Protective Efficacy and Immunogenicity of an Adenoviral Vector Vaccine Encoding the Codon-Optimized F Protein of Respiratory Syncytial Virus

Adenoviral vectors (AdV) have received considerable attention for vaccine development because of their high immunogenicity and efficacy. In previous studies, it was shown that DNA immunization of mice with codon-optimized expression plasmids encoding the fusion protein of respiratory syncytial virus (RSV F) resulted in enhanced protection against RSV challenge compared to immunization with plasmids carrying the wild-type cDNA sequence of RSV F. In this study, we constructed AdV carrying the codon-optimized full-length RSV F gene (AdV-F) or the soluble form of the RSV F gene (AdV-Fsol). BALB/c mice were immunized twice with AdV-F or AdV-Fsol and challenged with RSV intranasally. Substantial levels of antibody to RSV F were induced by both AdV vaccines, with peak neutralizing-antibody titers of 1:900. Consistently, the viral loads in lung homogenates and bronchoalveolar lavage fluids were significantly reduced by a factor of more than 60,000. The protection against viral challenge could be measured even 8 months after the booster immunization. AdV-F and AdV-Fsol induced similar levels of immunogenicity and protective efficacy. Therefore, these results encourage further development of AdV vaccines against RSV infection in humans.Human respiratory syncytial virus (RSV) is a highly infectious member of the paramyxovirus family causing upper and lower respiratory tract infections in humans. Serious acute RSV infections, including fatal cases of bronchiolitis and pneumonia, occur particularly in premature infants, immunocompromised adults, and patients with pre-existing chronic lung diseases or underlying heart defects (11, 12, 14, 39, 46, 56). In young children, RSV is the most common respiratory tract pathogen, accounting for approximately 50% of hospitalizations due to lower respiratory tract infections (21). In population-based surveillance studies for hospitalization in Europe, RSV was identified in 42 to 45% of enrolled children younger than 2 years with lower respiratory tract infections, and the rate of hospitalization due to RSV-induced respiratory illnesses was estimated at 3 to 6% among industrialized nations (45). Children with severe RSV infections suffer from oxygen deficiency with cyanosis and require intensive medical care. Furthermore, RSV infection in childhood is suspected to be a risk factor for development of asthma (36, 41, 43, 59). The urgent need for an RSV vaccine is further demonstrated by a study showing that levels of disease burden, mortality, and morbidity caused by RSV infections in the elderly are comparable to those induced by nonpandemic influenza A infections (11). However, the immunization of children with a formalin-inactivated (FI) RSV vaccine in the 1960s resulted in a more severe clinical illness, with two fatal cases, than in nonvaccinated infants following RSV infection, pointing out the difficulties in developing a safe and efficacious RSV vaccine (7, 29). It was shown previously that the enhanced disease severity and the development of pulmonary eosinophilia are mainly attributable to an excessive Th2-polarized immune response (15, 35, 57). Furthermore, the lack of high-affinity antibodies after poor Toll-like receptor stimulation has been suggested to be a key factor of the enhanced disease induced by FI RSV vaccination and subsequent RSV infection shown recently (8). However, the enhanced disease induced by FI RSV could partially be reversed by the chemical reduction of the carbonyl groups produced by prior treatment with aldehyde (34).Passive transfer of a neutralizing monoclonal antibody directed against RSV F (palivizumab) results in significant reduction of hospitalization rate due to RSV infection in children and preterm infants (16, 25), making RSV F a promising vaccine candidate for active immunization. Besides being a target for neutralizing antibodies, RSV F additionally contains cytotoxic-T-cell epitopes (1, 37). Moreover, RSV F based DNA vaccines induced encouraging immune responses of a balanced Th1/Th2 type in mice, as pulmonary eosinophilia and disease-enhancing effects were not observed after viral challenge (4, 5, 19, 31, 52). Additionally, RSV F is highly conserved between the two antigenic subgroups of RSV, which allows generation of cross-reactive antibodies after immunization (26).We recently showed that vaccination with codon-optimized RSV F expression plasmids induced improved humoral immune responses in mice compared to vaccination with wild-type cDNA expression plasmids (52). Consequently, viral load was reduced 13-fold in mice immunized with full-length RSV F and 170-fold in mice immunized with the soluble form of RSV F following RSV challenge in comparison to nonimmunized mice. Based on these results, we inserted the codon-optimized open reading frame (ORF) of both full-length RSV F and its soluble form into a replication-deficient adenoviral serotype 5 vector (AdV), generating AdV-F and AdV-Fsol, respectively, to further enhance the immunogenicity and efficiency of the delivered RSV F transgenes. AdVs were chosen because these viral vectors have been extensively studied and have proven their potential as vaccine vectors in multiple successful preclinical studies (reviewed in references 47, 24, and 51). AdVs are also potent inducers of both humoral and cellular immune responses in animal models and in humans (48, 49, 55). Furthermore, convenience of vector design, ease of handling and a robust antigen expression make AdVs a promising vaccine delivery platform. Another main advantage is their natural tropism for mucosal surfaces, which makes adenoviral vaccines convenient for the purpose of immunization against respiratory pathogens that preferentially initiate infection at the mucosal site (40).However, AdV vaccines expressing the wild-type RSV F protein were tested in several animal models without achieving convincing protection against RSV challenge (13, 22, 23). This might be due to poor RSV F expression levels caused by premature polyadenylation, which could be overcome by codon optimization (53). Hence, here we used the codon-optimized RSV F based AdVs AdV-F and AdV-Fsol and evaluated their potential as RSV vaccines, showing greatly improved vaccine efficacy.     

