番木瓜环斑病毒株系,分子生物学及其防治研究进展

番木瓜环斑病毒株系、分子生物学及其防治研究进展肖火根，范怀忠（华南农业大学植物病毒研究室，广州５１０６４２）ＡｄｖａｎｃｅｓｏｆＲｅｓｅａｒｃｈｏｎｔｈｅＳｔｒａｉｎｓ，ＭｏｌｅｃｕｌａｒＢｉｏｌｏｇｙａｎｄＣｏｎｔｒｏｌｏｆＰａｐａｙａＲｉｎｇｓｐ...     

番木瓜环斑病毒弱株系保护作用的研究

本文报道了在番木瓜环斑病毒（ＰＲＶ）弱株系保护作用中,保护接种与攻击接种的深度,以及攻击接种的部位等因素对ＨＡ５－１弱株系保护作用效果的影响结果。通过分析弱株系和强株系在保护接种后攻毒的植株体内的病毒浓度,表明ＨＡ５－１弱株系对Ｓｍ株系的保护作用的崩溃是由于强株系在植株顶端叶片听病毒浓度越来越高所致。本文还就ＰＲＶ弱株系在田间的应用技术作了一些讨论。     

菲对转基因番木瓜进行大田种植试验

AgBiotech Reporter2005年22卷3期17页报道：已知环斑病毒是多年来美国夏威夷州番木瓜种植业减产的严重病害。近据菲律宾的非赢利机构菲律宾生物技术联合会（BCP）主席BienvenidoPecson博士宣称,为防止环斑病毒对番木瓜的危害,菲律宾正在培育可有效地抵抗环斑病毒的新的转基因番木瓜品种,并批准对其进行大田种植试验。此外,菲律宾农业、林业和天然资源研究和开发委员会（PCARRD）的科学家已对上述品种的基因进了鉴定。     

几种化学制剂对番木瓜抗环斑病毒和防御酶活性的影响

研究几种化学制剂对番木瓜抗环斑病毒和叶片中防御酶活性影响的结果表明,接种番木瓜环斑病毒后,植株叶中多酚氧化酶（PPO）、超氧化物歧化酶（SOD）和过氧化物酶（POD）的活性均明显升高,其中PPO和POD总体的升高幅度大,SOD的总体升幅较小;病毒必克的升幅较大,83增抗剂和水杨酸的升幅较小。83增抗剂、水杨酸和病毒必克均能使番木瓜叶中PPO、SOD和POD活性持续升高,有效减轻了环斑病的病情,防治效果依次为83增抗剂〉水杨酸〉病毒必克。     

齿兰环斑病毒外壳蛋白基因克隆及序列分析

齿兰环斑病毒外壳蛋白基因克隆及序列分析刘志昕潘俊松邵寒霜郑学勤（中国热带农业科学院热带作物生物技术国家重点实验室,海南儋州５７１７３７）关键词齿兰环斑病毒,外壳蛋白基因,序列分析兰花受病毒危害相当严重,齿兰环斑病毒（Ｏｄｏｎｔｏｇｌｏｓｕｍｒｉｎｇｓ...     

番木瓜环斑病毒单克隆抗体的制备及在病毒分型上的初步应用

本试验是用番木瓜环斑病毒(Papaya ringspot virus, PRV)提纯制剂免疫的BALB/c小白鼠脾细胞与Sp~2/o-Ag14骨髓瘤细胞融合,获得三个能稳定传代并分泌抗番木瓜环斑病毒的单克隆抗体的杂交瘤细胞系。其中23H1 McAb的效价较高,用ELISA检测,腹水抗体效价高达1:76800,能被PRV兔抗血清所阻断。这3个杂交瘤细胞系产生的单抗与TMV和CMV无血清交叉反应。它们可把PRV四个毒株初步区分为三个血清型。     

