马铃薯卷叶病毒外壳蛋白基因的合成,分子克隆和全序列分析

以分离自马铃薯主栽品种“紫花白”的马铃薯卷叶病毒(PLRV)分离物的RNA为模板,用人工合成的引物,用反转录和随后PCR扩增的方法合成了PLRV外壳蛋白(CP)基因的cDNA,并克隆于pUC19中。进一步用限制酶切和核苷酸序列分析表明,合成的cDNA由627个核苷酸组成(包括起始和终止密码),序列中有Hinc Ⅱ和BamH Ⅰ两个酶切位点,与国外报道一致。和国外的4个PLRV分离物CP基因序列对比结果,具有高度同源性,其同源率达99.0—99.7％。     

传染性支气管炎病毒核衣壳蛋白基因克隆及在E.coli中的表达

核衣壳蛋白基因 (N基因 )是传染性支气管炎病毒的重要结构基因 .根据已报道的序列设计引物 ,利用RT PCR技术从病毒RNA中扩增和克隆到了N基因的cDNA ,并测定了核苷酸序列 .克隆的N基因片段ORF全长 12 30bp ,编码 4 0 9个氨基酸 .将该片段序列与其他IBV病毒株比较 ,核苷酸的同一性为 87 0 %～ 98 6 %,氨基酸的同一性为 91 0 %～ 98 1%.将该cDNA亚克隆到pBV2 2 0表达载体 ,转化大肠杆菌DH5α菌株 ,Western印迹检测 ,获得了分子量约 4 5kD表达蛋白     

基孔肯雅病毒非结构蛋白基因合成中多位点缺失突变的校正方法

目的:建立一种PCR方法,以快速校正基孔肯雅病毒非结构蛋白基因合成过程中发生的多位点缺失突变。方法:用PCR方法合成基孔肯雅病毒非结构蛋白基因;对测序的克隆进行序列比对,分析不同克隆上缺失突变发生的位置,以保守区域互相重叠的寡核苷酸为上下游引物、以该区域测序正确的克隆为模板进行PCR扩增,得到所需片段,再将这些片段用PCR方法进一步组装成完整的基因序列并进行测序。结果:测序结果表明,经过2次PCR扩增,校正了基孔肯雅病毒非结构蛋白基因合成过程中发生的5个位点缺失突变。结论:得到序列正确的基孔肯雅病毒非结构蛋白基因。在进行基因合成过程中如发生多位点缺失突变,可利用该方法同时对以上突变进行校正,无须再合成引物,降低了实验操作难度,并提高了实验效率。     

马铃薯S病毒RT-PCR检测技术的研究

从感染PVS病毒的马铃薯病叶组织中提取出病毒的RNA,进行反转录cDNA的合成,用特异性引物进行PCR扩增,得到一条长度约为199 bp的特异性PCR扩增产物,与理论设计的外壳蛋白基因大小一致。在基因水平上为PVS的检测提供了一种快速、灵敏、简便的新方法,为PVS的防治提供了有效手段。     

利用RNA干涉技术及微束激光转化法培育抗病毒马铃薯

针对马铃薯生产中危害严重、分布广泛并且具有强烈协生作用的马铃薯X病毒和马铃薯Y病毒,开展了抗病毒病的育种研究。采用RT-PCR技术分别克隆了267 bp的编码马铃薯X病毒外壳蛋白(PVX-cp)基因的相对保守区段X和294 bp的编码马铃薯Y病毒外壳蛋白(PVY-cp)基因的相对保守区段Y两个片段,将其按顺序连接,形成融合基因XY,然后分别将融合基因XY正向和反向插入到载体pHANN IBAL中,得到了载体pH IV,再用NoⅠt对pH IV进行酶切,将产生的大片段插入到载体pART27中,得到同时以PVX-cp基因和PVY-cp基因为靶标的XY的RNA i载体pAR IV。采用微束激光穿刺转化技术转化马铃薯品种Favorita的愈伤组织,得到了14株表型正常的转基因植株,转基因植株的southern b lot分析表明,导入的外源融合基因拷贝数介于2~4之间。攻毒实验表明,其中11株转基因植株对PVX、PVYo以及PVX和PVYo混合侵染均表现免疫,而其它3株的病毒浓度也低于对照。这一结果将为利用RNA i干涉技术开展植物抗多种病毒病的育种提供重要依据,验证了所构建的RNA干涉(RNA interference RNA i)载体具有良好的功能,同时又一次证明微束激光穿刺法是一种有效的遗传转化手段。     

马铃薯S病毒外壳蛋白基因的克隆与原核表达

依据马铃薯S病毒 (PotatovirusS ,PVS)外壳蛋白 (CP)基因序列 (885bp)设计合成了两对引物 ,通过RT PCR扩增得到长 0 .8kb的目的片段 ,将目的片段转入大肠杆菌 ,酶切鉴定证明得到了含有目的片段的重组子 ,测定序列结果与其他PVS分离物CP基因的序列比较 ,发现其核苷酸同源性达 95 %左右 ;构建了含PVSCP基因的融合蛋白原核表达载体 ,并在大肠杆菌中得到表达 ,SDS PAGE测定融合蛋白的分子量为 5 8kD。     

马铃薯S病毒外壳蛋白基因的克隆与原核表达

依据马铃薯S病毒(Potato virus S,PVS)外壳蛋白(CP)基因序列(885bp)设计合成了两对 引物,通过RT-PCR扩增得到长0.8kb的目的片段,将目的片段转入大肠杆菌,酶切鉴定证明 得到了含有目的片段的重组子,测定序列结果与其他PVS分离物CP基因的序列比较,发现其核苷酸同源性达95%左右;构建了含PVS CP基因的融合蛋白原核表达载体,并在大肠杆菌中得到表达,SDS-PAGE测定融合蛋白的分子量为58kD.     