呼吸道合胞病毒重组蛋白候选疫苗的质粒构建、表达及免疫原性和保护性研究

PCR扩增呼吸道合胞病毒（respiratory syncytial virus,RSV）M2 蛋白的CD8＋T细胞表位F/M2:81-95和RSV-G蛋白的B细胞表位片段G:125～225（简称G1）,以一个Linker连接,插入质粒pET-DsbA中构建原核表达重组质粒, 转染E.coli BL21(DE3)后成功表达了融合蛋白DsbA-G1-Linker-F/M2:81-95（简称D-G1LF/M2）,Western-blot结果表明该融合蛋白是RSV特异性的,采用Ni+螯合亲和层析法纯化变性的包涵体溶液,经梯度透析法复性,用该蛋白免疫BALB/c小鼠,结果表明被免疫小鼠肺部及血清中产生了高滴度的抗D-G1LF/M2及抗RSV IgG抗体和中和抗体,同时还诱导产生了RSV特异性的CTL应答;IgG的亚型IgG1/IgG2a的比值为2.66;用RSV攻击免疫后的小鼠,病毒滴定法检测肺部RSV滴度,结果表明D-G1LF/M2对小鼠肺部具有保护作用。     

A Novel Influenza Virus Hemagglutinin-Respiratory Syncytial Virus (RSV) Fusion Protein Subunit Vaccine against Influenza and RSV

Influenza A virus and respiratory syncytial virus (RSV) cause substantial morbidity and mortality afflicting the ends of the age spectrum during the autumn through winter months in the United States. The benefit of vaccination against RSV and influenza using a subunit vaccine to enhance immunity and neutralizing antibody was investigated. Influenza virus hemagglutinin (HA) and RSV fusion (F) protein were tested as vaccine components alone and in combination to explore the adjuvant properties of RSV F protein on HA immunity. Mice vaccinated with HA and F exhibited robust immunity that, when challenged, had reduced viral burden for both influenza and RSV. These studies show an enhancing and cross-protective benefit of F protein for anti-HA immunity.     

呼吸道合胞病毒疫苗研究进展

呼吸道合胞病毒(RSV)是引起严重下呼吸道感染的重要病原体,尽管经历了半个多世纪的努力,至今仍未有安全有效的RSV疫苗上市。近年来在RSV F蛋白结构生物学方面的研究进展为新一代RSV疫苗的开发提供了新方向,同时更多的采用不同技术、或针对不同人群的RSV侯选疫苗也在迅速发展,尤其是针对婴幼儿及老年人的RSV侯选苗已有60多种在研究中,大部分已处于临床前研究阶段,18种侯选苗已进入临床试验。我们简要介绍RSV疫苗的最新研究进展。     

抗呼吸道合胞病毒的免疫预防

呼吸道合胞病毒(RSV)感染是一个影响婴幼儿健康的全球性的问题,目前尚未有令人满意的治疗药物,免疫预防就显得尤为重要。近年研究表明,免疫预防在疫苗、单克隆抗体以及免疫球蛋白等领域均取得较大进展。     

A Cysteine Zipper Stabilizes a Pre-Fusion F Glycoprotein Vaccine for Respiratory Syncytial Virus

