DNA引发酶及其在肿瘤增殖和治疗中的作用

DNA聚合酶不能从游离的核苷酸开始合成DNA链,由DNA引发酶合成约7～10个核苷酸的RNA引物．DNA聚合酶利用引物提供自由的3′-OH末端合成新的DNA链。DNA引发酶在DNA复制的起始中起重要作用,而DNA复制是肿瘤细胞增殖的关键,抑制DNA引发酶活性,使引物的合成或延长受阻．DNA复制受抑制,肿瘤细胞不能增殖,从而达到抗肿瘤的目的。因此DNA引发酶是抗肿瘤药物研究的一个理想靶点。     

一种DNA扩增的新技术： 利用热稳定的Bst DNA聚合酶驱动跨越式滚环等温扩增反应

Bst DNA聚合酶具有热稳定性、链置换活性及聚合酶活性,在体外DNA等温扩增反应中起重要作用. 本文利用Bst DNA聚合酶的5′→3′聚合酶、核苷酸（末端）转移酶及链置换酶活性发展了一种新的体外环式DNA扩增技术跨越式滚环等温扩增(saltatory rolling circle amplification,SRCA)．在SRCA反应中,Bst DNA聚合酶以上游引物P1为模板合成其互补链RcP1,并和P1形成双链DNA|之后,Bst DNA聚合酶用其核苷酸转移酶活性在其P1的3′末端沿5′→3′方向随机掺入脱氧核糖核苷酸聚合形成寡聚核苷酸（dNMP)m序列,即DNA的合成反应跨越了RcP1 与下游引物P2之间的缺口|然后,以下游引物P2为模板形成互补序列（RcP2）;接着,Bst DNA聚合酶继续将脱氧核糖核苷酸随机添加到RcP2的3′末端,形成（dNMP)n序列．继而,Bst DNA聚合酶以RcP1为模板,继续催化聚合反应合成互补新链,并通过其链置换酶活性替换P1|如此往复,形成［P1-(dNMP)m-RcP2-(dNMP)n …］序列．本文通过电泳、酶切、测序等方法对扩增产物进行分析,演绎出上述扩增过程,并就工作原理进行了讨论．该反应可能对开发等温扩增技术检测微生物有一定助益,也为解释环介导等温扩增技术中假阳性反应和滚环等温扩增反应中的背景信号提供了线索．     

NS5B与HCV负链RNA 3＇末端特异性结合的分析

NS5B是RNA依赖性RNA聚合酶,在病毒RNA合成过程中起到中心催化酶的作用.在大肠杆菌中表达和提纯了GST-NS5B融合蛋白,应用紫外交联试验(UVcross-linking)检测NS5B与丙型肝炎病毒(HCV)负链RNA3＇末端的结合,确定NS5B是否参与HCV负链RNA3＇末端复制体的形成.NS5B可与HCV负链RNA3＇末端发生结合,这种结合存在量效关系,比与正链RNA3＇UTRX区的结合强约10倍,超大量的非同源性RNA和蛋白质不能竞争抑制NS5B与负链RNA3＇末端的结合,证明这种结合存在特异性.结果提示NS5B是HCV负链RNA3＇末端复制体的成分之一.     

基于多重置换扩增技术的RNA病毒基因组扩增方法研究

为了便于新发或罕见病毒性传染病的筛查检测,本研究利用多重置换扩增技术,以负链RNA病毒—发热伴血小板减少综合征病毒和正链RNA病毒—登革病毒为模拟样本探索临床样本中RNA病毒基因组非特异性扩增方法。研究中通过梯度稀释的RNA病毒模拟样本中可能存在的不同丰度的病原体,样本核酸依次加工成单链cDNA、双链cDNA、T4DNA连接酶处理后的双链cDNA以及添加外源辅助RNA后合成并连接的双链cDNA形式,然后进行Phi29DNA聚合酶等温扩增,使用荧光定量PCR方法比较各种方法对RNA病毒核酸扩增的影响。结果显示,对于不同类型的RNA病毒模拟标本,多重置换扩增对于单链及双链cDNA的扩增效果有限,而双链cDNA经DNA连接酶处理后的扩增能达到6×103倍;在cDNA合成过程中加入外源辅助RNA,模拟样本中病毒基因组的扩增可达2×105倍,尤其是对含有低丰度病原体的模拟样本扩增效果的改善更为明显。本研究摸索建立了基于多重置换扩增技术的RNA病毒基因组扩增方法,能够对样本中低丰度RNA病毒基因组实现有效扩增,可满足开展多种病原体筛查检测的需求。     

