Formaldehyde-inactivated human enterovirus 71 vaccine is compatible for co-immunization with a commercial pentavalent vaccine

In this study we tested the effectiveness of a formaldehyde-inactivated EV71 vaccine and its compatibility for co-immunization with a pentavalent vaccine that contained inactivated poliovirus (PV) vaccine. The inactivated EV71 vaccine (C2 genogroup) elicited an antibody response which broadly neutralized homologous and heterologous genogroups, including B4, C4, and B5. Pups from vaccinated dams were resistant to the EV71 challenge and had a high survival rate and a low tissue viral burden when compared to those from non-vaccinated counterparts. Co-immunization with pentavalent and inactivated EV71 vaccines elicited antibodies against the major components of the pentavalent vaccine including the PV, Bordetella pertussis, Haemophilus influenzae type b, diphtheria toxoid, and tetanus toxoid at the same levels as in mice immunized with pentavalent vaccine alone. Likewise, EV71 neutralizing antibody titers were comparable between EV71-vaccinated mice and mice co-immunized with the two vaccines. These results indicate that formaldehyde-inactivated whole virus EV71 vaccine is feasible for designing multivalent vaccines.     

Selection and characterization of vaccine strain for Enterovirus 71 vaccine development

Enterovirus 71 (EV71) has recently emerged as an important neurotropic virus in Asia because effective medications and prophylactic vaccine against EV71 infection are not available. Based on the success of inactivated poliovirus vaccine, the Vero cell-based chemically inactivated EV71 vaccine candidate could be developed. Identification of EV71 vaccine strain which can grow to high titer in Vero cell and induce cross-genotype virus neutralizing antibody responses represents the first step in vaccine development. In this report we describe the characterization and validation of a clinical isolate E59 belonging to B4 sub-genotype based on VP1 genetic analysis. Before selected as the vaccine strain, the genetic stability of E59 in passage had been analyzed based on the nucleotide sequences obtained from the Master Virus Seed, Working Seed banks and the virus harvested from the production lots, and found to be identical to those found in the original isolate. These results indicate that E59 vaccine strain has strong genetic stability in passage. Using this vaccine strain the prototype EV71 vaccine candidate was produced from 20 L of Vero cell grown in serum-containing medium. The production processes were investigated, characterized and quantified to establish the potential vaccine manufacturing process including the time for virus harvest, the membrane for diafiltration and concentration, the gel-filtration chromatography for the down-stream virus purification, and the methods for viral inactivation. Finally, the inactivated virion vaccine candidate containing sub-microgram of viral proteins formulated with alum adjuvant was found to induce strong virus neutralizing antibody responses in mice and rabbits. Therefore, these results provide valuable information for cell-based EV71 vaccine development.     

Safety and immunogenicity of a live attenuated Rift Valley Fever recombinant arMP-12ΔNSm21/384 vaccine candidate for sheep,goats and calves

Rift Valley fever (RVF) causes serious health and economic losses to the livestock industry as well as a significant cause of human disease. The prevention of RVF in Africa is a global priority, however, available vaccines have only been partially effective. Therefore, the objective of this study was to evaluate the safety and immunogenicity of a live, attenuated recombinant RVFV arMP-12ΔNSm21/384 nucleotide deletion vaccine candidate in domestic ruminants. Evaluation involved testing to determine the infectivity titer of the vaccine virus in Vero cells for industrial scale up vaccine production. Safety experiments were conducted to determine the potential of the vaccine virus to revert to virulence by serial passages in sheep, the possibility of virus spread from vaccinated sheep and calves to unvaccinated animals, and the potential health effects of administering overdoses of the vaccine to sheep, goats and calves. The immunogenicity of 3 doses of 10⁴, 10⁵ and 10⁶ Tissue Culture Infectious Doses_50% (TCID₅₀) of the vaccine was assessed in 3 groups of 10 sheep and 3 groups of 10 goats, and doses of 10⁵, 10⁶ and 10⁷ TCID₅₀ was evaluated in 3 groups of 10 calves subcutaenous vaccintation. The results showed that the infectivity titer of the vaccine virus was 10^8.4 TCID₅₀/ml, that the vaccine did not spread from vaccinated to un-vaccinated animals, there was no evidence of reversion to virulence in sheep and the vaccine overdoses did not cause any adverse effects. The immunogenicity among sheep, goats and calves indicated that doses of 10⁴–10⁶ TCID₅₀ elicited detectable antibody by day 7 post-vaccination (PV) with antibody titers ranging from 0.6 log to 2.1 log on day 14 PV with sustained titers through day 28 PV. Overall, these findings indicated that the RVFV arMP-12ΔNSm21/384 vaccine is a promising candidate for the prevention of RVF among domestic ruminants.     

