First peptide vaccine providing protection against viral infection in the target animal: studies of canine parvovirus in dogs.

A synthetic peptide vaccine which protects dogs against challenge with virulent canine parvovirus is described. The amino acid sequence used was discovered in previous studies on the immunogenic properties of previously mapped antigenic sites and represents the amino-terminal region of viral protein VP2. As with marker vaccines, it is possible to discriminate between vaccinated dogs that have not been exposed to the virus and dogs that have been infected with the virus. The protective mechanism can be explained by a humoral response against the peptide aided by T-cell epitopes contained in the carrier protein used for peptide coupling. This is the first example of a synthetic peptide vaccine that induces protection in target animals.     

Interspecies major histocompatibility complex-restricted Th cell epitope on foot-and-mouth disease virus capsid protein VP4

T-cell epitopes within viral polypeptide VP4 of the capsid protein of foot-and-mouth disease virus were analyzed using 15-mer peptides and peripheral blood mononuclear cells (PBMC) from vaccinated outbred pigs. An immunodominant region between VP4 residues 16 and 35 was identified, with peptide residues 20 to 34 (VP4-0) and 21 to 35 (VP4-5) particularly immunostimulatory for PBMC from all of the vaccinated pigs. CD25 upregulation on peptide-stimulated CD4(+) CD8(+) cells-dominated by Th memory cells in the pig-and inhibition using anti-major histocompatibility complex class II monoclonal antibodies indicated recognition by Th lymphocytes. VP4-0 immunogenicity was retained in a tandem peptide with the VP1 residue 137 to 156 sequential B-cell epitope. This B-cell site also retained immunogenicity, but evidence is presented that specific antibody induction in vitro required both this and the T-cell site. Heterotypic recognition of the residue 20 to 35 region was also noted. Consequently, the VP4 residue 20 to 35 region is a promiscuous, immunodominant and heterotypic T-cell antigenic site for pigs that is capable of providing help for a B-cell epitope when in tandem, thus extending the possible immunogenic repertoire of peptide vaccines.     

Identification of B cell epitopes of dengue virus 2 NS3 protein by monoclonal antibody

Dengue virus is a major international public health concern, and there is a lack of available effective vaccines. Virus-specific epitopes could help in developing epitope peptide vaccine. Previously, a neutralizing monoclonal antibody (mAb) 4F5 against nonstructural protein 3 (NS3) of dengue virus 2 (DV2) was developed in our lab. In this work, the B cell epitope recognized by mAb 4F5 was identified using the phage-displayed peptide library. The results of the binding assay and competitive inhibition assay indicated that the peptides, residues 460–469 (U460-469 RVGRNPKNEN) of DV2 NS3 protein, were the B cell epitopes recognized by mAb 4F5. Furthermore, the epitope peptides and a control peptide were synthesized and then immunized female BALB/c mice. ELISA analysis showed that immunization with synthesized epitope peptide elicited a high level of antibody in mice, and immunofluorescent staining showed that the antisera from fusion epitope-immunized mice also responded to DV2 NS3 protein, which further characterized the specific response of the present epitope peptide. Therefore, the present work revealed the specificity of the newly identified epitope (U460-469) of DV2 NS3 protein, which may shed light on dengue virus (DV) vaccine design, DV pathogenesis study, and even DV diagnostic reagent development.     

Recombinant VP1 protein expressed in Pichia pastoris induces protective immune responses against EV71 in mice

Human enterovirus 71 (EV71) is one of the major causative agents of hand, foot and mouth disease and is also associated with serious neurological diseases in children. Currently, there are no effective antiviral drugs or vaccines against EV71 infection. VP1, one of the major immunogenic capsid proteins of EV71, is widely considered to be the candidate antigen for an EV71 vaccine. In this study, VP1 of EV71 was expressed as a secretory protein with an N-terminal histidine tag in the methylotrophic yeast Pichia pastoris, and purified by Ni–NTA affinity chromatography. Immunogenicity and vaccine efficacy of the recombinant VP1 were assessed in mouse models. The results showed that the recombinant VP1 could efficiently induce anti-VP1 antibodies in BALB/c mice, which were able to neutralize EV71 viruses in an in vitro neutralization assay. Passive protection of neonatal mice further confirmed the prophylactic efficacy of the antisera from VP1 vaccinated mice. Furthermore, VP1 vaccination induced strong lymphoproliferative and Th1 cytokine responses. Taken together, our study demonstrated that the yeast-expressed VP1 protein retained good immunogenicity and was a potent EV71 vaccine candidate.     

