Protection against dengue virus by non-replicating and live attenuated vaccines used together in a prime boost vaccination strategy

A new vaccination strategy for dengue virus (DENV) was evaluated in rhesus macaques by priming with tetravalent purified inactivated virus (TPIV) or tetravalent plasmid DNA vaccines expressing the structural prME gene region (TDNA) then boosting 2 months later with a tetravalent live attenuated virus (TLAV) vaccine. Both vaccine combinations elicited virus neutralizing (N) antibodies. The TPIV/TLAV combination afforded complete protection against DENV 3 challenge at month 8. In a second experiment, priming with TPIV elicited N antibodies against all four serotypes (GMT 1:28 to 1:43). Boosting with TLAV led to an increase in the GMT for each serotype (1:500 to 1:1200 for DENVs 1, 3, and 4, and greater than 1:6000 for DENV 2), which declined by month 8 (GMT 1:62 for DENV 3, 1:154 for DENV 1, 1:174 for DENV 4, and 1:767 for DENV 2). After challenge with each one of the four DENV serotypes, vaccinated animals exhibited no viremia but showed anamnestic antibody responses to the challenge viruses.     

High-affinity antibody induced by immunization with a synthetic peptide is associated with protection of cattle against foot-and-mouth disease.

Previous work has shown that the synthetic peptide C-C-(200-213)-P-P-S-(141-158)-P-C-G, in which residues 200-213 and 141-158 correspond to immunogenic regions of the VP1 protein of foot-and-mouth disease virus (FMDV), is capable of inducing high levels of neutralizing antibody but only inconsistent protection of cattle against virulent FMDV challenge. The possibility exists that differences in affinity may well underlie the observed variations in biological effectiveness of the anti-peptide antibodies in immunized animals. This has been investigated by assessing the affinity for peptide and whole virus of the anti-peptide antibodies in sera from protected and non-protected cattle using both fluid-phase and solid-phase assays. The results obtained show that the affinities of serum antibodies for peptide and virus in protected cattle were significantly higher than those in non-protected animals. Thus in order to assess vaccine efficacy, particularly in the case where synthetic immunogens are employed, consideration should be given to the determination of antibody affinity in addition to other parameters of the antibody response.     

登革病毒4型E蛋白的表达与多克隆抗体的制备

 目的 在原核细胞中表达登革病毒4型E蛋白及E蛋白III区,分别以两种蛋白免疫家兔,获得可检测登革病毒的多克隆抗体。方法 将登革病毒4型E蛋白与E蛋白III区编码序列克隆到pET-32a（+）质粒中,分别构建两种蛋白的表达载体,以IPTG诱导其在Rosetta细胞中的大量表达,并进行SDS-PAGE检测。分别以两种蛋白免疫家兔,制备出针对E蛋白与E蛋白III区的多克隆抗体,并对其进行Western blot鉴定。结果 登革病毒4型E蛋白与E蛋白III区在Rosetta细胞中以包涵体的形式大量表达;利用所制备的多克隆抗体对登革病毒进行检测,出现了预期的条带。结论 本研究制备获得的多克隆抗体可用于登革病毒的检测,为登革病毒相关研究奠定了基础。     

The structural basis for serotype-specific neutralization of dengue virus by a human antibody

Dengue virus (DENV) is a mosquito-borne flavivirus that affects 2.5 billion people worldwide. There are four dengue serotypes (DENV1 to DENV4), and infection with one elicits lifelong immunity to that serotype but offers only transient protection against the other serotypes. Identification of the protective determinants of the human antibody response to DENV is a vital requirement for the design and evaluation of future preventative therapies and treatments. Here, we describe the isolation of a neutralizing antibody from a DENV1-infected patient. The human antibody 14c10 (HM14c10) binds specifically to DENV1. HM14c10 neutralizes the virus principally by blocking virus attachment; at higher concentrations, a post-attachment step can also be inhibited. In vivo studies show that the HM14c10 antibody has antiviral activity at picomolar concentrations. A 7 ? resolution cryoelectron microscopy map of Fab fragments of HM14c10 in a complex with DENV1 shows targeting of a discontinuous epitope that spans the adjacent surface of envelope protein dimers. As found previously, a human antibody specific for the related West Nile virus binds to a similar quaternary structure, suggesting that this could be an immunodominant epitope. These findings provide a structural and molecular context for durable, serotype-specific immunity to DENV infection.     

