Collaborative Research: Coupled genetic, geochemical, and physical controls on arsenic mobilization

合作研究：砷迁移的遗传、地球化学和物理耦合控制

• 批准号: 0951947
• 负责人: Chad Saltikov
• 金额: $ 23.29万
• 依托单位: University of California-Santa Cruz
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2010
• 资助国家: 美国
• 起止时间: 2010-09-01 至 2014-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0951947&HistoricalAwards=false
• 关键词: Collaborative; Research; Coupled; genetic; geochemical

The hazards imposed by arsenic on human health are well recognized and nowhere better exemplified than South/Southeast Asia where the consumption of arsenic contaminated ground water has resulted high incidences of skin disorders and various cancers. Arsenic is usually associated with iron oxide and other minerals in sediments. However, in the absence of oxygen, microbes can carry out iron and arsenic reduction reactions that result in arsenic release from sediments and accumulation in ground water. The contribution of iron vs. arsenate reduction to arsenic release, however, is unclear. Furthermore, our understanding of arsenic fate and transport within soils and sediments is limited by poorly understood biological and geochemical processes occurring within complex ground water flow pathways. Therefore, the overarching goal of this research is to determine how microbial metabolism impacts arsenic transport in sediments and soils. Specifically, researchers will investigate the expression of bacterial genes responsible for iron and arsenic reduction and commensurate biogeochemical processes responsible for controlling the partitioning and mobility of arsenic (along with their spatial distribution) within model systems that simulate the physical complexity of natural soils and sediments. The proposed research integrates biogeochemical and molecular genetic approaches aimed at developing a mechanistic understanding of the impacts of microbes on arsenic contamination of ground water. Because the nature of the arsenic problem is rooted in geomicrobiology, the intellectual merit of the proposed research is the generation of crucial information important to understanding the mechanism(s) leading to arsenic release or retention in sediments. The results will lead to a detailed conceptual model of how genetics and geochemical processes impact microbe-mineral interactions and arsenic fate. The broader impacts of the research will be to integrate research with teaching activities and community outreach by participating in a laboratory research mentorship program (called ACCESS) for community college students of under represented groups and a high school science summer program called COSMOS. Lastly, the collaboration will enhance and promote diversity through intercampus mentorship of minority graduate students at both Stanford and UCSC.

砷对人类健康造成的危害是众所周知的，南亚/东南亚是最好的例证，在那里，饮用受砷污染的地下水已导致皮肤病和各种癌症的高发病率。砷通常与沉积物中的氧化铁和其他矿物伴生。然而，在没有氧气的情况下，微生物可以进行铁和砷的还原反应，导致砷从沉积物中释放出来，并在地下水中积累。然而，铁和砷的减少对砷释放的贡献尚不清楚。此外，我们对砷在土壤和沉积物中的去向和迁移的了解受到发生在复杂的地下水流动路径中的生物和地球化学过程知之甚少的限制。因此，这项研究的首要目标是确定微生物代谢如何影响沉积物和土壤中砷的迁移。具体地说，研究人员将调查细菌基因的表达，这些基因负责铁和砷的减少，以及相应的生物地球化学过程，这些过程负责控制砷的分配和迁移(及其空间分布)，在模拟自然土壤和沉积物的物理复杂性的模型系统中。拟议的研究综合了生物、地质、化学和分子遗传学方法，旨在从机理上理解微生物对地下水砷污染的影响。由于砷问题的本质植根于地质微生物学，拟议研究的学术价值在于产生了对理解导致沉积物中砷释放或保留的机制至关重要的关键信息(S)。这些结果将产生一个详细的概念模型，说明遗传和地球化学过程如何影响微生物-矿物相互作用和砷的命运。这项研究的更广泛影响将是通过参与针对代表性不足群体的社区大学生的实验室研究指导计划(称为ACCESS)和名为COSMOS的高中科学暑期计划，将研究与教学活动和社区推广结合起来。最后，合作将通过校际辅导斯坦福大学和加州大学洛杉矶分校的少数族裔研究生来加强和促进多样性。