Collaborative Research: Unraveling the Dynamics of Microbial Mercury Methylation in Two Meromictic Lakes in Central New York, USA

合作研究：揭示美国纽约中部两个分流湖中微生物汞甲基化的动态

• 批准号: 2023712
• 负责人: Svetoslava Todorova
• 金额: $ 30.73万
• 依托单位: Syracuse University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2020
• 资助国家: 美国
• 起止时间: 2020-08-01 至 2024-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2023712&HistoricalAwards=false
• 关键词: Collaborative; Research; Unraveling; Dynamics; Microbial

Mercury is a widespread pollutant and its impacts on human and ecosystem health have spurred domestic and international policies and regulations that aim to limit its release and transport. Anthropogenic mercury contamination results from emissions to the atmosphere and releases to land and water. Aquatic ecosystems are the ultimate recipients of atmospheric and terrestrial mercury. They play a central role in the transformation of mercury to its most biologically accumulative form, methyl mercury—a known neurotoxin affecting brain development and reproductive, immune, and cardiovascular systems in humans and wildlife. Therefore, a critical need is to advance the understanding of factors influencing in-situ production of methylmercury. This project will improve the prediction of methylmercury concentrations in lakes and other inland systems. It will distinguish the effects of chemical interactions from the roles of microbial transformations in controlling methylmercury production and accumulation. The study will be conducted in Central New York, at two nearby lakes with distinct vertical chemical and biological structure: Glacier Lake and Fayetteville Green Lake. The proposed work will provide training opportunities for undergraduate and graduate students from diverse and non-traditional backgrounds. Scientific hand-on exploration will engage K-12 students from different age groups, culture, ethnical and racial identity. The results of this study will be disseminated through conferences and scientific publications. The principal investigators will impart the scientific findings to the broader scientific and policy community through policy briefs and short presentations at the meetings of the Conference of the Parties, expert working groups, and the intersessional consultations of the Minamata Convention on Mercury.Methylation of mercury is the critical process linking the atmospheric mercury emissions, deposition to the landscape, and mercury bioavailability in aquatic ecosystems. Methylmercury poses a risk to human and wildlife health and may require management interventions. This project will investigate the dynamics of mercury in the water column of two proximal meromictic lakes with well-defined redox profiles and a transitional chemocline of over a meter. The clear natural geochemical gradient combined with discrete thin-layer sampling will enable the distinction between geochemical and biological regulators of mercury methylation in the lakes. The team will perform fluorescence and molecular characterization of dissolved organic matter compounds that sequester mercury. Depth profiles of major elements (S, C, N), speciation of mercury, determination of dissolved organic material and its complexation with mercury, and dissolved low-molecular weight acids and alcohols will be integrated to evaluate factors driving in-situ mercury availability and methylmercury production. In addition, molecular analysis will be used to determine the nature, taxonomic identity, and spatial position of organisms capable of methylating mercury. Genome-centric metagenomics will enable the linkage of mercury methylation to other metabolic traits and provide a scaffold for metatranscriptomics, which will reveal the physiological conditions under which microorganisms methylate mercury absent substrate limitation.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

汞是一种广泛的污染物，它对人类和生态系统健康的影响促使国内和国际政策和法规旨在限制汞的释放和运输。人为汞污染是排放到大气中并释放到陆地和水中的结果。水生生态系统是大气和陆地汞的最终接受者。它们在将汞转化为生物积累最多的形式甲基汞的过程中发挥着核心作用，甲基汞是一种已知的神经毒素，会影响人类和野生动物的大脑发育和生殖、免疫和心血管系统。因此，迫切需要促进对影响就地生产甲基汞的因素的了解。该项目将改进对湖泊和其他内陆系统中甲基汞浓度的预测。它将区分化学相互作用的影响和微生物转化在控制甲基汞生产和积累中的作用。这项研究将在纽约中部附近的两个垂直化学和生物结构截然不同的湖泊进行：冰川湖和费耶特维尔绿湖。拟议的工作将为来自不同和非传统背景的本科生和研究生提供培训机会。科学实践探索将吸引来自不同年龄段、文化、民族和种族认同的K-12学生。这项研究的结果将通过会议和科学出版物传播。首席研究人员将通过政策简报和在缔约方会议、专家工作组会议和《水银公约》闭会期间磋商上的简短发言，向更广泛的科学界和政策界宣传科学发现。汞的甲基化是将大气汞排放、沉积到地貌和汞在水生生态系统中的生物有效性联系起来的关键过程。甲基汞对人类和野生动物健康构成风险，可能需要管理干预。该项目将调查两个氧化还原剖面清晰、过渡性趋化跃层超过一米的近端混生湖泊水柱中汞的动态。清晰的自然地球化学梯度与离散的薄层采样相结合，将能够区分湖泊中汞甲基化的地球化学和生物调节因素。该团队将对隔离汞的溶解有机物化合物进行荧光和分子表征。主要元素(S、C、N)的深度剖面、汞的形态、溶解有机物及其与汞的络合作用的测定、溶解低分子量酸和醇的测定将被综合起来，以评价驱动就地汞有效性和甲基汞产生的因素。此外，分子分析将被用来确定能够甲基化汞的生物体的性质、分类特征和空间位置。以基因组为中心的元基因组学将使汞甲基化与其他代谢特征相联系，并为代谢组学提供一个支架，这将揭示微生物在没有底物限制的情况下甲基化汞的生理条件。这一奖项反映了NSF的法定使命，并通过使用基金会的智力优势和更广泛的影响审查标准进行评估，被认为值得支持。