Supplementation of conventional trivalent influenza vaccine with purified viral N1 and N2 neuraminidases induces a balanced immune response without antigenic competition

Influenza viruses neuraminidase (NA) were chromatographically extracted from influenza viruses A/Nanchang/933/95 H3(NC)N2(NC) [R] and A/Johannesburg/82/96 H1(JH)N1(JH) [R] and used to supplement conventional inactivated trivalent influenza vaccine. Immunization of mice with this preparation resulted in high titers of antibodies to both hemagglutinins (HA) and neuraminidases (NA); there were no significant differences in the anti-HA antibody titers between the conventional and the supplemented vaccine preparation. Likewise, there were no significant differences in anti-NA antibody titers between the supplemented vaccine and titers from mice immunized with a neuraminidase vaccine containing a mixture of N1-NA and N2-NA. There was no evidence of a diminution of the immune response to the HA components of the vaccine despite the presence of antigenically equivalent amounts of both N1-NA and N2-NAs. Homotypic and distantly related heterotypic infections for both H1, N1 and H3N2 subtypes were suppressed and greater reduction in pulmonary virus titers (PVT) were observed in the trivalent vaccine supplemented with purified neuraminidase from each subtype, N1 and N2. Effects on the influenza B viral components were not studied. Previous studies on supplementation of conventional influenza vaccine focused only on monovalent H3N2 vaccine preparations; this study demonstrates in a mouse model system that supplementation of trivalent influenza vaccine with both influenza A subtype neuraminidases, N1 and N2 is highly immunogenic for HA and NA of each subtype and efficacious in protecting against influenza from homotypic and heterotypic infectious challenges of either subtype.     

A high dosage influenza vaccine induced significantly more neuraminidase antibody than standard vaccine among elderly subjects

Antibody to the neuraminidase (NA) antigen of influenza viruses has been shown to correlate with immunity to influenza in humans and animal models. In a previous report, we showed that an inactivated influenza vaccine containing 60 μg of the hemagglutinin (HA) of each strain induced significantly more serum anti-HA antibody among elderly persons than did the standard vaccine containing 15 μg of the HA of each component. We developed a lectin-based assay for anti-NA antibody and used it to measure anti-NA antibody responses among subjects who had participated in that study. The high dosage vaccine contained eight times as much NA activity as the standard vaccine and induced a significantly higher frequency of antibody responses and higher mean postvaccination anti-NA titers to the N1 and N2 of the A/H1N1 and A/H3N2 viruses in the vaccines than did the standard vaccine. Ensuring an increased antibody response to the NA antigen in inactivated influenza virus vaccines should increase the protection against influenza. An increased quantity of the NA antigen in the vaccine will ensure an increased response.     

VaxArray for hemagglutinin and neuraminidase potency testing of influenza vaccines

Practical methods to measure the potency of influenza vaccines are needed as alternatives for the standard single radial immunodiffusion (SRID) assay. VaxArray assays for influenza hemagglutinin (HA) and neuraminidase (NA) have been developed to address this need. In this report, we evaluate the use of these assays to assess the potency of HA and NA of an A/H3N2 subunit vaccine by determining the correlation between the amounts measured by VaxArray and the immunogenicity in mice. The antibody response after one and two doses of five formulations of the vaccine ranging from 5 µg/mL to 80 µg/mL of HA, was measured by hemagglutination inhibition (HAI) and neuraminidase inhibition (NAI) assays. For hemagglutinin, vaccine potency determined by VaxArray was equivalent to potency measured SRID and these amounts were predictive of immunogenicity, with excellent correlation between potency measured by VaxArray and the HAI geometric mean titers (GMT). Likewise, the amount of NA measured by VaxArray was predictive of the NAI GMT. The VaxArray NA assay reported non-detectable levels of intact NA for a sample that had been heat degraded at 56 °C for 20 h, demonstrating that the assay measures the native, active form of NA. Similarly, the HA potency measured by VaxArray in this heat-treated sample was very low when a monoclonal antibody was used to detect the amount of antigen bound. Importantly, the force degraded sample induced low HAI titers and the NAI titers were not measurable, supporting the conclusion that the VaxArray HA and NA assays measure the immunogenic forms of these A/H3N2 antigens. This study indicates that VaxArray assays can be used to assess the potency of HA and NA components in influenza vaccines as a proxy for immunogenicity.     