DNA复制和表达过程中的“水”

遗传信息的传递和表达主要指DNA复制、RNA转录和蛋白质翻译,属小分子单体物聚合成大分子物的过程。以文献、资料为依据,发现主要由DNA聚合酶、DNA连接酶和RNA聚合酶参与的DNA新链合成过程,由RNA聚合酶催化的RNA链延伸过程,以及由氨酰-tRNA酶、转肽酶等参与的肽链形成过程中均没有水的形成。     

RNA病毒基因组和转录复制多样性的分子基础

自然界中RNA病毒的种类和数量比DNA病毒多得多,根据基因组类型,RNA病毒可分为多种类型,许多研究者认为,存在于古细菌Myxobacteria中,仅仅有一个逆转录酶基因的反转子（Retron)可能是所有病毒的祖先,进化的模式如下,反转子→反座子→反转录转座子→反转录病毒→副反转录病毒→DNA病毒,RNA病毒转录。／复制在很多特征上与DNA病毒迥然不同,依赖于RNA的RNA聚合酶是RNA病转录／复制的主要催化剂,RNA病毒基因组转录和复制都从3'端poly(A)或类tRNA结构或其他结构起始,内部终止是转录,通读到5'末端终止是复制,RNA病毒的模板有正链病毒（RNA模板,负链病毒RNA模板和全长正负链反基因组RNA模板,RNA模板的选择调控机制非常复杂,目前知之甚少,选择模板,RNA聚合酶与转录因子结合形成复制体是两种主要的调控方法,另外,5'UTR和3'UTR也可以调控RNA病毒的转录。     

链特异性RT-PCR方法检测口蹄疫病毒负链RNA

旨在建立一种快速、灵敏、特异的检测口蹄疫病毒在复制过程中产生的负链RNA的方法。根据口蹄疫病毒(foot-and-mouth disease virus,FMDV)病毒5’-非编码区(5’-UTR)基因序列,设计了5条引物链特异性RT-PCR引物,建立检测口蹄疫病毒负链RNA的链特异性RT-PCR方法。提取FMD病毒RNA,应用设计的正向引物T1-H1做反转录引物,经反转录和RNA酶A消化后,再经两轮链特异性PCR扩增,可特异性地检测FMDV在复制过程中产生的负链RNA。所建立的检测口蹄疫病毒负链RNA的链特异性RT-PCR方法是一种可靠的方法,在确定细胞培养物和动物感染FMDV的病毒复制和了解病毒的致病性研究中具有应用前景。     

滚环复制技术的建立及在RNA病毒基因检测中的初步应用

滚环复制是噬菌体繁殖所采取的一种基因复制方式,这种方式可使单链的环形分子在聚合酶和引物的作用下进行体外自我扩增。本文中用可特异性连接环化的寡核苷酸链作为探针,分别进行了1份细胞培养的禽流感病毒H5N1亚型样品、1份细胞培养的SARS病毒样品和4份丙型肝炎病毒阳性血清样品的检测。检测原理是探针与靶序列杂交后便可在T4DNA连接酶的作用下形成滚环复制中的环化单链分子,该分子在同温下可被特异性引物滚动复制和支链扩增。本文还利用按禽流感病毒NA1基因区序列合成的模拟DNA分子对该检测方法的灵敏度进行了测试。结果显示：利用固相RCA技术成功检测到三种RNA病毒的基因,该方法的灵敏度可达到能检测10^3拷贝模式DNA分子的水平。与传统的PCR方法敏感性的比较尚待进一步研究。     

