猕猴B病毒gC蛋白特异性抗原表位的合成和表达

目的获得B病毒gC蛋白的特异性表位抗原。方法利用长片段基因合成的方法,合成B病毒C蛋白的特性抗原表位基因,将该基因连接到pMAL-5x载体,转化到BL21受体菌进行表达,并纯化表达产物。结果成功的获得了B病毒gC蛋白的特异性抗原蛋白,该蛋白以可溶的形式表达。结论利用原核表达系统,可以产生B病毒gC蛋白的可溶性抗原,可以作为B病毒的检测抗原。     

B细胞表位作图研究进展

抗原-抗体的特异性结合是由抗体表面的抗原决定簇与抗原表面的表位基序间的特异性互补识别决定的。B细胞表位作图既包括B细胞抗原表位基序的鉴定(即确定抗原分子上被B细胞表面受体或抗体特异性识别并结合的氨基酸基序),也包括绘制抗原蛋白的全部或接近全部的B细胞表位基序在其一级或高级结构上的分布图谱的过程。B细胞表位作图是研发表位疫苗、治疗性表位抗体药物和建立疾病免疫诊断方法的重要前提。目前,已经建立了多种B细胞表位鉴定或绘制抗原蛋白B细胞表位图谱的实验方法。基于抗原-单抗复合物晶体结构的X-射线晶体学分析的B细胞表位作图和基于抗原蛋白或抗原片段的突变体库筛选技术的B细胞表位作图可以在氨基酸水平,甚至原子水平上揭示抗原分子上与单抗特异性结合的关键基序;其它B细胞表位作图方法(如基于ELISA的肽库筛选技术)常常只能获得包含B细胞表位的抗原性肽段,因而,很少用于最小表位基序的鉴定;而改良的生物合成肽法多用于B细胞表位的最小基序鉴定和精细作图。鉴于每种B细胞作图方法都存在各自的优势与不足,B细胞表位作图往往需要多种作图方法的有机结合。本文对目前常用的B细胞表位作图的实验方法及其在动物疫病防控中的应用进行综述,以期为研究者设计最佳的表位作图方案提供参考。     

重组牛乳源金黄色葡萄球菌GapC蛋白优势B细胞抗原表位的预测和筛选

旨在表达牛乳源金黄色葡萄球菌(Staphylococcus aureus)GapC蛋白并对其B细胞抗原表位进行预测与鉴定，本研究利用实验室分离鉴定的S. aureus分离株15119扩增GapC基因并构建重组表达质粒pET-28a-GapC，诱导纯化得到分子量为44 kD重组蛋白GapC，以此免疫新西兰大白兔，获得特异多克隆抗体。利用生物信息学方法，对GapC蛋白的二级及三级结构进行分析，预测其B细胞抗原表位，并利用特异性抗体对筛选的表位进行鉴定。结果表明，GapC蛋白具有良好的免疫原性，筛选出7个线性B细胞抗原表位，利用兔抗重组GapC蛋白多克隆抗体鉴定得到了PL 5(²²¹ IPEIDGKLDGGAQRVP²³⁶)多肽和PL 7(²⁶⁴KNASNESFGYTEDEIVSSDVVGM²⁸⁶)2个优势B细胞表位。本研究成功制备了GapC蛋白，预测并鉴定了2个优势抗原表位，为其嵌合表位疫苗的开发提供了技术支持。     

