Immune Potential of a Novel Multiple-epitope Vaccine to FMDV Type Asia 1 in Guinea Pigs and Sheep

To develop a safe and efficient recombinant subunit vaccine to foot-and-mouth disease virus (FMDV) type Asia 1 in sheep, a tandem repeated multiple-epitope gene consisting of residues 137-160 and 197-211 of the VP1 gene of FMDV was designed and artificially synthesized. The biologically functional molecule, the ovine IgG heavy constant region (oIgG) as a protein carrier was introduced for design of the multiple-epitope recombinant vaccine and recombinant expression plasmids pET-30a-RE and pET-30a-RE-oIgG we...     

Protection against Foot-and-Mouth Disease Virus in Guinea Pigs via Oral Administration of Recombinant Lactobacillus plantarum Expressing VP1

Mucosal vaccination is an effective strategy for generating antigen-specific immune responses against mucosal infections of foot-and-mouth disease virus (FMDV). In this study, Lactobacillus plantarum strains NC8 and WCFS1 were used as oral delivery vehicles containing a pSIP411-VP1 recombinant plasmid to initiate mucosal and systemic immune responses in guinea pigs. Guinea pigs were orally vaccinated (three doses) with NC8-pSIP411, NC8-pSIP411-VP1, WCFS1-pSIP411, WCFS1-pSIP411-VP1 or milk. Animals immunized with NC8-pSIP411-VP1 and WCFS1-pSIP411-VP1 developed high levels of antigen-specific serum IgG, IgA, IgM, mucosal secretory IgA (sIgA) and neutralizing antibodies, and revealed stronger cell-mediated immune responses and enhanced protection against FMDV challenge compared with control groups. The recombinant pSIP411-VP1 effectively improved immunoprotection against FMDV in guinea pigs.     

Asia Ⅰ型口蹄疫病毒中和表位与羊IgG重链恒定区的融合表达及免疫原性测定

VP1蛋白是口蹄疫病毒(Foot-and-Mouth Disease Virus,FMDV)诱导机体产生抗病毒感染免疫的主要蛋白,含有病毒的若干中和表位.本研究设计和合成了由Asia Ⅰ型FMDV VP1蛋白136～160aa和198～211aa两个表位组成的重复串联表位的编码基因,并克隆了羊IgG重链恒定区编码基因.利用BamH I、EcoR I和Xho I位点将2个基因片段依次克隆到pPROExHTb载体,构建成重组质粒pPRO-FshIgG,将其转化大肠杆菌BL21(DE3)感受态细胞,以IPTG诱导表达得到融合蛋白FshIgG.100μg FshIgG蛋白免疫豚鼠后刺激豚鼠产生了高效价的FMDV中和抗体,而且使这些免疫豚鼠在用200 ID_(50)剂量FMDV攻击时得到了完全保护.由此证明,羊IgG重链恒定区蛋白能够作为FMDV表位肽的载体,而融合蛋白FshIgG可成为一种口蹄疫表位疫苗候选物用于口蹄疫的预防.     

Virus-like particles of recombinant PCV2b carrying FMDV-VP1 epitopes induce both anti-PCV and anti-FMDV antibody responses

Mixed infection of porcine circovirus type 2 (PCV2) and foot-and-mouth disease virus (FMDV) is devastating to swine populations. To develop an effective vaccine that can protect the pigs from the infection of PCV2 and FMDV, we used the neutralizing B cell epitope region (aa 135–160) of FMDV to replace the regions aa 123–151 and aa 169–194 of the PCV2b Cap protein to generate a recombinant protein designated as Capfb. The Capfb protein was expressed in Escherichia coli system and the purified Capfb protein assembled into virus-like particles (VLPs) through dialysis. The ability of the Capfb protein to induce effective immune response against FMDV and PCV2b was tested in mice and guinea pigs. The results showed that the Capfb-VLPs could elicit anti-PCV2b and anti-FMDV antibody response in mice and guinea pigs without inducing antibodies against decoy epitope. Moreover, the Capfb-VLPs could enhance the percentage and activation of B cells in lymph nodes when the mice were stimulated with inactivated FMDV or PCV2b. These data suggested that the Capfb-VLPs could be an efficacious candidate antigen for developing a novel PCV2b-FMDV bivalent vaccine.

