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。     

河南省及周边省份猪群中大面积感染猪伪狂犬病毒的病因分析

2011年初开始,猪伪狂犬病(pseudorabies,PR)在河南省及周边省份再次突然出现严重暴发。为查明原因,应用PRV gE抗体ELISA检测试剂盒对2011年1月至2013年5月送检的16 800份猪血清、905份猪流行性腹泻病毒(Porcine epidemic diarrhea virus,PEDV)"返饲"病料和56份PR基因缺失活疫苗分别进行野毒感染检测,通过PCR方法对11株PRV新流行毒株的TK、gE基因进行序列测定与分子特征分析,同时对这些毒株的毒价测定、免疫攻毒保护试验以及疫苗效价测定等开展研究。结果显示,PRV野毒感染阳性猪场检出率高达68.06%,血清总阳性率为38.47%,种母猪、种公猪、后备猪和商品猪的阳性率分别为40.12%、30.88%、54.67%和26.52%;新流行毒株聚在同一进化分支,均属于强毒株,但毒力较经典毒株变化不大,gE基因长度均为1 787bp,TK基因长度均为963bp,与不同年代中国参考毒株的核苷酸、氨基酸序列同源性分别为98.2%~99.8%、97.1%~99.8%和98.9%~99.6%和97.5%~99.4%;商品疫苗对新流行毒株的保护率为100%;疫苗和"返饲"病料中,PRV野毒阳性检出率分别为0%和40.44%。研究结果证实,2011年后河南省及周边省份猪群中,PRV野毒感染率大幅攀升;PRV新流行毒株的主要毒力基因并未发生明显变异;疫苗中未存在PRV野毒污染,而且可完全抵抗新流行毒株的攻击;种公猪、后备猪普遍带毒和PEDV"返饲"病料中严重污染野毒是造成2011~2013年间河南省及周边省份猪群中PRV大面积感染和疫情暴发的主要因素。     

新型猪瘟疫苗研究进展

猪瘟是由猪瘟病毒引起猪的一种急性、热性和高度接触性传染病.该病呈世界性分布,给世界养猪业造成了巨大的经济损失.目前,疫苗接种仍然是防控猪瘟的主要手段.虽然传统的猪瘟弱毒疫苗(如C株)安全有效,但猪瘟的临床表现发生了很大变化,呈现典型猪瘟和非典型猪瘟共存、隐性感染和持续感染并现,免疫失败的现象时有报道,且不能区分野毒感染和免疫接种.因此,研制安全、高效、能区分野毒感染和疫苗免疫动物(DIVA)的新型猪瘟疫苗极为必要.文中就近年来开发的核酸疫苗、病毒活载体疫苗、基于蛋白/肽的疫苗、基因缺失疫苗、嵌合瘟病毒疫苗等新型DIVA猪瘟疫苗作一综述.     

马传染性贫血病毒美洲流行株与我国弱毒疫苗株鉴别诊断方法的研究

马传染性贫血病毒(Equine infectious anemia virus,EIAV)是反转录病毒科慢病毒属的成员,是马传染性贫血病的病原.二十世纪七十年代我国就研制出马传染性贫血驴白细胞弱毒疫苗,成为世界第一个成功地应用该疫苗控制了我国的马传贫的发生[1].而且我国的马传贫弱毒疫苗对异源的美国、古巴和阿根廷等毒株也有很高的保护率[2].因此将我国的马传贫驴细胞弱毒疫苗推向国际市场成为可能.然而目前制约该苗出口的技术问题是现行的OIE推荐的琼脂扩散实验和ELISA等血清学方法不能鉴别自然感染马与我国弱毒疫苗免疫马,针对这个关键问题,本试验采用PCR方法初步建立了一种能够鉴别美洲(美国和阿根廷)流行毒株感染马和我国弱毒疫苗免疫马的实验室检测方法,为我国疫苗能在世界范围内应用提供了配套技术.     