Dengue virus neutralization by human immune sera: Role of envelope protein domain III-reactive antibody

Dengue viruses (DENV) are the etiological agents of dengue fever (DF) and dengue hemorrhagic fever (DHF). The DENV complex consists of four closely related viruses designated DENV serotypes 1 through 4. Although infection with one serotype induces cross reactive antibody to all 4 serotypes, the long-term protective antibody response is restricted to the serotype responsible for infection. Cross reactive antibodies appear to enhance infection during a second infection with a different serotype. The goal of the present study was to characterize the binding specificity and functional properties of human DENV immune sera. The study focused on domain III of the viral envelope protein (EDIII), as this region has a well characterized epitope that is recognized by strongly neutralizing serotype-specific mouse monoclonal antibodies (Mabs). Our results demonstrate that EDIII-reactive antibodies are present in primary and secondary DENV immune human sera. Human antibodies bound to a serotype specific epitope on EDIII after primary infection and a serotype cross reactive epitope on EDIII after secondary infection. However, EDIII binding antibodies constituted only a small fraction of the total antibody in immune sera binding to DENV. Studies with complete and EDIII antibody depleted human immune sera demonstrated that EDIII binding antibodies play a minor role in DENV neutralization. We propose that human antibodies directed to other epitopes on the virus are primarily responsible for DENV neutralization. Our results have implications for understanding protective immunity following natural DENV infection and for evaluating DENV vaccines.     

Broad neutralization of wild-type dengue virus isolates following immunization in monkeys with a tetravalent dengue vaccine based on chimeric yellow fever 17D/dengue viruses

The objective of the study was to evaluate if the antibodies elicited after immunization with a tetravalent dengue vaccine, based on chimeric yellow fever 17D/dengue viruses, can neutralize a large range of dengue viruses (DENV). A panel of 82 DENVs was developed from viruses collected primarily during the last decade in 30 countries and included the four serotypes and the majority of existing genotypes. Viruses were isolated and minimally amplified before evaluation against a tetravalent polyclonal serum generated during vaccine preclinical evaluation in monkey, a model in which protection efficacy of this vaccine has been previously demonstrated (Guirakhoo et al., 2004). Neutralization was observed across all the DENV serotypes, genotypes, geographical origins and isolation years. These data indicate that antibodies elicited after immunization with this dengue vaccine candidate should widely protect against infection with contemporary DENV lineages circulating in endemic countries.     

Administration of noninternal image monoclonal anti-idiotypic antibodies induces idiotype-restricted responses specific for human immunodeficiency virus envelope glycoprotein epitopes.

A mouse monoclonal anti-idiotypic antibody (anti-Id), designated MC1, was generated against chimpanzee antibodies specific for a synthetic peptide corresponding to a native epitope associated with gp41 of human immunodeficiency virus (HIV). This anti-Id recognized a shared idiotope/idiotype (Id) on a second chimpanzee anti-gp41 peptide preparation but failed to detect this Id on rabbit and mouse anti-gp41 peptide antibodies induced by immunization with the gp41 synthetic peptide. The chimpanzee Id-MC1 reaction was not inhibited by either synthetic peptide or recombinant gp160 suggesting that MC1 exhibits noninternal image, Ab-2 alpha-like characteristics. Immunization of syngeneic Balb/c mice with MC1 induced an antigen-positive (Ag+) response capable of binding the synthetic peptide, recombinant gp160, and gp41, whereas MC1-immunized rabbits did not produce any detectable anti-peptide and/or anti-HIV envelope glycoprotein antibody response. The MC1-induced anti-Id response (Ab-3) in both mice and rabbits expressed a similar Id with the Ab-1, which is not normally expressed in the anti-gp41 peptide antibody response induced by the nominal antigen in Balb/c mice and in rabbits. Together, these studies indicate that a mouse monoclonal anti-Id of the Ab-2 alpha class can induce an anti-HIV response specific for a gp41 epitope defined by a synthetic peptide, which does not cross species barriers.     