Recombinant subunit vaccines should contain minimal non-pathogen motifs to reduce potential off-target reactivity. We recently developed a vaccine antigen against respiratory syncytial virus (RSV), which comprised the fusion (F) glycoprotein stabilized in its pre-fusion trimeric conformation by “DS-Cav1” mutations and by an appended C-terminal trimerization motif or “foldon” from T4-bacteriophage fibritin. Here we investigate the creation of a cysteine zipper to allow for the removal of the phage foldon, while maintaining the immunogenicity of the parent DS-Cav1+foldon antigen. Constructs without foldon yielded RSV F monomers, and enzymatic removal of the phage foldon from pre-fusion F trimers resulted in their dissociation into monomers. Because the native C terminus of the pre-fusion RSV F ectodomain encompasses a viral trimeric coiled-coil, we explored whether introduction of cysteine residues capable of forming inter-protomer disulfides might allow for stable trimers. Structural modeling indicated the introduced cysteines to form disulfide “rings”, with each ring comprising a different set of inward facing residues of the coiled-coil. Three sets of rings could be placed within the native RSV F coiled-coil, and additional rings could be added by duplicating portions of the coiled-coil. High levels of neutralizing activity in mice, equivalent to that of the parent DS-Cav1+foldon antigen, were elicited by a 4-ring stabilized RSV F trimer with no foldon. Structure-based alteration of a viral coiled-coil to create a cysteine zipper thus allows a phage trimerization motif to be removed from a candidate vaccine antigen.     

Enhancement of the Immunogenicity and Protective Efficacy of a Mucosal Influenza Subunit Vaccine by the Saponin Adjuvant GPI-0100

Identification of safe and effective adjuvants remains an urgent need for the development of inactivated influenza vaccines for mucosal administration. Here, we used a murine challenge model to evaluate the adjuvant activity of GPI-0100, a saponin-derived adjuvant, on influenza subunit vaccine administered via the intranasal or the intrapulmonary route. Balb/c mice were immunized with 1 µg A/PR/8 (H1N1) subunit antigen alone or in combination with varying doses of GPI-0100. The addition of GPI-0100 was required for induction of mucosal and systemic antibody responses to intranasally administered influenza vaccine and significantly enhanced the immunogenicity of vaccine administered via the intrapulmonary route. Remarkably, GPI-0100-adjuvanted influenza vaccine given at a low dose of 2×1 µg either in the nares or directly into the lungs provided complete protection against homologous influenza virus infection.     

Immunogenicity and Protective Efficacy of Replication-Incompetent Influenza Virus-Like Particles

Despite the success of influenza virus vaccines in reducing severe illness, their efficacy is suboptimal. We describe here the immunogenicity and protective capacity of replication-incompetent influenza virus-like particles (VLPs) which were generated entirely from cDNAs and lacked either the entire NS gene (encoding both the NS1 and NS2 protein) or only the NS2 gene. In mammalian cells infected with NS gene-deficient VLPs, the nucleoprotein, but not other viral proteins including hemagglutinin (HA) and neuraminidase (NA), was detected. In contrast, cells infected with VLPs expressing NS1 but not NS2 (NS2 knockout) expressed multiple viral proteins, including HA and NA. When challenged with lethal doses of an antigenically homologous mouse-adapted influenza virus, 94% of mice vaccinated with the NS2-knockout VLPs survived, compared with less than 10% of those given the NS-deficient VLPs. These results demonstrate the potential of replication-incompetent NS2-knockout VLPs as novel influenza vaccines and perhaps also as vectors to express genes from entirely unrelated pathogens.     

Immunization of Pigs with a Particle-Mediated DNA Vaccine to Influenza A Virus Protects against Challenge with Homologous Virus

Particle-mediated delivery of a DNA expression vector encoding the hemagglutinin (HA) of an H1N1 influenza virus (A/Swine/Indiana/1726/88) to porcine epidermis elicits a humoral immune response and accelerates the clearance of virus in pigs following a homotypic challenge. Mucosal administration of the HA expression plasmid elicits an immune response that is qualitatively different than that elicited by the epidermal vaccination in terms of inhibition of the initial virus infection. In contrast, delivery of a plasmid encoding an influenza virus nucleoprotein from A/PR/8/34 (H1N1) to the epidermis elicits a strong humoral response but no detectable protection in terms of nasal virus shed. The efficacy of the HA DNA vaccine was compared with that of a commercially available inactivated whole-virus vaccine as well as with the level of immunity afforded by previous infection. The HA DNA and inactivated viral vaccines elicited similar protection in that initial infection was not prevented, but subsequent amplification of the infection is limited, resulting in early clearance of the virus. Convalescent animals which recovered from exposure to virulent swine influenza virus were completely resistant to infection when challenged. The porcine influenza A virus system is a relevant preclinical model for humans in terms of both disease and gene transfer to the epidermis and thus provides a basis for advancing the development of DNA-based vaccines.     

