猪瘟病毒C株兔脾毒在SK6细胞中的增殖培养及其鉴定

猪瘟病毒(Classical swine fever virus,CSFV)是猪的最重要传染病之一,给养猪业造成巨大经济损失.传统疫苗C株在猪瘟防制中曾发挥了巨大作用,但由于猪瘟病毒逐渐产生变异,同时使用传统疫苗无法区分自然感染动物和免疫动物,从而使传统疫苗的应用受阻.因此十分必要研制新型猪瘟疫苗.用适宜的宿主细胞培养猪瘟传统弱毒疫苗C株,通过灵敏可靠的方法检测病毒在宿主细胞中的感染,是研究猪瘟病毒C株的一个重要基础环节.     

基于Erns和E2基因的猪瘟标记疫苗研究概述

猪瘟(Classical swine fever,CSF)是猪的一种急性、热性和致死性传染病。该病流行范围很广,而且致死率极高,给世界养猪业造成严重危害。目前,猪瘟流行地区或国家仍然采用接种弱毒疫苗的方法作为预防猪瘟的主要策略,但接种弱毒疫苗的传统预防控制方法无法区别猪瘟疫苗免疫抗体和野毒感染抗体。为了净化、消灭猪瘟,新型标记疫苗的研究已迫在眉睫。近些年,陆续有国内外研究者应用分子生物学和基因工程方法,对猪瘟野毒株或弱毒株进行基因修饰构建出新毒株,其中以Erns和E2为基础构建新毒株的方法占据着重要地位。部分候选疫苗具有较好的免疫效果,可用于区分免疫和自然感染动物,而且有望作为新一代疫苗来替代传统弱毒疫苗。     

某猪场猪瘟典型病例综合诊断及病毒E2基因分析

2018年7月,山东省某育肥猪场猪群突然发病并出现大量死亡,病猪临床表现高热、皮肤潮红并布满点状出血。为查明发病原因,对病猪进行病理剖检并采样,经实验室综合检测,初步诊断为猪瘟病毒感染。对检测到的CSFV E2基因进行了分子测序及核酸序列同源性对比,最终确诊为2.1d亚型猪瘟病毒感染。结果显示,本实验室分离到的CSFV(命名为SDXT2018)与21株参考毒株的E2基因核苷酸序列同源性为81.3%～96.2%。与21株参考毒株中同源性最高的是2.1d亚型的JQ001834,同源性达96.2%;与2.3亚型的经典毒株HQ148061的同源性最低,为81.3%。结果说明,我国猪瘟病毒流行毒株的变异趋势越发严峻,以致于常规疫苗免疫的猪场有可能爆发典型猪瘟疫情,这对养猪业构成了严重威胁。因此,亟待人们开展病毒遗传变异趋势的研究,并针对病毒抗原特性研制、生产高效疫苗。     

含双拷贝CSFV E2基因A和D片段原核表达载体的构建及表达

猪瘟是严重危害养猪业的传染病,该病具有高度接触传染性,其流行性广,发病率高,死亡率高,危害极大,被世界动物卫生组织(OIE)列为A类传染病之一。本病的主要临床特征是高热、实质器官出血、淋巴细胞和血小板减少,而怀孕母猪多发生繁殖防碍。每年,猪瘟的发生都为国家造成巨大的经济损失。猪瘟的病原是猪瘟病毒,属于黄病毒科瘟病毒属成员,是单股正链RNA病毒[1]。囊膜糖蛋白E2是猪瘟病毒的主要保护性抗原[2,3]。E2蛋白可诱导机体产生坚强的中和性免疫保护,具有良好的免疫原性和反应原性[4~6] ,这为本病的诊断提供了重要的分子生物学及免疫学…     

