鸡贫血病毒全基因组点突变体的体外构建及其在宿主细胞MSB1的转染研究

在已构建鸡贫血病毒（CAV）全基因组体外克隆（pCAV2.4)的基础上,设计一对特定引物,用CPR定向点突变方法扩增出含有完整的EcoRI位点的CAV全基因组（2.3kb）,并克隆入pUC18载体中,获得阳性克隆,命名为pCAVE^ 。经酶切鉴定和序列分析EcoRI位点两侧序列,原先不完整的EcoRI位点（－GACTTC－）已被定向点突变为完整的EcoRI位点（－GAATTC-)。对重组质粒pCAVE^ 以EcoRI酶切回收CAV全基因组DNA,在体外连接并经纯化后,经Effectene转染易感宿主细胞MSB1。将转染细胞培养上清连续传代8次以后,出现病毒复制（MSB1细胞培养基颜色不再变黄）。取此时细胞培养液感染无CAV的1日SPF小鸡,14天出现典型的鸡盆血症状和胸腺萎缩、骨髓脂肪变性等病变。获得了能在体外自主复制并组装成完整CAV病毒子的感染性核酸。     

人干细胞因子cDNA的设计、合成与克隆

选择大肠杆菌的偏爱密码子,分成18个长约60个碱基且相互配对的寡核苷酸片段,合成了可溶形式的人干细胞因子（hSCF)的cDNA,合成片段经纯化、5′-端磷酸化后,通过PCR进行合成hSCF的cDNA一次性组装与扩增,得到了含有可溶形式的hSCF的全部编码区及EcoRⅠ、SalⅠ位点在内的全长共515个碱基对的DNA片段,回收该DNA片段,酶切消化,定向克隆进质粒pUC19。经酶切鉴定以及序列测定,得到了全序列正确的克隆株,为下一步的工作奠定了基础。     

猪水泡病病毒HK′1／70株基因组全长cDNA的构建及其序列测定

从实验感染猪水泡病病毒(SVDV)的乳鼠组织中提取RNA,利用长距离的RACE技术,扩增出覆盖SVDVHK′1/70株全基因组的2个忠实性的cDNA重叠片段(3′PCR片段和5′PCR片段),分别克隆进pGEM-T Easy载体。利用AatⅡ和BssHⅡ酶切含5′PCR片段的重组质粒,回收目的片段,定向克隆于含3′PCR片段的重组质粒,构建出了SVDV HK′1/70株全长cDNA重组质粒,然后进行序列测定。结果表明,HK′1/70株基因组全基因组序列长7 401 nt(poly A除外),其中5′NCR长743 nt,该毒株蛋白编码区的核苷酸序列为6 558 nt,编码一个长2 185个氨基酸的聚合蛋白,3′NCR长102 nt,其后是至少含有74个A碱基的poly A尾。在HK′1/70株全长cDNA序列的5′端引入了T7启动子序列,在poly A3′端引入了Psp1406Ⅰ识别序列。通过序列同源性和进化树分析,结果表明,HK′1/70属于第Ⅱ抗原遗传群,SVDV与CB5的遗传关系最近,且位于CB5遗传进化树的分支上。HK′1/70株全长cDNA的序列测定及构建,为拯救SVDV和在分子水平进一步深入研究SVDV打下坚实的基础。     

鹅源新城疫病毒ZJI株基因组cDNA克隆的序列修饰

将鹅源新城疫病毒ZJI株全基因组cDNA克隆通过酶切切下包含T7启动子区域和转录载体的片段,将其自身环化后获得约6．5kb的质粒。设计引物,利用基因定点突变技术,在此质粒上T7启动子与NDV Leader序列之间突变插入额外的3个G碱基,将此突变最终引入到原基因组cDNA克隆中。应用RT—PCR技术从尿囊液中扩增NDV基因组F／HN基因区域部分片段,利用限制性内切酶BsmBI将扩增片段连接,最终将原cDNA克隆中相应片段替换下。测序结果表明,原基因组cDNA克隆中特定位置碱基插入突变成功,F／HN基因区域碱基突变均得以纠正。以上cDNA克隆的修饰与替换为该毒株的反向遗传研究打下了基础。     