     

重组鸡痘病毒和DNA疫苗对口蹄疫病毒的豚鼠免疫保护

将构建的携带FMDV衣壳蛋白P1-2A和蛋白酶3C编码基因的重组鸡痘病毒活载体疫苗vUTAL3CP1以及编码FMDVP1-2A基因和猪IL-18基因的重组DNA疫苗pVIRIL18P1,分别以单独和混合的方式给豚鼠进行2次免疫,然后测定FMDV特异性结合抗体、中和抗体和T淋巴细胞增殖反应,并用250ID50的FMDV进行攻击,观察其保护效果。结果表明这2种基因工程疫苗均能诱导豚鼠产生特异性的体液免疫及细胞免疫应答。其中以vUTAL3CP1两次免疫组的效果最好,其诱导的抗体水平已接近于常规灭活疫苗,而细胞免疫水平则比后者高得多。攻击保护结果表明该组完全保护率可达3/4,而另外两组也具有一定保护效果。上述研究结果为进一步进行大动物免疫攻毒试验,并最终筛选出最佳疫苗和免疫程序奠定了基础。     

Chimeric virus-like particles elicit protective immunity against serotype O foot-and-mouth disease virus in guinea pigs

Foot-and-mouth disease (FMD) is an acute and highly contagious disease caused by foot-and-mouth disease virus (FMDV) that can affect cloven-hoofed animal species, leading to severe economic losses worldwide. Therefore, the development of a safe and effective new vaccine to prevent and control FMD is both urgent and necessary. In this study, we developed a chimeric virus-like particle (VLP) vaccine candidate for serotype O FMDV and evaluated its protective immunity in guinea pigs. Chimeric VLPs were formed by the antigenic structural protein VP1 from serotype O and segments of the viral capsid proteins (VP2, VP3, and VP4) from serotype A. The chimeric VLPs elicited significant humoral and cellular immune responses with a higher level of anti-FMDV antibodies and cytokines than the control group. Furthermore, four of the five guinea pigs vaccinated with the chimeric VLPs were completely protected against challenge with 100 50% guinea pig infectious doses (GPID₅₀) of the virulent FMDV strain O/MAY98. These data suggest that chimeric VLPs are potential candidates for the development of new vaccines against FMDV.     

O型口蹄疫病毒VP1 T细胞、B细胞表位双拷贝基因与大肠杆菌LTB、STI肠毒素基因融合表达产物的免疫应答

合成O型口蹄疫病毒VP1蛋白中与细胞免疫（21～40表位肽）及体液免疫（141～160表位肽）相关的基因序列2020VP1,运用基因工程技术构建了含有肠毒素大肠杆菌LTB、STI基因及双拷贝2020VP1的融合表达载体r2020-B-2020-STI,转化宿主菌BL21(DE3)RIL后的表达产物经SDS-PAGE分析,结果显示重组融合蛋白的分子量约为45kDa,表达量较高。ELISA实验结果显示,融合蛋白能与霍乱毒素（choleratoxin）CTB抗体特异结合。动物实验表明,融合蛋白能够诱发兔体产生较强的FMDV中和抗体,免疫豚鼠在低浓度FMDV刺激下能够产生特异性T淋巴细胞增殖反应,说明融合蛋白能诱导机体产生FMDV特异性细胞及体液免疫反应;同时,融合蛋白免疫雌鼠能够抵抗大肠杆菌强毒株攻击,免疫兔体能够产生STI中和抗体,且融合蛋白不具STI毒性,证明融合蛋白具有良好的LTB、STI免疫原性。实验结果表明,此融合蛋白具有开发成为口蹄疫及肠毒素腹泻联合疫苗的应用价值。     

Induction of HIV neutralizing antibodies against the MPER of the HIV envelope protein by HA/gp41 chimeric protein-based DNA and VLP vaccines

Several conserved neutralizing epitopes have been identified in the HIV Env protein and among these, the MPER of gp41 has received great attention and is widely recognized as a promising target. However, little success has been achieved in eliciting MPER-specific HIV neutralizing antibodies by a number of different vaccine strategies. We investigated the ability of HA/gp41 chimeric protein-based vaccines, which were designed to enhance the exposure of the MPER in its native conformation, to induce MPER-specific HIV neutralizing antibodies. In characterization of the HA/gp41 chimeric protein, we found that by mutating an unpaired Cys residue (Cys-14) in its HA1 subunit to a Ser residue, the modified chimeric protein HA-C14S/gp41 showed increased reactivity to a conformation-sensitive monoclonal antibody against HA and formed more stable trimers in VLPs. On the other hand, HA-C14S/gp41 and HA/gp41 chimeric proteins expressed on the cell surfaces exhibited similar reactivity to monoclonal antibodies 2F5 and 4E10. Immunization of guinea pigs using the HA-C14S/gp41 DNA or VLP vaccines induced antibodies against the HIV gp41 as well as to a peptide corresponding to a segment of MPER at higher levels than immunization by standard HIV VLPs. Further, sera from vaccinated guinea pigs were found to exhibit HIV neutralizing activities. Moreover, sera from guinea pigs vaccinated by HA-C14S/gp41 DNA and VLP vaccines but not the standard HIV VLPs, were found to neutralize HIV pseudovirions containing a SIV-4E10 chimeric Env protein. The virus neutralization could be blocked by a MPER-specific peptide, thus demonstrating induction of MPER-specific HIV neutralizing antibodies by this novel vaccine strategy. These results show that induction of MPER-specific HIV neutralizing antibodies can be achieved through a rationally designed vaccine strategy.     