禽呼肠孤病毒感染对鸡法氏囊及免疫应答的影响

研究LY株禽呼肠孤病毒(ARV)感染1日龄SPF鸡后对法氏囊发育影响,对传染性法氏囊病毒(IBDV)、禽流感病毒(AIV)、新城疫病毒(NDV)疫苗免疫诱发的抗体的影响,及对强毒株IBDV致病作用的影响。结果表明,LY株ARV感染1日龄SPF鸡可引起法氏囊萎缩和部分淋巴细胞减少,但对增重及AIV和NDV疫苗免疫后抗体滴度却没有显著影响。ARV感染可降低弱毒IBDV疫苗免疫后的抗体反应,但对随后IBDV强毒株攻毒的抵抗力却与对照鸡无显著差异。经IBDV弱毒疫苗免疫后,再接种强毒株IBDV,不会引起死亡,但却仍能显著抑制对AIV、NDV疫苗免疫后的抗体滴度。然而,对于1~7日龄经ARV感染的鸡,IBDV强毒的这种免疫抑制作用又显著低于未经ARV感染的对照鸡。     

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.     

马传染性贫血病毒弱毒疫苗株与亲本强毒株的体内病毒载量与诱导保护性免疫关系的研究

慢病毒免疫应答的载量阈值学说认为病毒载量决定了机体对病毒反应的类型。为了探讨马传染性贫血病毒(EIAV)血浆病毒载量与马体免疫保护的相关性,本研究利用Real-time RT-PCR方法对EIAV弱毒疫苗株(EIA-VDLV125)免疫马和EIAV强毒株(EIAVLN40)非致死剂量接种马血浆中病毒载量进行了动态比较。结果显示两组马在监测过程中皆可检测到相似水平的病毒载量(103～105copies/mL),且两者之间差异不显著(P0.05)。以上毒株接种23周后,对马匹进行了强毒株(EIAVLN40)的致死剂量攻毒,根据攻毒后典型马传贫急性发病与否确定接种保护率。结果显示,疫苗组的保护率为67%而非致死剂量强毒组的保护率为0。以上结果提示,病毒血浆载量不是决定EIAV弱毒疫苗诱导免疫保护能力的主要或单一因素。     

猪霍乱沙门菌载体介导猪瘟病毒DNA免疫研究

构建了猪瘟病毒(CSFV)主要保护性抗原E2基因的真核表达质粒pVAXE2。将其电转化猪霍乱沙门氏菌C500疫苗株,得到了携带pVAXE2质粒的猪霍乱沙门氏菌工程菌株S.C500/pVAXE2,对该菌株的特征、培养特性和生化特性进行了鉴定。分别用1×10⁸CFU、2×10⁹CFU S.C500/pVAXE2经口服或肌肉注射免疫小鼠和家兔,间接ELISA检测免疫动物的特异性抗体,在第三次免疫后2周用20ID50猪瘟兔化弱毒和致死量猪霍乱沙门氏菌强毒株对免疫兔进行攻击。结果表明,S.C500/pVAXE2保持了猪霍乱沙门氏菌原有形态特征、培养特性和生化特性,免疫鼠和兔都产生了抗CSFV和猪霍乱沙门菌的ELISA抗体,免疫家兔能抵抗猪瘟兔化弱毒株和猪霍乱沙门氏菌强毒株的攻击。显示了以S.C500为DNA运输载体构建二联或多联猪用疫苗的可行性。     

流行性乙型脑炎病毒的变异 Ⅳ.SA14-A株蝕斑病毒的致病力和免疫力

预防流行性乙型脑炎疾病的综合措施中,应用疫苗对人羣进行自动免疫,是控制该病的重要方法之一。由于乙型脑炎死毒疫苗存在着反应重或免疫效果较差的缺点,近年来我们着手研究乙型脑炎活疫苗的工作。本文为继以往的工作,将SA14-A減弱株,继续通过地鼠肾细胞100代的病毒培养液中,挑选出3株对小白鼠脑內感染几乎不致死而对恆河猴完全不致死的毒株,较原有的SA14-A減弱株的毒力又有进一步的减弱,而且这些毒株经小白鼠及豚鼠免疫后仍然表现出良好的免疫性。因此,我们认为将这些毒株再做适当的减毒并保持其一定的毒力稳定性后,可以供乙型脑炎活疫苗做为毒株用。     