dsRNA介导的番木瓜环斑病毒（PRSV）的抗病性研究

以模式植物拟南芥（Arabidopsis thaliana）和烟草（Nicotiana tabacum）及PRSV寄主植物番木瓜（CaricapapayaL.）作为试验材料,开展了番木瓜环斑病毒外壳蛋白基因dsRNA介导的PRSV病原抗性的研究。利用农杆菌介导法将番木瓜环斑病毒外壳蛋白CP基因反向重复表达载体pHellsgate12-CPIR（简称PHG12-CPIR）分别转化到烟草和拟南芥中,获得阳性植株,并利用渗透法和农杆菌介导的瞬时表达体系将pHG12-CPIR载体导入到番木瓜中。对转基因植株进行攻毒试验并分析了其抗病性。在接种3~7d内,在拟南芥和番木瓜上转基因植株的发病情况较轻,而野生型植株叶片与转基因植株相比,均表现出不同程度的黄化、皱缩和枯斑等症状。在接种PRSV后,番木瓜和拟南芥转化植株表现症状的叶片的比例与对照相比,结果显著低于对照,而在烟草植株上症状表现的差异不明显。在3种植物上RT-PCR检测结果显示,在接种番木瓜环斑病毒PRSV后,野生型植株中有高浓度的病毒积累,而转pHG12-CPIR基因植株中几乎没有病毒积累,推测转pHG12-CPIR基因植株中瞬时表达系统已启动RNAi机制抑制了CP基因的表达。     

花粉管通道法介导PRSV-CP基因dsRNA转化番木瓜

以番木瓜‘蔬罗Ⅰ号’植株为受体材料,采用花粉管通道技术将番木瓜环斑病毒外壳蛋白(PRSV-CP)基因3′-端同源序列dsRNA转入番木瓜子房中。用PCR方法对T0代种子进行了分子检测,获得53株转基因番木瓜,转化率达到8.9%;对获得的T0代转基因番木瓜进行了田间抗病性鉴定,结果表明,转基因番木瓜植株对番木瓜环斑病毒(PRSV)表现为不同程度的抗性,可以推迟发病。     

宁夏甜菜的烟草环斑病毒的鉴定

从宁夏患丛根病甜菜的病根中分离到一种球状病毒粒子,直径约为２８ｎｍ。提纯病毒的紫外扫描呈典型的核蛋白曲线,最大吸收为２６０ｎｍ,最小吸收为２４０ｎｍ,Ａ＿（２６０）／Ａ＿（２８０）＝１．３０。寄主范围广,能侵染茄科、豆科、藜科、葫芦科、番杏科等１７种植物。病毒的ＴＤＰ为６５℃,ＤＥＰ为１０￣（－３）,体外存活期６－７天。有较强的免疫原性。病毒的抗血清与烟草环斑病毒（ＴＲＳＶ）之间产生明显的沉淀线。经初步鉴定认为该分离物是烟草环斑病毒。     

植物组织粗汁液中的番木瓜环斑病毒的ELISA检测技术

本研究建立和改进了检测番木瓜和西葫芦组织粗汁液里的番木瓜环斑病毒（ＰＲＶ）的ＤＡＣ－ＥＬＩＳＡ法和Ｄｏｔ－ＥＬＩＳＡ法。用不同的ＥＬＩＳＡ方法来检测不同寄主植物粗汁液里的ＰＲＶ,其所用的合适的制备粗汁液的缓冲液是不同的。用ＤＡＣ－ＥＬＩＳＡ法检测西葫芦粗汁液时,以０．５ｍｏｌ／Ｌ磷酸盐缓冲液（ｐＨ７．５,内含０．１ｍｏｌ／Ｌ乙二胺四乙酸二钠）为宜;而检测番木瓜粗汁液时,则还要加入０．２５ｍｏｌ／Ｌ脲。用Ｄｏｔ－ＥＬＩＳＡ法检测时,在上述磷酸盐缓冲液中加入２％聚乙烯吡咯烷铜能提高对西葫芦粗汁液的检测效果。应用合适的制备粗汁液的缓冲液,ＤＡＣ－ＥＬＩＳＡ法和Ｄｏｔ－ＥＬＩＳＡ法的灵敏度分别提高到１／４０９６和１／１０２４（稀释度）。本研究还表明,影响ＤＡＣ－ＥＬＩＳＡ法的定过测定的主要因素是粗汁液的稀释度和包被液（０．０５ｍｏｌ／Ｌ碳酸盐缓冲液,ｐＨ９．６）的用过。在较高粗汁液稀释度和包被液的用量相同时,粗汁液里的病毒含量与ＤＡＣ－ＥＬＩＳＡ法的ＯＤ４９２ｎｍ值呈真实的线性关系。     