Correlation between efficacy and structure of recombinant epitope vaccines against bovine type O foot and mouth disease virus

To develop recombinant epitope vaccines against foot-and-mouth disease virus (FMDV), genes coding for six recombinant proteins (rP1–rP6) consisting of different combinations of B cell and T cell epitope from VP1 capsid protein (VP1) of type O FMDV were constructed and the 3D structure of these proteins analyzed. This revealed a surface-exposed RGD sequence of B cell epitopes in all six recombinant proteins as that in VP1 of FMDV and rP1, rP2 and rP4 globally mimicked the backbone conformation of the VP1. rP1, rP2 and rP4 stimulated guinea pigs to produce higher level of neutralizing antibodies capable of protecting suckling mice against FMDV challenge. rP1 stimulated cattle to produce FMDV-neutralizing antibody. The data suggest that an efficient recombinant epitope vaccine against FMDV should share local similarities with the natural VP1 of FMDV.     

Novel polyvalent live vaccine against varicella–zoster and mumps virus infections

The varicella–zoster virus (VZV) Oka vaccine strain (vOka) is a highly immunogenic and safe live vaccine that has long been used worldwide. Because its genome is large, making it suitable for inserting foreign genes, vOka is considered a candidate vector for novel polyvalent vaccines. Previously, a recombinant vOka, rvOka‐HN, that expresses mumps virus (MuV) hemagglutinin‐neuraminidase (HN) was generated by the present team. rvOka‐HN induces production of neutralizing antibodies against MuV in guinea pigs. MuV also expresses fusion (F) protein, which is important for inducing neutralizing antibodies, in its viral envelope. To induce a more robust immune response against MuV than that obtained with rvOka‐HN, here an rvOka expressing both HN and F (rvOka‐HN‐F) was generated. However, co‐expression of HN and F caused the infected cells to form syncytia, which reduced virus titers. To reduce the amount of cell fusion, an rvOka expressing HN and a mutant F, F(S195Y) were generated. Almost no syncytia formed among the rvOka‐HN‐F(S195Y)‐infected cells and the growth of rvOka‐HN‐F(S195Y) was similar to that of the original vOka clone. Moreover, replacement of serine 195 with tyrosine had no effect on the immunogenicity of F in mice and guinea pigs. Although obvious augmentation of neutralizing antibody production was not observed after adding F protein to vOka‐HN, the anti‐F antibodies did have neutralizing activity. These data suggest that F protein contributes to induction of immune protection against MuV. Therefore this recombinant virus is a promising candidate vaccine for polyvalent protection against both VZV and MuV.     

口蹄疫病毒VP1基因在番茄中的表达及转基因番茄对豚鼠诱导免疫保护

构建克隆有O型口蹄疫病毒China99株VP1基因的植物双元表达载体pBin438/VP1。通过农杆菌介导法转化番茄子叶,经卡那霉素抗性筛选,获得60株抗性植株。对抗性植株分别做PCR、RT-PCR检测目的基因的整合与转录,ELISA筛选约40%的卡那抗性植株阳性,分别提取两株ELISA和Western blot检测阳性的转基因番茄叶片蛋白与弗氏佐剂乳化,于0、15、30d经肌肉途径免疫豚鼠,第三次免疫后28d用100ID50的同源强毒攻击,根据豚鼠抗体水平的消长动态和免疫豚鼠抗强毒攻击的保护率进行转基因植物疫苗免疫原性的评估。结果表明,双元表达载体pBin438/VP1构建正确,PCR、RT-PCR结果证实口蹄疫病毒VP1基因已整合到番茄基因组并在转录水平表达,ELISA和Western blot检测重组蛋白能够与FMDV阳性血清反应。转基因番茄第三次免疫豚鼠后21d血清效价最高可达1∶64,攻毒后两组免疫豚鼠保护率分别达80%和40%,证明转基因番茄表达的VP1蛋白具有良好的免疫原性。     

