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EDGE CMT: RUI: Roles of Toxin-Antitoxin Systems in Biofilm Formation and Horizontal Gene Transfer in the genus Variovorax

EDGE CMT：RUI：毒素-抗毒素系统在 Variovorax 属生物膜形成和水平基因转移中的作用

基本信息

批准号：
2128184
负责人：
Paul Orwin
金额：
$ 69.27万
依托单位：
University Enterprises Corporation at CSUSB
依托单位国家：
美国
项目类别：
Standard Grant
财政年份：
2021
资助国家：
美国
起止时间：
2021-07-15 至 2022-01-31
项目状态：
已结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=2128184&HistoricalAwards=false
关键词：
EDGE CMT RUI Roles Toxin

项目摘要

This proposal will address the connection between the movement of DNA in bacterial populations and the formation of complex multi-cellular structures called biofilms. This project is focused on evaluating the role of these elements in the important soil bacterium Variovorax paradoxus. This bacterium plays a crucial role in the association of bacterial populations with plant roots, as well as in many other soil processes. Biofilm formation and DNA transfer in the environment are connected by the release of genetic material into the environment by cells within the biofilm. This material forms part of the structure of the biofilm, as well as a potential source of genetic variation. The bacteria within the biofilm are lysed to release their cellular contents, including their DNA, which then becomes part of the structure. The movement of DNA between bacterial cells is critical factor in understanding how bacterial populations respond to changes in their environment. These processes are thought to be connected in many bacterial species from diverse environments, and the mechanism proposed to be at work here may be widely responsible for connecting the two phenotypes. Using cutting edge DNA and RNA sequencing approaches, combined with laboratory experiments, the researchers, which include many undergraduates, aim to functionally link the structure and function of specific genetic elements to the formation of biofilms and the transfer of genetic material between cells via the biofilm matrix. Via course based undergraduate research experiences, students will have the opportunity to formulate their own research questions, perform state of the art genomic sequencing and bioinformatic analyses, and contribute to the writing of peer-reviewed publications. Recently finished genome assemblies show that Variovorax isolates have diverse genomic architectures including chromosomes, chromids, and plasmids. These genomes include numerous putative Toxin-Antitoxin systems in all three types of replicon, that are proposed to function as addiction or anti-addiction modules depending on expression level and location. This is hypothesized to be connected with biofilm formation through a global regulatory system controlling transcript stability during biofilm formation. An alternative RNA degradosome component is highly expressed specifically in Variovorax paradoxus EPS biofilms, which is proposed to decrease TA system RNA stability to promote cell lysis, releasing eDNA critical for dense biofilm formation and horizontal gene transfer. Differentially expressed TA operons are potential determinants of both biofilm formation and horizontal gene transfer. The TA systems in the genus Variovorax will be identified in silico, expression will be evaluated using RNA-seq, and addiction module function will be tested using tightly regulated expression systems. Saturation mutagenesis (RB-TnSeq) will be used to identify accessory genes that influence the function of TA systems in regulating plasmid stability. Chromosomal TA systems as anti-addiction modules will be evaluated similarly with TA systems integrated in single copy using mini-Tn7. The connection between TA system function, biofilm formation, and HGT will be examined using marked strains. These experiments will demonstrate that eDNA generation by TA system toxin activity is necessary and sufficient to allow for natural transformation in Variovorax biofilms. They will also show that these phenotypes are inextricably linked through biofilm growth dependent alteration of RNA stability.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.

该提案将解决细菌种群中DNA运动与称为生物膜的复杂多细胞结构形成之间的联系。该项目的重点是评估这些元素在重要的土壤细菌Variovorax paradoxus中的作用。这种细菌在细菌种群与植物根系的联系以及许多其他土壤过程中起着至关重要的作用。生物膜形成和环境中的DNA转移通过生物膜内的细胞将遗传物质释放到环境中来连接。这种物质构成了生物膜结构的一部分，也是遗传变异的潜在来源。生物膜内的细菌被裂解以释放它们的细胞内容物，包括它们的DNA，然后它们成为结构的一部分。DNA在细菌细胞之间的运动是理解细菌种群如何应对环境变化的关键因素。这些过程被认为是连接在许多细菌物种从不同的环境，和机制提出在这里工作可能是广泛负责连接两个表型。使用尖端的DNA和RNA测序方法，结合实验室实验，研究人员，其中包括许多本科生，旨在功能性地将特定遗传元件的结构和功能与生物膜的形成以及遗传物质通过生物膜基质在细胞之间的转移联系起来。通过基于课程的本科研究经验，学生将有机会制定自己的研究问题，进行最先进的基因组测序和生物信息学分析，并为同行评审出版物的撰写做出贡献。最近完成的基因组组装表明，Variovorax分离株具有不同的基因组结构，包括染色体，染色体和质粒。这些基因组在所有三种类型的复制子中包括许多推定的毒素-抗毒素系统，其被提议取决于表达水平和位置而作为成瘾或抗成瘾模块起作用。这被假设为通过在生物膜形成期间控制转录物稳定性的全局调节系统与生物膜形成相关联。另一种RNA降解体组分在Variovorax paradoxus EPS生物膜中特异性高度表达，其被提出降低TA系统RNA稳定性以促进细胞裂解，释放对于致密生物膜形成和水平基因转移至关重要的eDNA。差异表达的TA操纵子是生物膜形成和水平基因转移的潜在决定因素。将通过计算机模拟鉴定Variovorax属中的TA系统，使用RNA-seq评价表达，并使用严格调控的表达系统测试成瘾模块功能。饱和诱变（RB-TnSeq）将用于鉴定影响TA系统在调节质粒稳定性中的功能的辅助基因。作为抗成瘾模块的染色体TA系统将与使用mini-Tn 7整合在单拷贝中的TA系统类似地进行评价。TA系统功能、生物膜形成和HGT之间的联系将使用标记的菌株进行检查。这些实验将证明，通过TA系统毒素活性产生eDNA是必要的，并且足以允许在Variovorax生物膜中进行自然转化。他们还将表明，这些表型是密不可分的联系，通过生物膜生长依赖改变RNA stability.This奖项反映了NSF的法定使命，并已被认为是值得通过使用基金会的智力价值和更广泛的影响审查标准进行评估的支持。