反向遗传学技术在猪瘟病毒研究中的应用

猪瘟目前在许多国家流行并对养猪业造成巨大损失。虽然常规疫苗(如中国猪瘟兔化弱毒疫苗,即C株)在猪瘟防控中发挥巨大作用,但近年来在猪瘟防控中出现的新情况,如非典型感染、持续性感染及免疫失败等;同时目前世界上许多国家正开展的猪瘟扑灭计划使得弱毒疫苗的应用受到很大限制。因此,加强猪瘟病毒在致病机理、传播机制等方面的研究以及加快新型猪瘟疫苗的开发是当务之急。近年来,反向遗传学技术的发展为猪瘟病毒基因功能研究和疫苗制备方面开辟了新思路。以下回顾了反向遗传操作技术在猪瘟病毒基因功能研究与标记疫苗株构建方面的研究进展,同时提出了该领域目前面临的问题,并对其未来发展方向进行了展望。     

非洲猪瘟防控及疫苗研发：挑战与对策

非洲猪瘟是由非洲猪瘟病毒引起的一种接触传染性、广泛出血性猪烈性传染病,最急性和急性感染死亡率高达100%。自2018年8月我国发生首起非洲猪瘟疫情后,3个多月内,已有18个省份累计暴发69起,给我国养猪业造成了沉重打击。从目前非洲猪瘟全球流行态势及世界各国防控经验来看,我国非洲猪瘟防控和根除面临的形势不容乐观,亟需安全有效的疫苗用于该病的防控。文中结合当前非洲猪瘟病原学最新研究成果,系统总结了非洲猪瘟防控策略、疫苗研究进展及其面临的挑战,重点分析了疫苗研发历程、存在的问题、未来发展方向以及商业化应用所面临的关键科学问题,以期为我国非洲猪瘟防控及病原和疫苗研究提供借鉴。     

猪瘟病毒与宿主天然免疫系统的相互作用

猪瘟(Classical swine fever,CSF)是由猪瘟病毒(Classical swine fever virus,CSFV)感染引起的一种高度接触性传染病,临床上以出血综合征与免疫抑制为主要特征。它在多个国家流行,给中国乃至世界养猪业造成巨大的经济损失。研究表明,猪瘟病毒感染能够诱导宿主的天然免疫应答,也能通过影响天然免疫效应分子的表达来抑制宿主的天然免疫功能。本文将对猪瘟病毒感染与天然免疫应答及其免疫抑制的现象与机理进行综述。     

猪瘟疫苗研究进展

猪瘟是猪的一种重要传染病,给世界养猪业造成了巨大的经济损失。疫苗免疫是预防该病的主要手段。本文综述了猪瘟流行现状、传统疫苗、亚单位疫苗、活载体疫苗、标记疫苗、核酸疫苗的研究进展,并对它们的发展趋势作了初步探讨和展望。     

管式磁微粒非洲猪瘟病毒pp62蛋白化学发光抗体检测方法的建立

【背景】非洲猪瘟(African swine fever, ASF)作为高致病性传染病,给我国生猪养殖业造成了严重的经济损失,因此建立快捷、灵敏的诊断方法至关重要。【目的】建立一种管式非洲猪瘟病毒pp62蛋白化学发光抗体检测方法。【方法】以重组pp62蛋白作为包被抗原,羧基磁珠(carboxylic magnetic beads)作为固相载体,碱性磷酸酶(alkaline phosphatase, AP)标记的兔抗猪IgG作为酶标二抗,通过对反应条件进行优化,采用非洲猪瘟国家参考品作为溯源血清绘制出标准曲线,建立基于ASFV pp62蛋白的化学发光抗体检测方法。【结果】用建立的化学发光方法检测277份临床样品血清,通过受试者工作特征(receiver operating characteristic, ROC)曲线分析确定阴性、阳性临界值,并确定判定标准：浓度值>140.02 U时为抗体阳性,浓度值<140.02 U时为抗体阴性。此方法对6种不同的病原血清抗体进行检测均无交叉反应,且批内和批间变异系数均在10%以内,与商品化非洲猪瘟抗体检测试剂盒的符合率达96.7%。【结论】本研究建立的管式非洲猪瘟病毒化学发光抗体检测方法具有良好的特异性、敏感性和重复性,可为非洲猪瘟早期监测及试剂盒研发提供参考。     