以猪IgG重链恒定区为抗原载体的抗口蹄疫病毒DNA疫苗的研制

口蹄疫(Foot-and-Mouth Disease, FMD)是当今世界上最为严重的家畜传染病之一,主要危害猪、牛、羊等偶蹄动物.FMD的致病原为FMD病毒(FMDV),属小RNA病毒科口蹄疫病毒属,有A、O、C、SATⅠ、SATⅡ、SATⅢ及AsiaⅠ共7个血清型.FMDV结构较简单,完整的病毒颗粒由4种结构蛋白VP1、VP2、VP3及VP4各60个拷贝构成的衣壳包裹一条单股正链RNA组成,其中VP1是主要的抗原蛋白[1].     

Expression, processing, and assembly of foot-and-mouth disease virus capsid structures in heterologous systems: induction of a neutralizing antibody response in guinea pigs.

Plasmids containing the foot-and-mouth disease virus structural protein precursor (P1) and 3C protease genes or the P1 gene alone were expressed in Escherichia coli. A recombinant baculovirus containing the P1 gene was also generated and expressed in Spodoptera frugiperda cells. Expression of the P1 and 3C genes in E. coli resulted in efficient synthesis and processing of the structural protein precursor and assembly into 70S empty capsids. This material reacted with neutralizing monoclonal antibodies which recognize only conformational epitopes and elicited a significant neutralizing antibody response in vaccinated guinea pigs. Expression of the P1 gene in E. coli resulted in synthesis of an insoluble product, whereas in insect cells infected with the recombinant baculovirus a soluble product was synthesized. Both soluble and insoluble P1 reacted with a 12S-specific monoclonal antibody, but only soluble P1 elicited a neutralizing antibody response in guinea pigs.     

三种大肠杆菌表达的口蹄疫病毒A型多表位蛋白对猪的免疫原性比较

【目的】研制猪口蹄疫病毒(foot-and-mouth disease virus,FMDV)A型多表位蛋白疫苗,为猪FMDV A型的防控提供安全有效的疫苗。【方法】根据前期试验结果及国内外FMDVA型流行病学信息,设计并合成了3种多表位免疫原基因A10、IA10和FA10。在大肠杆菌BL21(DE3)中诱导表达,表达蛋白纯化复性后,制苗免疫猪。分别于免疫前和免疫后14和28d采血分离血清,用液相阻断ELISA(LPB-ELISA)方法检测血清IgG抗体滴度。免疫28d后用FMDV强毒攻毒,以评估免疫保护效果。【结果】SDS-PAGE和Western blotting结果证实A10、IA10和FA10三种蛋白均获得表达,分子量分别为35、57和64 kDa,与预测蛋白大小一致,且能被FMDV感染阳性血清所识别。LPB-ELISA结果表明,A10+201免疫组IgG滴度低于灭活疫苗组,但高于其他免疫组。攻毒后A10+201免疫组和灭活疫苗免疫组全部猪(5/5)获得保护,IA10+201和FA10+201免疫组80%(4/5)猪保护,A10和FA10免疫组只有20%(1/5)猪保护,而PBS+201组所有猪均未保护。【结论】A10+201免疫保护效果较好,可作为候选疫苗进行进一步评价。     

Randomized Controlled Field Trial to Assess the Immunogenicity and Safety of Rift Valley Fever Clone 13 Vaccine in Livestock

BackgroundAlthough livestock vaccination is effective in preventing Rift Valley fever (RVF) epidemics, there are concerns about safety and effectiveness of the only commercially available RVF Smithburn vaccine. We conducted a randomized controlled field trial to evaluate the immunogenicity and safety of the new RVF Clone 13 vaccine, recently registered in South Africa.MethodsIn a blinded randomized controlled field trial, 404 animals (85 cattle, 168 sheep, and 151 goats) in three farms in Kenya were divided into three groups. Group A included males and non-pregnant females that were randomized and assigned to two groups; one vaccinated with RVF Clone 13 and the other given placebo. Groups B included animals in 1^st half of pregnancy, and group C animals in 2^nd half of pregnancy, which were also randomized and either vaccinated and given placebo. Animals were monitored for one year and virus antibodies titers assessed on days 14, 28, 56, 183 and 365.ResultsIn vaccinated goats (N = 72), 72% developed anti-RVF virus IgM antibodies and 97% neutralizing IgG antibodies. In vaccinated sheep (N = 77), 84% developed IgM and 91% neutralizing IgG antibodies. Vaccinated cattle (N = 42) did not develop IgM antibodies but 67% developed neutralizing IgG antibodies. At day 14 post-vaccination, the odds of being seropositive for IgG in the vaccine group was 3.6 (95% CI, 1.5 – 9.2) in cattle, 90.0 (95% CI, 25.1 – 579.2) in goats, and 40.0 (95% CI, 16.5 – 110.5) in sheep. Abortion was observed in one vaccinated goat but histopathologic analysis did not indicate RVF virus infection. There was no evidence of teratogenicity in vaccinated or placebo animals.ConclusionsThe results suggest RVF Clone 13 vaccine is safe to use and has high (>90%) immunogenicity in sheep and goats but moderate (> 65%) immunogenicity in cattle.     