Stability of neuraminidase in inactivated influenza vaccines

Influenza vaccines are effective in protecting against illness and death caused by this seasonal pathogen. Antibodies that block the function of either hemagglutinin (HA) or neuraminidase (NA) contribute to vaccine efficacy, however vaccine potency is based only on HA content. NA protein content in vaccines varies from season to season due to differences in the relative amounts of HA and NA in influenza A, H1N1 and H3N2, and influenza B viruses that are selected for each manufacturing campaign. This, as well as potential inherent differences in NA immunogenicity, may result in varying responses from year to year. Moreover, the antigenic stability of NA is likely to dictate whether similar antibody responses will be obtained to this antigen throughout the shelf-life of the vaccine. To address this factor, we subjected NAs of influenza A (subtypes N1 and N2) and B viruses to denaturing conditions to evaluate the stability of enzyme activity. Each NA type/subtype had unique sensitivity to denaturing conditions. The N2 enzyme activity was more thermostable than that of N1 or influenza B, while the NA activity of influenza B was most resistant to detergent. N1 enzyme activity was most resistant of the three NAs to freeze–thaw cycling. In these experiments, enzyme activity was indicative of the immunogenicity of NA, but was strain-dependent, with greater neuraminidase inhibiting (NI) antibody titers elicited following immunization with the 2009 H1N1 pandemic virus A/California/7/2009, than the previously circulating seasonal H1N1 strain, A/Brisbane/59/2007. Robust NI antibody titers against both N1 and N2 components were induced following vaccination of mice with a trivalent inactivated influenza vaccine. When stored under recommended conditions, the NA of both N1 and N2 subtypes remained immunogenic well after the vaccine expiry date.     

Inactivated influenza virions are a flexible vaccine platform for eliciting protective antibody responses against neuraminidase

Most seasonal influenza vaccines are produced using hemagglutinin (HA) surface antigens from inactivated virions. However, virions are thought to be a suboptimal source for the less abundant neuraminidase (NA) surface antigen, which is also protective against severe disease. Here, we demonstrate that inactivated influenza virions are compatible with two modern approaches for improving protective antibody responses against NA. Using a DBA/2J mouse model, we show that the strong infection-induced NA inhibitory (NAI) antibody responses are only achieved by high dose immunizations of inactivated virions, likely due to the low viral NA content. Based on this observation, we first produced virions with higher NA content by using reverse genetics to exchange the viral internal gene segments. Single immunizations with these inactivated virions showed enhanced NAI antibody responses and improved NA-based protection from a lethal viral challenge while also allowing for the development of natural immunity to the heterotypic challenge virus HA. Second, we combined inactivated virions with recombinant NA protein antigens. These combination vaccines increased NA-based protection following viral challenge and elicited stronger antibody responses against NA than either component alone, especially when the NAs possessed similar antigenicity. Together, these results indicate that inactivated virions are a flexible platform that can be easily combined with protein-based vaccines to improve protective antibody responses against influenza antigens.     

H5N1禽流感病毒血凝素和神经氨酸酶基因在杆状病毒中的共表达

目的构建共表达H5N1禽流感病毒血凝素(HA)和神经氨酸酶(NA)蛋白的杆状病毒表达系统。方法利用PCR方法分别扩增A/Hubei/1/2010(H5N1)病毒的HA和NA基因,克隆至经改造带有对虾白斑综合病毒(WSSV)早期启动子iel的mpFastBac Dual载体,构建mpFast Bac-HA-NA表达质粒,转化DH10Bac感受态细胞,用获得的Bacmid-HA-NA穿梭质粒转染sf9细胞,获得重组杆状病毒Bac-HA-NA;提取重组杆状病毒Bac-HA-NA的DNA并使用PCR方法检测;利用Western blot检测HA和NA表达,并分别检测重组杆状病毒Bac-HA-NA红细胞凝集能力和神经氨酸酶活性。结果经PCR鉴定,构建的质粒Bacmid-HA-NA正确;Western blot检测表明Bacmid-HANA能在sf9细胞中有效表达HA和NA蛋白,生物活性检测表明Bac-HA-NA能引起红细胞凝集并具有神经氨酸酶活性。结论获得了能同时表达禽流感病毒HA和NA的重组杆状病毒Bac-HA-NA,为进一步研究流感疫苗奠定了基础。     

