Production of Polyclonal Antibodies to the Recombinant Potato virus M (PVM) Non‐structural Triple Gene Block Protein 1 and Coat Protein

The genes encoding the coat protein (CP) and triple gene block protein 1 (TGBp1) of Potato virus M (PVM) were cloned into expression vector pET‐45b(+) (N‐terminal 6xHis tag) and expressed in E. coli Rosetta gami‐2(DE3). The purified recombinant antigens were used for raising polyclonal antibodies. The antibodies against recombinant CP were successfully used in Western blot analysis, plate‐trapped ELISA and DAS‐ELISA as a coating for PVM detection in infected potato leaf samples. The antibodies against recombinant non‐structural protein detected the TGBp1 only in Western blot analysis. This is the first report of the production of polyclonal antibodies against recombinant coat protein and TGBp1 of PVM and their use for detecting the virus.     

Expression of Coat Protein of an Ordinary Strain of Potato virus Y in Escherichia coli and Production of Polyclonal Antibodies for Diagnosis

The coat protein gene (CP) of an ordinary strain of Potato virus Y (PVY^O) was cloned into the expression vector, pET‐28a(+). The insert was sequenced and analysis showed that the CP gene was in frame with intact N‐terminal 6X histidine tags. An approximately 35 kDa recombinant fusion protein was observed in inclusion bodies of induced Escherichia coli BL21 cells. This fusion protein was purified and used as antigen to raise polyclonal antibodies in rabbits. In Western blot and dot blot immuno‐binding assay (DIBA), both PVY^O‐CP IgG and PVY^O IgG strongly reacted with the recombinant CP. The PVY^O‐CP IgG could detect PVY^O in infected samples up to 1 : 3200 dilutions. A PVY^O‐CP ELISA kit was prepared and compared with conventional ELISA kit based on purified virus particles (PVY^O ELISA kit). The PVY^O‐CP ELISA kit consistently detected the PVY^O in DAS‐ELISA of field samples and was as effective as PVY^O ELISA kit.     

Production of Polyclonal Antibodies to the Recombinant Coat Protein of Citrus tristeza virus and their Effectiveness for Virus Detection

Citrus tristeza virus (CTV) is distributed worldwide and causes the most economically important virus diseases of citrus. Enzyme‐linked immunosorbent assay (ELISA) and/or immunoprinting have become an indispensable tools for large‐scale diagnosis of CTV worldwide. Several CTV detection kits are commercially available, based on either polyclonal or monoclonal antibodies developed against purified virus preparations. We have developed polyclonal antibodies to recombinant p25 CTV coat proteins (rCP) and determined their effectiveness for both trapping and as the intermediate antibody in double‐antibody sandwich indirect (DASI) ELISA. The p25 coat protein gene of three CTV isolates was amplified by RT‐PCR and further cloned and expressed in Escherichia coli cells. The rCP was injected into rabbits and goats for antibody production. Western blotting assays with the rCP CTV‐specific antibodies reacted positively with the homologous and heterologous rCP of the three CTV isolates and with the corresponding native coat protein present in crude sap extracts of CTV‐infected citrus tissue, but not with extracts from healthy tissue. The rCP antibodies from goat and rabbit reacted as both plate trapping and intermediate antibodies in DASI‐ELISA, discriminating healthy and CTV‐infected citrus, with optical density (OD₄₀₅) values in the range of 0.151–2.415 for CTV‐infected samples and less than 0.100 for healthy tissue. Commercially available anti‐CTV antibodies were used as a reference. Previous reports indicate that antibodies developed to recombinant antigens, including those of CTV, may not be functional for trapping the target antigens under non‐denaturing conditions. Our results showed the feasibility of CTV antibodies developed to the rCP for use as both trapping and intermediate antibodies in DASI‐ELISA, when the recombinant antigen was fractioned with polyacrylamide electrophoresis gel and further extensively dialysed against phosphate buffer saline prior to its use as immunogen.     

Production of Antiserum to Recombinant Coat Protein for Detecting Lily mottle virus in Yunnan, China

Lily mottle virus (LMoV), Potyvirus genus, is very difficult to purify for the preparation of diagnostic antisera. The coat protein (CP) gene of LMoV was amplified by RT-PCR from infected plants and cloned into the prokaryotic pET-30a vector to generate the recombinant plasmid pET-CP. The resulting carboxy-terminal His-tagged CP was over-expressed in Escherichia coli BL 21 cells by Isopropyl-β- d -thiogalactoside (IPTG) induction and purified over Ni-NTA affinity columns. The purified CP was used to elicit a polyclonal antiserum in rabbits. The antiserum had a titre of 1 : 128 in double diffusion tests, and specifically recognized LMoV in Western blots, Enzyme-Linked Immunosorbent Assays and Immuno-Electron Microscopy. The CP antiserum was also used to evaluate LMoV infection of lily bulbs used for commercial production in Yunnan, China. Substantial levels of infection were found in both imported and native bulbs, and provide the basis to implement flexible, rapid and large-scale virus indexing of lily plants for use in propagation and to meet virus-free quarantine regulations.     

