Coordination of HSV Lagging Strand Synthesis

HSV 滞后链合成的协调

• 批准号: 7150138
• 负责人: Deborah S. Parris
• 金额: $ 29.94万
• 依托单位: OHIO STATE UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2006
• 资助国家: 美国
• 起止时间: 2006-08-01 至 2010-07-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7150138
• 关键词: DNA primase; DNA primers; DNA replication; enzyme activity; enzyme complex; helicase; herpes simplex virus 1; intermolecular interaction; mass spectrometry; nucleic acid amplification techniques; plasmids; protein protein interaction; protein structure function; proteomics; virus DNA; virus genetics; virus replication

DESCRIPTION (provided by applicant): Duplex DNA is copied continuously on one strand (leading), but discontinuously on the other (lagging) strand to form short segments called Okazaki fragments. Thus, lagging strand synthesis is a much more complex process. Failure to properly synthesize and process Okazaki fragments can lead to increased mutations, genomic instability, and replication failure. How lagging strand synthesis is coordinated in eukaryotes is poorly understood. Herpes simplex virus (HSV) is a genetically tractable and simple organism that encodes most, but not all, of the enzymes required for DNA synthesis. The overarching hypothesis guiding the studies proposed in this application is that synthesis and processing of Okazaki fragments require the coordination of HSV-encoded and cellular enzymatic activities. In the first aim, we will examine the requirements for coordination of the HSV-1 primase activity with its polymerase activity and for coordination of the helicase activity with primase activities of UL5/UL52/UL8 complex. A series of half-forked and forked DNA substrates that contain high efficiency sites for initiation of primer synthesis will examine the optimum orientation for loading UL5/UL52/UL8 for priming compared to that for translocation and fork unwinding, and for elongation of primers by polymerase. In the second aim, the conditions and factors that trigger the cycling of the processive HSV polymerase to new primers following termination of Okazaki fragments will be determined. In the third aim, the protein:protein and protein:DNA interactions that occur under the most efficient in vitro conditions for initiation, termination, or processing of Okazaki fragments will be determined. In addition, we will use a global proteomics approach to identify by mass spectrometry, cellular and viral proteins that specifically associate with replicating DNA. A novel approach to gently and specifically isolate plasmids that amplify in cells in an HSV origin-dependent manner is proposed. A better understanding of the steps required for HSV lagging strand synthesis could lead to novel strategies to disrupt the virus replication cycle. The simple model system also provides a unique opportunity to understand the formation and processing of lagging strand DNA in mammalian cells that is so vital to genomic stability.

描述（由申请人提供）：双链体DNA在一条链（前导）上连续复制，但在另一条链（滞后）上不连续复制，形成称为冈崎片段的短片段。因此，滞后链合成是一个复杂得多的过程。不能正确合成和处理冈崎片段会导致突变增加，基因组不稳定和复制失败。在真核生物中，滞后链的合成是如何协调的，人们还知之甚少。单纯疱疹病毒（HSV）是一种遗传上易于处理的简单生物体，它编码DNA合成所需的大部分酶，但不是全部。指导本申请中提出的研究的总体假设是，冈崎片段的合成和加工需要HSV编码的酶活性和细胞酶活性的协调。在第一个目标中，我们将检查HSV-1引发酶活性与其聚合酶活性的协调以及UL 5/UL 52/UL 8复合物的解旋酶活性与引发酶活性的协调的要求。一系列含有用于引发引物合成的高效位点的半叉和叉状DNA底物将检查与易位和叉解旋以及通过聚合酶延伸引物的最佳取向相比，用于装载UL 5/UL 52/UL 8以引发的最佳取向。在第二个目标中，将确定在冈崎片段终止后触发进行性HSV聚合酶循环为新引物的条件和因素。在第三个目标中，将确定在最有效的体外条件下发生的蛋白质：蛋白质和蛋白质：DNA相互作用，用于冈崎片段的起始、终止或加工。此外，我们将使用全球蛋白质组学方法，通过质谱法鉴定与复制DNA特异性相关的细胞和病毒蛋白质。提出了一种新的方法来温和和特异性地分离质粒，在细胞中扩增的HSV来源依赖性的方式。更好地理解HSV滞后链合成所需的步骤可能会导致破坏病毒复制周期的新策略。简单的模型系统还提供了一个独特的机会，了解哺乳动物细胞中落后链DNA的形成和加工，这对基因组稳定性至关重要。