Collaborative Research: Gene content, gene expression, and physiology in mesopelagic ammonia-oxidizing archaea

合作研究：中层氨氧化古菌的基因含量、基因表达和生理学

• 批准号: 1259994
• 负责人: Christopher Dupont
• 金额: $ 50.09万
• 依托单位: J. Craig Venter Institute, Inc.
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2013
• 资助国家: 美国
• 起止时间: 2013-04-15 至 2018-03-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1259994&HistoricalAwards=false
• 关键词: Collaborative; Research; Gene; content; gene

Intellectual Merit. How organisms respond to their physical and chemical and environment is a central question in marine ecology. For microbes living in the mesopelagic - the ocean's "twilight zone" - an efficient response is particularly important to capitalize on the intermittent delivery of organic and inorganic compounds sinking from the surface ocean. These organisms must have a suite of metabolic and regulatory strategies used to cope with environmental variability, but these strategies are largely unknown. Understanding when and why metabolic genes are expressed is critical to our understanding of nutrient remineralization in the ocean. Marine group 1 (MG1) archaea are ubiquitous, abundant microbes in the meso- and bathypelagic and promising model organisms for investigating these questions. MG1 archaea are chemolithoautotrophs that oxidize ammonia for energy and fix carbon for biomass, and as such, play a central role in the ocean's coupled carbon and nitrogen cycles. Though MG1 have historically eluded cultivation, recent efforts have been successful at bringing representative MG1 archaea from the open ocean into culture and demonstrating their importance in the production of the greenhouse gas nitrous oxide. This project takes advantage of unique MG1 cultures and the recently sequenced draft genome of one of the organisms - strain CN25 - to investigate the physiological and transcriptional responses of MG1 archaea to variations in their chemical environment, specifically:1. Comparative transcriptomics of CN25 cells grown under a range of energy availability and nitrosative stress will identify select genes that can be used to diagnose the physiological state of natural populations2. Improvements in the genomic and transcriptomic knowledge of MG1 archaea will facilitate a thorough reinterpretation of existing metagenomic and metatranscriptomic datasets, as well as provide a better contextual understanding in future studiesThe investigators will conduct comparative transcriptomics of CN25 cells harvested in mid-exponential growth and stationary phase versus starved cells. Transcriptomes of cells grown at high nitrate concentrations and low pO2 with those grown in standard conditions will be characterized. A strand-specific, high-density RNAseq approach will be used to examine the expression of putative ORFs, polycistronic operons, and small RNAs, which, in addition to gene expression profiling, has the ancillary benefit of improving genome annotation. Finally, the investigators will sequence the genomes of two additional MG1 strains isolated from the open ocean, as well as single cells from environmental surveys, and leverage the combination with the CN25 genome to reanalyze available metagenomic and metatranscriptomic datasets. The results will define the transcriptional response of a model mesopelagic microbe to a range of chemical environments, and show how the physicochemical environment induces changes in gene expression and gene content that result in greenhouse gas production. This work will rapidly generate new knowledge of how some of the most ubiquitous, yet heretofore elusive, microorganisms respond to geochemical variability and shape our evolving understanding of the marine nitrogen cycle.Broader Impacts. The scientific and societal impact of the project will be to elucidate the mechanisms of greenhouse gas production in a model marine organism that is of broad interest to biological and chemical oceanographers. Transcriptome sequencing will improve the assembly of the CN25 genome, the first genome of an MG1 archaeon from the open ocean. Both the genome and transcriptomes will be important references for researchers using metagenomics, metatranscriptomics, and metaproteomics in the ocean, as these techniques are reliant on a knowledgebase composed of both DNA sequence and physiology. Thus, the results add value to both existing and future studies. The proposed research will advance education, teaching, and training for the next generation of marine scientists by providing support for two early-career investigators, one postdoctoral researcher, and a secondary school teacher.

知识价值。生物如何对它们的物理、化学和环境作出反应是海洋生态学的一个中心问题。对于生活在中上层（海洋的“模糊地带”）的微生物来说，利用从海洋表面下沉的有机和无机化合物的间歇性传递，有效的反应尤为重要。这些生物必须有一套代谢和调节策略来应对环境的变化，但这些策略在很大程度上是未知的。了解代谢基因表达的时间和原因对我们理解海洋中的营养再矿化至关重要。海洋1群（MG1）古细菌是中远洋和深海中普遍存在的丰富微生物，是研究这些问题的有希望的模式生物。MG1古菌是一种化能岩石自养生物，它能氧化氨以获取能量，并为生物量固定碳，因此在海洋的碳氮耦合循环中起着核心作用。虽然MG1在历史上一直无法培养，但最近的努力已经成功地将具有代表性的MG1古菌从开阔的海洋中引入了培养，并证明了它们在温室气体一氧化二氮生产中的重要性。该项目利用独特的MG1培养物和最近测序的生物体之一-菌株CN25的基因组草图，研究MG1古菌对其化学环境变化的生理和转录反应，具体如下：1。在能量可用性和亚硝化胁迫下生长的CN25细胞的比较转录组学将鉴定出可用于诊断自然种群生理状态的精选基因2。MG1古菌基因组学和转录组学知识的改进将有助于对现有的宏基因组学和亚转录组学数据集进行彻底的重新解释，并为未来的研究提供更好的背景理解。研究人员将对在指数生长中期和静止期收获的CN25细胞与饥饿细胞进行转录组学比较。在高硝酸盐浓度和低pO2条件下生长的细胞转录组将与在标准条件下生长的细胞转录组进行表征。一种链特异性、高密度的RNAseq方法将用于检测假定的orf、多顺反子操纵子和小rna的表达，除了基因表达谱外，它还具有改善基因组注释的辅助益处。最后，研究人员将对从开放海洋中分离的另外两种MG1菌株以及从环境调查中获得的单细胞进行基因组测序，并利用CN25基因组的组合重新分析现有的宏基因组和亚转录组数据集。这些结果将定义一个模型介层微生物对一系列化学环境的转录反应，并显示物理化学环境如何诱导基因表达和基因含量的变化，从而导致温室气体的产生。这项工作将迅速产生新的知识，了解一些最普遍但迄今为止难以捉摸的微生物如何对地球化学变异性做出反应，并塑造我们对海洋氮循环的不断发展的理解。更广泛的影响。该项目的科学和社会影响将是阐明生物和化学海洋学家广泛感兴趣的模型海洋生物中温室气体产生的机制。转录组测序将改善CN25基因组的组装，这是来自开放海洋的MG1古菌的第一个基因组。基因组和转录组对于在海洋中使用元基因组学、元转录组学和宏蛋白质组学的研究人员来说都是重要的参考，因为这些技术依赖于由DNA序列和生理学组成的知识库。因此，该结果对现有和未来的研究都有价值。拟议的研究将通过为两名早期职业调查员、一名博士后研究员和一名中学教师提供支持，促进下一代海洋科学家的教育、教学和培训。