Detection,distribution and control of Potato mop-top virus,a soil-borne virus,in northern Europe

Potato mop-top virus (PMTV; genus Pomovirus; family Virgaviridae) is transmitted by the soil-borne Spongospora subterranea f.sp. subterranea, a protoctist that causes powdery scab on potato. PMTV is distributed widely in the potato growing areas in South and North America, Japan and northwestern Europe. This article reviews the current knowledge on detection, distribution and control of PMTV with focus on the Baltic Sea region. Since the 1980s, PMTV has caused great economic losses to potato production in the Nordic countries (Norway, Sweden, Denmark and Finland), but its occurrence in other countries of the Baltic Sea region remained unknown. To fill this knowledge gap, harmonised sampling and virus detection procedures including bioassays and serological and molecular methods were employed by 21 research institutions to detect PMTV in potato tubers and soil samples in 2005–2008. Potato growing areas were widely contaminated with PMTV in the Nordic countries. Only the main seed potato production area in northern Sweden and the High Grade seed potato production zone in Finland were negative for PMTV. Intensive and systematic surveys in Poland in 2004–2008 found no evidence of PMTV, except a single PMTV-infected tuber detected in 2008. Surveys in the Baltic countries (Lithuania, Latvia and Estonia) and northwestern Russia (Leningrad province) were negative for PMTV, except infection of minitubers in a screenhouse in Latvia in 2005. Varying percentages of tubers expressing spraing symptoms in Sweden, Norway, Denmark and Poland were infected with Tobacco rattle virus, and bioassays indicated similar results for Russia. Incidence of symptomless infections with PMTV was high in tubers of many potato cultivars. Here, we discuss the contrasting patterns of distribution of PMTV in the Baltic Sea region, factors playing a role in dispersal and establishment of PMTV in new fields and means for controlling PMTV and its spread to new areas. We emphasise the use of the current virus-specific methods for the detection of PMTV in symptomless potato tubers and the high risks of disseminating PMTV to new fields and areas in viruliferous resting spores of S. subterranea in the soil adhering to seed tubers. PMTV-resistant potato cultivars will provide the only sustainable means for preventing yield losses in the infested fields and the prospects of resistance breeding are summarised.     

重组蛋白在大肠杆菌周间腔的分泌表达

大肠杆菌是用于生产重组蛋白的重要工程宿主菌。但是,要获得足够的正确折叠的蛋白还存在一定的缺陷,其中一种解决此问题的方法就是使重组蛋白分泌到大肠杆菌的周间腔里。在这篇综述中,主要讨论了使重组蛋白分泌表达至大肠杆菌周间腔的近期的研究进展。     

Complete Nucleotide Sequence of the RNA 3 of Bacopa chlorosis virus and Production of Polyclonal Antibodies to a Recombinant Coat Protein

The complete sequence of the RNA 3 of a virus causing chlorosis in Impatiens in Germany was determined and identified as an isolate of Bacopa chlorosis virus (BaCV, genus Ilarvirus). BaCV has previously only been reported from bacopa in the USA, but no coat protein (CP) sequence has been previously available. Both RNA 3 encoded proteins, CP and movement protein, showed highest sequence identity to Parietaria mottle virus, a subgroup 1 ilarvirus. Attempts to purify BaCV failed, so an antiserum was raised against a recombinant CP. The polyclonal antiserum so produced allowed specific detection of BaCV but showed no serological cross‐reaction with other ilarviruses and was unsuitable for immunoelectron microscopy. The host range includes many important flowering plant species, highlighting the potential threat BaCV might pose for the horticultural industry. This is the first report of BaCV occurring in Germany and outside the US.     