Oral immunization with transgenic rice seeds expressing VP2 protein of infectious bursal disease virus induces protective immune responses in chickens

The expression of infectious bursal disease virus (IBDV) host-protective immunogen VP2 protein in rice seeds, its immunogenicity and protective capability in chickens were investigated. The VP2 cDNA of IBDV strain ZJ2000 was cloned downstream of the Gt1 promoter of the rice glutelin GluA-2 gene in the binary expression vector, pCambia1301-Gt1. Agrobacterium tumefaciens containing the recombinant vector was used to transform rice embryogenic calli, and 121 transgenic lines were obtained and grown to maturity in a greenhouse. The expression level of VP2 protein in transgenic rice seeds varied from 0.678% to 4.521% µg/mg of the total soluble seed protein. Specific pathogen-free chickens orally vaccinated with transgenic rice seeds expressing VP2 protein produced neutralizing antibodies against IBDV and were protected when challenged with a highly virulent IBDV strain, BC6/85. These results demonstrate that transgenic rice seeds expressing IBDV VP2 can be used as an effective, safe and inexpensive vaccine against IBDV.     

Synthetic peptide vaccines against foot-and-mouth disease. II. Comparison of the response of guinea-pigs, rabbits and mice to various formulations

The immune response of guinea-pigs to vaccination with either of two aphthovirus-specific synthetic peptides was investigated. One peptide copied the sequence of amino acids 141 to 160 from the VP1 of aphthovirus strains O1BFS 1860 and O1 Kaufbeuren (O peptide), the other copied the equivalent sequence from aphthovirus strain A24 Cruzeiro (A peptide). The immune response was enhanced when the peptides were conjugated to a carried protein, but the choice of carrier protein and cross-linking agent was not critical in obtaining enhancement. The response was greatest when the peptide or peptide-carrier conjugate was adjuvanted in Freund's complete adjuvant (FCA). The O peptide was poorly immunogenic and did not confer protection against challenge with infectious virus, whereas the A peptide had good immunogenicity and did confer protection. This reflected the relative immunogenicity of the parent viruses. Rabbits, three strains of guinea-pigs and seven strains of mice were vaccinated with the O peptide conjugated to keyhole limpet haemocyanin (KLH). Considerable variation was observed between the responses of each strain and it is proposed that this relates to their repertoire of immune response genes.     

Protective immune response to 16 kDa immunoreactive recombinant protein encoding the C-terminal VP1 portion of Foot and Mouth Disease Virus type Asia 1.

Recombinant protein of Foot and Mouth Disease Virus (FMDV) type Asia 1 corresponding to the C-terminal half of VP1 was expressed in Escherichia coli. As an alternative to the synthetic peptide, this selected C-terminal region was used as a protein vaccine in guinea pigs in order to study the immune response with various adjuvant formulations: immune stimulatory complexes (ISCOMs), Montanide ISA 206, Freund's incomplete adjuvant (FIA), lipopolysaccharide (LPS) and cytokine mixture. A primary dose of 40 microg/animal followed by a booster of the same dose was injected after a 21-day interval. The sera were collected at intervals of 21, 42 and 63 days after the booster. The humoral response to vaccine was monitored by sandwich enzyme-linked immunosorbent assay (ELISA) and a serum neutralization test (SNT). The guinea pig sera showed high titers both in ELISA and SNT, which could be protective. Further, irrespective of the adjuvant preparation used, the vaccine conferred protection against the challenge virus 105 days post-vaccination in 13 of 15 animals (86%). The results indicated that a combination of recombinant protein ISCOMs and Montanide ISA 206 would be a better choice for achieving early protective titers and longer lasting immunity and that the C-terminal half of the VP1 protein may be tried as a safe vaccine for secondary immunization.     