关于DNA复制的引物和DNA聚合酶

DNA复制是由DNA聚合酶催化的,反应需要四种脱氧核苷三磷酸和引物-模板;在引物的3′-羟基上,按模板的指令逐个添加脱氧核苷酸,生成碱基序列与模板互补的新DNA。复制时,DNA双链先打开,形成复制叉,随着复制叉的移动完成复制过程。双链DNA的复制是半不连续的,即先导链是连续合成滞后链则为不连续合成;后者先生成若干短片段(冈崎片段),再连在一起。 DNA复制在基因组的加倍、DNA重组以及修复DNA所受损伤等方面都对生命有决定性的作用。     

流感病毒的分子生物学研究进展

流感病毒是分节段的负链RNA病毒,由RNA依赖的RNA聚合酶起始病毒的复制。流感病毒的特殊基因组结构和病毒蛋白的功能使其极易发生抗原转换和抗原漂移,这使得病毒能够逃避多种宿主的长效中和性免疫反应。本文从病毒结构、基因组及其编码蛋白质、病毒复制过程和病毒的易感宿主等几方面论述了流感病毒的分子生物学研究进展。     

Novel application of Phi29 DNA polymerase: RNA detection and analysis in vitro and in situ by target RNA-primed RCA

We present a novel Phi29 DNA polymerase application in RCA-based target RNA detection and analysis. The 3′→5′ RNase activity of Phi29 DNA polymerase converts target RNA into a primer and the polymerase uses this newly generated primer for RCA initiation. Therefore, using target RNA-primed RCA, padlock probes may be targeted to inner RNA sequences and their peculiarities can be analyzed directly. We demonstrate that the exoribonucleolytic activity of Phi29 DNA polymerase can be successfully applied in vitro and in situ. These findings expand the potential for detection and analysis of RNA sequences distanced from 3′-end.     

A high-throughput genome-walking method and its use for cloning unknown flanking sequences

We developed a PCR-based high-throughput genome-walking protocol. The novelty of this protocol is in the random introduction of unique walker primer binding sites into different regions of the genome efficiently by taking advantage of the rolling circle mode of DNA synthesis by Phi29 DNA polymerase after annealing the partially degenerate primers to the denatured genomic DNA. The inherent strand-displacement activity of the Phi29 DNA polymerase displaces the 5′ ends of downstream strands and DNA synthesis continues, resulting in a large number of overlapping fragments that cover the whole genome with the unique walker adapter attached to the 5′ end of all the genomic DNA fragments. The directional genome walking can be performed using a locus-specific primer and the walker primer and Phi29 DNA polymerase-amplified genomic DNA fragments as template. The locus-specific primer will determine the position and direction of the genome walk. Two rounds of successive PCR amplifications by locus-specific and walker primers and their corresponding nested primers effectively amplify the flanking DNA fragments. The desired PCR fragment can be either cloned or sequenced directly using another nested, locus-specific primer. We successfully used this protocol to isolate and sequence 5′ flanking regions/promoters of selected plant genes.     

Highly efficient DNA synthesis by the phage phi 29 DNA polymerase. Symmetrical mode of DNA replication

The results presented in this paper indicate that the phi 29 DNA polymerase is the only enzyme required for efficient synthesis of full length phi 29 DNA with the phi 29 terminal protein, the initiation primer, as the only additional protein requirement. Analysis of phi 29 DNA polymerase activity in various in vitro DNA replication systems indicates that two main reasons are responsible for the efficiency of this minimal system: 1) the phi 29 DNA polymerase is highly processive in the absence of any accessory protein; 2) the polymerase itself is able to produce strand displacement coupled to the polymerization process. Using primed M13 DNA as template, the phi 29 DNA polymerase is able to synthesize DNA chains greater than 70 kilobase pairs. Furthermore, conditions that increase the stability of secondary structure in the template do not affect the processivity and strand displacement ability of the enzyme. Thus, the catalytic properties of the phi 29 DNA polymerase are appropriate for a phi 29 DNA replication mechanism involving two replication origins, strand displacement and continuous synthesis of both strands. The enzymology of phi 29 DNA replication would support a symmetrical model of DNA replication.     