茶尺蠖小RNA病毒全长cDNA克隆的构建

为了初步研究茶尺蠖小RNA病毒(Ectropis oblique picorna-like virus, EoPV)的复制机制,从被EoPV感染致死的茶尺蠖幼虫中分离并纯化病毒粒子,提取病毒RNA,根据已公布的EoPV核苷酸序列,利用基因组上单一的酶切位点,设计特异性引物,应用RT-PCR扩增出5个覆盖全长的片段。 随后采用融合PCR将5个片段拼接,最终将全长定向克隆到低拷贝质粒载体上,成功构建cDNA全长克隆p-EoPV。 双酶切及测序鉴定证明全长克隆构建成功。 与原序列比较发现,该克隆在氨基酸水平上有8个突变和1个缺失。 本研究为深入探讨EoPV病毒生物学特性、病毒复制机理等奠定了基础     

磁珠富集法分离刀鲚微卫星标记

利用磁珠富集法分离微卫星序列,以开发长江刀鲚微卫星分子标记。将长江刀鲚基因组DNA经限制内切酶Mse I酶切,回收400-1 000 bp片段,安装接头,构建长江刀鲚全基因组PCR文库。用生物素标记的微卫星探针(CA)12与其杂交,磁珠富集含有微卫星序列的DNA片段。将洗脱所得片段进行PCR扩增,然后进行克隆。经过菌落PCR检验后挑选出118个阳性克隆进行测序,其中97条含有微卫星序列。用设计合成59对微卫星引物对30尾养殖长江刀鲚进行引物的多态性筛选,得到9对多态性引物。     

人呼吸道合胞病毒兰州株基因组全长cDNA克隆的构建及鉴定

目的构建用于呼吸道合胞病毒(respiratory syncytial virus,RSV)体外拯救的RSV基因组全长cDNA克隆,并进行鉴定。方法根据RSV Long株基因组序列设计并合成引物,利用RT-PCR技术分6段扩增RSV LZ01/09基因组序列并构建克隆载体;测序后,利用重叠PCR与酶切连接技术,根据基因组序列选择特异性酶切位点,引入Kpn I、Xma I和Sal I酶切位点,构建成4个亚克隆载体;将亚克隆载体的插入片段连接至经过改造且包含T7启动子、锤头状核酶、多克隆位点、丁肝核酶、T7终止子的p RSV1载体中,构建RSV基因组全长cDNA克隆;对克隆全长cDNA序列进行测定,与亲本RSV LZ01/09基因组进行同源性比对分析,并与RSV实验参比株进行系统进化树分析。结果测序结果显示,RSV LZ 01/09的基因组全长为15 204 bp,与GenBank公布的RSV基因组序列长度相当,将完整的序列提交GenBank,登录号为KY782635;酶切及测序结果显示,用于RSV全长cDNA克隆构建的基本载体p BSKS-MCS(简称p RSV1)与预期相符,RSV全长基因组cDNA克隆质粒(简称转录载体p RSV1-4F)酶切片段大小与预期一致;同源性比对结果显示,全长cDNA序列与亲本RSV LZ01/09基因组序列同源性高达99.83%;系统进化树分析结果显示,其与RSV-A亚型序列同属于一个分支。结论测序及酶切分析结果表明已成功构建RSVLZ01/09基因组全长cDNA克隆,为建立拯救RSV重组病毒的反向遗传学系统平台奠定了基础。     

应用聚合酶链反应突变和克隆HIV-lgag基因片段

作者设计并合成了一对突变引物PGO1和PGO2,分别在两引物中设计了两个突变点,使突变后基因含有EcoRI、BamHI和ATG及TAA序列,以便于HlV-1gag基因序列的定向克隆和表达。用PCO1和PGO2作引物,采用PCR方法从HIV-1基因组DNA中扩增出一个长504bp的DNA片段,用EcoRl和BamHI双酶切位点将此片段定向克隆入pUC19质粒。将克隆基因插入M13mp18进行DNA序列分析,结果表明,该基因序列及读框完全正确,且在其5′末端突变出EcoRI位点和ATG起始码,3′末端突变出TAA终业码和BamHI位点,从而为该基因的表达研究奠定了基础。     

