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Collaborative Research: EAGER: Salinity-based selection between sister clades of abundant coastal bacterioplankton

合作研究：EAGER：丰富的沿海浮游细菌姐妹进化枝之间基于盐度的选择

基本信息

批准号：
1747681
负责人：
Cameron Thrash
金额：
$ 16.19万
依托单位：
Louisiana State University
依托单位国家：
美国
项目类别：
Continuing Grant
财政年份：
2018
资助国家：
美国
起止时间：
2018-01-01 至 2019-06-30
项目状态：
已结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=1747681&HistoricalAwards=false
关键词：
Collaborative Research EAGER Salinity based

项目摘要

Adaptation to new environments is a fundamental challenge for organisms, including microbes, in expanding their habitat range. It is important to investigate the cellular mechanisms underlying salinity tolerance in coastal bacterioplankton and their different responses to salinity in nature because (i) it will provide fundamental understanding for how microorganisms evolve to inhabit environments with different salinities, and (ii) alterations in coastal salinity are connected to climate change, so the way these alterations affect abundant coastal microorganisms also alters the biogeochemical cycling of, e.g., carbon. The project will examine microbial adaptations to salinity and determine how changes in salinity affect microbial metabolism using two closely related groups of abundant coastal bacterioplankton as model taxa. In addition, the research will continue and expand microbiology Course-based Undergraduate Research Experiences (mCUREs) in high-throughput cultivation and microbial characterization at the Lousiana State University. Sections of freshman biology laboratories will learn how to isolate, characterize, and molecularly identify microorganisms from local aquatic systems. mCURE sections will lead to newly isolated strains, genome sequences, and physiological data, these results will be published with the contributing students as co-authors. The relative success of mCURE sections will be assessed compared to traditional freshman biology sections. mCURE sections will offer unique opportunities for LSU students by creating excitement about research through discovery of new organisms and generating knowledge of the coastal habitats that are essential to the livelihood of the Gulf Coast.The evolutionary transition between salt- and freshwater environments occurs rarely in microorganisms. In one of the most abundant aquatic groups, SAR11, the transition between salt- and freshwater environments has happened only once: all freshwater SAR11 belong to subclade IIIb/LD12, which has also been found to inhabit coastal environments where salinity varies widely. The first reported isolates of the SAR11 freshwater clade LD12 and a member of the sister clade IIIa from the same region are now available. These pure culture representatives provide a powerful model for experimentally investigating adaptations to new environments in microorganisms, specifically (i) the genomic pathway and regulatory distinctions that arise during the evolutionary transition from marine to freshwater environments, and (ii) the physiological mechanisms that underlie the ecological restrictions imposed on microorganisms by ionic strength in coastal and freshwater environments. Furthermore, because these organisms have distinct differences in metabolic potential, the isolates facilitate testing (iii) the effects of changing coastal salinity on microbial contributions to other biogeochemical cycles, such as that for carbon. The project will test the hypothesis that the relative ionic strength tolerances between the sister lineages (LD12, IIIa) result from fundamental differences in metabolic flexibility at a genomic and regulatory level. To do so it will assess transcriptional and metabolic responses to varied ionic strength for both taxa and measure the distribution and activity of both groups in nature to translate laboratory findings to the field. The research will provide new understanding of LD12 habitat range and insights into how the "freshwater" lineage evolved from a SAR11 common ancestor. The project will also more generally provide important information on microbial responses to salinity changes in coastal systems and the evolutionary paths separating freshwater and marine microorganisms.This award is co-funded by Biological Oceanography, Division of Ocean Sciences in the Directorate for Geosciences and by Systems and Synthetic Biology, Division of Molecular and Cellular Biosciences in the Directorate for Biological Sciences.

适应新环境是包括微生物在内的生物体在扩大其栖息地范围方面面临的根本挑战。研究沿海浮游细菌耐盐性的细胞机制及其对自然界盐度的不同反应是很重要的，因为（i）它将为微生物如何进化以栖息于不同盐度的环境提供基本的理解，（ii）沿海盐度的变化与气候变化有关，因此，这些变化影响丰富的沿海微生物的方式也改变了海洋地球化学循环，例如，carbon.该项目将研究微生物对盐度的适应性，并利用两组密切相关的丰富的沿海浮游细菌作为模式分类群，确定盐度的变化如何影响微生物的新陈代谢。此外，该研究将继续和扩大在路易斯安那州立大学的高通量培养和微生物表征的微生物学课程为基础的本科生研究经验（mCURES）。新生生物实验室的部分将学习如何从当地水生系统中分离，表征和分子鉴定微生物。mCURE部分将导致新分离的菌株，基因组序列和生理数据，这些结果将与贡献的学生作为共同作者发表。与传统的大一生物学部分相比，将评估mCURE部分的相对成功。mCURE部分将提供独特的机会，路易斯安那州立大学的学生通过创造兴奋的研究，通过发现新的生物体和沿海栖息地，是必不可少的墨西哥湾沿岸的生计产生的知识。盐和淡水环境之间的进化过渡很少发生在微生物。在最丰富的水生类群之一SAR 11中，盐和淡水环境之间的转变只发生过一次：所有的淡水SAR 11都属于亚支IIIb/LD 12，它也被发现栖息在盐度变化很大的沿海环境中。第一次报道的分离物的SAR 11淡水进化枝LD 12和一个成员的姐妹进化枝IIIa从同一地区现在可用。这些纯培养物的代表提供了一个强大的模型，为实验研究适应新的环境中的微生物，特别是（i）的基因组途径和监管的差异，从海洋到淡水环境的进化过渡过程中出现的，和（ii）的生理机制，在沿海和淡水环境中的离子强度对微生物施加的生态限制。此外，由于这些生物体在代谢潜力上有明显的差异，这些分离物有助于测试（iii）沿海盐度变化对微生物对其他生物地球化学循环（如碳）的贡献的影响。该项目将测试姐妹谱系（LD 12，IIIa）之间的相对离子强度耐受性是由基因组和监管水平上代谢灵活性的根本差异引起的假设。要做到这一点，它将评估转录和代谢反应，以不同的离子强度为两个类群，并测量这两个群体在自然界中的分布和活动，将实验室的研究结果转化为实地。这项研究将提供对LD 12栖息地范围的新理解，并深入了解“淡水”谱系如何从SAR 11共同祖先进化而来。该项目还将更广泛地提供关于微生物对沿海系统盐度变化的反应以及淡水和海洋微生物的进化路径的重要信息，该奖项由地球科学局海洋科学司生物海洋学和生物科学局分子和细胞生物科学司系统和合成生物学共同资助。