共表达PCV2 ORF2和猪IL-18基因的重组猪伪狂犬病毒对小鼠的免疫原性

【目的】研制猪伪狂犬病毒(PRV)和猪圆环病毒2型(PCV2)的二联活疫苗,并用猪IL-18作为免疫佐剂。【方法】将猪IL-18基因插入到质粒p GO中,获得的重组转移质粒p GO18与猪PRV弱毒HB98株DNA共转染ST细胞,并进行空斑筛选和纯化;RT-PCR和Western blot分别从转录和蛋白水平鉴定其表达情况。将重组病毒PGO18和PGO、PRV弱毒株HB98、PCV2灭活商品苗和1640细胞培养基分别免疫6周龄雌性昆明小鼠,4周后二次免疫,二免后4周用PCV2 DF强毒和PRV Min/A强毒接种小鼠。通过ELISA、血清中和试验和流式细胞术及攻毒保护试验评价重组病毒的免疫原性。【结果】获得了重组病毒PGO18,并且可在ST细胞内表达;PGO18可诱导小鼠机体产生PCV2的ELISA和PRV的中和抗体水平,刺激CD3+、CD4+、CD8+T细胞亚群的增殖,且能有效抵抗PCV2和PRV强毒攻击。【结论】IL-18基因可增强重组病毒的免疫效果,使重组病毒具有良好的免疫原性,有望成为防治PCV2和PRV的候选疫苗株。     

猪伪狂犬病毒浙江株感染性细菌人工染色体克隆的构建

通过同源重组将携带细菌人工染色体(Bacterial Artificial Chromosome,BAC)载体和GFP表达框的pHA2质粒序列插入到PRV病毒的UL23(TK)基因内,获得了重组病毒rPRV-HA2;将该重组病毒的环状基因组电转化到感受态细胞EscherichiacoliDH10B,筛选到病毒的感染性克隆PRV BAC(pPRV)。pPRV转染VeroE6细胞可以重新启动病毒的生产性感染,该拯救病毒的细胞病变和体外增殖特性与rPRV-HA2一致。病毒生长曲线表明TK基因的部分删除和BAC载体的插入不会影响病毒在体外的复制。PRV感染性BAC克隆的成功构建,将方便在大肠杆菌内对病毒基因组进行快速、准确的操作,为进一步开展PRV基因功能和病毒载体研究奠定基础。     

A novel recombinant pseudorabies virus expressing parvovirus VP2 gene: Immunogenicity and protective efficacy in swine

Background

Porcine parvovirus (PPV) VP2 gene has been successfully expressed in many expression systems resulting in self-assembly of virus-like particles (VLPs) with similar morphology to the native capsid. Here, a pseudorabies virus (PRV) system was adopted to express the PPV VP2 gene.

Methods

A recombinant PRV SA215/VP2 was obtained by homologous recombination between the vector PRV viral DNA and a transfer plasmid. Then recombinant virus was purified with plaque purification, and its identity confirmed by PCR amplification, Western blot and indirect immunofluorescence (IFA) analyses. Electronic microscopy of PRV SA215/VP2 confirmed self-assembly of both pseudorabies virus and VLPs from VP2 protein.

Results

Immunization of piglets with recombinant virus elicited PRV-specific and PPV-specific humoral immune responses and provided complete protection against a lethal dose of PRV challenges. Gilts immunized with recombinant viruses induced PPV-specific antibodies, and significantly reduced the mortality rate of (1 of 28) following virulent PPV challenge compared with the control (7 of 31). Furthermore, PPV virus DNA was not detected in the fetuses of recombinant virus immunized gilts.

Conclusions

In this study, a recombinant PRV SA215/VP2 virus expressing PPV VP2 protein was constructed using PRV SA215 vector. The safety, immunogenicity, and protective efficacy of the recombinant virus were demonstrated in piglets and primiparous gilts. This recombinant PRV SA215/VP2 represents a suitable candidate for the development of a bivalent vaccine against both PRV and PPV infection.

     

A recombinant pseudorabies virus co-expressing capsid proteins precursor P1-2A of FMDV and VP2 protein of porcine parvovirus: a trivalent vaccine candidate

Pseudorabies (PR), foot-and-mouth disease (FMD), and porcine parvovirus disease are three important infectious diseases in swine worldwide. The gene-deleted pseudorabies virus (PRV) has been used as a live-viral vector to develop multivalent genetic engineering vaccine. In this study, a recombinant PRV, which could co-express protein precursor P1-2A of FMDV and VP2 protein of PPV, was constructed using PRV TK⁻/gE⁻/LacZ⁺ mutant as the vector. After homologous recombination and plaque purification, recombinant virus PRV TK⁻/gE⁻/P1-2A-VP2 was acquired and identified. Immunogenicity, safety of the recombinant PRV and its protection against PRV were confirmed in a mouse model by indirect ELISA and serum neutralization test. The results show that the recombinant PRV is a candidate vaccine strain to develop a novel trivalent vaccine against PRV, FMDV and PPV in swine.     