Identification and characterization of a cross-neutralization epitope of Enterovirus 71

Enterovirus 71 (EV71) infections in children manifest as exanthema and are most commonly known as hand-foot-and-mouth disease (HFMD). Because it can cause severe neurological complications like poliomyelitis, EV71 has now emerged as an important neurotropic virus in Asia. EV71 virus has been shown to consist of 3 (A, B and C) genotypes and many subgenotypes. Although EV71 vaccine development has recently yielded promising preclinical results, yet the correlation between the content of antigen(s) in vaccine candidates and the level of protective antibody responses is not established. The neutralization epitope(s) of EV71 antigens could be used as the surrogate biomarker of vaccine potency. Using peptide ELISA, antisera generated from animals immunized with formalin-inactivated EV71 virion vaccine formulated in alum, EV71-specific neutralizing monoclonal antibody (nMAb) and a panel of 153 overlapping synthetic peptides covering the entire sequences of VP1, VP2 and VP3 of EV71, we screened for immunodominant linear neutralization epitope(s). Synthetic peptide VP2-28, corresponding to residues 136-150 of VP2, was found to bind to and inhibit the binding to EV71 of nMAb MAB979 that was found to have cross-neutralizing activity against different genotypes of EV71 virus. In addition, VP2-28 was found to be recognized only by neutralizing antisera generated from rabbits immunized with the formalin-inactivated whole EV71 virion vaccine but not by antisera from immunized mice and rats. During the epitope mapping, a murine EV71 genotype- and strain-specific linear neutralization epitope VP1-43 was identified within residues 211-220 of VP1. Furthermore, based on sequence alignment and structure prediction analysis using poliovirus as the template for molecular modeling, the VP1-43 and VP2-28 epitopes were shown to run in parallel within 0.1 nm and form a rim of the canyon at the junction site of VP1 and VP2 in the viral capsid. In mouse, rat and rabbit immunogenicity studies, a dose-dependent relationship between the number of VP2-28 epitope units measured by a quantitative assay in vaccine preparations and the magnitude of neutralizing titers was demonstrated. VP2-28 has amino acid sequences that are highly conserved among EV71 genotypes, is not affected by formalin-treatment and long-term storage. Thus, VP2-28 could be used as the surrogate biomarker in the potency testing of candidate EV71 vaccines.     

Optimization of microcarrier cell culture process for the inactivated enterovirus type 71 vaccine development

Enterovirus 71 (EV71) is an enterovirus that could lead to severe neurological disorders and fatalities. The inactivated vaccine is an appropriate EV71 vaccine format for meeting current needs. Large-scale preparation of the inactivated EV71vaccine depends on a scalable cell culture system for industrial mass production. In this paper, Vero cells were found to produce higher titers of EV71 than did MRC-5 and WI-38 cells. High-density microcarrier Vero cell cultures were established using 5g/L Cytodex 1 microcarriers and found to promote the release of EV71s from infected Vero cells. For the large-scale production of the inactivated vaccine antigen, the extracellular virus titers produced in the 2L bioreactor were found to be 10 times lower than the spinner flask culture but improved by 30-folds using glucose/glutamine feedings during infection. A serum-free Vero cell microcarrier culture was also established in the bioreactor, yielding a high-titer of 5.8 x 10(7) TCID50/mL for EV71 production. The immunogenicity of the inactivated virions produced in serum-free culture elicited a slightly higher level of neutralizing antibody response in immunized mice. These results constitute valuable information on the development of a large-scale microcarrier cell culture process for producing inactivated EV71 vaccine.     

