Collaborative research: Microbial dynamics on marine snow particles

合作研究：海洋雪颗粒的微生物动力学

• 批准号: 0352125
• 负责人: Kam Tang
• 金额: $ 35.19万
• 依托单位: College of William & Mary Virginia Institute of Marine Science
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2004
• 资助国家: 美国
• 起止时间: 2004-04-01 至 2008-03-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0352125&HistoricalAwards=false
• 关键词: Collaborative; research; Microbial; dynamics; marine

Marine snow fluxes sequester carbon to the deep ocean, significantly buffering the greenhouse effect. In response to continuing global warming, large-scale ocean fertilization has been proposed as a way to enhance marine snow fluxes and remove extra atmospheric CO2. Marine snow particles harbor high densities of bacteria and other microbes, whose activities modify the physical and chemical characteristics of the particles. Understanding these processes is critical to predicting the fate of marine snow fluxes in the ocean. This project is aimed at a mechanistic understanding of the microbial dynamics on marine snow particles, using an innovative approach of combining experiments, observations and modeling. This project is 1) characterizing the time-dependent microbial dynamics on marine snow particles, 2) investigating how different biotic and abiotic factors modify the dynamics, and 3) developing mathematical models to quantitatively describe such dynamics. Lab-generated diatom aggregates are being used to test encounter models for predicting the rate at which bacteria colonize marine snow. Agar-aggregates are being used to examine bacterial chemosensory response to marine snow chemicals, and the effects of the bacterial physiological status on the colonization process. Predator-prey dynamics on snow particles are being investigated by grazing experiments with bacterivorous protists. Field studies are following the changes in bacterial colonization behavior, size and morphology of natural marine snow and the associated microbes during the course of an algal bloom. Laboratory and field observations are being used to test and expand colonization models in order to describe microbial dynamics on marine snow based on hydrodynamics, microbial behavior, growth and interspecific interactions. These models are being integrated with coagulation models to study how marine snow formation coupled with microbial dynamics affects marine snow and carbon fluxes in the water column. This project is extending the existing collaborations between VIMS, TAMU and three outstanding European research institutions. Graduate research training and education are integral parts of the project. To promote ethnic diversity and leadership training in marine sciences, minority undergraduates are being recruited through a new internship program DREAMS to participate in the project and gains hands-on research experience. The PIs are developing education materials for the general public with focus on global warming, ocean-climate interactions and ocean fertilization. These materials are being implemented by DREAMS interns in their outreach activities that target grade school students and teachers, allowing them to establish themselves as future leaders in climate issues.

海洋雪通量将碳封存到深海，大大缓冲了温室效应。为了应对持续的全球变暖，大规模的海洋施肥被提议作为一种增加海洋雪通量和去除大气中额外二氧化碳的方法。 海洋雪颗粒含有高密度的细菌和其他微生物，它们的活动改变了颗粒的物理和化学特性。了解这些过程对于预测海洋雪通量的命运至关重要。该项目旨在通过实验、观察和建模相结合的创新方法，从机理上了解海洋雪颗粒上的微生物动力学。 该项目是1）表征海洋雪颗粒上随时间变化的微生物动力学，2）研究不同的生物和非生物因素如何改变动力学，3）开发数学模型来定量描述这种动力学。 实验室产生的硅藻聚集体被用来测试遭遇模型，以预测细菌在海洋雪中定居的速度。琼脂聚集体被用来研究细菌化学传感器响应海洋雪化学物质，和细菌的生理状态的殖民过程中的影响。 雪颗粒上的捕食者-被捕食者动态正在通过食菌原生生物的放牧实验进行研究。 野外研究是在藻华过程中跟踪细菌定殖行为、天然海洋雪的大小和形态以及相关微生物的变化。正在利用实验室和实地观察来测试和扩大定殖模型，以便根据流体力学、微生物行为、生长和种间相互作用来描述海洋积雪上的微生物动态。这些模型正在与凝结模型相结合，以研究海洋雪的形成与微生物动力学如何影响海洋雪和水柱中的碳通量。该项目扩大了VIMS、TAMU和三个杰出的欧洲研究机构之间的现有合作。研究生研究培训和教育是该项目的组成部分。为了促进海洋科学的种族多样性和领导力培训，少数民族本科生正在通过一个新的实习计划梦想招募参加该项目，并获得实践研究经验。这些方案执行机构正在为公众编写教育材料，重点是全球变暖、海洋与气候的相互作用和海洋肥化。这些材料正在由DREAMS实习生在针对小学学生和教师的外联活动中实施，使他们能够成为气候问题的未来领导者。