非洲猪瘟病毒CP204L基因的原核表达与单抗制备

由非洲猪瘟病毒(ASFV)引起的非洲猪瘟(ASF)给我国养猪业带来了不可估量的经济损失,严重阻碍了我国养猪业的发展,研发ASFV快速诊断试剂是目前最重要的内容之一。CP204L基因编码ASFV结构蛋白p30。本研究以克隆ASFV的CP204L基因为基础,通过基因重组技术,加入His标签,将构建的重组质粒命名为pET-28a-CP204L。将重组质粒转化至大肠杆菌BL21(DE3)感受态细胞,37℃经1mmol/L异丙基-β-D-硫代半乳糖苷(IPTG)诱导表达6h,表达蛋白进行SDS-PAGE鉴定和Western Blot检测。重组蛋白纯化后免疫小鼠制备筛选单克隆抗体,Western Blot和IFA验证单抗的结合特异性。结果表明,重组的pET-28a-CP204L诱导后表达蛋白为30kD,以不可溶性包涵体形式存在;表达蛋白利用His标签进行纯化,获得纯化蛋白2mg,单克隆抗体筛选获得5株IgG亚型的ASFV p30蛋白的单抗,且均具有良好的结合活性。本研究为发展ASFV检测方法提供了基础。     

Identification of Hog Cholera Viral Antigen by Immunofluorescence. Application as a Diagnostic and Assay Method

In the absence of detectable cytologic changes in hog cholera virus-infected tissue culture cells, hog cholera viral antigen was readily detected by immunofluorescence. The ability to detect hog cholera viral antigen by this method allowed for determination of infectivity titers and also for titration of homologous antibody. Immunofluorescence made possible the identification, in tissue culture, of hog cholera virus from blood, serum, and spleen extracts of experimentally infected swine. Further applications of this method and its limitations are being investigated.     

Vaccination of Pigs Against Hog Cholera (Classical Swine Fever) With a Detergent Split Vaccine

Four pigs were inoculated subcutaneously with a detergent (triton X 100) split hog cholera virus in Freund’s incomplete adjuvant. Four other pigs were in the same way inoculated with a detergent split bovine viral diarrhoea virus, also in Freund’s incomplete adjuvant. In the experiment were used 3 control pigs. The vaccinations were repeated after 3 weeks. All pigs were challenged with highly virulent hog cholera virus (Tübingen) 12 weeks after primary inoculations. Signs of hog cholera were only noted in the control pigs. This introductory experiment was succeeded by a larger experiment with subcutaneous inoculations of: 10 pigs with detergent split hog cholera virus in Freund’s incomplete adjuvant, 10 pigs with detergent split hog cholera virus in a saponin (Quil A) solution, 10 pigs with detergent split bovine viral diarrhoea virus in Freund’s incomplete adjuvant, 10 pigs with detergent split bovine viral diarrhoea virus in the Quil A solution plus 5 control pigs. The vaccinations were repeated after 3 weeks, and finally all pigs were challenged 9 weeks later with the highly virulent hog cholera virus strain. With the exception of 1 animal which died accidentally, all animals survived in the groups inoculated with the Quil A vaccines and in the group inoculated with the detergent split hog cholera virus/oil adjuvant vaccine. In the group inoculated with the detergent split bovine viral diarrhoea virus/oil adjuvant vaccine, some of the pigs died of hog cholera.     

Demonstration of an Antigenic Relationship Between Hog Cholera and Bovine Viral Diarrhea Viruses by Immunofluorescence

Specific staining of antigen within bovine embryo kidney tissue culture cells, infected with either Oregon C24V or NADL-MD bovine viral diarrhea virus, was accomplished using fluorescein-conjugated swine anti-hog cholera or bovine antiviral diarrhea globulin. Also specific staining of antigen within pig kidney tissue culture cells, infected with hog cholera virus, was accomplished using the same two types of conjugates. Specificity was confirmed by appropriate controls. The authors found immunofluorescence to be a convenient and sensitive method for determining an antigenic relationship between hog cholera and bovine viral diarrhea viruses.     