Generation and characterization of a monoclonal antibody that cross‐reacts with the envelope protein from the four dengue virus serotypes

Dengue viruses (DENVs; serotypes 1–4) are members of the flavivirus family. The envelope protein (E) of DENV has been defined as the principal antigenic target in terms of protection and diagnosis. Antibodies that can reliably detect the E surface glycoprotein are necessary for describing and mapping new DENV epitopes as well as for developing more reliable and inexpensive diagnostic assays. In this study, we describe the production and characterization of a monoclonal antibody (mAb) against a recombinant DENV‐2 E protein that recognizes a sequential antigen in both native and recombinant form located in domain II of the E protein of all four DENV serotypes. We confirmed that this mAb, C21, recognizes a sequence located in the fusion peptide. In addition, C21 does not have neutralizing activity against DENV‐2 in an in vitro system. Furthermore, the C21 mAb is an ideal candidate for the development of research reagents for studying DENV biology because it cross‐reacts with the four dengue serotypes.     

Inhibitory effects of monoclonal antibodies to a synthetic peptide of influenza haemagglutinin on the processing and presentation of viral antigens to class II-restricted T-cell clones

Monoclonal antibodies (mAb) prepared against a synthetic peptide of influenza virus haemagglutinin (HA), containing a known T-cell determinant, were used to examine the mechanism of antigen-induced activation of HA-specific class II-restricted T-cell clones. Previous studies had shown that T-cell clones, established from mice primed by infection with influenza virus, recognize variable antibody binding region of HA, including a determinant formed from residues within the sequence HA1 48-68. MAb to the synthetic peptide, p48-68, recognized purified HA and whole virus in an ELISA, and their specificity pattern for natural variant viruses was similar to that described for the T-cell clones specific for the same peptide. The anti-peptide mAb inhibited peptide or virus-induced proliferation of the peptide specific T-cell clones (but has no effect on a unrelated HA-specific clone), whereas mAb to the native HA molecule inhibited virus but not peptide-induced T-cell activation. In addition, the anti-peptide mAb showed significant inhibition of T-cell proliferation to peptide or virus pulsed antigen-presenting cell (APC). The results suggest that the anti-HA mAb affect antigen induced T-cell activation simply through blocking virus uptake by the APC, whereas the anti-peptide antibodies, which appear to recognize the same determinant on the peptide and the processed antigen, mediate their effect at the level of antigen presentation.     

The immune response to poliovirus-specific synthetic peptides: effects of adjuvants and test animal species

Carrier protein conjugates of five synthetic peptides containing amino acid sequences specific to capsid proteins VP1 and VP2 of poliovirus type 1 were tested for their abilities to elicit an immune response in the presence of either of two adjuvants and in several animal species. Freund's adjuvant induced significantly higher level anti-peptide antibody titers than A1(OH)3. However, no difference was noted between the two adjuvants in their abilities to aid in the induction of cross-reactive virus neutralizing antibody. The latter antibody was more readily produced by rabbits than by guinea pigs in spite of equivalent anti-peptide titers. Rats failed to produce neutralizing antibodies and their anti-peptide antibody levels were generally lower. The significance of these results for studies involving the development of synthetic peptide immunogens is discussed.     