AF03 adjuvant improves anti-hemagglutinin and anti-neuraminidase immune responses induced by licensed seasonal quadrivalent influenza vaccines in mice

Seasonal influenza remains a serious public health concern as the viral infection spreads easily from person to person and due to antigenic drift of neutralizing epitopes. Vaccination is the best method for disease prevention, however current seasonal influenza vaccines stimulate antibodies which are often effective against only antigenically similar strains. To boost the immune responses and increase vaccine effectiveness, adjuvants have been used for the past 20 years. The current study explores the use of oil-in-water adjuvant, AF03 to improve an immunogenicity of 2 licensed vaccines. A standard-dose inactivated quadrivalent influenza vaccine (IIV4-SD), containing both hemagglutinin (HA) and neuraminidase (NA) antigens, and recombinant quadrivalent influenza vaccine (RIV4), containing only HA-antigen were adjuvanted with AF03 in naïve BALB/c mouse model. Functional HA-specific antibody titers against all four homologous vaccine strains were enhanced by AF03, indicating potential increase in protective immunity. An increase in HA-specific total immunoglobulin G (IgG) binding titers were detected against homologous HAs, heterologous panel of 30 H3 HAs and seven Influenza B HAs. The neuraminidase inhibition (NAI) activity was significantly higher in IIV4-SD-AF03 group. Use of AF03 adjuvant improved the immune response to two influenza vaccines in a mouse model via an increase in functional and total antibodies against NA and a broad panel of HA-antigens.     

Randomized comparative study of the serum antihemagglutinin and antineuraminidase antibody responses to six licensed trivalent influenza vaccines

Background

Serum antibody to the hemagglutinin (HA) surface protein of influenza virus induced by influenza vaccination is a correlate of protection against influenza. The neuraminidase (NA) protein is also on the surface of the virus; antibody to it has been shown to impair virus release from infected cells and to reduce the intensity of influenza infections in animal models and in humans challenged with infectious virus. Recently we have shown that NA inhibiting antibody can independently contribute to immunity to naturally-occurring influenza immunity in the presence of antibody to the HA.

Purpose

The present study was conducted to evaluate induction of antibody to the NA and the HA by commercially available influenza vaccines.

Methods

Healthy young adults were vaccinated with one of five commercially available trivalent inactivated vaccines or live influenza vaccine. Frequencies of serum antibody and fold geometric mean titer (GMT) increases four weeks later were measured to each of the three vaccine viruses (A/H1N1, A/H3N2, B) in hemagglutination-inhibition (HAI) and neutralization (neut) assays. Frequency and fold GMT increase in neuraminidase-inhibition (NI) antibody titers were measured to the influenza A viruses (A/H1N1, A/H3N2).

Results

No significant reactogenicity occurred among the vaccinated subjects. The Fluvirin inactivated vaccine induced more anti-HA antibody responses and a higher fold GMT increase than the other inactivated vaccines but there were no major differences in response frequencies or fold GMT increase among the inactivated vaccines. Both the frequency of antibody increase and fold GMT increase were significantly lower for live vaccine than for any inactivated vaccine in HAI and neut assays for all three vaccine viruses. Afluria inactivated vaccine induced more N1 antibody and Fluarix induced more N2 antibody than the other vaccines but all inactivated vaccines induced serum NI antibody. The live vaccine failed to elicit any NI responses for the N2 NA of A/H3N2 virus and frequencies were low for the N1 of A/H1N1 virus.