Hog Cholera Antibodies in Pigs Vaccinated with an Aujeszky-Vaccine Based on Antigen Produced in IB-RS-2 Cells

The cell line IB-RS-2 is confirmed to be persistently infected with hog cholera virus. Vaccination of pigs against Aujeszky’s Disease with an inactivated vaccine based on antigen produced on this cell line induced neutralizing antibodies against hog cholera virus.     

Use of the agar diffusion precipitation test in the diagnosis of hog cholera

The application of the agar diffusion precipitation (ADP) test for diagnosing hog cholera was investigated. The test used as antigen, pancreatic tissue from 272 pigs that had been inoculated with hog cholera virus. The test was positive for 13.5% of the animals that were sick for 4 days or less, 40% of those sick for 5 days, and 77% of those sick for 6 days or more. The test was positive for 13.5% of all animals that had been vaccinated with crystal violet-glycerol hog cholera vaccine and had been sick for at least 6 days after challenge inoculation. Titration of the virus in ADP-test-negative and ADP-test-positive pancreatic suspensions did not show a direct correlation between the infective virus particle and the precipitating antigen.     

两个猪瘟病毒野毒株gp55基因抗原编码区序列的分析及比较

利用反转录－PCR方法扩增了吉林省猪瘟病毒（HCV）两个野毒株gp55基因的主要保护性抗原编码区,并将其克隆到pGEM－T载体中,然后用Sanger双脱氧法测定了其核苷酸序列,并推导了其氨基酸序列。将测定的这两个HCV野毒株的部分序列（350bp）与国内外已知的HCV序列进行比较,结果表明：这两个野毒株的核苷酸序列的同源性为94．9％,氨基酸序列同源性为97．4％,与1985～1992年意大利中部分离4个野毒株的同源性明显高于其它HCV毒株,核苷酸同源性分别为97．2％～98．3％和94.0％～949％,氨基酸同源性分别为98．3％～991％和97.4％～98.3％,而与我国的HCV标准强毒株即石门株的核苷酸同源性仅分别为83.1％和83.1％,氨基酸同源性仅分别为90.6％和91.4％。因此认为吉林省这两个野毒株与意大利中部的4个野毒株具有密切的关系,而与石门株很可能来源不同。     

Differences in pathogenicity and antigenicity among hog cholera virus strains.

Using antiserum against a particular strain of bovine viral diarrhea virus, the strains of hog cholera virus were divided into two groups, H and B, on the basis of the difference in the degree of neutralization. Group H consisted of strains reacting poorly in neutralization, and group B Consisted of strains reacting well with bovine viral diarrhea antiserum. Most of the strains of group H induced a typical clinical form of hog cholera in experimentally infected pigs. Inoculation of pigs with a strain of group B, however, resulted in a chronic type of illness. When immunized with bovine viral diarrhea virus, pigs succumbed to challenge with group H virus after showing clinical signs of hog cholera, but survived challenge with group B virus without manifesting any clinical sign.     

Live attenuated pseudorabies virus expressing envelope glycoprotein E1 of hog cholera virus protects swine against both pseudorabies and hog cholera

To investigate whether live attenuated pseudorabies virus (PRV) can be used as a vaccine vector, PRV recombinants that expressed envelope glycoprotein E1 of hog cholera virus (HCV) were generated. Pigs inoculated with these recombinants developed high levels of neutralizing antibodies against PRV and HCV and were protected against both pseudorabies and hog cholera (classical swine fever).     

Pathogenesis of classical swine fever: B-lymphocyte deficiency caused by hog cholera virus.

Hog cholera, also known as classical or European swine fever, is caused by hog cholera virus, a member of the genus Pestivirus. It is shown here that the end stage of lethal infection in the natural host is associated with a dramatic depletion preferentially of B lymphocytes in the circulatory system as well as in lymphoid tissues. Already at the onset of disease, viral replication in lymphoid tissues demarcates the germinal centers, and the viral genome remains localized to that site as the disease progresses even after morphologic disintegration of the follicular structure. A block in B-lymphocyte maturation by infection and destruction of germinal centers is discussed as a key event in the pathogenesis of acute, lethal hog cholera.