The potential of immunization with synthetic peptides to overcome the immunosuppressive effect of maternal anti-measles virus antibodies in young mice.

In this paper, we describe the results of experiments designed to test the hypothesis that immunogenic synthetic peptides representing non-immunodominant B- and T-cell epitopes of measles virus (MV) proteins can overcome the suppressive effect of maternal antibodies and induce anti-MV antibodies in young mice in the presence of maternal antibody to the virus. We have established a mouse model of immunosuppression by maternal antibody of both anti-MV and anti-peptide antibody responses in the young. Results obtained with this model immunization of young mice with a cocktail of synthetic peptides can overcome the suppression by maternal anti-MV antibodies and results in the induction of anti-peptide antibodies which recognize the virus. This work indicates that appropriately selected synthetic peptides have potential as vaccines which can be immunogenic and induce antibodies reactive with the virus-virus antibodies. in the presence of maternal anit-virus antibodies.     

Antigenic determinants of influenza virus hemagglutinin. XII. the epitopes of a synthetic peptide representing the C-terminus of HA1

A synthetic peptide comprising the C-terminal 24 amino acids of the heavy chain (HA1) of influenza virus hemagglutinin was constructed and examined for antigenic and immunogenic activity. Monoclonal antibodies as well as polyclonal antisera raised against the synthetic peptide were able to bind to intact virus. This binding was greatly enhanced if the virus was first subjected to pH 5, suggesting that this treatment exposes the C-terminus of HA1. Using synthetic analogs of the native sequence it was shown that the epitope recognized by one of the monoclonal antibodies encompasses one or more of the C-terminal four amino acids of HA1 (residues 325-328), which are conserved within subtypes but differ between subtypes, while the other monoclonal antibody recognizes a different epitope which involves at least one of the five variable residues at positions 311-315.     

Timely diagnosis of respiratory tract infections: evaluation of the performance of the Respifinder assay compared to the xTAG respiratory viral panel assay

BackgroundDengue virus (DENV), which causes mosquito-borne disease dengue hemorrhagic fever (DHF), consists of four serotypes co-circulating in endemic areas. Currently, DENV serotypes can be identified by laborious virus isolation followed by immunofluorescent assay and sophisticated RT-PCR.ObjectiveTo establish a new assay designated as “serotyping-NS1-ELISA” to detect the NS1 protein and to identify DENV serotypes simultaneously.Study designThe monoclonal antibodies (Mabs) against NS1 of each DENV serotype were produced and characterized for their serotype-specificity. To develop serotyping-NS1-ELISA, the selected serotype-specific anti-NS1 Mabs were applied to detect the NS1 antigen, which was previously captured by a flavivirus cross-reactive anti-NS1 Mab. Serotyping accuracy of the developed assay was validated with NS1 from DENV-infected cell culture supernatants and from well-characterized clinical specimens.ResultsOf 30 anti-NS1 Mabs, 1 serotype-specific anti-NS1 Mab to each DENV serotype was selected based on NS1 capture ELISA results for developing the serotyping-NS1-ELISA. Using DENV-infected cell culture supernatants for validation, the selected antibodies were shown to be capable of differentiating four DENV serotypes. When acute phase plasma from DENV-infected patients was used for validation, 65 out of 85 specimens (76.5% overall sensitivity) were positive to one of the four serotypes developed in our assay. Interestingly, identification of DENV serotypes by our serotyping-NS1-ELISA was 100% accurate for DENV1, 3 and 4 and 82.4% for DENV2 as compared with standard RT-PCR. Assay specificity was 100% (90/90).ConclusionsThe developed serotyping-NS1-ELISA provides an alternative for simultaneous detection of DENV NS1 and identification of its serotype in acute patients’ specimens. The assay would be applicable for dengue diagnosis and epidemiological studies.     

