Microbial Community Controls on Sulfide Oxidation Rates and Cave Formation in a Subsurface Biogeochemical System

微生物群落对地下生物地球化学系统中硫化物氧化速率和洞穴形成的控制

• 批准号: 0513549
• 负责人: Jennifer Macalady
• 金额: $ 6.34万
• 依托单位: Pennsylvania State Univ University Park
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2004
• 资助国家: 美国
• 起止时间: 2004-11-03 至 2007-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0513549&HistoricalAwards=false
• 关键词: Microbial; Community; Controls; Sulfide; Oxidation

This project aims to discover rules governing microbial community assembly and diversity, and the effects of these on geochemical process rates. These questions are difficult to address in most ecosystems, where microbial diversity is very high and spatial heterogeneities are large. The Frasassi cave ecosystem is distant from surface sources of fixed carbon and nitrogen and is fueled only by sulfur oxidation, so that microbial activity can be directly related to sulfuric acid production. The cave hosts both neutral and pH 0-1 sulfur-oxidizing communities, and these community types will be compared to test hypothesis about microbial diversity and community function. For example, we hypothesize that microbial diversity is strongly controlled by the number of available electron donors and electron acceptors, rather than by limitations posed by environmental extremes such as low pH. In this case, both pH 0-1 and neutral Frasassi microbial communities will have lower diversity than a previously studied pH 0-1 acid mine drainage system where both iron and sulfur electron donors are available. The project also aims to identify biological and geological controls on sulfuric acid production (cave dissolution). Molecular biological methods will be used to quantify microbial populations, geochemical methods to document and monitor cave habitats and microbial cultures, and lipid and isotope-labeling methods to quantify biomass and identify autotrophic microorganisms in the cave communities.The project will involve 6 undergraduate thesis students and the development of an educational module to be incorporated into the highly successful Carleton College Geology Program in Italy. The work will generate young scientists with interdisciplinary training in geomicrobiology and publications that identify factors that control the structure and function of subsurface microbial communities responsible for sulfuric acid production and cave formation. More generally, understanding how microbial communities are assembled, and how these patterns of assembly affect the use of available resources, is a critical component of understanding the biogeochemistry of both ancient and present-day environments.

该项目旨在发现控制微生物群落组装和多样性的规则，以及这些规则对地球化学过程速率的影响。这些问题在大多数生态系统中很难解决，因为那里的微生物多样性非常高，空间异质性很大。Frasassi洞穴生态系统远离固定碳和氮的地表来源，仅由硫磺氧化提供燃料，因此微生物活动可以与硫酸生产直接相关。洞穴中有中性和pH值为0-1的硫氧化群落，这些群落类型将被比较，以检验关于微生物多样性和群落功能的假说。例如，我们假设微生物多样性受到可用电子供体和电子受体数量的强烈控制，而不是受环境极端条件(如低pH值)的限制。在这种情况下，pH 0-1和中性Frasassi微生物群落的多样性将低于之前研究的pH 0-1酸性矿山排水系统，在该系统中，铁和硫的电子供体都可用。该项目还旨在确定对硫酸生产(洞穴溶解)的生物和地质控制。将使用分子生物学方法来量化微生物种群，使用地球化学法来记录和监测洞穴生境和微生物培养，以及使用脂类和同位素标记法来量化生物量和识别洞穴社区中的自养微生物。该项目将涉及6名本科生，并开发一个教育模块，将纳入意大利非常成功的卡尔顿学院地质学计划。这项工作将培养接受地质微生物学跨学科培训的年轻科学家，并出版确定控制地下微生物群落结构和功能的因素的出版物，这些微生物群落负责硫酸生产和洞穴形成。更广泛地说，了解微生物群落是如何组装的，以及这些组装模式如何影响可用资源的使用，是了解古代和现代环境的生物地球化学的关键组成部分。