猪流行性腹泻病毒S蛋白主要抗原表位区的原核表达及间接ELISA检测方法的建立

【目的】建立一种快速、特异、敏感的检测血清中猪流行性腹泻病毒(PEDV)抗体的方法。【方法】利用生物学软件对PEDV S蛋白进行抗原位点分析,选择S蛋白的主要抗原表位区进行原核表达。采用SDS-PAGE和Western-blot对重组蛋白进行鉴定及抗原性分析。用纯化的重组蛋白作为包被抗原,经过条件优化、特异性和重复性试验,建立一种针对血清中PEDV抗体的间接ELISA检测方法。【结果】表达了重组S蛋白,重组的S蛋白能与PEDV阳性血清发生特异性反应,并建立一种基于重组S蛋白的间接ELISA检测方法。组内及组间变异系数均小于10%,重复性较好。建立的间接ELISA检测方法分别与商品化PEDV抗体检测试剂盒和Western-blot鉴定结果相比,两者符合率分别为86.67%和88.89%。【结论】建立的间接ELISA方法可以用于PEDV抗体的检测。     

人巨细胞病毒包膜糖蛋白B主要中和表位单克隆抗体的制备

人巨细胞病毒(Human Cytomegalovirus,HCMV)分布广泛,能够引发多种疾病,人群感染率极高,严重威胁到人类健康。现根据标准毒AD169基因序列,人工合成包膜糖蛋白B(glycoprotein B,g B)AD13区段的主要中和抗原表位AD-1、AD-2、AD-3,并将其与表达载体pET-32a连接,构建重组表达质粒;用IPTG诱导表达重组蛋白,采用Western-blot进行特异性鉴定;将纯化后的重组蛋白免疫BALB/c小鼠,取免疫小鼠脾细胞和SP2/0细胞融合,然后筛选制备AD13单克隆抗体(monoclonal antibody,m Ab)。12%SDS-PAGE电泳鉴定表明重组蛋白表达成功,其相对分子质量约为35 kD;Western-blot和间接ELISA结果说明,重组AD13蛋白作为抗原具有良好的免疫反应性;克隆化后筛选到5个AD13单克隆抗体细胞株,经间接ELISA鉴定,与AD13抗原有良好的特异性反应。上述研究为研发HCMV快速诊断试剂盒提供了原料,也为研究HCMV亚单位疫苗提供了相关的基础。     

UreB蛋白B细胞抗原表位快速筛选与鉴定

以幽门螺旋杆菌(Helicobacterpylori,Hp)主要抗原蛋白尿素酶B(ureaseB,UreB)为靶蛋白,建立一种新的B细胞抗原表位筛选与鉴定方法.运用Fmoc固相肽合成法合成11条HpUreB蛋白的单表位抗原肽片段,在其氨基端标记FITC荧光素,应用荧光偏振方法(fluorescencepolarization,FP)快速鉴定这些肽片段的抗原性,并通过FP法在大规模样品中快速筛选相应抗体滴度高、分布人群广的优势抗原表位肽.结果表明,合成的11条UreB蛋白线性抗原肽中,10条具有较强的抗原性,其中No.2、No.5和No.11抗原肽相应的特异性抗体在感染Hp的人群中分布较广,抗体滴度较高,为UreB的优势抗原表位肽.对抗原表位进行多参数综合分析与设计,通过FP技术快速鉴定抗原肽,并筛选优势抗原表位肽,对于疾病的抗原表位谱研究具有重要的意义,同时在疾病的诊断、分型及治疗中具有重要的应用前景.     