金黄色葡萄球菌一氧化氮合酶基因(nos)缺失突变株的构建

目的：构建金黄色葡萄球菌一氧化氮合酶基因（nos）缺失突变株。方法从金黄色葡萄球菌RN6390的基因组DNA中扩增了nos基因的上、下游片段;以大肠杆菌和金黄色葡萄球菌穿梭质粒pMAD（含有温度敏感性的复制起点,红霉素抗性基因（erm）和B．半乳糖苷酶基因（bgaB）为筛选标记）为骨架,构建基于nos基因位点的同源重组载体pMADAnos,该载体经金黄色葡萄球菌RN4220修饰后再转入金黄色葡萄球菌RN6390。经过在30℃和42℃交替培养,通过抗生素抗性和β-半乳糖苷酶活性筛选nos基因缺失突变株。结果筛选得到的突变菌株,经基因组PCR、定量PCR及序列分析表明,金黄色葡萄球菌RN6390基因组中的nos基因被成功地敲除。结论利用同源重组的方法构建了金黄色葡萄球菌RN6390nos缺失突变株,为金黄色葡萄球菌nos基因功能的研究奠定了基础,     

用PCR扩增和克隆鸡传染性贫血病毒全基因组DNA

根据已发表的序列,分别在鸡贫血病毒(CAV)环形基因组DNA(全长2.3kb)的EcoRI位点和BamHI位点的两侧选择适当序列合成两对引物,用PCR技术,从斑点杂交检测到病毒核酸的CAV感染的MDCC-RP1细胞基因组DNA中,分别扩增出包含EcoRI和BamHI分割开的病毒基因组两部分(1.5kb和0.8kb)约1.5kb和约1.25kb的两个片段.再将其中相应序列拼接克隆进pUC18载体,获得包含CAV全基因组序列DNA片段的克隆质粒pCAV2.4.酶切分析表明,该质粒具有预期的BamHI位点、PstI位点、HindⅢ位点,而预期的EcoRI位点消失.重组质粒插入DNA片段的两端序列分析表明,质粒pCAV2.4是包含CAV全基因组序列的重组质粒,插入DNA片段序列中的EcoRI位点序列发生了一个碱基突变.     

应用限制性显示技术制备HCV cDNA诊断基因芯片的初步研究

制备丙型肝炎病毒 (HCV)检测芯片并进行验证、初步检测质量评价。采用限制性显示 (Restrictiondisplay ,RD)技术制备芯片探针 ,从载体pCV_J4L6S中切出HCV全长cDNA ,Sau3AⅠ酶消化 ,所得的限制性片段进行RD_PCR扩增 ,经聚丙烯酰胺电泳 (PAGE)结合银染法进行分离。切胶回收后作 3次PCR ,得到较纯净的HCVcDNA限制性片段。扩增后的产物克隆至pMD18_T载体进行快速鉴定。将筛选出的限制性片段打印在氨基修饰的玻片上制备成检测芯片进行杂交验证分析 ,对芯片检测进行优化、初步的质量评估。运用RD技术 ,得到 2 4个 2 0 0～ 80 0bp、大小均一的基因片段 ,序列分析表明 ,均属于HCV特异基因 ,可以作为诊断芯片探针 ;杂交、测序结果显示 ,芯片检测的敏感性、特异性、准确度、重复性、线性等指标均佳。利用RD技术制备基因芯片探针是一种快速、简便的实用方法 ;制备的诊断芯片可以用于检测HCVRNA ,具有敏感、检测结果较为可靠的优点。     

Screening for mutations in human HPRT cDNA using the polymerase chain reaction (PCR) in combination with constant denaturant gel electrophoresis (CDGE).