表达猪瘟病毒E2蛋白的重组腺病毒的构建及其在兔体内的免疫原性分析

为了构建猪瘟重组腺病毒载体疫苗,通过细菌内同源重组法构建了含有猪瘟病毒E2基因的重组腺病毒rAdV-E2.测定其一步生长曲线,同时用间接免疫荧光试验和Western blotting检测外源基因表达,然后用rAdV-E2免疫家兔,免疫后6周用猪瘟兔化弱毒疫苗株(c株)进行攻击,攻毒后3 d取其脾脏,用实时荧光定量RT-PCR检测C株病毒RNA.结果表明,该重组腺病毒传至第10代时,毒价可达1.0×1010TCID<,50/mL;外源基因可在其中得到稳定表达;rAdV-E2接种兔免疫后2周产生猪瘟特异性抗体,免疫后5 W抗体达到峰值,攻毒后rAdV-E2接种兔和C株接种兔均未出现定型热反应,从其脾脏也未检测到C株病毒RNA,而野生型腺病毒接种兔均出现了定型热反应,并且从其脾脏检测大量C株病毒RNA,其含量达到了103拷贝/μL以上.由此表明,rAdV-E2可望开发为猪瘟候选疫苗.     

Plant‐made E2 glycoprotein single‐dose vaccine protects pigs against classical swine fever

Classical Swine Fever Virus (CSFV) causes classical swine fever, a highly contagious hemorrhagic fever affecting both feral and domesticated pigs. Outbreaks of CSF in Europe, Asia, Africa and South America had significant adverse impacts on animal health, food security and the pig industry. The disease is generally contained by prevention of exposure through import restrictions (e.g. banning import of live pigs and pork products), localized vaccination programmes and culling of infected or at‐risk animals, often at very high cost. Current CSFV‐modified live virus vaccines are protective, but do not allow differentiation of infected from vaccinated animals (DIVA), a critical aspect of disease surveillance programmes. Alternatively, first‐generation subunit vaccines using the viral protein E2 allow for use of DIVA diagnostic tests, but are slow to induce a protective response, provide limited prevention of vertical transmission and may fail to block viral shedding. CSFV E2 subunit vaccines from a baculovirus/insect cell system have been developed for several vaccination campaigns in Europe and Asia. However, this expression system is considered expensive for a veterinary vaccine and is not ideal for wide‐spread deployment. To address the issues of scalability, cost of production and immunogenicity, we have employed an Agrobacterium‐mediated transient expression platform in Nicotiana benthamiana and formulated the purified antigen in novel oil‐in‐water emulsion adjuvants. We report the manufacturing of adjuvanted, plant‐made CSFV E2 subunit vaccine. The vaccine provided complete protection in challenged pigs, even after single‐dose vaccination, which was accompanied by strong virus neutralization antibody responses.     

Selection of classical swine fever virus with enhanced pathogenicity reveals synergistic virulence determinants in E2 and NS4B