应用ELISPOT方法筛选确定HIV-1B'/C亚型疫苗六种抗原的H-2d限制的T细胞表位

为了筛选和确定用于检测表达HIV-1 B’/C亚型病毒6种抗原(gp160、gag、polr、evt、at和nef)的艾滋病疫苗免疫小鼠后H-2d限制的特异性T细胞表位,本研究使用表达上述6种抗原的复制型DNA疫苗和非复制型重组痘苗病毒疫苗联合免疫BALB/c小鼠,通过矩阵设计将HIV-1 B(C)亚型6种相应抗原全序列肽库分别混合成肽池,使用肽池对免疫小鼠进行IFN-γELISPOT检测,根据检测结果确定肽库中特异反应的优势表位肽。结果显示:筛选到七条针对Gag的特异表位肽,其中有5条与文献报道相同,另2条为新表位肽;筛选到3条针对Pol蛋白特异表位肽,其中一条为新表位肽;筛选到2条针对gp160特异表位肽,其中一条为新表位肽;在Nef肽库中筛选到一条新的表位肽;从Tat肽库中筛选到3条表位肽,这三条肽在肽库中是连续的序列,都包含(或部分包含)网上公布的表位序列;在Rev肽库中没有筛选到能够产生阳性反应的特异性表位肽。本研究使用IFN-γELISPOT方法筛选和确定了可用于检测表达HIV-1 B’/C亚型病毒6种抗原(gp160、gag、pol、revt、at和nef)的艾滋病疫苗免疫小鼠后H-2d限制的特异性T细胞表位。     

猴B病毒被膜糖蛋白gC的原核表达及诊断价值评价

目的:原核表达猴B病毒糖蛋白gC胞外区片段,评价其在猴B病毒血清学检测中的特异性和敏感性,为猴B病毒检测奠定基础。方法:利用PCR方法扩增gC胞外区基因片段,同时合成该片段的优化密码子序列,将其插入表达载体pET-28b(+)形成重组质粒,转化至大肠杆菌BL21(DE3)并进行诱导表达;纯化蛋白先以Western印迹进行验证,再以ELISA方法和标准阳性、阴性血清评价其诊断价值。结果:直接从病毒DNA模板上获得的基因片段未能表达,而优化后的基因片段表达水平较高,表达蛋白的相对分子质量约为48×103,为包涵体形式,占菌体总蛋白的30%左右;Western印迹显示,重组蛋白能与猴B病毒阳性血清和His单克隆抗体发生免疫反应;34份标准阳性血清和25份阴性血清的ELISA检测结果显示,重组蛋白的敏感性和特异性分别为94.1%(32/34)和100%(25/25)。结论:利用原核表达系统制备的gC胞外区重组蛋白,可作为猴B病毒血清学检测抗原,其特异性和敏感性都较好。     

噬菌体展示技术及其在肿瘤研究中的应用

噬菌体表面展示技术是一项特异性多肽或蛋白的筛选技术,它将随机序列的多肽或蛋白片段与噬菌体衣壳蛋白融合表达而呈现于病毒表面,被展示的多肽能保持相对独立的空间结构,使其能够与配体作用而达到模仿性筛选特异性分子表位,从而提供了高通量高效率的筛选系统。近年来噬菌体展示技术已广泛应用于肿瘤抗原抗体库的建立、单克隆抗体制备、多肽筛选、疫苗研制、肿瘤相关抗原筛选和抗原表位研究、药物设计、癌症检测和诊断、基因治疗及细胞信号转导研究等。就近年来噬菌体展示技术在肿瘤相关研究中的运用作以综述。     

HIV-1辅助蛋白Vpr多肽抗体的制备与鉴定

预测Vpr蛋白的B细胞抗原表位,并利用合成的B细胞表位肽制备Vpr特异性抗体。应用生物信息学技术获得Vpr蛋白共享氨基酸序列并预测其潜在B细胞抗原表位,与载体蛋白血蓝蛋白(KLH)偶联合成多肽并免疫家兔,鉴定及纯化获得的多肽特异性抗体。软件预测显示,Vpr蛋白N端的第3～19位(N)和C端的第82～95位(C)氨基酸序列为潜在B细胞抗原表位;ELISA检测抗血清中多肽特异性抗体的效价都达到1:105以上;Western-Blotting结果显示,无论对HIV-1B亚型还是CRF07_BC重组型的Vpr蛋白,其多肽N抗体和C抗体均能特异性识别;免疫沉淀结果显示,Vpr多肽N和C抗体也能特异性结合未变性的野生型Vpr或GFP-Vpr融合蛋白。利用生物信息学技术能成功预测Vpr蛋白B细胞抗原表位,免疫所获得的抗体具有较好的特异性和应用性。     

Antigenic variation (mar mutations) in herpes simplex virus glycoprotein B can induce temperature-dependent alterations in gB processing and virus production.

