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Collaborative Research: Evaluating the contribution of small eukaryotes to nitrate-based new production in the North Pacific Subtropical Gyre

合作研究：评估小型真核生物对北太平洋副热带环流硝酸盐新生产的贡献

基本信息

批准号：
2219972
负责人：
Angelicque White
金额：
$ 29.74万
依托单位：
University of Hawaii
依托单位国家：
美国
项目类别：
Standard Grant
财政年份：
2022
资助国家：
美国
起止时间：
2022-12-15 至 2025-11-30
项目状态：
未结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=2219972&HistoricalAwards=false
关键词：
Collaborative Research Evaluating contribution small

项目摘要

The subtropical oceans in the middle latitudes are “ocean deserts,” where there are relatively little nutrients in the surface waters. Nitrogen is an important nutrient that is particularly scarce. Nitrogen in the ocean occurs as nitrate or ammonium. As a result of limited nutrients in the subtropical gyres, marine algae or phytoplankton there grow slowly. In deeper waters below the surface, there are more nutrients. However, it is not well understood how phytoplankton living in surface waters in summer can access the nutrients in the deeper waters. This award will investigate how phytoplankton access subsurface nitrogen at Station ALOHA in the North Pacific Subtropical Gyre (NPSG). Phytoplankton will be sorted by size and pigment composition. The researchers will make measurements of the stable nitrogen isotope ratios of sorted populations and determine where phytoplankton are getting the needed nutrients, either nitrate from the subsurface or ammonium from the surface waters. The researchers will use metatranscriptomic analysis to investigate the physiological pathways that different phytoplankton populations use to take up the needed nitrogen. The metatranscriptomic analysis involves analyzing the RNA sequences transcribed by plankton, comparing the sequence to documented gene sequences and mapped to documented physiological pathways. The researchers will assess which taxonomic groups are using nitrate versus recycled sources of nitrogen. They will test the hypothesis that eukaryotic phytoplankton primarily use nitrate whereas prokaryotic phytoplankton mostly use recycled sources of nitrogen. With these measurements, the researchers will help the society anticipate climate impacts on the productivity of subtropical gyres. This project will support two graduate students and a post-doctoral researcher in laboratory and ship-based research. Principal Investigator (PI) Granger in Connecticut will engage high school students and sponsor graduate students from underrepresented groups via AGU’s Bridge Partner Program. PI Marchetti in North Carolina will sponsor the internship of a high school student from a local minority county. PI White in Hawaii will engage with Hawaiian high school students though the Indigenous Partnership for Ocean Monitoring program to mentor and teach essential research skills. The researchers of this project will investigate the drivers of productivity at station ALOHA in NPSG. They will exploit a high-sensitivity method for natural abundance N isotope analysis (the ‘persulphate-denitrifier’ method) to evaluate the extent to which taxonomically distinct components of the plankton sorted by flow cytometry rely on nitrate vs. reduced N sources in surface waters. We will also query physiological nitrogen pathways of the plankton with metatranscriptomic analysis to infer which clades are reliant on nitrate. We will quantify the fraction of primary production fueled by nitrate to characterize seasonal trends and explore potential mechanisms of nitrate supply to the euphotic zone and its mixed layer. The work proposed here will resolve the relative contribution of nitrate mixed from the ocean interior to surface production at station ALOHA, to better define seasonal dynamics of the biological pump in the NPSG. We will identify plankton groups that contribute dominantly to nitrate-based production and resolve eco-physiological strategies that confer fitness in a severely N-limited environment. Seasonal trends in the contributions of nitrate to total nitrogen production will be evaluated considering incident hydrography to infer potential mechanisms of nitrate supply.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.

中纬度的亚热带海洋是“海洋沙漠”，那里的表层水中营养物质相对较少。氮是一种特别稀缺的重要营养物质。海洋中的氮以硝酸盐或铵的形式存在。由于亚热带环流中的营养物质有限，那里的海藻或浮游植物生长缓慢。在地表以下更深的水域，有更多的营养物质。然而，人们对夏季生活在表层水域的浮游植物如何获取深层水域的营养物质还没有很好的了解。该奖项将调查北太平洋亚热带环流(NPSG)Aloha站浮游植物如何获取次表层氮。浮游植物将根据大小和色素组成进行分类。研究人员将对分类种群的稳定氮同位素比率进行测量，并确定浮游植物从哪里获得所需的营养，要么是来自地下的硝酸盐，要么是来自地表水域的铵。研究人员将使用元转录分析来调查不同浮游植物种群用来吸收所需氮的生理途径。后转录分析包括分析浮游生物转录的RNA序列，将该序列与已记录的基因序列进行比较，并映射到已记录的生理途径。研究人员将评估哪些分类群体正在使用硝酸盐，而不是回收的氮源。他们将检验这样一种假设，即真核浮游植物主要使用硝酸盐，而原核浮游植物主要使用回收的氮源。通过这些测量，研究人员将帮助社会预测气候对副热带涡旋生产力的影响。该项目将支持实验室和船舶研究的两名研究生和一名博士后研究人员。康涅狄格州的首席调查员(PI)格兰杰将通过AGU的桥梁合作伙伴计划吸引高中生，并资助来自代表性不足群体的研究生。北卡罗来纳州的Pi Marchetti将赞助一名来自当地少数民族县的高中生的实习。夏威夷的Pi White将通过土著海洋监测伙伴计划与夏威夷高中生接触，指导和传授基本的研究技能。该项目的研究人员将调查NPSG阿罗哈核电站生产力的驱动因素。他们将利用一种高灵敏度的自然丰度氮同位素分析方法(过硫酸盐反硝化法)来评估通过流式细胞仪分类的不同浮游生物成分对地表水域中硝酸盐和还原氮源的依赖程度。我们还将通过后转录分析来查询浮游生物的生理氮途径，以推断哪些分支依赖于硝酸盐。我们将量化由硝酸盐提供燃料的初级生产力的比例，以表征季节趋势，并探索向真光带及其混合层供应硝酸盐的潜在机制。这里提出的工作将解决海洋内部混合的硝酸盐对ALOHA站表层生产的相对贡献，以更好地定义NPSG中生物泵的季节动态。我们将确定对基于硝酸盐的生产做出主要贡献的浮游生物种群，并解决在严重氮限制的环境中提供适宜性的生态生理策略。硝酸盐在总氮产量中的贡献的季节性趋势将根据事件水文进行评估，以推断硝酸盐供应的潜在机制。该奖项反映了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。