Development of a live-attenuated influenza B ΔNS1 intranasal vaccine candidate

We discovered a unique, single amino acid mutation in the influenza B M1 protein promoting viral growth of NS1 truncation mutants in Vero cells. Due to this mutation, we were able to generate an influenza B virus lacking the complete NS1 open reading frame (ΔNS1-B virus) by reverse genetics, which was growing to titers of 8 log₁₀ TCID₅₀/ml in a Vero cell culture-based micro-carrier fermenter. The ΔNS1-B vaccine candidate was attenuated in IFN-competent hosts such as human alveolar epithelial cells (A549) similar to influenza A ΔNS1 viruses. In ferrets, the ΔNS1-B virus was replication-deficient and did not provoke any clinical symptoms. Importantly, a single intranasal immunization of ferrets at a dose as low as 6 log₁₀ TCID₅₀/animal induced a significant HAI response and provided protection against challenge with wild-type influenza B virus. So far, the lack of a ΔNS1-B virus component growing to high titers in cell culture has been limiting the possibility to formulate a trivalent vaccine based on deletion of the NS1 gene. Our study closes this gap and paves the way for the clinical evaluation of a seasonal, trivalent, live replication-deficient ΔNS1 intranasal influenza vaccine.     

Use of MDCK cells for production of live attenuated influenza vaccine

To develop a cell-based live attenuated influenza vaccine (LAIV) manufacturing process, several different cell lines were evaluated by comparing the titer of viruses after infection with LAIV strains. While several cell lines have been reported to support influenza virus replication, the degree of replication and the ability to support replication of LAIV strains have not been systematically examined. MDCK cells, which have been considered as potential substrates for influenza vaccine production were evaluated in addition to Vero, MRC-5, WI-38 and FRhL cells. MRC-5, WI-38 and FRhL cells produced low to moderate titers of virus with titers equal or below 5.0 log₁₀ TCID₅₀/mL. Both Vero and MDCK cells could support a higher level of virus replication for certain strains, however, Vero cells only produced high titers when grown in the presence of serum. MDCK cells supported high levels of vaccine virus production for multiple different LAIV subtypes in both serum containing and serum-free media. These results suggest that MDCK cell-based production can be used as an alternative production platform to the currently used egg-based LAIV production system.     

TAK − 021, an inactivated Enterovirus 71 vaccine candidate,provides cross-protection against heterologous sub-genogroups in human scavenger receptor B2 transgenic mice

BackgroundEnterovirus 71 (EV71) is a major cause of outbreaks of hand, foot and mouth disease, most frequently in children, and is a public health concern in the Asia-Pacific region. Takeda is developing TAK-021, an inactivated EV71 vaccine candidate based on sub-genogroup B2 strain MS87. In a phase I clinical trial, TAK-021 was safe, well tolerated, and immunogenic in healthy adults and elicited cross-neutralizing antibodies against heterologous EV71 sub-genogroup viruses. TAK-021 confers protection from lethal challenge with a mouse-adapted homologous strain in AG129 mice. However, it has not been determined whether TAK-021 can provide cross-protection against heterologous EV71 sub-genogroups.MethodsWe examined the efficacy of TAK-021 against challenge with EV71 sub-genogroups B4, B5, C1, C2, and C4 on day 42 (short-term) and sub-genogroups B5 and C4 on day 120 (long-term) after immunization of human scavenger receptor B2 transgenic (hSCARB2-tg) mice with TAK-021 on days 0 and 28. Antibody titers were monitored over 120 days using plaque reduction neutralization test of the homologous vaccine virus.ResultsTAK-021 elicited neutralizing antibody (nAb) in greater than 90% of the mice and nAb persisted through day 120. Challenge of control animals led to weight loss and death, as well as virus detection in various organs and histopathological lesions in the brain. All mice that received two doses of TAK-021 developed nAb and survived a short-term challenge given on day 42, while more than 80% survived a long-term challenge given on day 120. EV71 was detected less frequently and at lower levels in organs of immunized mice compared to non-immunized control mice.ConclusionsThe results show that TAK-021 can confer protection in mice against the EV71 sub-genogroups tested.     