Classical swine fever virus (CSFV) is the causative agent of classical swine fever (CSF), a highly contagious disease of pigs. There are numerous CSFV strains that differ in virulence, resulting in clinical disease with different degrees of severity. Low-virulent and moderately virulent isolates cause a mild and often chronic disease, while highly virulent isolates cause an acute and mostly lethal hemorrhagic fever. The live attenuated vaccine strain GPE(-) was produced by multiple passages of the virulent ALD strain in cells of swine, bovine, and guinea pig origin. With the aim of identifying the determinants responsible for the attenuation, the GPE(-) vaccine virus was readapted to pigs by serial passages of infected tonsil homogenates until prolonged viremia and typical signs of CSF were observed. The GPE(-)/P-11 virus isolated from the tonsils after the 11th passage in vivo had acquired 3 amino acid substitutions in E2 (T830A) and NS4B (V2475A and A2563V) compared with the virus before passages. Experimental infection of pigs with the mutants reconstructed by reverse genetics confirmed that these amino acid substitutions were responsible for the acquisition of pathogenicity. Studies in vitro indicated that the substitution in E2 influenced virus spreading and that the changes in NS4B enhanced the viral RNA replication. In conclusion, the present study identified residues in E2 and NS4B of CSFV that can act synergistically to influence virus replication efficiency in vitro and pathogenicity in pigs.     

表达猪圆环病毒2型Cap蛋白的重组猪瘟兔化弱毒疫苗株的构建与鉴定

猪瘟(CSF)是由猪瘟病毒(CSFV)引起的一种毁灭性传染病,给养猪业造成重大经济损失。猪瘟兔化弱毒疫苗(C株)是一株非常安全、有效的优秀弱毒疫苗,对各年龄和品种的猪都极其安全,同时对不同基因亚型的CSFV均能提供有效的免疫保护。在现地,CSFV和猪圆环病毒2型(PCV2)混合感染的现象时常发生,有必要研制针对这两种病毒混合感染的二价疫苗。本研究首次构建了表达PCV2 Cap蛋白的重组C株,并评价了其在体内外的特性。结果表明,该重组病毒与C株具有相近的体外增殖特征,能够稳定表达Cap蛋白,在家兔体内具有与C株相似的生物学表型,在免疫家兔后10 d,抗CSFV E2抗体全部转阳,然而抗Cap抗体未能转阳。本研究为进一步优化表达PCV2Cap蛋白的重组C株奠定了基础。     

Challenge of pigs with classical swine fever viruses after C-strain vaccination reveals remarkably rapid protection and insights into early immunity

Pre-emptive culling is becoming increasingly questioned as a means of controlling animal diseases, including classical swine fever (CSF). This has prompted discussions on the use of emergency vaccination to control future CSF outbreaks in domestic pigs. Despite a long history of safe use in endemic areas, there is a paucity of data on aspects important to emergency strategies, such as how rapidly CSFV vaccines would protect against transmission, and if this protection is equivalent for all viral genotypes, including highly divergent genotype 3 strains. To evaluate these questions, pigs were vaccinated with the Riemser® C-strain vaccine at 1, 3 and 5 days prior to challenge with genotype 2.1 and 3.3 challenge strains. The vaccine provided equivalent protection against clinical disease caused by for the two challenge strains and, as expected, protection was complete at 5 days post-vaccination. Substantial protection was achieved after 3 days, which was sufficient to prevent transmission of the 3.3 strain to animals in direct contact. Even by one day post-vaccination approximately half the animals were partially protected, and were able to control the infection, indicating that a reduction of the infectious potential is achieved very rapidly after vaccination. There was a close temporal correlation between T cell IFN-γ responses and protection. Interestingly, compared to responses of animals challenged 5 days after vaccination, challenge of animals 3 or 1 days post-vaccination resulted in impaired vaccine-induced T cell responses. This, together with the failure to detect a T cell IFN-γ response in unprotected and unvaccinated animals, indicates that virulent CSFV can inhibit the potent antiviral host defences primed by C-strain in the early period post vaccination.     