Monoclonal antibody-resistant (mar) mutants altered in the antigenic structure of glycoprotein B (gB) of herpes simplex virus type 1, strain KOS-321, were selected by neutralization with each of six independently derived gB-specific monoclonal antibodies. Analysis of the reactivity patterns of these mar mutants with a panel of 16 virus-neutralizing monoclonal antibodies identified at least five nonoverlapping epitopes on this antigen, designated groups I through V. Multiple mar mutations were also introduced into the gB structural gene by recombination and sequential antibody selection to produce a set of mar mutants with double, triple, and quadruple epitope alterations. Group II (B2) and group III (B4) antibodies were used to select the corresponding mutants, mar B2.1 and mar B4.1, which in addition to carrying the mar phenotype were temperature sensitive (ts) for processing of the major partially glycosylated precursor of gB, pgB (Mr = 107,000), to mature gB (Mr = 126,000) and showed reduced levels of gB on the cell surface at high temperature (39 degrees C). These mutants were not, however, ts for production of infectious progeny. A recombinant virus, mar B2/4.1, carrying both of these alterations was ts for virus production and failed to produce and transport any detectable mature gB to the cell surface at 39 degrees C. Rather, pgB accumulated in the infected cell. Revertants of the ts phenotype, isolated from virus plaques at 39 degrees C, regained the B2 but not the B4 epitope and were phenotypically indistinguishable from the mar B4.1 parent. Finally, it was shown that group II (B5) and group III (B4) antibodies failed to immunoprecipitate pgB (39 degrees C) produced by ts gB mutants of herpes simplex virus type 1 which were not selected with monoclonal antibodies. Taken together, our findings indicate that (i) mar mutations can alter antigenic as well as other functional domains of gB, namely, the domain(s) involved in processing and infectivity, and (ii) group II and group III epitopes lie within an essential functional domain of gB which is a target for ts gB mutations.     

Expression of the Marek's disease virus (MDV) homolog of glycoprotein B of herpes simplex virus by a recombinant baculovirus and its identification as the B antigen (gp100, gp60, gp49) of MDV.

A gene encoding a homolog of glycoprotein B of herpes simplex virus (gB homolog) has been identified on the Marek's disease virus (MDV) genome (L. J. N. Ross, M. Sanderson, S. D. Scott, M. M. Binns, T. Doel, and B. Milne, J. Gen. Virol. 70:1789-1804, 1989); however, the molecular and immunological characteristics of the gene product(s) are still not clear. In the present study, the gB homolog of MDV was expressed in insect cells by a recombinant baculovirus, and it was characterized to determine its molecular and antigenic properties. The expressed recombinant protein had three molecular sizes (88 to 110, 58, and 49 kDa) and was recognized by antisera from chickens inoculated with each of the three serotypes of MDV. By immunofluorescence analysis, it was shown that the protein was expressed in the cytoplasm and on the surface of the recombinant baculovirus-infected cells. The gB homolog of MDV was processed similarly to pseudorabies virus and varicella-zoster virus with respect to cleavage and the intramolecular disulfide bond between the cleaved products. Interestingly, the expressed protein reacted with monoclonal antibody M51, specific to the B antigen (gp100, gp60, gp49) of MDV, although the locations of the gene encoding the B antigen and of the gene encoding the gB homolog were reported to be different. Moreover, competitive experiments revealed that anti-gB homolog serum and monoclonal antibody M51 recognized the same molecules. From these results, the gB homolog and the B antigen of MDV seem to be the same glycoprotein.     