Molecular Analysis of the Coat Protein of Potato virus Y Isolates in Greece Suggests Multiple Introduction from Different Genetic Pools

The phylogenetic relationships among Potato virus Y (PVY) isolates from northern and southern Greece were investigated. A large part of coat protein gene of 49 tobacco isolates and three from pepper was examined. The analysis showed that all 52 isolates consisted of 34 distinct haplotypes, with only one haplotype found in both northern and southern regions. The southern population was more diverse than that from the north. The phylogenetic analyses of the Greek haplotypes alone or in combination with isolates from other countries using the maximum likelihood method classified unambiguously almost all the haplotypes examined. Nine tobacco haplotypes from the south were classified as C‐like (particularly C1), whereas 22 haplotypes from tobacco and two from pepper from both north and south were classified as N‐like. One tobacco haplotype from the south was found recombinant between N‐like and C1 lineages. The pattern of molecular evolution was examined using the fixed‐effects likelihood and the single‐likelihood ancestor counting methods. The analysis indicated that the evolution of PVY isolates appeared to be conservative (purifying selection and neutral evolution). These findings are discussed in relation to the introduction of PVY in the tobacco crop in Greece and the between region dispersal. A scenario of multiple introductions of PVY isolates in north and south Greece from different genetic pools and low or nil between region spread of the virus isolates was proposed.     

马铃薯单双三价抗病毒基因表达载体的构建

马铃薯Y病毒(PVY)、X病毒(PVX)和卷叶病毒(PLRV)引起的病害是造成我国马铃薯退化的主要原因,严重危害我国的马铃薯生产。PVY和PVX或PVY和PLRV混合侵染带来的损失远远大于各病毒单独侵染。国外科学家通过在马铃薯植株体内表达病毒外壳蛋白(CP)基因来减缓病毒病害的发生已取得相当的成功。 我们从河北省坝上地区农科所试验田中采集PLRV感病材料Burbank及87-1,参照文献提取病毒RNA并以其为模板,反转录合成cDNA。根据PLRV澳大利亚分离物已发表的序列,设计并     

Polyclonal Antibodies to the Bacterially Expressed Coat Protein of Faba Bean Necrotic Yellows Virus

Specific rabbit polyclonal antibodies against bacterially expressed coat protein of Faba bean necrotic yellows virus (FBNYV, genus Nanovirus) were produced using a recombinant DNA approach. The FBNYV capsid protein (CP) gene located on component 5 was cloned in an expression vector pQE‐9 (Qiagen, QIAGEN Inc., Chatswortch, CA91311, USA). Expression of the CP with an N‐terminal hexahistidine tag in Escheri‐ chia coli M15 cells was induced by adding isopropyl‐3‐D ‐1‐thiogalactoside (IPTG) to a final concentration of 2 mM . About 8 mg of bacterially expressed CP (BE‐CP) was purified from 1 litre of bacterial liquid culture using a Ni‐NTA resin column (Qiagen). The expressed CP which migrated as a protein of approximately 23 kDa in sodium dodecyl sulphate (SDS)‐polyacrylamide gel electrophoresis (PAGE) was identified by its strong reaction with polyclonal antibodies produced against FBNYV particles and 2‐5H9 FBNYV‐monoclonal in Western blots. Expressed and purified CP (SDS‐PAGE 23 kDa band) was injected into a white rabbit, using seven intramuscular injections at weekly intervals. The antiserum produced was evaluated for FBNYV detection in double antibody sandwich (DAS)‐enzyme‐linked immunosorbent assay (ELISA), triple antibody sandwich (TAS)‐ELISA, tissue blot immunoassay (TBIA), dot blot, Western blot and goat antimouse coating (GAMC)‐ELISA using 13 different FBNYV monoclonal antibodies. The antiserum raised against the BE‐CP gave strong FBNYV‐specific TBIA reactions and very weak background reactions with non‐infected tissue, similar to those produced by monoclonal antibodies. Furthermore, BE‐CP polyclonal antibody reacted weakly with FBNYV‐infected tissue and strongly with BE‐CP in DAS‐ELISA, but not with FBNYV‐infected tissue in TAS‐ELISA when 13 detecting monoclonal antibodies were used. In addition, BE‐CP polyclonal antibody reacted strongly with BE‐CP in TAS‐ELISA only when 2‐5H9 detecting monoclonal was used. When monoclonals were used as primary antibody and BE‐CP polyclonal as detecting antibody (GAMC‐ELISA), FBNYV‐infected tissue gave moderate reactions with 2‐5H9 and strong reactions with 3‐2E9 monoclonal, whereas BE‐CP gave equally strong reactions with both monoclonals. These results showed that the BE‐CP polyclonal antibody is useful for the detection of FBNYV in infected tissue by TBIA and dot blot tests.     

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.     