2018−2019年四川省伪狂犬病毒的流行病学调查及gC、gE、TK基因遗传进化分析

【背景】伪狂犬病毒(pseudorabies virus,PRV)是养猪生产中的一类重要病原,自2011年以来,我国接种了Bartha-K61疫苗的养殖场暴发了大规模的伪狂犬病疫情。【目的】调查目前四川省PRV的流行病学以及毒株的遗传进化,对2018?2019年从86个猪场收集的384份疑似PRV感染样本进行病原学检测。【方法】根据PRV-gE基因检测引物对采集的384份样品进行PCR扩增,并对不同季节、不同地区的PRV阳性率进行统计,将PRV感染与临床症状的相关性进行统计学分析。选择部分PRV阳性样本在BHK-21细胞上进行病毒的分离,随后进行分离毒株的gC、gE、TK基因的遗传进化分析。【结果】PRV阳性猪只的比率为9.9% (38/384);阳性猪场比率为16.3% (14/86);流产母猪的PRV阳性率为32.1% (27/84);种公猪阳性率为2.0% (4/198);神经症状猪的PRV阳性率为11.4% (4/35);呼吸症状猪的PRV阳性率为4.5% (3/67)。统计学分析表明,PRV感染与母猪和公猪繁殖障碍症状相关(P<0.01)。其中,冬季(12月、1月、2月) PRV阳性率最高,约为33.0% (31/94);春季(3月、4月、5月)的阳性率为9.1% (3/33);夏季和秋季的阳性率分别约为1.5% (2/130)和1.6% (2/127)。在2018?2019年共分离出3株PRV毒株,分别命名为PRV-SN、PRV-DJY、PRV-CD。PRV-XJ为本实验室2016年在四川省分离的一株毒株,为了了解毒株的遗传进化信息,先后扩增了这4个毒株的gC、gE、TK基因。序列比对表明四川分离株与国内株相似,存在额外的零星性突变和缺失。【结论】养殖场仍应加强对种猪群中伪狂犬病的净化。     

The murine homolog (Mph) of human herpesvirus entry protein B (HveB) mediates entry of pseudorabies virus but not herpes simplex virus types 1 and 2

A mouse member of the immunoglobulin superfamily, originally designated the murine poliovirus receptor homolog (Mph), was found to be a receptor for the porcine alphaherpesvirus pseudorabies virus (PRV). This mouse protein, designated here murine herpesvirus entry protein B (mHveB), is most similar to one of three related human alphaherpesvirus receptors, the one designated HveB and also known as poliovirus receptor-related protein 2. Hamster cells resistant to PRV entry became susceptible upon expression of a cDNA encoding mHveB. Anti-mHveB antibody and a soluble protein composed of the mHveB ectodomain inhibited mHveB-dependent PRV entry. Expression of mHveB mRNA was detected in a variety of mouse cell lines, but anti-mHveB antibody inhibited PRV infection in only a subset of these cell lines, indicating that mHveB is the principal mediator of PRV entry into some mouse cell types but not others. Coexpression of mHveB with PRV gD, but not herpes simplex virus type 1 (HSV-1) gD, inhibited entry activity, suggesting that PRV gD may interact directly with mHveB as a ligand that can cause interference. By analogy with HSV-1, envelope-associated PRV gD probably also interacts directly with mHveB during viral entry.     

The IE180 protein of pseudorabies virus suppresses phosphorylation of translation initiation factor eIF2α

We have previously shown that the porcine alphaherpesvirus pseudorabies virus (PRV) efficiently interferes with phosphorylation of the eukaryotic translation initiation factor eIF2α. Inhibition of phosphorylation of eIF2α has been reported earlier for the closely related alphaherpesvirus herpes simplex virus 1 (HSV-1) through its ICP34.5 and US11 proteins. PRV, however, does not encode an ICP34.5 or US11 orthologue. Assays using cycloheximide, UV-inactivated PRV, or phosphonoacetic acid (PAA) showed that de novo expression of one or more (immediate) early viral protein(s) is required for interference with eIF2α phosphorylation. In line with this, a time course assay showed that eIF2α phosphorylation was abolished within 2 h after PRV inoculation. PRV encodes only one immediate-early protein, IE180, the orthologue of HSV-1 ICP4. As reported earlier, a combinational treatment of cells with cycloheximide and actinomycin D allowed expression of IE180 without detectable expression of the US3 early protein in PRV-infected cells. This led to a substantial reduction in eIF2α phosphorylation levels, indicative for an involvement of IE180. In support of this, transfection of IE180 also potently reduced eIF2α phosphorylation. IE180-mediated interference with eIF2α phosphorylation was not cell type dependent, as it occurred both in rat neuronal 50B11 cells and in swine testicle cells. Inhibition of the cellular phosphatase PP1 impaired PRV-mediated interference with eIF2α phosphorylation, indicating that PP1 is involved in this process. In conclusion, the immediate-early IE180 protein of PRV has the previously uncharacterized ability to suppress phosphorylation levels of the eukaryotic translation initiation factor eIF2α.     