In silico prediction of monovalent and chimeric tetravalent vaccines for prevention and treatment of dengue fever

Reverse vaccinology method was used to predict the monovalent peptide vaccine candidate to produce antibodies for therapeutic purpose and to predict tetravalent vaccine candidate to act as a common vaccine to cover all the dengue virus serotypes. Envelope (E)-proteins of DENV-1-4 serotypes were used for vaccine prediction using NCBI, Uniprot/Swissprot, Swiss-prot viewer, VaxiJen V2.0, TMHMM, BCPREDS, Propred-1, Propred and MHC Pred. Eproteins of DENV-1-4 serotypes were identified as antigen from which T cell epitopes, through B cell epitopes, were predicted to act as peptide vaccine candidates. Each selected T cell epitope of E-protein was confirmed to act as vaccine and to induce complementary antibody against particular serotype of dengue virus. Chimeric tetravalent vaccine was formed by the conjugation of four vaccines, each from four dengue serotypes to act as a common vaccine candidate for all the four dengue serotypes. It can be justifiably concluded that the monovalent 9-mer T cell epitope for each DENV serotype can be used to produce specific antibody against dengue virus and a chimeric common tetravalent vaccine candidate to yield a comparative vaccine to cover any of the four dengue virus serotype. This vaccine is expected to be highly immunogenic against dengue fever.     

Anti-HV3 peptide antibodies as probes for conformational changes in immunoglobulins

Recent studies have shown that monoclonal anti-alprenolol antibody 37A4 could mimic the beta-adrenergic receptor with respect to binding properties and alprenolol-induced changes in intrinsic fluorescence. We prepared and characterized polyclonal antibodies against a synthetic tetradecapeptide corresponding to residues 92-105 of the 37A4 VH domain. In ELISA and immunoblotting assays, the anti-peptide antibodies bound to the intact IgG molecule as well as to the isolated heavy chain. They failed to interact with the native IgG protein but recognized with high specificity the conformationally modified Ig molecule; as a consequence, their reactivity to the entire protein was found to vary with the conditions of the assay. This study illustrates that anti-peptide antibodies might be used as probes for the detection of conformational changes occurring in the Ig hypervariable regions.     

Effect of different hapten-carrier conjugation ratios and molecular orientations on antibody affinity against a peptide antigen

Hapten-carrier conjugate immunization is an important tool in the generation of hapten-specific antibodies for analytical purposes and in the uncovering of basic vaccine-immunological mechanisms. The affinity of antibodies is known to play an important role for the resulting sensitivity of antibody-based assay systems and in deciding whether a vaccine-induced antibody response will be protective. With ovalbumin as a carrier protein and a peptide (7.2 NY) representing a 19 amino acid sequence from the E. coli-derived Verotoxin 2e as a model hapten we investigated whether it was possible to influence the affinity and titre of antibodies raised against the hapten using different conjugation ratios and orientations. The peptide was coupled to ovalbumin in four conjugation ratios and two molecular orientations - terminal and central - and the conjugates were verified by mass spectrometry. Mice were immunised ten times at two-weeks intervals with low doses of the eight conjugates. Blood samples collected between each immunisation were analysed by ELISA for specific antibody titres and relative affinities. With both types of conjugations, the anti-peptide antibody titres increased in response to increasing conjugation ratios, but central conjugation resulted in markedly higher titres than terminal conjugation. The overall anti-peptide antibody affinities reached approximately similar levels with both orientations, whereas a reversed proportionality was observed between conjugation ratio and antibody affinity for terminal conjugation. Thus, it appears that the molar ratio of a peptide and its carrier may affect the resulting antibody affinities, and that a conjugation ratio between a terminally conjugated peptide and its carrier approaching one will result in relatively high antibody affinities. Furthermore, the molecular orientation of the coupled peptide has a major effect on the anti-peptide antibody titres induced.     