Development of a enterovirus diagnostic assay system for diagnosis of viral myocarditis in humans

The coxsackieviruses type B3 (CVB3) are members of the genus Enterovirus of the family Picornaviridae. They are the commonest cause of chronic myocarditis and dilated cardiomyopathy. However, there is still no effective method for diagnosing CVB3 infection in humans. Here, a fast and accurate system that uses a capsid‐protein‐specific peptide sequence to detect CVB3 in the sera of patients with viral myocarditis was established. The peptide sequence was selected from the whole CVB3 capsid protein sequence by computationally predicting fragments with high antigenicity and low hydrophobicity. Two of eight possible peptide sequences were selected and commercially synthesized. The synthesized peptides encoded either the VP2 or VP1 capsid protein and induced immunoglobulin G antibody expression in immunized rabbits. Anti‐VP2 and anti‐VP1 sera detected the viral proteins extracted from CVB3‐infected HeLa cells. The newly synthesized peptides successfully induced antibody production. These peptides, applied in an ELISA system, detected anti‐CVB3 antibodies in virus‐infected mouse serum. Moreover, an ELISA system based on the VP2 peptide detected CVB3 infection in patients with positively identified CVB3‐induced fulminant myocarditis. These results indicate that these new peptides specifically interact with anti‐CVB3 IgG antibodies in mouse and human sera. This ELISA system should be useful for the clinical diagnosis of enterovirus‐induced myocarditis.     

Recombinant M2e Protein-Based ELISA: A Novel and Inexpensive Approach for Differentiating Avian Influenza Infected Chickens from Vaccinated Ones

Available avian influenza (AIV) serological diagnostic tests cannot distinguish vaccinated from naturally infected birds. Differentiation of vaccinated from infected animals (DIVA) is currently advocated as a means of achieving the full control of H5N1. In this study, for the first time, recombinant ectodomain of M2 protein (M2e) of avian influenza virus (H5N1 strain) was used for the DIVA serology test. M2e was cloned into pMAL-P4X vector and expressed in E. coli cells. We used Western blot to recognize the expressed M2e-MBP protein by chicken antisera produced against live H5N1 virus. Also, the specificity of M2e-MBP protein was compared to the M2e synthetic peptide via ELISA. In M2e-MBP ELISA, all sera raised against the live avian influenza viruses were positive for M2e antibodies, whereas sera from killed virus vaccination were negative. Furthermore, M2e-MBP ELISA of the field sera obtained from vaccinated and non-vaccinated chickens showed negative results, while challenged vaccinated chickens demonstrated strong positive reactions. H5N1-originated recombinant M2e protein induced broad-spectrum response and successfully reacted with antibodies against other AIV strains such as H5N2, H9N2, H7N7, and H11N6. The application of the recombinant protein instead of synthetic peptide has the advantages of continues access to an inexpensive reagent for performing a large scale screening. Moreover, recombinant proteins provide the possibility of testing the DIVA results with an additional technique such a Western blotting which is not possible in the case of synthetic proteins. All together, the results of the present investigation show that recombinant M2e-MBP can be used as a robust and inexpensive solution for DIVA test.     

High-level expression of the simian virus 40 genes LP1, VP1 and VP2 as fusion proteins in Escherichia coli

The complete sequences of the SV40 agnogene (LP1) and the genes coding for the capsid proteins VP1 and VP2 have been cloned into Escherichia coli expression plasmids. High levels of expression were obtained when the SV40 genes were inserted into the coding sequence of the influenza virus NS1 gene, which has previously been expressed in E. coli. The NS1A-LP1 and NS1A-VP2 chimeric proteins consist of the 81 N-terminal residues of NS1 (designated as peptide NS1A) fused to the complete sequence of the corresponding SV40 protein. The NS1A-VP1 chimera consists of NS1A followed by a linker of nine arbitrary residues and the complete sequence of the SV40 major capsid protein. The observed levels of expression vary considerably among the three chimeric proteins, ranging from approx. 70 micrograms/ml in the case of NS1A-LP1 to approx. 5 micrograms/ml in the case of NS1A-VP2. Cyanogen bromide cleavage of the NS1A-LP1 fusion protein produces fragments with Mrs expected for isolated NS1A and LP1 peptides. A plasmid has also been constructed which expresses the NS1A peptide in high yield.     