Combined peptides of human enterovirus 71 protect against virus infection in mice

Human enterovirus 71 (EV71) is a cause of hand, foot and mouth disease (HMFD) in children under 6 years old, and could cause serious neurological complications in some patients. Numerous large outbreaks of EV71 caused HMFD have occurred recently in Asia, especially in China. The cross-reactivity of EV71 with human brain tissue was observed and the cross-reactivity inducing regions were identified in previously study, which suggested that there were two regions in structural proteins of virus should be avoided in the vaccine. Six peptides without cross-reactivity were selected and combined into three vaccine candidates and applied in further evaluation in neonatal mice. The Vac6 comprising the peptides of P_70–159, P_140–249, P_324–443 and P_746–876 of the structural proteins could provide effective protection on pups against virus infection, as shown in viral copies detection and histopathology examination. Immunohistochemical staining results indicated that Vac6 had no cross-reactivity with human brain tissues. Our results suggested that Vac6 could have potential clinical value against EV71 epidemics caused mainly by C4 strains in the mainland of China.     

High immunogenic enterovirus 71 strain and its production using serum-free microcarrier Vero cell culture

Developing an effective vaccine against enterovirus 71 (EV71) infection provides the best means to control the disease. We have previously reported that large-scale preparation of a low immunogenic EV71 strain can be achieved using serum free microcarrier Vero cell culture in a 2-l bioreactor [Wu SC, Liu CC, Lian WC. Optimization of microcarrier cell culture process for the inactivated enterovirus type 71 vaccine development. Vaccine 2004;22:3858-64]. This present work further investigated the virus growth and the immunogenicity of two high immunogenic strains (EV71-075 and EV71-117) prepared in serum-free microcarrier cell cultures. Our results showed that serum free culture increased cell death rate after infection, reduced the virus specific productivity, but resulted in elicitation of higher neutralizing titers in immunized mice as compared to that parallel obtained in serum-containing cultures. Therefore, serum-free microcarrier culture is a valuable process for developing inactivated EV71 vaccines.     

Development of a live attenuated vaccine against Muscovy duck reovirus infection

The Muscovy duck reovirus (MDRV) is a highly pathogenic virus that causes substantial economic losses in the Muscovy duck industry. While MDRV poses a significant threat to Muscovy ducklings, no vaccine candidates are available to date to alleviate MDRV infection throughout the world. The present study presents efforts toward establishing an attenuated vaccine for MDRV. For this purpose, a live attenuated vaccine strain named CA was obtained via alternate propagation of the MDRV isolate MW9710 in both Muscovy duck embryo fibroblasts (MDEFs) and chicken embryo fibroblasts (CEFs) for 90 passages. The CA strain achieved an adaptive growth capacity in CEFs with a viral titer that ranged between 10^5.0–10^5.5 TCID₅₀/100 μL and lost its pathogenicity in 1-day-old Muscovy ducklings. Compared to the parent strain MW9710, the CA strain has 42 scattered amino acid substitutions, most of which are located in the λB, λC, μB, σB, and σC protein. The CA strain maintained its attenuation and showed no gene mutation or virulence reversion after back propagation into 1-day-old ducklings for five rounds. The minimum protective dose was calculated to be 300 TCID₅₀ of the CA strain. Furthermore, a single dose of CA vaccine protected immunized ducklings against lethal challenge by the virulent MDRV strain MW9710 and significantly decreased viral loads. In summary, the CA strain exhibited striking genetic stability, excellent safety, and effective immunogenicity. This CA strain of MDRV is a promising vaccine candidate for the prevention and control of MDRV infection.     