Herpes simplex virus type 1 and pseudorabies virus bind to a common saturable receptor on Vero cells that is not heparan sulfate.

Herpes simplex virus type 1 (HSV-1) and pseudorabies virus (PRV) infect different natural hosts but are very similar in structure, replicative cycle, and entry into cultured cells. We determined whether HSV-1 and PRV use the same cellular components during entry into Vero cells, which are highly susceptible to each virus but are not from native hosts for either. UV-inactivated virions of either HSV-1 or PRV could saturate cell surfaces to block infection of challenge HSV-1 or PRV. In the presence of saturating levels for infection of either virus, radiolabeled virus bound well and in a heparin-sensitive manner. This result shows that heparan sulfate proteoglycans on Vero cells are not the limiting cellular component. To identify the virus component required for blocking, we used an HSV-1 null mutant virus lacking gB, gD, or gH as blocking virus. Virions lacking gB were able to block infection of challenge virus to the same level as did virus containing gB. In contrast, virions lacking gD lost all and most of the ability to block infection of HSV-1 and PRV, respectively. HSV-1 lacking gH and PRV lacking gp50 also were less competent in blocking infection of challenge virus. We conclude that HSV-1 and PRV bind to a common receptor for infection of Vero cells. Although both viruses bind a heparin-like cell component on many cells, including Vero cells, they also attach to a different and limited cell surface component that is bound at least by HSV-1 gD and possibly gH and to some degree by PRV gp50 but not gB. These results clearly demonstrate binding of both HSV-1 and PRV to a common cell receptor that is not heparan sulfate and demonstrate that several types of attachment occur for both viruses during infectious entry.     

Genome Characteristics and Evolution of Pseudorabies Virus Strains in Eastern China from 2017 to 2019

Since late 2011, outbreaks of pseudorabies virus(PRV) have occurred in southern China causing major economic losses to the pig industry. We previously reported that variant PRV forms and recombination in China could be the source of continued epidemics. Here, we analyzed samples from intensive pig farms in eastern China between 2017 and 2019, and sequenced the main glycoproteins(gB, gC, gD, and gE) to study the evolution characteristics of PRV. Based on the g C gene, we found that PRV variants belong to clade 2 and detected a founder effect during by the PRV epidemic. In addition,we detected inter-and intra-clade recombination; in particular, inter-clade recombination in the g B genes of strains FJ-ZXF and FJ-W2, which were recombinant with clade 1 strains. We also found specific amino-acid changes and positively selected sites, possibly associated with functional changes. This analysis of the emergence of PRV in China illustrates the need for continuous monitoring and the development of vaccines against specific variants of PRV.     

Assembly of pseudorabies virus genome-based transfer vehicle carrying major antigen sites of S gene of transmissible gastroenteritis virus: potential perspective for developing live vector vaccines.

Two severe porcine infectious diseases, pseudorabies (PR) and transmissible gastroenteritis (TGE) caused by pseudorabies virus (PRV) and transmissible gastroenteritis virus (TGEV) respectively often result in serious economic loss in animal husbandry worldwide. Vaccination is the important prevention means against both infections. To achieve a PRV genome-based virus live vector, aiming at further TGEV/PRV bivalent vaccine development, a recombinant plasmid pUG was constructed via inserting partial PK and full-length gG genes of PRV strain Bartha K-61 amplified into pUC119 vector. In parallel, another recombinant pHS was generated by introducing a fragment designated S1 encoding the major antigen sites of S gene from TGEV strain TH-98 into a prokaryotic expression vector pP(RO)EX HTc. The SV40 polyA sequence was then inserted into the downstream of S1 fragment of pHS. The continuous region containing S1fragment, SV40 polyA and four single restriction enzyme sites digested from pHS was subcloned into the downstream of gG promoter of pUG. In addition, a LacZ reporter gene was introduced into the universal transfer vector named pUGS-LacZ. Subsequently, a PRV genome-based virus live vector was generated via homologous recombination. The functionally effective vector was purified and partially characterized. Moreover, the potential advantages of this system are discussed.