重组登革病毒2型NS1蛋白的分泌表达及其抗体制备

目的分泌表达重组登革病毒2型NS1蛋白,并制备兔抗NS1多克隆抗体。方法应用毕赤酵母表达系统表达全长登革病毒2型NS1蛋白,制备抗原,免疫家兔;采集免疫血清,制备兔抗NS1蛋白多克隆抗体;应用Western-blot、ELISA法鉴定和检测抗体效价;经辛酸-硫酸铵法、亲和层析法纯化抗体,SDS-PAGE电泳检测抗体的纯度：用Western-blot、ELISA法检测纯化后IgG性质及效价。结果重组NS1蛋白获得分泌表达。其免疫血清经Western-blot、ELISA法证实获得特异性兔抗NS1多克隆抗体,抗体效价为1：6000。结论重组登革病毒2型NS1蛋白在毕赤酵母真核表达系统中高效表达,纯化产物有较强的免疫原性,成功获得特异性兔抗NS1多克隆抗体,为进一步研究登革病毒NS1蛋白及其抗体在登革病毒致病与免疫机制中的作用奠定了基础。     

Anti-idiotypic antibodies of a predefined specificity generated against CDR3VH synthetic peptides define a private anti-CD4 idiotype

A synthetic peptide corresponding to the third complementarity determining region (CDR) of the heavy chain (CDR3VH) of anti-Leu3a, a monoclonal anti-CD4 antibody which inhibits HIV gp120 binding to CD4, was used to elicit specific anti-peptide antibodies in rabbits. The anti-peptide antisera showed anti-idiotypic antibody (anti-Id) activity and recognized both the immunizing peptide and the intact cognate protein by ELISA. In addition, the antisera reacted with isolated heavy chains of anti-Leu3a by Western blot analysis. The lack of reactivity with a panel of monoclonal anti-CD4 antibodies suggested that the anti-peptide antisera recognize a private idiotype (Id) associated with the anti-Leu3a CDR3VH region. Further studies demonstrated the inability of the rabbit antisera to inhibit the binding of anti-Leu3a to the CD4 molecule. In addition, soluble recombinant CD4 was unable to inhibit the binding of the rabbit anti-peptide antisera to anti-Leu3a indicating that the CDR3VH region may not be involved in CD4 recognition. Anti-Id containing sera from mice, rabbits and nonhuman primates immunized with the intact anti-Leu3a molecule did not bind the CDR3VH synthetic peptide, suggesting that the corresponding region of anti-Leu3a may not represent an immunodominant idiotypic determinant in thes e species. These results suggest the potential use of synthetic peptides corresponding to immunoglobulin variable (V) region amino acid sequences in generating anti-Id reagents of a predefined specificity. In addition, V-region synthetic peptides may be useful in mapping the idiotopes recognized by an anti-Id response to the cognate molecule.     

48-mer synthetic peptide analogue of the hepatitis B virus "a" determinant induces an anti-HBs antibody response after a single injection

An extended (48 amino acid) synthetic peptide analogue of the hepatitus B virus (HBV) S protein (HBsAg) 'a' determinant has been produced by using 9-fluorenylmethoxycarbonyl (fmoc) chemistry and a low substitution polystyrene resin as the solid phase support. This peptide (S121/48) elicited a sustained anti-peptide antibody response in BALB/c (H-2(d)) mice when immunised with Freund's complete adjuvant (FCA). Cross-reactive, anti-HBs antibodies were induced, directed against a significant proportion of the conformationally restrained epitope repertoire on the native HBsAg particles. Similar responses were obtained by injection of guinea pigs, a species known both to be exquisitely sensitive to HBsAg and to produce a wide range of B cell responses to HBsAg antigens. Taken together, these data show for the first time, that a synthetic peptide mimicking conformational epitopes can be produced by chemical synthesis and can be used to induce significant titres of anti-HBs antibodies after a single injection. This immunogen has considerable potential for incorporation into novel delivery systems, e.g., microspheres, thus offering the potential of a controlled release, single dose hepatitis B vaccine.