DNA Vaccine Encoding Hemagglutinin Provides Protective Immunity against H5N1 Influenza Virus Infection in Mice

In Hong Kong in 1997, a highly lethal H5N1 avian influenza virus was apparently transmitted directly from chickens to humans with no intermediate mammalian host and caused 18 confirmed infections and six deaths. Strategies must be developed to deal with this virus if it should reappear, and prospective vaccines must be developed to anticipate a future pandemic. We have determined that unadapted H5N1 viruses are pathogenic in mice, which provides a well-defined mammalian system for immunological studies of lethal avian influenza virus infection. We report that a DNA vaccine encoding hemagglutinin from the index human influenza isolate A/HK/156/97 provides immunity against H5N1 infection of mice. This immunity was induced against both the homologous A/HK/156/97 (H5N1) virus, which has no glycosylation site at residue 154, and chicken isolate A/Ck/HK/258/97 (H5N1), which does have a glycosylation site at residue 154. The mouse model system should allow rapid evaluation of the vaccine’s protective efficacy in a mammalian host. In our previous study using an avian model, DNA encoding hemagglutinin conferred protection against challenge with antigenic variants that differed from the primary antigen by 11 to 13% in the HA1 region. However, in our current study we found that a DNA vaccine encoding the hemagglutinin from A/Ty/Ir/1/83 (H5N8), which differs from A/HK/156/97 (H5N1) by 12% in HA1, prevented death but not H5N1 infection in mice. Therefore, a DNA vaccine made with a heterologous H5 strain did not prevent infection by H5N1 avian influenza viruses in mice but was useful in preventing death.     

An Epitope-Substituted DNA Vaccine Improves Safety and Immunogenicity against Dengue Virus Type 2

Dengue virus (DENV), a global disease, is divided into four serotypes (DENV1-4). Cross-reactive and non-neutralizing antibodies against envelope (E) protein of DENV bind to the Fcγ receptors (FcγR) of cells, and thereby exacerbate viral infection by heterologous serotypes via antibody-dependent enhancement (ADE). Identification and modification of enhancing epitopes may mitigate enhancement of DENV infection. In this study, we characterized the cross-reactive DB21-6 and DB39-2 monoclonal antibodies (mAbs) against domain I-II of DENV; these antibodies poorly neutralized and potently enhanced DENV infection both in vitro and in vivo. In addition, two enhancing mAbs, DB21-6 and DB39-2, were observed to compete with sera antibodies from patients infected with dengue. The epitopes of these enhancing mAbs were identified using phage display, structural prediction, and mapping of virus-like particle (VLP) mutants. N8, R9, V12, and E13 are the reactive residues of DB21-6, while N8, R9, and E13 are the reactive residues of DB39-2. N8 substitution tends to maintain VLP secretion, and decreases the binding activity of DB21-6 and DB39-2. The immunized sera from N8 substitution (N8R) DNA vaccine exerted greater neutralizing and protective activity than wild-type (WT)-immunized sera, both in vitro and in vivo. Furthermore, treatment with N8R-immunized sera reduced the enhancement of mortality in AG129 mice. These results support identification and substitution of enhancing epitope as a novel strategy for developing safe dengue vaccines.     

Prospects For the Use of Peptides against Respiratory Syncytial Virus

Molecular Biology - The human respiratory syncytial virus (RSV) is one of the most common viral pathogens that affects the lower respiratory tract and could be a reason of bronchiolitis and/or...     

人H5N1流感病毒血凝素蛋白DNA疫苗的构建及其免疫原性研究

将我国分离的首株人H5N1亚型禽流感病毒A/Anhui/1/2005作为研究对象,扩增其HA和HA1基因片段并克隆至真核表达载体pStar,构建成真核表达质粒。通过Western blot和间接免疫荧光检测方法确认,构建的重组质粒在真核细胞中成功地表达了目的蛋白HA和HA1。将重组质粒免疫BALB/c小鼠,检测免疫后外周血中HA/HA1特异性抗体的效价,并比较HA和HA1的免疫原性。结果表明,重组质粒免疫后成功地诱导了体液免疫反应,且二者的血清抗体效价无显著性差异。     

Evaluation of the Safety and Immune Efficacy of Recombinant Human Respiratory Syncytial Virus Strain Long Live Attenuated Vaccine Candidates