鹅细小病毒主要免疫原性蛋白基因的克隆与序列分析

利用PCR技术,从纯化鹅细小病毒SYG99-5毒株鹅胚尿囊液中扩增出病毒主要免疫原性蛋白基因.将该PCR扩增片段克隆入pGEMR-T质粒载体的HincⅡ和SacⅠ位点之间,酶切分析筛选并进一步通过Southern杂交验证后,获得含1.6kb基因片段的重组质粒GpG3.序列测定结果表明,该片段与国外已报道的GPV B株苷酸序列有96%的同源性,氨基酸序列有97%的同源性.     

乙型脑炎病毒结构蛋白C＋pre M和E基因的克隆与序列分析

目的对乙型脑炎病毒（Japanese encephalitis virus,JEV）结构蛋白基因进行扩增、克隆和序列测定。方法根据GenBank中发表的乙脑病毒结构蛋白基因C＋pre M基因和E序列,设计合成两对引物,以JEV Nakayama-NIH株RNA为模板,反转录并扩增目的cDNA,然后与pGEM-T easy载体连接并转化大肠杆菌DH5α菌株,提取的重组质粒用电泳、PCR和酶切鉴定后并进行测序。将JEV Nakayama-NIH与GenBank中报道的多株JEV结构蛋白C＋pre M基因和E基因序列进行了比较。结果Nakayama-NIH与其他参考株C＋pre M和E基因的核苷酸同源性为99%,证实扩增克隆的是JEV的结构蛋白C＋pre M和E基因。结论对JEV分子生物学特征进行了分析,为JEV特异性核酸探针的研制奠定了基础。     

辣椒温和斑点病毒(PMMV)外壳蛋白基因的克隆和序列测定

从本院分离的辣椒温和斑点病毒株系PMMV-QD中提取RNA.根据已有报道的外壳蛋白(CP)自行设计引物P1、P2,用RT-PCR扩增PMMV-QD的CP基因的cDNA,插入pMD 18-T载体,转化感受态受体菌XL1-B1ue,以蓝白菌落筛选转化株,用PCR检测白色菌落,确认获得了含cDNA的阳性重组子.序列测定和比较的结果表明该片段确含有PMMV的CP基因编码区,此种cDNA与国外报道的PMMV病毒株系核苷酸序列的同源性达到97.7%.     

Expression of Potato Virus Y Coat Protein Gene in Transgenic Potato

Potato virus Y (PVY) N coat protein (CP) coding sequence was cloned into a plant expression vector pMON316 under the CaMV 35S promoter. Leaf discs of potato (Solanum tuberosum) were used to Agrobacterium-mediated gene transfer. A large number of regenerated putative transgenic plants were obtained based on kanamycin resistance. Using total DNA purified from transgenic plants as templates and two oligonucleotides synthesized from 5' and 3' of the PVY coat protein gene as primers, the authors carried out polymerase chain reaction (PCR) to check the presence of this gene and obtained a 0. 8 kb specific DNA fragment after 35 cycles of amplification. Southern blot indicated that the PCR product was indeed PVY CP gene which had been integrated into the potato genome. Enzyme-linked immunosorbent assay (ELISA) of our transgenic plants showed that CP gene was expressed in at least some transgenic potato plants.     

采用液质联用方法检测黄秋葵荚果黄酮类物质含量

该研究为了培育兼抗4种病毒的马铃薯品种,采用RT￣PCR技术对PVX、PVS、PVY和PLRV的外壳蛋白( CP )基因进行克隆与分析,获得了大小分别为670、800、700、600 bp的CP基因序列,将获得的CP基因序列与NCBI中已报道的序列进行比对分析,其同源性都在96％以上。根据所克隆的CP 基因对靶标片段进行筛选,获得了大小约300 bp的靶标片段PVX￣rh、PVS￣rh、PVY￣rh和PLRV￣rh,同时利用 Overlap￣PCR技术将4种病毒的靶标片段进行拼接,得到了长度约为1200 bp的融合片段XSYV￣rh,与预期目标片段XSYV￣yxz的相似性达100％。利用DNA重组技术将融合片段XSYV￣rh克隆到pGM￣T载体上构建成克隆载体pGM￣T￣XSYV￣rh,用SpeⅠ和SacⅠ对克隆载体pGM￣T￣XSYV￣rh和植物表达载体pART27进行同步双酶切,用T4 DNA连接酶将XSYV￣rh片段连接到载体pART27上,成功构建了同时含4种病毒CP 基因片段的植物表达载体pART27￣XSYV￣rh。采用直接转化法将植物表达载体导入根癌农杆菌LBA4404中,并利用农杆菌介导法对烟草品种T12试管苗进行遗传转化,转化后的烟草植株经PCR检测,有40株转化植株可扩增出目的条带,表明XSYV￣rh融合基因已成功转入烟草基因组中。     