Characterization of a Discontinuous Neutralizing Epitope on Glycoprotein B of Human Cytomegalovirus

Human cytomegalovirus (HCMV) is a ubiquitously distributed pathogen that causes severe disease in immunosuppressed patients and newborn infants infected in utero. The viral envelope glycoprotein B (gB) is an attractive molecule for active vaccination and passive immunoprophylaxis and therapy. Using human monoclonal antibodies (MAbs), we have recently identified antigenic region 4 (AD-4) on gB as an important target for neutralizing antibodies. AD-4 is formed by a discontinuous sequence comprising amino acids 121 to 132 and 344 to 438 of gB of HCMV strain AD169. To map epitopes for human antibodies on this protein domain, we used a three-dimensional (3D) model of HCMV gB to identify surface-exposed amino acids on AD-4 and selected juxtaposed residues for alanine scans. A tyrosine (Y) at position 364 and a lysine (K) at position 379 (the YK epitope), which are immediate neighbors on the AD-4 surface, were found to be essential for binding of the human MAbs. Recognition of AD-4 by sera from HCMV-infected individuals also was largely dependent on these two residues, indicating a general importance for the antibody response against AD-4. A panel of AD-4 recombinant viruses harboring mutations at the crucial antibody binding sites was generated. The viruses showed significantly reduced susceptibility to neutralization by AD-4-specific MAbs or polyclonal AD-4-specific antibodies, indicating that the YK epitope is dominant for the AD-4-specific neutralizing antibody response during infection. To our knowledge, this is the first molecular identification of a functional discontinuous epitope on HCMV gB. Induction of antibodies specific for this epitope may be a desirable goal following vaccination with gB.     

The early expression of glycoprotein B from herpes simplex virus can be detected by antigen-specific CD8+ T cells

The immune response to cutaneous herpes simplex virus type 1 (HSV-1) infection begins with remarkable rapidity. Activation of specific cytotoxic T lymphocytes (CTL) begins within hours of infection, even though the response within the draining lymph nodes peaks nearly 5 days later. HSV gene products are classified into three main groups, alpha, beta, and gamma, based on their kinetics and requirements for expression. In C57BL/6 mice, the immunodominant epitope from HSV is derived from glycoprotein B (gB(498-505)). While gB is considered a gamma or "late" gene product, previous reports have indicated that some level of gene expression may occur soon after infection. Using brefeldin A as a specific inhibitor of viral antigen presentation to major histocompatibility complex class I-restricted CTL, we have formally addressed the timing of gB peptide expression in an immunologically relevant manner following infection. Presentation of gB peptide detected by T-cell activation was first observed within 2 h of infection. Comparison with another viral epitope expressed early during infection, HSV-1 ribonucleotide reductase, demonstrated that gB is presented with the same kinetics as this classical early-gene product. Moreover, this rapidity of gB expression was further illustrated via rapid priming of na?ve transgenic CD8(+) T cells in vivo after HSV-1 infection of mice. These results establish that gB is expressed rapidly following HSV-1 infection, at levels capable of effectively stimulating CD8(+) T cells.     

Full length antigen priming enhances the CTL epitope-based DNA vaccine efficacy

Although CD8⁺ cytotoxic T lymphocyte (CTL) epitope-based DNA vaccination is valuable experience on vaccine research but many attempts are still continued to achieve acceptable protective response. To study the role of full length antigen in CTL epitope immunization, we evaluated cellular immunity of diverse patterns of complete Herpes simplex virus type 1 (HSV-1) glycoprotein B (gB) and the immunodominant CTL epitope (498–505) DNA injection in C57BL/6 mice. Optimal immune response was observed in the group immunized with the full length of gB in the first injection and CTL epitope in the second and third vaccination as assessed by lymphocyte proliferation assay (MTT), cytokine assay (ELISA) and CTL assay. B cell and spatially CD4⁺ T cell epitopes in full length protein might be important for appropriate priming of CTL immune response. These findings may have important implication for the improvement of CTL epitope based DNA vaccine against HSV and other pathogens.     