Human respiratory syncytial virus(RSV) infection is the leading cause of lower respiratory tract illness(LRTI), and no vaccine against LRTI has proven to be safe and effective in infants. Our study assessed attenuated recombinant RSVs as vaccine candidates to prevent RSV infection in mice. The constructed recombinant plasmids harbored(5' to 3') a T7 promoter, hammerhead ribozyme, RSV Long strain antigenomic cDNA with cold-passaged(cp) mutations or cp combined with temperature-sensitive attenuated mutations from the A2 strain(A2cpts) or further combined with SH gene deletion(A2cpts△SH), HDV ribozyme(δ), and a T7 terminator. These vectors were subsequently co-transfected with four helper plasmids encoding N, P, L, and M2-1 viral proteins into BHK/T7-9 cells, and the recovered viruses were then passaged in Vero cells. The rescued recombinant RSVs(rRSVs) were named rRSV-Long/A2 cp, rRSV-Long/A2 cpts, and rRSV-Long/A2 cpts △SH, respectively, and stably passaged in vitro, without reversion to wild type(wt) at sites containing introduced mutations or deletion. Although rRSV-Long/A2 cpts and rRSV-Long/A2 cpts △SH displayed temperature-sensitive(ts)phenotype in vitro and in vivo, all rRSVs were significantly attenuated in vivo. Furthermore, BALB/c mice immunized with rRSVs produced Th1-biased immune response, resisted wt RSV infection, and were free from enhanced respiratory disease.We showed that the combination of △SH with attenuation(att) mutations of cpts contributed to improving att phenotype,efficacy, and gene stability of rRSV. By successfully introducing att mutations and SH gene deletion into the RSV Long parent and producing three rRSV strains, we have laid an important foundation for the development of RSV live attenuated vaccines.     

Enhanced T-Cell Immunogenicity and Protective Efficacy of a Human Immunodeficiency Virus Type 1 Vaccine Regimen Consisting of Consecutive Priming with DNA and Boosting with Recombinant Fowlpox Virus

The induction of human immunodeficiency virus (HIV)-specific T-cell responses is widely seen as critical to the development of effective immunity to HIV type 1 (HIV-1). Plasmid DNA and recombinant fowlpox virus (rFPV) vaccines are among the most promising safe HIV-1 vaccine candidates. However, the immunity induced by either vaccine alone may be insufficient to provide durable protection against HIV-1 infection. We evaluated a consecutive immunization strategy involving priming with DNA and boosting with rFPV vaccines encoding common HIV-1 antigens. In mice, this approach induced greater HIV-1-specific immunity than either vector alone and protected mice from challenge with a recombinant vaccinia virus expressing HIV-1 antigens. In macaques, a dramatic boosting effect on DNA vaccine-primed HIV-1-specific helper and cytotoxic T-lymphocyte responses, but a decline in HIV-1 antibody titers, was observed following rFPV immunization. The vaccine regimen protected macaques from an intravenous HIV-1 challenge, with the resistance most likely mediated by T-cell responses. These studies suggest a safe strategy for the enhanced generation of T-cell-mediated protective immunity to HIV-1.     

稳定携带新城疫病毒DNA疫苗减毒沙门氏菌的构建及其免疫原性

采用PCR技术从重组质粒pVAX1-F中扩增出新城疫病毒JS5株的融合蛋白(F)基因,将其克隆入真核表达质粒pmcDNA3.1 中,获得重组表达质粒pmcDNA3.1-F.通过电穿孔转化法将重组质粒转入减毒鼠伤寒沙门氏菌SL7207,构建成功携带DNA疫苗的重组沙门氏菌SL7207(pmcDNA3.1-F).体内、体外试验结果表明,重组质粒pmcDNA3.1-F在沙门氏菌中的稳定性显著高于pcDNA3.1-F.将重组菌SL7207(pmcDNA3.1-F)和SL7207(pcDNA3.1-F)分别以1×109 CFU剂量两次口服免疫BALB/c小鼠,免疫小鼠可产生针对新城疫病毒F蛋白的血清抗体和黏膜抗体.重组菌以5×109 CFU剂量两次口服免疫4日龄SPF鸡,免疫鸡产生的针对新城疫病毒F蛋白的血清抗体和小肠黏膜抗体效价水平与空载体组之间存在显著性差异(P＜0.05).免疫保护试验结果显示,SL7207(pmcDNA3.1-F)和SL7207(pcDNA3.1-F)免疫组的免疫保护率均与空载体组之间存在显著性差异(P＜0.05),且SL7207(pmcDNA3.1-F)免疫组的保护率较SL7207(pcDNA3.1-F)免疫组提高了20.0%,说明稳定携带新城疫病毒DNA疫苗的减毒沙门氏菌具有良好的免疫原性和免疫保护性.