Effect of cDNA fragments in different length derived from Potato Virus Y coat protein gene on the induction of RNA-mediated virus resistance

Potato virus Y (PVY) is a main viral pathogen infecting economic crops such as potato and tobacco plants. Genetic engineering has been so far the most effective method to produce viral resistant plants. Be-cause of the shortage of viral resistant genes in plants, cDNAs derived from viral genes were often used for induction of resistance in transgenic plants (the so- called pathogen-derived resistance)[1]. Among the genes used in the pathogen-derived resistance strategy, the coat protein gen…     

Transgenic Potato with PVY Coat Protein Gene and Its Small-Scale Field Test

Potato virus Y (PVY) infection may cause a severe yield depression up to 80%. To develop the potato (Solanum tuberosum L. ) cultivars that resist PVY infection is very crucial in potato production. The authors have been cloned the coat protein gene of PVY from its Chinese isolate. A chimaeric gene containing the cauliflower mosaic virus 35S promoter and PVY coat protein coding region was introduced into the potato cultivars “Favorita”, “Tiger head” and “K4” via Agrobacterium tumefaciens. Results from PCR and Southern blot analysis confirmed that the foreign gene has integrated into the potato chromosomes. These transgenic potato plants were mechanically inoculated with PVY virus (20 mg/L). The presence of the virus in the potato plants was determined by ELISA and method of back inoculation into tobacco. The authors observed a drastic reduction in the accumulation of virus in some transgenic potato lines. Furthermore, some transgenic potato lines produced more tubers per plant than the untransformed potato did, and the average weight of these transgenic plant tubers was also increased. In the field test, the morphology and development of these transgenic potato plants were normal, 3 transgenic lines of “Favorita” exhibited a higher yield than the untrasformed virus-free potato with an increase ranged from 20% to 30%. From these transgenic lines, it will be very hopeful to develop a potato cultivar which not only has a significant resistance to PVY infection, but also a good harvest in potato production.     

Expression of the PVYO coat protein (CP) under the control of the PVX CP gene leader sequence: protection under greenhouse and field conditions against PVYO and PVYN infection in three potato cultivars

Coat protein-mediated resistance (CPMR), resistance conferred as a result of the expression of viral coat proteins in transgenic plants, has been illustrated to be an effective way of protecting plants against several plant viruses. Nonetheless, consistent protection has not been achieved for transgenic plants expressing the coat protein of potato virus Y (PVY), the type member of the potyvirus family. In this report, three different potato cultivars were transformed with a chimeric construct consisting of the capsid protein (CP) coding sequences of PVY flanked by the AUG codon and the translational enhancer from the coat protein gene of potato virus X (PVX). These cultivars were shown to express high levels of PVY CP and confer a high degree of protection against PVY^o and PVY^N under both greenhouse and field conditions. In addition, transgenic plants infected with potato virus A (PVA), a related potyvirus, exhibited a delay in virus accumulation, which could be easily overcome with increasing virus concentrations. Received: 26 October 1995 / Accepted: 14 June 1996     

Potato virus Y mRNA expression knockdown mediated by siRNAs in cultured mammalian cell line

RNA interference (RNAi) is a powerful tool for functional gene analysis which has been successfully used to downregulate the expression levels of target genes. The goal of this research was to provide a highly robust and concise methodology for in-vitro screening of efficient siRNAs from a bulk to be used as a tool to protect potato plants against PVY invasion. In our study, a 480bp fragment of the capsid protein gene of potato virus Y (CP-PVY) was used as a target to downregulate PVY mRNA expression in-vitro, as the CP gene interferes with viral uncoating, translation and replication. A total of six siRNAs were designed and screened through transient transfection assay and knockdown in expression of CP-PVY mRNA was calculated in CHO-k cells. CP-PVY mRNA knockdown efficiency was analyzed by RT-PCR and real-time PCR of CHO-k cells co-transfected with a CP gene construct and siRNAs. Six biological replicates were performed in this study. In our findings, one CP gene specific siRNA out of a total of six was found to be the most effective for knockdown of CP-PVY mRNA in transfected CHO-k cells by up to 80%–90%.     

Small-scale field tests with transgenic potato,cv. Bintje,to test resistance to primary and secondary infections with potato virus y

The coat protein (CP) gene of the potato virus Y (PVY) strain N605 has been cloned into a plant binary expression vector and introduced into the potato variety Bintje. The transformed lines, Bt6, that contained two copies of the CP gene showed complete resistance to the homologous strain PVY-N605 and a good resistance to the related strain PVY-O803 in the greenhouse. The good resistance of Bt6 to primary and secondary infections by PVY was confirmed in two successive field tests where the virus was transmitted by its natural aphid vector.