Antigenic analysis of divergent genotypes human Enterovirus 71 viruses by a panel of neutralizing monoclonal antibodies: Current genotyping of EV71 does not reflect their antigenicity

In recent year, Enterovirus 71 (EV71)-associated hand, foot and mouth disease (HFMD) has become an important public health issue in China. EV71 has been classified into genotypes A, B1–B5 and C1–C5. With such genetic diversity, whether the convalescent or recovery antibody responses can cross-protect infections from other genotypes remains a question. Understanding of the antigenicity of such diverse genetic EV71 isolates is crucial for the EV71 vaccine development. Here, a total of 186 clones anti-EV71 MAbs was generated and characterized with Western blot and cell-based neutralization assay. Forty neutralizing anti-EV71 MAbs were further used to analyze the antigenic properties of 18 recent EV71 isolates representing seven genotypes in neutralization assay. We found that most neutralizing anti-EV71 MAbs are specific to conformational epitopes. We also classified the 40 neutralizing anti-EV71 MAbs into two classes according to their reactivity patterns with 18 EV71 isolates. Class I MAb can neutralize all isolates, suggesting conserved epitopes are present among EV71. Class II MAb includes four subclasses (IIa–IId) and neutralizes only subgroups of EV71 strains. Conversely, 18 EV71 strains were grouped into antigenic types 1 and four antigenic subtypes (2.1–2.4). These results suggest that the current genotyping of EV71 does not reflect their antigenicity which may be important in the selection of EV71 vaccine strains. This panel of neutralizing anti-EV71 MAbs may be useful for the recognition of emerging antigenic variants of EV71 and vaccine development.     

Fibroblast-stimulating lipopeptide-1 as a potential mucosal adjuvant enhances mucosal and systemic immune responses to enterovirus 71 vaccine

To prevent viral infection at the site of entry, mucosal vaccines are potent tools for inducing IgA secretion for defense. Because Toll-like receptor (TLR) ligands serve as strong adjuvants, two ligands that mimic the structure of mycoplasmal and bacterial lipopeptides represent interesting vaccine candidates. Pam3CSK4, a synthetic triacylated lipopeptide, interacts with TLR2/1. Because fibroblast-stimulating lipopeptide-1 (FSL-1), a synthetic diacylated lipopeptide, is recognized by TLR2/6, we targeted the potential immuno-inducibility of Pam3CSK4 and FSL-1 as adjuvants of an enterovirus 71 (EV71) mucosal vaccine. Naïve BALB/c mice were used for intranasal immunization three times over a 3-week interval, with results showing that EV71-specific IgG and IgA in serum, nasal washes, bronchoalveolar lavage fluid, and feces from the EV71 + FSL-1 group were significantly higher than levels observed in mice treated with EV71 + Pam3CSK4, EV71 alone, or the control group treated with phosphate-buffered saline. Furthermore, we observed more EV71-specific IgG and IgA-producing cells in treatments using EV71 formulated with FSL-1. Additionally, T cell-proliferative responses and interferon-γ and interleukin-17 secretion were significantly increased when inactivated EV71 was formulated using FSL-1. Moreover, serum from immunized mice was capable of neutralizing the infectivity of EV71 (C2 genotype) and was able to cross-neutralize the B4 and B5 genotypes of EV71. Our data suggested that FSL-1 could be used as an efficient adjuvant for intranasal EV71-vaccine immunization.     

Attenuation and genetic characteristics of a Moroccan strain of Camel pox virus

Camel pox (CML) is a widespread infectious viral disease of camels that causes huge economic losses to the camel industry. In this study, a local strain of Camel pox virus (CMLV) was attenuated by 175 serial passages in Vero cells and the residual pathogenicity and infectivity were tested in naïve camels at 120, 150 and 175 passage levels. Also, the safety and immunogenicity of the 175th passage were evaluated in camels using a dose of 10^4.0 Tissue Culture Dose 50% (TCID₅₀₎ and monitored for up to one-year post vaccination (pv) for neutralizing antibody. Seroconversion was noted at day 14 pv with neutralizing antibody titers ranging from 0.5 and 1.6 logs over the one-year of the study. Among 8 camels inoculated with the P175 strain, 4 were challenged at 12-month pv with 10^5.7 TCID₅₀/ml of the original virulent CMLV and complete protection was recorded in all animals. Whole genome sequencing detected six mutations in the original CMLV strain that were not present in the attenuated 175th passage of this strain. Overall, the findings of this study indicated that the 175th passage of the CMLV was attenuated, safe and afforded protection to camels against virulent CMLV, and is therefore, a promising vaccine candidate for the prevention of CML in camels.     