Insights into strand displacement and processivity from the crystal structure of the protein-primed DNA polymerase of bacteriophage phi29

The DNA polymerase from phage phi29 is a B family polymerase that initiates replication using a protein as a primer, attaching the first nucleotide of the phage genome to the hydroxyl of a specific serine of the priming protein. The crystal structure of phi29 DNA polymerase determined at 2.2 A resolution provides explanations for its extraordinary processivity and strand displacement activities. Homology modeling suggests that downstream template DNA passes through a tunnel prior to entering the polymerase active site. This tunnel is too small to accommodate double-stranded DNA and requires the separation of template and nontemplate strands. Members of the B family of DNA polymerases that use protein primers contain two sequence insertions: one forms a domain not previously observed in polymerases, while the second resembles the specificity loop of T7 RNA polymerase. The high processivity of phi29 DNA polymerase may be explained by its topological encirclement of both the downstream template and the upstream duplex DNA.     

Specific recognition of parental terminal protein by DNA polymerase for initiation of protein-primed DNA replication

The linear genome of Bacillus subtilis phage phi29 has a protein covalently linked to the 5' ends, called parental terminal protein (TP), and is replicated using a free TP as primer. The initiation of phage phi29 DNA replication requires the formation of a DNA polymerase/TP complex that recognizes the replication origins located at the genome ends. The DNA polymerase catalyzes the formation of the initiation complex TP-dAMP, and elongation proceeds coupled to strand displacement. The same mechanism is used by the related phage Nf. However, DNA polymerase and TP from phi29 do not initiate the replication of Nf TP-DNA. To address the question of the specificity of origin recognition, we took advantage of the initiation reaction enhancement in the presence of Mn(2+), allowing us to detect initiation activity in heterologous systems in which DNA polymerase, TP, and template TP-DNA are not from the same phage. Initiation was selectively stimulated when DNA polymerase and TP-DNA were from the same phage, strongly suggesting that specific recognition of origins is brought through an interaction between DNA polymerase and parental TP.     

Duality of polynucleotide substrates for Phi29 DNA polymerase: 3'-->5' RNase activity of the enzyme

Phi29 DNA polymerase is a small DNA-dependent DNA polymerase that belongs to eukaryotic B-type DNA polymerases. Despite the small size, the polymerase is a multifunctional proofreading-proficient enzyme. It catalyzes two synthetic reactions (polymerization and deoxynucleotidylation of Phi29 terminal protein) and possesses two degradative activities (pyrophosphorolytic and 3'-->5' DNA exonucleolytic activities). Here we report that Phi29 DNA polymerase exonucleolyticaly degrades ssRNA. The RNase activity acts in a 3' to 5' polarity. Alanine replacements in conserved exonucleolytic site (D12A/D66A) inactivated RNase activity of the enzyme, suggesting that a single active site is responsible for cleavage of both substrates: DNA and RNA. However, the efficiency of RNA hydrolysis is approximately 10-fold lower than for DNA. Phi29 DNA polymerase is widely used in rolling circle amplification (RCA) experiments. We demonstrate that exoribonuclease activity of the enzyme can be used for the target RNA conversion into a primer for RCA, thus expanding application potential of this multifunctional enzyme and opening new opportunities for RNA detection.     

New insights in the ϕ29 terminal protein DNA‐binding and host nucleoid localization functions

Protein‐primed DNA replication constitutes a strategy to initiate viral DNA synthesis in a variety of prokaryotic and eukaryotic organisms. Although the main function of viral terminal proteins (TPs) is to provide a free hydroxyl group to start initiation of DNA replication, there are compelling evidences that TPs can also play other biological roles. In the case of Bacillus subtilis bacteriophage ?29, the N‐terminal domain of the TP organizes viral DNA replication at the bacterial nucleoid being essential for an efficient phage DNA replication, and it contains a nuclear localization signal (NLS) that is functional in eukaryotes. Here we provide information about the structural properties of the ?29 TP N‐terminal domain, which possesses sequence‐independent DNA‐binding capacity, and dissect the amino acid residues important for its biological function. By mutating all the basic residues of the TP N‐terminal domain we identify the amino acids responsible for its interaction with the B. subtilis genome, establishing a correlation between the capacity of DNA‐binding and nucleoid localization of the protein. Significantly, these residues are important to recruit the DNA polymerase at the bacterial nucleoid and, subsequently, for an efficient phage DNA replication.