Recombinant IgA Is Sufficient To Prevent Influenza Virus Transmission in Guinea Pigs

A serum hemagglutination inhibition (HAI) titer of 40 or greater is thought to be associated with reduced influenza virus pathogenesis in humans and is often used as a correlate of protection in influenza vaccine studies. We have previously demonstrated that intramuscular vaccination of guinea pigs with inactivated influenza virus generates HAI titers greater than 300 but does not protect vaccinated animals from becoming infected with influenza virus by transmission from an infected cage mate. Only guinea pigs intranasally inoculated with a live influenza virus or a live attenuated virus vaccine, prior to challenge, were protected from transmission (A. C. Lowen et al., J. Virol. 83:2803–2818, 2009.). Because the serum HAI titer is mostly determined by IgG content, these results led us to speculate that prevention of viral transmission may require IgA antibodies or cellular immune responses. To evaluate this hypothesis, guinea pigs and ferrets were administered a potent, neutralizing mouse IgG monoclonal antibody, 30D1 (Ms 30D1 IgG), against the A/California/04/2009 (H1N1) virus hemagglutinin and exposed to respiratory droplets from animals infected with this virus. Even though HAI titers were greater than 160 1 day postadministration, Ms 30D1 IgG did not prevent airborne transmission to passively immunized recipient animals. In contrast, intramuscular administration of recombinant 30D1 IgA (Ms 30D1 IgA) prevented transmission to 88% of recipient guinea pigs, and Ms 30D1 IgA was detected in animal nasal washes. Ms 30D1 IgG administered intranasally also prevented transmission, suggesting the importance of mucosal immunity in preventing influenza virus transmission. Collectively, our data indicate that IgG antibodies may prevent pathogenesis associated with influenza virus infection but do not protect from virus infection by airborne transmission, while IgA antibodies are more important for preventing transmission of influenza viruses.     

Elicitation of immunity in mice after immunization with the S2 subunit of the severe acute respiratory syndrome coronavirus

The S2 domain of the severe acute respiratory syndrome coronavirus (SARS-CoV) spike (S) protein is responsible for fusion between virus and target cell membranes, and is expected to be immungenic. In this study, we investigated the immune responses against the S2 subunit in BALB/c mice, which were vaccinated either with plasmid DNA encoding the S2 domain (residues 681-1120), the recombinant S2 fragment (residues 681-980) in incomplete Freund's adjuvant, or with inactivated SARS-CoV. The increased number of specific cytotoxic cells (CTLs) and the high titer of specific antibody showed stimulation of both arms of the immune system in these groups. The shift in cytokines suggested that Th1-polarized immune response was induced by plasmid pCoVS2, meanwhile the Th2-dominant response was induced by recombinant S2 fragment and inactivated vaccine. However, the titer of neutralizing antibodies was only detectable in mice immunized with inactivated virus, but not with pCoVS2 plasmid. Taken together, the S2 domain could induce specific cellular immune response and a high level of total IgG but little neutralizing antibodies against infection by SARSCoV.     

The Effect of Bovine IFN-α on the Immune Response in Guinea Pigs Vaccinatedwith DNA Vaccine of Foot-and-Mouth Disease Virus

Foot-and-mouth disease virus (FMDV) belongs to thegenus Aphthovirus of the family Picornavidae. The FMDVgenome is a copy of positive-sense, single-stranded RNA,which contains one large open reading frame (ORF). TheORF is translated into a polypeptide, which undergoesautoproteolytic cleavage to produce the structural and non-structural proteins and ultimately forms mature viral pro-teins [1,2]. FMD is caused by the FMDV, which is a highly conta-gious vesicular disease of cloven-hoofe…