Production of Aujeszky's disease (pseudorabies) virus envelope glycoproteins gB and gC as recombinant polyhedra in baculovirus-infected silkworm larvae

The expression of viral antigens in baculovirus-infected insect cells is often ineffective. As an alternative approach, therefore, we developed the recombinant polyhedra technology, which is an efficient strategy for the production of viral subunit vaccine. Here, we report a strategy for the large-scale production of a pseudorabies virus (PRV) gB or gC in the larvae of a baculovirus-infected silkworm, Bombyx mori. We constructed a recombinant B. mori nucleopolyhedrovirus (BmNPV) that expressed recombinant polyhedra together with the epitope regions of PRV gB or heparin-binding domains of PRV gC. Recombinant BmNPV-PRV-gB or BmNPV-PRV-gC-infected silkworm larvae expressed native polyhedrin and fusion protein that was detected using both anti-polyhedrin and anti-PRV gB or anti-PRV-gC antibodies. Electron and confocal microscopy demonstrated that the recombinant polyhedra contained both the fusion protein and native polyhedrin with a normal morphology and that the recombinant polyhedra contained PRV gB or gC. The yield of gB or gC antigen produced in BmNPV-PRV-gB or BmNPV-PRV-gC-infected silkworm larvae reached 0.69 or 0.46 mg per larva, respectively, at 6 days post-infection. These results demonstrate that the recombinant polyhedra strategy can be used for the large-scale production of PRV gB or gC antigen.     

A Human CD4+ T Cell Epitope in the Influenza Hemagglutinin Is Cross-Reactive to Influenza A Virus Subtypes and to Influenza B Virus

The hemagglutinin protein (HA) of the influenza virus family is a major antigen for protective immunity. Thus, it is a relevant target for developing vaccines. Here, we describe a human CD4(+) T cell epitope in the influenza virus HA that lies in the fusion peptide of the HA. This epitope is well conserved in all 16 subtypes of the HA protein of influenza A virus and the HA protein of influenza B virus. By stimulating peripheral blood mononuclear cells (PBMCs) from a healthy adult donor with peptides covering the entire HA protein based on the sequence of A/Japan/305/1957 (H2N2), we generated a T cell line specific to this epitope. This CD4(+) T cell line recognizes target cells infected with influenza A virus seasonal H1N1 and H3N2 strains, a reassortant H2N1 strain, the 2009 pandemic H1N1 strain, and influenza B virus in cytotoxicity assays and intracellular-cytokine-staining assays. It also lysed target cells infected with avian H5N1 virus. We screened healthy adult PBMCs for T cell responses specific to this epitope and found individuals who had ex vivo gamma interferon (IFN-γ) responses to the peptide epitope in enzyme-linked immunospot (ELISPOT) assays. Almost all donors who responded to the epitope had the HLA-DRB1*09 allele, a relatively common HLA allele. Although natural infection or standard vaccination may not induce strong T and B cell responses to this highly conserved epitope in the fusion peptide, it may be possible to develop a vaccination strategy to induce these CD4(+) T cells, which are cross-reactive to both influenza A and B viruses.     

Glycoprotein B of herpes simplex virus type 1 oligomerizes through the intermolecular interaction of a 28-amino-acid domain.