Expression of Recombinant Potato leafroll virus Structural and Non‐structural Proteins for Antibody Production

Vector pMPM‐A4Ω and vectors pQE‐30 and pET‐45b(+) containing the 6x His‐tag sequence were used for expression of Potato leafroll virus (PLRV) structural and non‐structural proteins in Escherichia coli. Coat protein (CP) and RNA‐dependent RNA polymerase (RdRp)–fragments RdRp_43‐616 and RdRp_304‐537 were chosen for expression. A high level of CP and RdRp_304‐537 was obtained only in an expression system using pET‐45b(+) vector and E. coli Rosetta‐gami 2(DE3) cells. After purification, the His‐tagged PLRV proteins were used for immunization of rabbits.     

重组甘蔗花叶病毒E株系外壳蛋白的纯化及其多克隆抗体制备

目的：制备可用于甘蔗花叶病毒（ScMV）E株系（ScMV-E）检测用多克隆抗体。方法：将ScMV-E外壳蛋白（CP）基因连接到pET29a（＋）上,经PCR检测、酶切及测序鉴定获得重组质粒pET29a-CP,在大肠杆菌BL21（DE3）中诱导表达重组ScMV-E外壳蛋白;采用His Trap Kit纯化目的蛋白,作为抗原免疫新西兰大白兔,制备特异性抗体;通过间接ELISA、Western blot和组织印迹法检测所制备抗体的特异性。结果：SDS-PAGE分析表明,重组融合蛋白含6个组氨酸标记,相对分子质量约43000;Western blot检测显示所获得的抗体特异性良好,间接ELISA法测得血清的效价为1：81 920;甘蔗叶片的组织印迹检测结果显示杂交效果良好。结论：制备的多克隆抗体可直接用于ScMV-E检测,并有望用于制备ScMV-E检测试剂盒。     

Production of Polyclonal Antibodies Using Recombinant Coat Protein of Papaya ringspot virus and their Use in Immunodiagnosis

Production of polyclonal antibodies requires large amount of purified virus that can be avoided by the use of recombinant coat protein (CP). Recombinant CP of Papaya ringspot virus (PRSV) was thus used for the production of polyclonal antibodies as the virus purification from papaya tissues provides low virus yields. CP was expressed as a fusion protein (～72 kD) containing a fragment of E. coli maltose binding protein. Polyclonal antibodies from rabbits immunized with the fusion protein, successfully detected natural infection of PRSV in papaya and cucurbits samples collected from different locations at 1:4000 dilution in direct antigen-coated enzyme-linked immunosorbent assay.     

Polyclonal Antibodies to the Coat Protein of Carnation etched ring virus Expressed in Bacterial System: Production and Use in Immunodiagnosis†

Carnation etched ring virus (CERV), is the most widespread virus in carnation cultivars after Carnation mottle virus. It's incidences has been reported worldwide. It has double stranded DNA genome with the length of ∼8 kbp. Primers were designed for CERV coat protein gene (1482 bp) amplification and directional and inframe cloning in expression vector, pET‐28a(+) (Novagen, USA), using Escherichia coli strain BL 21 strain competent cells. Expression conditions for maximum recovery of soluble recombinant protein was standardized. The in vitro expressed protein was purified and was used as an antigen for raising antisera. Both intramuscular and sub‐cutaneous routes were used separately for antisera production and the antisera was purified. Some of the antisera was used for enzyme conjugate preparation. This antiserum and conjugate were then used for formulation of an ELISA‐based diagnostic kit for CERV detection. Its properties were compared with the commercially available kit. In all cases, with both glasshouse and field material, the antibodies had good detectability and specificity. These antibodies combine specificity to the target protein and versatility with regard to all the more important serological techniques.     

Detection and molecular characterisation of Potato virus S of weed reservoirs in Iran

Potato virus S causes destructive disease on the plants. In this research, 44 weed samples symptomless were collected during 2015 from Fars, Razavi Khorasan and Kerman provinces of Iran. The coat protein (CP) and 11 K genes from eight PVS isolates were amplified, cloned and sequenced. PVS was detected in eight weed samples including: one sample of Solanum nigrum, two samples of Chenopodium botrytis, three samples of Chenopodium album and two samples of Amaranthus hybridus. Phylogenetic analysis showed that seven Iranian isolates fell into group I, II near to European isolates and one Iranian isolate formed a separate group. Comparison of coat protein and 11 k nucleotide indicated that all Iranian isolates belonged to Ordinary strain and there were 79–100% identity among the eight Iranian isolates and the world isolates of PVS. The highest identity was between Iranian and Ukraine isolates. Recombination analysis identified four recombinant isolates among eight new Iranian isolates.