Process intensification for Peste des Petites Ruminants Virus vaccine production

Process intensification for Peste des Petites Ruminants Virus (PPRV) vaccine production in anchorage dependent Vero cells is challenging, involving substantial amount of bioprocess development.In this study, we describe the implementation of a new, scalable bioprocess for PPRV vaccine production in Vero cells using serum-free medium (SFM), microcarrier technology in stirred-tank bioreactors (STB), in-situ cell detachment from microcarriers and perfusion. Vero cells were successfully adapted to ProVero™-1 SFM, reaching growth rates similar to serum-containing cultures (0.030 1/h vs 0.026 1/h, respectively). An in-situ cell detachment method was successfully implemented, with efficiencies above 85%. Up to 2.5-fold increase in maximum cell concentration was obtained using perfusion when compared to batch culture. Combining perfusion with the in-situ cell detachment method enabled the scale-up to 20 L STB directly from a 2 L STB, surpassing the need for a mid-scale platform (i.e. 5 L STB) and thus reducing seed train duration. Head-to-head comparison of cell growth and PPRV production in the 2 L and 20 L STB was performed, and no significant differences could be observed. Estimated infectious PPRV titers in Tissue Culture Infection Dose (TCID₅₀) (TCID₅₀/mL = 5 × 10⁶ and TCID₅₀/cell = 5) are within the log-range reported in literature for PPRV production in STB and SFM by Silva et al. (2008), thus confirming the feasibility and scalability of the seed train designed [1].The novel and scalable vaccine production process herein proposed has the potential to assist the upcoming Peste des Petites Ruminants (PPR) Global Eradication Program (targeted by FAAO for 2030) by providing African local and/or regional manufacturers with a platform capable of generating over 25,000 doses of Nigeria 75/1 strain in just 19 days using a 20 L STB.     

深圳市一起肠道病毒71型引发手足口病流行的基因型别分析

目的 对2004年深圳市一起肠道病毒71型(EV71)引发手足口病流行的基因型别分析.方法 用EV71型特异性引物进行RT-PCR,并对EV71的VPl和VP4基因进行克隆,所得的序列与EV71型A、B、C基因型代表株的核苷酸序列用TreeView和PHYLIP软件(3.6b)进行系统进化分析.结果 4株病毒与C基因型代表株比较接近,VP1区核苷酸同源性在87.8%～92.0%之间,VP4区核苷酸同源性在85.9%～87.4%之间;与A、B基因型代表株比较差异较大,VPI区核苷酸同源性为81.9%～84.2%,VP4区为80.6%～85.0%;4株病毒VP1核苷酸同源性为94.1%～99.8%,VP4同源性为100%,组成一个独立的小分支.结论 对EV71的VPI和VP4区进行基因进化分析,可得出类似的结果 ,4株EV71深圳流行株可命名为C4亚型.     

A Phase I,randomized, open-label study to evaluate the safety and immunogenicity of an enterovirus 71 vaccine

Background

Large-scale outbreaks of enterovirus 71 (EV71) infections have occurred in Asia-Pacific regions. Severe complications include encephalitis and poliomyelitis-like paralysis, cardiopulmonary collapse, and death, necessitating an effective vaccine against EV71.

Methods

In this randomized Phase I study, we evaluated the safety and immunogenicity of an inactivated alum-adjuvanted EV71 whole-virus vaccine produced on Vero cell cultures. Sixty healthy volunteers aged 20–60 years received two doses of vaccine, administered 21 days apart. Each dose contained either 5 μg of EV71 antigen with 150 μg of adjuvant (Group A05) or 10 μg of EV71 antigen with 300 μg of adjuvant (Group B10). Serologic analysis was performed at baseline, day 21, and day 42.

Results

There were no serious adverse events. Mild injection site pain and myalgia were the most common adverse events with either vaccine formulation. The immunogenicity data showed that 90% of vaccine recipients have a 4-fold or greater increase in neutralization antibody titers (NT) after the first dose, without a further increase in NT after the second dose. The seroconversion rates on day 21 and day 42 were 86.7% and 93.1% respectively, in Group A05, and 92.9% and 96.3%, respectively, in Group B10. Thus, 5 μg and 10 μg of the EV71 vaccine can induce a remarkable immune response in healthy adults after only the first vaccination.