Conclusions

Trivalent inactivated influenza vaccines with similar HA dosage induce similar serum anti-HA antibody responses in healthy adults. Current inactivated vaccines all induce serum anti-NA antibody to the N1 and N2 NA proteins but some are better than others for N1 or N2. The live vaccine, Flumist, was a poor inducer of either anti-HA or anti-NA serum antibody compared to inactivated vaccine in the healthy adults. In view of the capacity for contributing to immunity to influenza in humans, developing guidelines for NA content and induction of NA antibody is desirable.     

A practical influenza neutralization assay to simultaneously quantify hemagglutinin and neuraminidase-inhibiting antibody responses

Influenza vaccine immunogenicity is commonly assessed by determining hemagglutination inhibition (HAI) titers in serum samples. HAI titers have been used to predict vaccine efficacy, but this often fails when live attenuated vaccines are evaluated, because it does not encompass all immune mediators of protection. Although antibodies that inhibit viral neuraminidase (NA) also contribute to protection against disease, there is currently no routine assessment of NA inhibition titers. A serological method with the capacity to measure functional inhibition of both HA and NA would be valuable. We developed a high-throughput virus neutralization assay that uses viral NA activity to quantify influenza replication (the AVINA assay), and showed its capacity to identify antivirals with a broad range of target specificities. In this report we demonstrate that antibodies with specificity for either HA or NA are detected in this assay, whereas a commonly used virus neutralization assay only detects those with HA-specificity. We also compared human responses to seasonal influenza vaccines measured by HAI, micro-neutralization, NA inhibition and AVINA assays. The response rates to both trivalent inactivated and live attenuated vaccines were greater when measured by the AVINA than the other assays, reflecting the dual antigen reactivity and increased sensitivity of the assay. The potential of this single assay to predict protection against influenza-induced tachypnea was demonstrated in vaccinated cotton rats. The AVINA assay is therefore a practical, comprehensive method to determine influenza vaccine immunogenicity and potential efficacy.     

H5N1 VLP vaccine induced protection in ferrets against lethal challenge with highly pathogenic H5N1 influenza viruses

In this study, recombinant virus-like particles (VLPs) were evaluated as a candidate vaccine against emerging influenza viruses with pandemic potential. The VLPs are composed of the hemagglutinin (HA), neuraminidase (NA), and matrix 1 (M1) proteins of the H5N1 A/Indonesia/05/2005 (clade 2.1; [Indo/05]) virus, which were expressed using baculovirus in Spodoptera frugiperda (Sf9) cells. Ferrets received either 2 injections of the VLP vaccine at escalating doses (based on HA content), recombinant HA, or were mock vaccinated. Vaccinated ferrets were then challenged with either H5N1 Indo/05 or H5N1 A/Viet Nam 1203/2004 (VN/04) wild-type viruses. All ferrets that received the VLP vaccine survived regardless of the VLP dose or challenge strain, whereas seven of eight mock vaccinated ferrets died. The VLP vaccine induced HAI antibodies against the homologous H5N1 clade 2.1 strain, as well as heterologous strains from H5N1 clades 1, 2.2, and 2.3. The magnitude of the HAI titers correlated with VLP dose. Neutralizing antibody responses against the Indo/05 and VN/04 strains showed a similar pattern. Affinity of the anti-HA antibodies raised by the H5N1 Indo/05 VLPs had a higher association rate to the homologous clade 2.1 HA than to the clade 1 (VN/04) HA; however, once bound, antibodies had similar slow disassociation rates. These results provide support for continued development of the H5N1 VLPs as a candidate vaccine against pandemic influenza. Exploration of immunologic correlates of protection for H5N1 vaccines beyond HAI and neutralizing antibody responses is warranted.     