Development of AAVLP(HPV16/31L2) particles as broadly protective HPV vaccine candidate

The human papillomavirus (HPV) minor capsid protein L2 is a promising candidate for a broadly protective HPV vaccine yet the titers obtained in most experimental systems are rather low. Here we examine the potential of empty AAV2 particles (AAVLPs), assembled from VP3 alone, for display of L2 epitopes to enhance their immunogenicity. Insertion of a neutralizing epitope (amino acids 17-36) from L2 of HPV16 and HPV31 into VP3 at positions 587 and 453, respectively, permitted assembly into empty AAV particles (AAVLP(HPV16/31L2)). Intramuscularly vaccination of mice and rabbits with AAVLP(HPV16/31L2)s in montanide adjuvant, induced high titers of HPV16 L2 antibodies as measured by ELISA. Sera obtained from animals vaccinated with the AAVLP(HPV16/31L2)s neutralized infections with several HPV types in a pseudovirion infection assay. Lyophilized AAVLP(HPV16/31L2) particles retained their immunogenicity upon reconstitution. Interestingly, vaccination of animals that were pre-immunized with AAV2--simulating the high prevalence of AAV2 antibodies in the population--even increased cross neutralization against HPV31, 45 and 58 types. Finally, passive transfer of rabbit antisera directed against AAVLP(HPV16/31L2)s protected na?ve mice from vaginal challenge with HPV16 pseudovirions. In conclusion, AAVLP(HPV16/31L2) particles have the potential as a broadly protective vaccine candidate regardless of prior exposure to AAV.     

转基因植物作为生物反应器生产口蹄疫疫苗的研究进展

利用转基因植物作为生物反应器表达重组蛋白,生产外源蛋白质作为动物疫苗是一个很有吸引力的廉价生产系统,它有可能代替生产成本较高的传统疫苗的发酵生产系统。通过口蹄疫病毒VP1结构蛋白基因在转基因植物中的表达,口蹄疫疫苗已在植物中产生。在植物中生产的抗原能够保持其自身的免疫原性。本文简要综述了近十年来用转基因植物作为生物反应器生产口蹄疫疫苗的研究进展、特点及其应用前景 。     

一种新型T细胞免疫原的原核表达及对口蹄疫疫苗的免疫增强作用

主要探讨了T细胞免疫原TI对口蹄疫疫苗的免疫增强作用。设计并原核表达产生了一种包含口蹄疫病毒VP1,VP4,3A和3D蛋白上多个T细胞表位与两个通用T细胞表位的T细胞免疫原,命名为TI;同时表达了O和Asia 1两个型口蹄疫病毒 VP1 蛋白的串联编码基因,表达产物命名为OA-VP1。将上述T细胞免疫原分别与OA-VP1和口蹄疫灭活疫苗按不同剂量组合免疫小鼠,于免疫后不同时间测定各组小鼠的体液与细胞免疫应答情况。采用微量中和试验检测小鼠O型和Asia1型中和抗体,采用流式细胞检测技术和测定γ-干扰素的水平来分析不同免疫组小鼠细胞免疫的水平。结果显示,与灭活疫苗或OA-VP1单独免疫组相比,添加TI抗原后灭活疫苗 (P＜0.01) 和OA-VP1免疫组(P＜0.05)小鼠均能产生高水平的特异性中和抗体;且CD4+ T细胞数量显著增多,IFN-γ产生水平显著升高 (P＜0.01)。说明TI抗原具有很好的诱导特异性体液与细胞免疫应答的作用,是一种很好的免疫增效剂,可作为口蹄疫蛋白亚单位疫苗和灭活疫苗中的一种有效成分,以提高疫苗的免疫效果。     

Antigenicity and Protective Efficacy of a Leishmania Amastigote-specific Protein,Member of the Super-oxygenase Family,against Visceral Leishmaniasis

Background

The present study aimed to evaluate a hypothetical Leishmania amastigote-specific protein (LiHyp1), previously identified by an immunoproteomic approach performed in Leishmania infantum, which showed homology to the super-oxygenase gene family, attempting to select a new candidate antigen for specific serodiagnosis, as well as to compose a vaccine against VL.