Previously, we reported the modification of denaturing gradient gel electrophoresis called constant denaturant gel electrophoresis (CDGE). CDGE separates mutant fragments in specific melting domains. CDGE seems to be a useful tool in mutation detection. Since the hypoxanthine phosphoribosyltransferase (HPRT) gene is widely used as target locus for mutation studies in vitro and in vivo, we have examined the approach of analyzing human HPRT cDNA by polymerase chain reaction (PCR) and CDGE. All nine HPRT exons are included in a 716-bp cDNA fragment obtained by PCR using HPRT cDNA as template. When the full-length cDNA fragment was examined by CDGE, it was possible to detect mutations only in the last part of exon 8 and exon 9. However, digestion of the cDNA fragment with the restriction enzyme AvaI prior to CDGE enabled us to detect point mutations in most of exon 2, the beginning of exon 3, the last part of exon 8 and exon 9. With the use of two internal primer sets, including a GC-rich clamp on one of the primers in each pair, a region containing most of exon 3 through exon 6 was amplified and we were able to resolve fragments with point mutations in this region from wild-type DNA. The approach described here allows for rapid screening of point mutations in about two thirds of the human HPRT cDNA sequence. In a test of this approach, we were able to resolve 12 of 13 known mutants. The mutant panel included one single-base deletion, one two-base deletion and 11 single-base substitutions.     

口蹄疫病毒泛亚型O/CHINA/99株全长cDNA分子克隆构建和感染性鉴定

设计并合成了O型口蹄疫泛亚型代表毒株O/CHINA/99基因组9条引物,利用RT-PCR扩增各基因片段,酶切后连到pOK-12载体上,经酶切、PCR和序列测定表明,O/CHINA/99全基因组由8 200个核苷酸组成,构建的感染性cDNA与原毒株的序列同源性为99.1%;利用T7 RNA聚合酶系统进行体外转录,转录产物RNA用脂质体转入BHK-21细胞传代培养,可观察到典型的FMDV致细胞病变效应;拯救病毒接种2日龄乳鼠后,可出现典型的临床症状,并于16～48h内死亡。以上结果表明,O/CHINA/99株全长cDNA分子克隆构建成功,并从构建的全长cDNA拯救出了口蹄疫病毒。     

应用PCR技术对先天性长QT综合征KCNQ1 基因进行定点突变的研究

利用聚合酶链反应（PCR）技术对长QT综合征（LQTS）KCNQ1基因进行定点突变的研究。首先设计两对引物（包含预定的突变）,通过3轮PCR扩增,扩增出含有所需突变位点的片段,然后将片段克隆入T载体中,通过酶切连接的方法将突变点引入到pIRES2-EGFP-KCNQ1中,随后用Effectene转染试剂介导转染HEK293细胞。结果在真核表达载体pIRES2-EGFP-KCNQ1基础上获得了KCNQ1 cDNA C934T的突变体,测序表明在序列中发生了预期的突变。将含突变点的pIRES2-EGFP-KCNQ1转染HEK293细胞后,在荧光显微镜下观察到被转染的HEK293细胞发出绿色荧光,表明含突变点的pIRES2-EGFP-KCNQ1得到了表达。Abstract: To study PCR site-directed mutagenesis of long QT syndrome KCNQ1 gene in vitro. The site-directed mutagenesis of LQTS gene KCNQ1 was made by PCR. Two sets of primers were designed according to the sequence of KCNQ1 cDNA, and mismatch was introduced into primers. Mutagenesis was performed in a three-step PCR. The amplified fragments from the third PCR which contained the mutation site were subcloned into the T-vecor PCR2.1.Then the fragments containing the mutation site was obtained from PCR2.1 with restriction enzyme digestion and was inserted into the same restriction site of pIRES2-EGFP-KCNQ1. With Effectene Transfection Reagent, pIRES2-EGFP-KCNQ1 was transfected into HEK293 cell. The sequencing analysis showed that the mutation site was correct. Mutation from T to C in 934 site of KCNQ1 cDNA was found. Under the fluorescence microscope, the green fluorescence was spread in the transfected HEK293 cell, meaning the pIRES2-EGFP-KCNQ1 containing the mutation site was expressed correctly.     