Simultaneous quantification of the viral antigens hemagglutinin and neuraminidase in influenza vaccines by LC-MSE

Current methods for quality control of inactivated influenza vaccines prior to regulatory approval include determining the hemagglutinin (HA) content by single radial immunodiffusion (SRID), verifying neuraminidase (NA) enzymatic activity, and demonstrating that the levels of the contaminant protein ovalbumin are below a set threshold of 1 μg/dose. The SRID assays require the availability of strain-specific reference HA antigens and antibodies, the production of which is a potential rate-limiting step in vaccine development and release, particularly during a pandemic. Immune responses induced by neuraminidase also contribute to protection from infection; however, the amounts of NA antigen in influenza vaccines are currently not quantified or standardized. Here, we report a method for vaccine analysis that yields simultaneous quantification of HA and NA levels much more rapidly than conventional HA quantification techniques, while providing additional valuable information on the total protein content. Enzymatically digested vaccine proteins were analyzed by LC-MS(E), a mass spectrometric technology that allows absolute quantification of analytes, including the HA and NA antigens, other structural influenza proteins and chicken egg proteins associated with the manufacturing process. This method has potential application for increasing the accuracy of reference antigen standards and for validating label claims for HA content in formulated vaccines. It can also be used to monitor NA and chicken egg protein content in order to monitor manufacturing consistency. While this is a useful methodology with potential for broad application, we also discuss herein some of the inherent limitations of this approach and the care and caution that must be taken in its use as a tool for absolute protein quantification. The variations in HA, NA and chicken egg protein concentrations in the vaccines analyzed in this study are indicative of the challenges associated with the current manufacturing and quality control testing procedures.     

Changing perspective on immunization against influenza

Current vaccination strategies against influenza rely on decades old technology of strain selection and prolonged labor-intensive, embryonated chicken-egg based production methods. Although, containing both major surface glycoproteins, hemagglutinin (HA) and neuraminidase (NA), the immunity engendered by these vaccines is dominated by the anti-HA response. Consequently, current vaccines are susceptible to failure resulting from significant antigenic drift or shift in the time elapsing from the selection of the vaccine candidate strain and wild-type virus exposure. Therefore, immunity may be of short duration. There must be a change in vaccine strategy to include immunization with both HA and NA to broaden the immune response against influenza. Inclusion of the more slowly evolving NA in a vaccine against influenza will reduce the vulnerability to antigenic changes in a potential emerging influenza virus. Alternative production technologies such as recombinant baculovirus and yeast should be explored to decrease vaccine production times.     

A recombinant West Nile virus envelope protein vaccine candidate produced in Spodoptera frugiperda expresSF+ cells

In this study, a recombinant truncated West Nile virus envelope protein antigen (rWNV-E) was produced in serum-free cultures of the expresSF+ insect cell line via baculovirus infection. This production system was selected based on its use in the production of candidate human and animal vaccine antigens. A defined fermentation and purification process for the rWNV-E antigen was established to control for purity and immunogenicity of each protein batch. The material formulated with aluminum hydroxide was stable for greater than 8 months at 4 °C. The recombinant vaccine candidate was evaluated for immunogenicity and protective efficacy in several animal models. In mouse and hamster WNV challenge models, the vaccine candidate induced viral protection that correlated with anti-rWNV-E immunogenicity and WNV neutralizing antibody titers. The rWNV-E vaccine candidate was used to boost horses previously immunized with the Fort Dodge inactivated WNV vaccine and also to induce WNV neutralizing titers in naïve foals that were at least 14 weeks of age. Furthermore, the vaccine candidate was found safe when high doses were injected into rats, with no detectable treatment-related clinical adverse effects. These observations demonstrate that baculovirus-produced rWNV-E can be formulated with aluminum hydroxide to produce a stable and safe vaccine which induces humoral immunity that can protect against WNV infection.     

An Advax-CpG55.2 adjuvanted recombinant hemagglutinin vaccine provides immunity against H7N9 influenza in adult and neonatal mice