猪瘟病毒感染猪白细胞凋亡基因表达谱变化的研究

为了了解CSFV感染引起猪细胞凋亡的分子机制,利用基因芯片分析了猪感染CSFV前后基因组转录水平的变化。分离攻毒前和攻毒后猪外周血白细胞(Peripheral blood leucocyte,PBL),提取总RNA,经反转录和体外转录得到cRNA,与Affymetrix猪全基因组cDNA芯片进行杂交分析,筛选差异表达的凋亡基因。结果显示,感染猪的PBLs中共筛选到24个涉及细胞凋亡有关基因发生2倍以上变化,并对差异表达的12个宿主细胞凋亡相关基因,用荧光定量RT-PCR进行了验证。功能分析显示,这些凋亡基因的表达变化与CSFV诱导宿主细胞凋亡的机制有关。本文首次用猪全基因组芯片研究了CSFV感染诱导宿主基因的表达变化,建立了CSFV感染猪细胞凋亡相关基因的表达谱,初步阐释了CSFV感染诱导宿主细胞凋亡的分子机制。     

Expression and characterization of a recombinant porcinized antibody against the E2 protein of classical swine fever virus

Applied Microbiology and Biotechnology - Classical swine fever virus (CSFV) is the causative agent of classical swine fever (CSF), a highly contagious and economically important disease of pigs....     

Generation and Efficacy Evaluation of Recombinant Classical Swine Fever Virus E2 Glycoprotein Expressed in Stable Transgenic Mammalian Cell Line

Classical swine fever virus (CSFV) is the causative agent of classical swine fever (CSF), which is a highly contagious swine disease that causes significant economic loses to the pig industry worldwide. The envelope E2 glycoprotein of CSFV is the most important viral antigen in inducing protective immune response against CSF. In this study, we generated a mammalian cell clone (BCSFV-E2) that could stably produce a secreted form of CSFV E2 protein (mE2). The mE2 protein was shown to be N-linked glycosylated and formed a homodimer. The vaccine efficacy of mE2 was evaluated by immunizing pigs. Twenty-five 6-week-old Landrace piglets were randomly divided into five groups. Four groups were intramuscularly immunized with mE2 emulsified in different adjuvants twice at four-week intervals. One group was used as the control group. All mE2-vaccinated pigs developed CSFV-neutralizing antibodies two weeks after the first vaccination with neutralizing antibody titers ranging from 1∶40 to 1∶320. Two weeks after the booster vaccination, the neutralizing antibody titers increased greatly and ranged from 1∶10,240 to 1∶81,920. At 28 weeks after the booster vaccine was administered, the neutralizing antibody titers ranged from 1∶80 to 1∶10240. At 32 weeks after the first vaccination, pigs in all the groups were challenged with a virulent CSFV strain at a dose of 1×10⁵ TCID₅₀. At two weeks after the challenge, all the mE2-immunized pigs survived and exhibited no obvious symptoms of CSF. The neutralizing antibody titer at this time was 20,480. Unvaccinated pigs in the control group exhibited symptoms of CSF 3–4 days after challenge and were euthanized from 7–9 days after challenge when the pigs became moribund. These results indicate that the mE2 is a good candidate for the development of a safe and effective CSFV subunit vaccine.     

Molecular characterization of lapinized classical Swine Fever vaccine strain by full-length genome sequencing and analysis

The complete genome of a lapinized classical swine fever virus (CSFV) vaccine strain was amplified into nine overlapping fragments by RT-PCR, and nucleotide sequences were determined. Complete genome sequence alignment and phylogenetic analysis indicated 92.6-98.6% identities at the nucleotide level with other reported CSFV strains and could be grouped into subgroup 1.1 along with other attenuated strains of CSFV. The 5'-UTR demonstrated >97.0% nucleotide similarity with most of vaccine CSFV strains from China. Further, its 3'-UTR sequence indicated a length similar to all the CSFV strains from China with >98.0% nucleotide similarity, although high length heterogeneity of 3'-UTR was reported among different CSFV strains. There was 12 nt (TTTTCTTTTTTT) insertion in 3'-UTR similar to other reported attenuated vaccine strains. However, secondary structure of 3'-UTR indicated that Indian CSFV strain requires further passage to obtain a 3'-UTR structure similar to most of the attenuated strains.