Conclusion

The 5 μg and 10 μg adjuvanted EV71 vaccines are generally safe and immunogenic in healthy adults. (ClinicalTrials.gov number, NCT01268787).     

Cross-reactive neutralizing antibody epitopes against Enterovirus 71 identified by an in silico approach

Currently, infections of hand, foot and mouth disease (HFMD) due to Human Enterovirus 71 (EV71) cannot be prevented or treated, as there are no suitable vaccines or antiviral drugs. This study aimed to identify potential vaccine candidates for EV71 using in silico analysis of its viral capsid proteins. A combined in silico approach utilizing computational hidden Markov model (HMM), propensity scale algorithm, and artificial learning, identified three 15-mer structurally conserved B-cell epitope candidates lying within the EV71 capsid proteins. Peptide vaccine candidates incorporating a target B-cell epitope and a promiscuous T-cell epitope from the related polio virus were synthesized using solid-phase Fmoc chemistry. Inbred BALB/C mice which were inoculated with two 10 μg doses of the synthetic peptide, generated anti-peptide antibodies. Purified IgG isolated from pooled sera of the inoculated mice neutralized EV71 infections in vitro. Furthermore, these neutralizing antibodies were cross-reactive against other members of the Picornaviridae family, demonstrating greater than 50% virus neutralization. This indicates that the current approach is promising for the development of synthetic peptide-based vaccine candidates against Picornaviridae. Development of effective vaccines is of paramount importance in managing the disease in the Asia Pacific regions where this virus is endemic and has significant social, economic and public health ramifications.     

A new EV71 VP3 epitope in norovirus P particle vector displays neutralizing activity and protection in vivo in mice

Enterovirus 71 (EV71) and Coxsackievirus A16 (CVA16), as the main agents causing hand, foot and mouth disease (HFMD), have become a serious public health concern in the Asia-Pacific region. Recently, various neutralizing B cell epitopes of EV71 were identified as targets for promising vaccine candidates. Structural studies of Picornaviridae indicated that potent immunodominant epitopes typically lie in the hypervariable loop of capsid surfaces. However, cross-neutralizing antibodies and cross-protection between EV71 and CVA16 have not been observed. Therefore, we speculated that divergent sequences of the two viruses are key epitopes for inducing protective neutralizing responses. In this study, we selected 10 divergent epitope candidates based on alignment of the EV71 and CVA16 P1 amino acid sequences using the Multalin interface page, and these epitopes are conserved among all subgenotypes of EV71. Simultaneously, by utilizing the norovirus P particle as a novel vaccine delivery carrier, we identified the 71-6 epitope (amino acid 176–190 of VP3) as a conformational neutralizing epitope against EV71 in an in vitro micro-neutralization assay as well as an in vivo protection assay in mice. Altogether, these results indicated that the incorporation of the 71-6 epitope into the norovirus P domain can provide a promising candidate for an effective synthetic peptide-based vaccine against EV71.     

Enterovirus type 71 neutralizing antibodies in the serum of macaque monkeys immunized with EV71 virus-like particles

Enterovirus type 71 (EV71) is a virulent form of enteroviruses causing hospitalizations for children less than three years of age. Currently there are no anti-viral therapies or vaccines available for EV71. Due to the high risk of poliomyelitis-like paralysis and fatal encephalitis, an effective vaccine to EV71 could potentially prevent virus-induced morbidity and mortality. In this study, we first tested a potential EV71 vaccine candidate based on virus-like particles (VLP). We vaccinated macaque monkeys to validate the immunogenicity of the VLP vaccine to EV71. We detected the VLP or EV71-specific antibodies, neutralization titers, ELISPOT, and T cell response to find their immune responses to EV71. When the VLP vaccine adjuvanted with alum was given to macaque monkeys, these monkeys developed both specific humoral and cellular immune responses to EV71. Despite lower neutralizing antibodies to EV71 were found in sera of VLP-immunized monkeys than monkeys vaccinated with inactivated EV71, VLP-based vaccine generated a memory immune response to EV71. Hence, VLP-based EV71 vaccine is a potential vaccine against EV71 infection.