RGPIN-2014-05048
• 负责人: Swanson, Heidi
• 金额: $ 1.89万
• 依托单位: University of Waterloo
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2018
• 资助国家: 加拿大
• 起止时间: 2018-01-01 至 2019-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=666285
• 关键词: Aquatic; Ecology; Contaminant; Accumulation; Northern

The Canadian north is often thought of as a pristine environment, but this region is extremely vulnerable to human-induced stressors such as long-range air pollution, climate warming, and industrial development. Many northerners, particularly Aboriginal northerners, rely on traditionally-harvested fish for nutritional, social, and cultural well-being. In recent years, northern scientists, regulators, and Aboriginals have become increasingly concerned with predicting how stressors will affect the long-term safety (e.g., are the fish safe to eat?), and productivity (e.g., will there be enough fish?) of northern fisheries. **Mercury is at the forefront of issues relating to the safety of northern subsistence fisheries. Mercury is a potent neurotoxin that comes from both natural and human sources. It accumulates in fish as they grow larger and older and increases with each step in the food chain so that predator fish (e.g., Lake Trout, Northern Pike) have the highest mercury levels. Pollution abatement programs in industrialized countries have resulted in stabilizing mercury levels in the atmosphere, but, contrary to our expectations, mercury levels in some northern lakes continue to rise. To better predict future mercury levels in northern fishes, we need to understand how ecological factors that affect mercury levels, such as fish growth rate and diet, will respond to continuing stressors.**Many ecological factors that affect accumulation of mercury in fish are subject to climate-induced change, such as fish growth rates, fish diet, and propensity of sea-run fish to make marine migrations. Melting of glaciers and permafrost is also expected to affect lake water chemistry and concentrations of contaminants. In lakes that receive significant meltwater from glaciers, inputs of glacial sediment could affect growth rates, diet, and mercury levels in top predator fishes, but our understanding of this is inadequate.**In the first five years of my Discovery program, I will use analyses of stable isotope ratios, fatty acids, and microchemistry of otoliths to investigate: i) why fish mercury levels are increasing in some northern lakes but stable in other lakes; ii) how melting glaciers affects growth, diet, and mercury levels in two important northern fishes, Lake Trout and Arctic Grayling; and, iii) how juvenile growth rates and lake temperature may affect life history and productivity of partially anadromous (i.e., sea-run) populations of Lake Trout in the Arctic.**This innovative and complementary research program includes elegant, whole-ecosystem `natural experiments' at remote northern lakes in the Northwest Territories, Yukon Territory, and Nunavut. Research will be conducted in collaboration with Aboriginal and government partners. Results will help scientists, regulators, industry, and communities understand, predict, and manage human-induced changes in the safety and productivity of northern fisheries by answering novel questions about variability in fish mercury levels in northern lakes, how melting glaciers will affect fish ecology and fish mercury levels, and what environmental and internal factors determine whether partially sea-run Lake Trout begin migrations to the ocean or not. Together with other research in my lab, results will contribute to the foundational long-term objective of my research program, which is to better understand interactions among lake chemistry, fish life history and ecology, and contaminant bioaccumulation through application of chemical tracers at population, community, and ecosystem scales.

加拿大北部通常被认为是一个原始的环境，但这个地区非常容易受到人类引起的压力，如长期空气污染，气候变暖和工业发展。许多北方人，特别是土著北方人，依靠传统捕捞的鱼类获得营养，社会和文化福祉。近年来，北方科学家、监管机构和原住民越来越关注预测压力源将如何影响长期安全（例如，鱼可以安全食用吗？）和生产率（例如，（鱼够吗？）北方渔业的最大优势** 汞是与北方自给性渔业安全有关的问题的首要问题。汞是一种强大的神经毒素，来自自然和人类来源。随着鱼的长大和衰老，它在鱼体内积累，并随着食物链中的每一步而增加，鳟鱼湖，北方派克）有最高的汞含量。工业化国家的污染减排计划已经稳定了大气中的汞含量，但是，与我们的预期相反，北方一些湖泊中的汞含量继续上升。为了更好地预测北方鱼类未来的汞含量，我们需要了解影响汞含量的生态因素，如鱼类生长速度和饮食，将如何对持续的压力源作出反应。许多影响汞在鱼类体内积累的生态因素都受到气候引起的变化的影响，例如鱼类生长率、鱼类饮食以及海洋鱼类进行海洋洄游的倾向。冰川和永久冻土的融化预计也会影响湖水的化学性质和污染物的浓度。在从冰川接收大量融水的湖泊中，冰川沉积物的输入可能会影响顶级捕食者鱼类的生长速度，饮食和汞水平，但我们对此的理解是不够的。在我的发现计划的前五年，我将使用稳定同位素比，脂肪酸和耳石的微化学分析来调查：i）为什么鱼类汞含量在北方一些湖泊中增加，但在其他湖泊中稳定; ii）冰川融化如何影响两种重要的北方鱼类，湖鳟鱼和北极灰鹤的生长，饮食和汞含量;以及，iii）幼鱼生长速率和湖水温度如何影响部分溯河产卵的生活史和生产力（即，北极湖鳟鱼的数量。**这一创新和互补的研究方案包括在西北地区、育空地区和努纳武特偏远的北方湖泊进行优雅的全生态系统“自然实验”。将与土著和政府伙伴合作开展研究。研究结果将帮助科学家、监管机构、行业和社区了解、预测和管理人类引起的北方渔业安全和生产力变化，方法是回答有关北方湖泊鱼类汞含量变化、冰川融化将如何影响鱼类生态和鱼类汞含量、以及什么样的环境和内部因素决定了部分海洋运行的湖鳟鱼开始迁移到海洋或没有。与其他研究在我的实验室，结果将有助于我的研究计划，这是更好地了解湖泊化学，鱼类生活史和生态之间的相互作用，以及污染物的生物积累，通过在人口，社区和生态系统尺度上的化学示踪剂的应用，我的基础长期目标。