Herpes simplex virus type 1 glycoprotein B (gB) is an envelope component that plays an essential role in virus infection. The biologically active form of gB is an oligomer that contributes to the process of viral envelope fusion with the cell surface membrane, resulting in viral penetration and initiation of the replication cycle. In previous studies, two discontinuous sites for oligomer formation were identified: a nonessential upstream site located between residues 93 and 282 and an essential downstream site located between residues 596 and 711. In this study, in vitro-transcribed and -translated gB test molecules were used to characterize the more active essential membrane-proximal domain. A series of gB test polypeptides mutated in this downstream oligomerization domain were assayed for their abilities to form oligomers with a mutant gB capture polypeptide containing the analogous wild-type domain. Detection of oligomers was achieved by coimmunoprecipitation of two gB mutant molecules by using a monoclonal antibody specific for a hemagglutinin epitope tag introduced into the coding sequence of the capture polypeptide. Analysis of the immune-precipitated products by sodium dodecyl sulfate-polyacrylamide gel electrophoresis demonstrated that the downstream oligomerization domain resided within residues 626 to 676. This region was further resolved into two segments, residues 626 to 653 and 653 to 675, each of which was independently sufficient to form oligomers. However, residues 626 to 653 provided for a stronger interaction between gB monomers. Moreover, this stretch of 28 amino acids was shown to form oligomers when introduced into the carboxy-terminal region of gB monomers lacking this domain at the normal site, thus indicating that this domain was functionally independent of its natural location within the gB molecule. Further analysis of the sequence within residues 596 to 653 by using mutant test polypeptides altered in individual amino acids revealed that cysteines 9 and 10 located at positions 596 and 633, respectively, were not required for oligomer formation but contributed to dimer formation and/or stabilization. The results of this study suggest that oligomerization of gB monomers is induced by interactions between contiguous residues localized within the ectodomain near the site of molecule insertion into the viral envelope membrane.     

一株抗蓝舌病病毒8型VP2蛋白单克隆抗体识别的线性抗原表位的鉴定

为研究本实验室制备的一株抗蓝舌病病毒8型(BTV-8)VP2蛋白的单克隆抗体(MAb)3G11识别的B细胞抗原表位,利用噬菌体肽库展示技术对3G11识别的抗原表位进行筛选并鉴定。经过4轮淘选后挑取蓝斑测序,测序结果经分析后获得KLLAT序列,与BTV-8 VP2蛋白氨基酸序列比对后获得共同的短肽序列为283LL284;合成4种短肽序列:KLLAA、KALAT、KLAAT和KLLAT,与3G11细胞上清和腹水分别进行间接ELISA鉴定,结果表明,短肽KLLAA和KLLAT与3G11细胞上清及腹水具有较强的结合能力;与24种BTV标准阳性血清反应结果表明,这两种短肽都可与BTV-8阳性血清发生特异性反应;序列分析结果可见,该表位的氨基酸序列283LL284在不同来源的BTV-8毒株间保守,确定283LL284为MAb3G11识别抗原表位的关键氨基酸。本研究为建立8型BTV特异性的免疫学检测方法和相关病毒蛋白的功能研究奠定了基础。     

PRRSV NJ-a株ORF5基因A表位的修饰与糖基化位点的突变对其DNA疫苗免疫效力的影响

为了提高PRRSVORF5基因的免疫效力,对ORF5基因进行了改造,将CpG序列和通用型辅助性T淋巴细胞表位插入A表位与B表位之间,并对N33与N51位糖基化位点进行了点突变,获得改造的ORF5基因。在此基础上构建了由两个CMV启动子调控的共表达改造的ORF5(MORF5)与ORF6基因的真核表达质粒pcDNA-M5A-6A。经Western-blot与IFA验证真核质粒的体外表达后,免疫6周龄Balb/c小鼠,利用微量中和试验检测免疫后的中和抗体,利用MTT法检测免疫后淋巴细胞的增生情况,并与未改造ORF5基因真核表达质粒pcDNA-5A-6A、弱毒疫苗以及灭活疫苗的免疫效果进行比较。结果表明,pcDNA-M5A-6A不但能够刺激免疫小鼠在较短的时间内产生更高水平的中和抗体,而且可以诱导产生更强烈的T淋巴细胞增殖反应。所构建的共表达PRRSV改造的ORF5基因与ORF6基因的DNA疫苗pcDNA-M5A-6A,能够较好的诱发小鼠产生较高的特异性针对PRRSV的中和抗体和细胞免疫应答,为研究能够更好地防制PRRSV的新型疫苗提供了新的思路。