Structural studies of RNA polymerase regulation by RNA

RNA 调节 RNA 聚合酶的结构研究

• 批准号: 8431355
• 负责人: Seth A. Darst
• 金额: $ 31.83万
• 依托单位: ROCKEFELLER UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-03-01 至 2016-01-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8431355
• 关键词: 6S RNA; Bacteria; Bacterial RNA; Binding; Biochemical; Combined Modality Therapy; Complex; Couples; DNA; DNA-Directed RNA Polymerase; Data; Development; Elongation Factor; Enzymes; Escherichia coli; Event; Frequencies; Gene Expression; Gene Expression Regulation; Genetic Transcription; Goals; Holoenzymes; Lead; Maps; Molecular Conformation; Nutrient; Operon; Phase; Play; Process; RNA; Regulation; Resolution; Rifampin; Site; Specificity; Staging; Structure; Thermus; Transcript; Translations; Tuberculosis; Ursidae Family; X-Ray Crystallography; aminoacid biosynthesis; antimicrobial; attenuation; improved; insight; man; programs; promoter; public health relevance; research study; resistant strain; response; three dimensional structure

DESCRIPTION (provided by applicant): Transcription is the major control point of gene expression and RNA polymerase (RNAP), conserved from bacteria to man, is the central enzyme of transcription. Our long term goal is to understand the mechanism of transcription and its regulation. Determining three-dimensional structures of RNAP and its complexes with DNA, RNA, and regulatory factors, is an essential step. We focus on highly characterized prokaryotic RNAPs. To this end, we bring to bear a combined biochemical and biophysical approach. Here we propose structure/function studies of transcription complexes in different stages of the transcription cycle, aimed towards adding to our understanding of RNAP regulation by the product of transcription itself, RNA. Specifically, we propose to: 1. Use X-ray crystallography to determine high-resolution structures of Thermus RNAP paused transcription complexes, with and without NusA or NusA domains, at the his pause site. Transcriptional pausing plays key roles in the regulation of gene expression by coordinating RNAP with other regulatory events. Transcriptional pausing couples transcription and translation to control the expression of many amino acid biosynthesis operons in a process called attenuation. These regulatory pauses, such as at the his pause site, are stabilized by an RNA hairpin that forms in the just transcribed RNA transcript, likely through an allosteric mechanism. In addition, extrinsic factors, such as the conserved elongation factor NusA, can further stabilize the pause. We've crystallized a paused elongation complex and collected diffraction data to 3.8 E-resolution. Further experiments are proposed to i) improve the resolution limit of these crystals, ii) trap additional relevant conformational states of the paused complex, and iii) crystallize a complex containing NusA or NusA domains. 2. Structurally characterize the 6S RNA/RNAP-holoenzyme complex. The 6S RNA, a key player in the response of the bacterial transcriptional program to nutrient limitation in stationary phase, binds with marked specificity to C70-holoenzyme and inhibits its function. The 6S RNA mimics the DNA in an open promoter complex, and can serve as a transcription template, providing a mechanism for releasing the 6S RNA when nutrients become plentiful. We will: i) Use biochemical and biophysical approaches to map E. coli C70-holoenzyme interactions with 6S RNA, ii) Use X-ray crystallography to determine structures of 6S RNA/RNAP-holoenzyme complexes.

描述（由申请人提供）：转录是基因表达的主要控制点，RNA聚合酶（RNAP）是转录的中心酶，从细菌到人都是保守的。我们的长期目标是了解转录机制及其调控。确定RNAP及其与DNA、RNA和调节因子的复合物的三维结构是重要的一步。我们专注于高度特征化的原核RNAP。为此，我们采取了生物化学和生物物理相结合的方法。在这里，我们提出了在转录周期的不同阶段的转录复合物的结构/功能研究，旨在增加我们的理解RNAP调节的转录本身的产品，RNA。具体而言，我们建议：1.使用X射线晶体学来确定Thermus RNAP暂停转录复合物的高分辨率结构，有和没有NusA或NusA结构域，在his暂停位点。转录暂停通过协调RNAP与其他调控事件在基因表达调控中起着关键作用。转录暂停耦合转录和翻译以在称为衰减的过程中控制许多氨基酸生物合成操纵子的表达。这些调节暂停，例如在his暂停位点，通过在刚刚转录的RNA转录物中形成的RNA发夹稳定，可能是通过变构机制。此外，外部因素，如保守的延伸因子NusA，可以进一步稳定暂停。我们已经结晶了一个暂停的伸长复合物，并收集了衍射数据，分辨率为3.8 E。提出了进一步的实验以i）提高这些晶体的分辨率极限，ii）捕获暂停复合物的另外的相关构象状态，以及iii）使含有NusA或NusA结构域的复合物结晶。2.对6S RNA/RNAP全酶复合物进行结构表征。6S RNA是细菌转录程序对静止期营养限制的反应中的关键参与者，其以显著的特异性结合C70全酶并抑制其功能。6S RNA模拟开放启动子复合物中的DNA，并且可以作为转录模板，提供当营养物变得丰富时释放6S RNA的机制。我们将：i）使用生物化学和生物物理的方法来映射E。coli C70-全酶与6S RNA的相互作用，ii）使用X射线晶体学来确定6S RNA/RNAP-全酶复合物的结构。