犬瘟热病毒小熊猫株反向遗传系统的构建及其鉴定

以驯化致弱的犬瘟热病毒小熊猫株(Canine distemper virus,CDV)为模板,构建犬痘热病毒感染性cDNA克隆.对其全基因组序列测定后,用RT-PCR的方法获得组成全长基因的7个片段,通过酶切、拼接将7段CDVcDNA序列插入到真核表达载体pCI的MCS上,构建犬瘟热病毒小熊猫株的全长cDNA质粒(pCI-CDV-LP),同时分别克隆CDV小熊猫株N、P、L蛋白ORF构建三个辅助质粒.酶切鉴定和序列测定表明,pCI载体中插入的核酶及CDV cDNA序列正确无误,使用转染试剂Lipofectamine TM 2000将全长质粒和三个辅助质粒共转染中国仓鼠肾细胞(BSR),经RT-PCR、间接免疫荧光和病毒感染VERO-SLAM细胞试验鉴定,成功拯救出CDV小熊猫株,显示CDV小熊猫株反向遗传系统构建完成,为犬瘟热病毒致病机理及免疫研究奠定基础.     

Novel cell culture-adapted genotype 2a hepatitis C virus infectious clone

Although the recently developed infectious hepatitis C virus system that uses the JFH-1 clone enables the study of whole HCV viral life cycles, limited particular HCV strains have been available with the system. In this study, we isolated another genotype 2a HCV cDNA, the JFH-2 strain, from a patient with fulminant hepatitis. JFH-2 subgenomic replicons were constructed. HuH-7 cells transfected with in vitro transcribed replicon RNAs were cultured with G418, and selected colonies were isolated and expanded. From sequencing analysis of the replicon genome, several mutations were found. Some of the mutations enhanced JFH-2 replication; the 2217AS mutation in the NS5A interferon sensitivity-determining region exhibited the strongest adaptive effect. Interestingly, a full-length chimeric or wild-type JFH-2 genome with the adaptive mutation could replicate in Huh-7.5.1 cells and produce infectious virus after extensive passages of the virus genome-replicating cells. Virus infection efficiency was sufficient for autonomous virus propagation in cultured cells. Additional mutations were identified in the infectious virus genome. Interestingly, full-length viral RNA synthesized from the cDNA clone with these adaptive mutations was infectious for cultured cells. This approach may be applicable for the establishment of new infectious HCV clones.     

用DREAM技术纠正人工合成基因中的突变

目的：介绍一种简便、有效的定点突变技术。方法：根据突变位点附近的DNA序列推导出氨基酸序列,再以此氨基酸序列进行逆翻译,这样在不改变氨基酸序列的前提下可以得到数目巨大的隐性突变体（silent mutants）,这些突变体中包含大量的限制性内切酶位点,选择合适的酶切位点设计引物用PCR技术扩增两侧DNA片段,然后以相应酶切融合这两个片段即可完成定点突变。结果：用该方法成功地在人工合成的含有缺失的可溶性组织因子基因的472位插入C,T两个碱基,校正了阅读框架,获得了预期的目的基因。结论：该方法简便、有效, 避免了多轮PCR和合成长引物导致突变的可能性,这种改进的PCR 定点诱变技术我们称之为“设计限制酶辅助突变”（Designed Restriction Enzyme Assisted Mutagenesis, DREAM）。此技术简单方便, 诱变的成功率高, 适于实验室常规应用。     

A novel method for producing partial restriction digestion of DNA fragments by PCR with 5-methyl-CTP.

Partial digestion of DNA fragments is a standard procedure for subcloning analysis and for generating restriction maps. We have developed a novel method to generate a partial digestion for any DNA fragment that can be amplified by PCR. The method involves the incorporation of 5-methyl-dCTP into the PCR product to protect most of the restriction sites. As a result, complete digestion of the modified PCR products with a 5-methyl-dCTP-sensitive enzyme will produce an array of restriction fragments equivalent to a partial restriction enzyme digestion reaction done on unmethylated PCR products. This method reduces the time and material needed to produce partially-digested DNA fragments by traditional methods. Furthermore, using fluorescein-labeled primers in the reaction, we were able to detect the fluorescein-labeled end fragments resulting from the enzyme digestion using a fluorimager or anti-fluorescein-AP antibody and thus determine the restriction maps.