Methodology/Principal Findings

The LiHyp1 DNA sequence was cloned; the recombinant protein (rLiHyp1) was purified and evaluated for its antigenicity and immunogenicity. The rLiHyp1 protein was recognized by antibodies from sera of asymptomatic and symptomatic animals with canine visceral leishmaniasis (CVL), but presented no cross-reactivity with sera of dogs vaccinated with Leish-Tec, a Brazilian commercial vaccine; with Chagas'' disease or healthy animals. In addition, the immunogenicity and protective efficacy of rLiHyp1 plus saponin was evaluated in BALB/c mice challenged subcutaneously with virulent L. infantum promastigotes. rLiHyp1 plus saponin vaccinated mice showed a high and specific production of IFN-γ, IL-12, and GM-CSF after in vitro stimulation with the recombinant protein. Immunized and infected mice, as compared to the control groups (saline and saponin), showed significant reductions in the number of parasites found in the liver, spleen, bone marrow, and in the paws'' draining lymph nodes. Protection was associated with an IL-12-dependent production of IFN-γ, produced mainly by CD4 T cells. In these mice, a decrease in the parasite-mediated IL-4 and IL-10 response could also be observed.

Conclusions/Significance

The present study showed that this Leishmania oxygenase amastigote-specific protein can be used for a more sensitive and specific serodiagnosis of asymptomatic and symptomatic CVL and, when combined with a Th1-type adjuvant, can also be employ as a candidate antigen to develop vaccines against VL.     

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].     

Peptide vaccine against canine parvovirus: identification of two neutralization subsites in the N terminus of VP2 and optimization of the amino acid sequence.

The N-terminal domain of the major capsid protein VP2 of canine parvovirus was shown to be an excellent target for development of a synthetic peptide vaccine, but detailed information about number of epitopes, optimal length, sequence choice, and site of coupling to the carrier protein was lacking. Therefore, several overlapping peptides based on this N terminus were synthesized to establish conditions for optimal and reproducible induction of neutralizing antibodies in rabbits. The specificity and neutralizing ability of the antibody response for these peptides were determined. Within the N-terminal 23 residues of VP2, two subsites able to induce neutralizing antibodies and which overlapped by only two glycine residues at positions 10 and 11 could be discriminated. The shortest sequence sufficient for neutralization induction was nine residues. Peptides longer than 13 residues consistently induced neutralization, provided that their N termini were located between positions 1 and 11 of VP2. The orientation of the peptides at the carrier protein was also of importance, being more effective when coupled through the N terminus than through the C terminus to keyhole limpet hemocyanin. The results suggest that the presence of amino acid residues 2 to 21 (and probably 3 to 17) of VP2 in a single peptide is preferable for a synthetic peptide vaccine.     

Serum-neutralizing antibody to VP4 and VP7 proteins in infants following vaccination with WC3 bovine rotavirus.

Serum specimens from infants 2 to 12 months old vaccinated with the WC3 bovine rotavirus were analyzed to determine the relative concentrations of neutralizing antibody to the VP4 and VP7 proteins of the vaccine virus. To do this, reassortant rotaviruses that contained the WC3 genome segment for only one of these two neutralization proteins were made. The segment for the other neutralization protein in these reassortants was from heterotypic rotaviruses that were serotypically distinct from WC3. Sera were examined from 31 infants who had no evidence of a previous rotavirus infection and the highest postvaccination WC3-neutralizing antibody titers (i.e., 160 to 600) of the 103 subjects administered the vaccine. A reassortant (3/17) that contained both neutralization proteins from the heterotypic rotaviruses, i.e., EDIM (EW strain of mouse rotavirus) VP7 and rhesus rotavirus VP4, was not neutralized by these sera (geometric mean titer [GMT], less than 20). A reassortant (E19) that contained EDIM VP7 and WC3 VP4 was also very poorly neutralized by these antisera (GMT = 20). In contrast, antibody titers to a reassortant (R20) that contained WC3 VP7 and rhesus rotavirus VP4 were higher than those against WC3 (GMTs of 458 and 313, respectively). Thus, VP7 appeared to be the dominant immunogen for production of neutralizing antibody after intestinal infection of previously uninfected infants vaccinated with WC3 bovine rotavirus.     

Identification of a highly immunoreactive epitope of Brugia malayi TPx recognized by the endemic sera

Filarial thiordoxin peroxidase is a major antioxidant that plays a crucial role in parasite survival. Although Brugia malayi TPx has been shown to be a potential vaccine candidate, it shares 63% homology with its mammalian counterpart, limiting its use as a vaccine or drug target. In silico analysis of TPx sequence revealed a linear B epitope in the host's nonhomologous region. The peptide sequence (TPx peptide(27-48)) was synthesized, and its reactivity with clinical sera from an endemic region was analyzed. The peptide showed significantly high reactivity (P < 0.05) against the sera of putatively immune individuals compared to the nonendemic control sera. It also showed high reactivity against the sera of patients with chronic pathology and patent infection. The high reactivity of the peptide with endemic immune sera equivalent to that of whole protein shows that it forms a dominant B epitope of TPx protein and thus could be utilized for incorporation into a multiepitope vaccine construct for filariasis.     

Expression, purification, and improved antigenic specificity of a truncated recombinant bp26 protein of Brucella melitensis M5-90: a potential antigen for differential serodiagnosis of brucellosis in sheep and goats

Antibodies produced in animals vaccinated using live attenuated vaccines against Brucella spp. are indistinguishable using current conventional serological tests from those produced in infected animals. One potential approach is to develop marker vaccines in which specific genes have been deleted from parental vaccine strains that show good immunogenicity and vaccine efficacy. Corresponding methods of detection for antibodies raised by the marker vaccine should also be developed. A specific fragment of the bp26 gene of Brucella melitensis M5-90 was cloned into vector pQE32 to construct the recombinant plasmid (pQE32-rΔbp26). It was used to transform Escherichia coli M15 (pREP4) host cells, which expressed the rΔbp26 protein. Subsequently, the recombinant protein was purified by immobilized metal affinity chromatography and size-exclusion chromatography. The results of sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that the purified rΔbp26 protein was represented by only one band, with a molecular weight of 14 kDa, and it showed good antigenic specificity on western blot and enzyme-linked immunosorbent assay (ELISA). The purified rΔbp26 protein was intended to be used as an antigen to develop a novel ELISA to differentiate animals vaccinated with bp26 mutants of Brucella spp. from those infected naturally and those vaccinated with the parental vaccine strains.     

蓝舌病病毒vp7基因的表达及其产物在c—ELISA中的应用

获得稳定、高效的具有良好抗原性的蓝舌病毒(Bluetongue virus,BTV)vp7基因重组抗原。将BTV编码群特异性抗原VP7的S7基因片段克隆至pMD18-T质粒载体中,构建S7克隆重组质粒,进行核苷酸序列分析。与已报道的多株BTV编码VP7的基因比较后发现,所测定毒株的核苷酸序列与BTV10型的S7基因同源性高达98．7％,推测的氨基酸同源性为99．3％,证实为BTV的S7基因。然后亚克隆插入pBAD/Thio TOPO表达载体,转化LGM194细胞,经抗性培养、PCR、限制性内切酶分析、测序鉴定,筛选获得BTV S7基因片段正向插入、有正确读码框的阳性克隆,成功构建了BTV群特异性抗原VP7的重组表达载体。经L-araboinose诱导表达,可稳定、高效地表达VP7蛋白抗原。SDS-PAGE、ELISA试验表明,表达蛋白为融合蛋白,具有反应原性,分子量约54．5kD,重组蛋白的获得率为1．52mg／g湿菌,其表达产量约占菌体总蛋白的12％左右,相当于93．5mg／L菌液。融合蛋白中含有BTV VP7特异性蛋白抗原,可作为c-ELISA包被抗原,为蓝舌病的免疫血清学诊断试剂的制备和分子生物学研究打下了坚实基础。