There is a major unmet need for strategies to improve the immunogenicity and effectiveness of pandemic influenza vaccines, particularly in poor responder populations such as neonates. Recombinant protein approaches to pandemic influenza offer advantages over more traditional inactivated virus approaches, as they are free of problems such as egg adaptation or need for high level biosecurity containment for manufacture. However, a weakness of recombinant proteins is their low immunogenicity. We asked whether the use of an inulin polysaccharide adjuvant (Advax) alone or combined with a TLR9 agonist (CpG55.2) would enhance the immunogenicity and protection of a recombinant hemagglutinin vaccine against H7N9 influenza (rH7HA), including in neonatal mice. Advax adjuvant induced predominantly IgG1 responses against H7HA, whereas Advax-CpG55.2 adjuvant also induced IgG2a, IgG2b and IgG3 responses, consistent with the TLR9 agonist component inducing a Th1 bias. Advax-CpG55.2 adjuvanted rH7HA induced high serum neutralizing antibody titers in adult mice. In newborns it similarly overcame immune hypo-responsiveness and enhanced serum anti-rH7HA IgG levels in 7-day-old BALB/C and C57BL/6 mice. Immunized adult mice were protected against a lethal H7N9 virus challenge. When formulated with Advax-CpG55.2 adjuvant, greater protection was seen with rH7HA than with inactivated H7 whole virus antigen. Advax-CpG55.2 adjuvanted rH7HA represents a promising influenza vaccine platform for further development.     

Recombinant H1N1 virus-like particle vaccine elicits protective immunity in ferrets against the 2009 pandemic H1N1 influenza virus

The pandemic virus of 2009 (2009 H1N1) continues to cause illness worldwide, especially in younger age groups. The widespread H1N1 virus infection further emphasizes the need for vaccine strategies that are effective against emerging pandemic viruses and are not dependent on the limitations of traditional egg-based technology. This report describes a recombinant influenza virus-like particle (VLP) vaccine consisting of hemagglutinin (HA), neuraminidase (NA), and matrix (M1) proteins of influenza A/California/04/2009 (H1N1) virus. Influenza H1N1 VLPs with a diameter of approximately 120 nm were released into the culture medium from Sf9 insect cells infected with recombinant baculovirus coexpressing HA, NA, and M1 proteins. Purified recombinant H1N1 VLPs morphologically resembled influenza virions and exhibited biological characteristics of influenza virus, including HA and NA activities. In the ferret challenge model, 2009 influenza H1N1 VLPs elicited high-titer serum hemagglutination inhibition (HI) antibodies specific for the 2009 H1N1 virus and inhibited replication of the influenza virus in the upper and lower respiratory tract tissues following A/Mexico/4482/09 (H1N1) virus challenge. Moreover, a single 15 μg dose of H1N1 VLPs resulted in complete virus clearance in the ferret lung. These results provide support for the use of recombinant influenza VLP vaccine as an effective strategy against pandemic H1N1 virus.     

Antigenic characterization of influenza viruses produced using synthetic DNA and novel backbones

The global system for manufacturing seasonal influenza vaccines has been developed to respond to the natural evolution of influenza viruses, but the problem of antigenic mismatch continues to be a challenge in certain years. In some years, mismatches arise naturally due to the antigenic drift of circulating viruses after vaccine strain selection has already been made. In other years, antigenic differences between the vaccine virus and circulating viruses are introduced as part of the current system, which relies on the use of egg-adapted isolates as a starting material for candidate vaccine viruses (CVVs). Improving the current process for making vaccine viruses can provide great value. We have previously established a synthetic approach for rapidly generating influenza viruses in a vaccine-approved Madin Darby canine kidney (MDCK) cell line using novel, high-growth backbones that increase virus rescue efficiency and antigen yield. This technology also has the potential to produce viruses that maintain antigenic similarity to the intended reference viruses, depending on the hemagglutinin (HA) and neuraminidase (NA) sequences used for gene synthesis. To demonstrate this utility, we generated a panel of synthetic viruses using HA and NA sequences from recent isolates and showed by hemagglutination inhibition (HI) tests that all synthetic viruses were antigenically-like their conventional egg- or cell-propagated reference strains and there was no impact of the novel backbones on antigenicity. This synthetic approach can be used for the efficient production of CVVs that may be more representative of circulating viruses and may be used for both egg- and cell-based vaccine manufacturing platforms. When combined with mammalian cell culture technology for antigen production, synthetic viruses generated using HA and NA sequences from a non-egg-adapted prototype can help to reduce the potential impact of antigenic differences between vaccine virus and circulating viruses on vaccine effectiveness.     

Prediction of highly pathogenic avian influenza vaccine efficacy in chickens by comparison of in vitro and in vivo data: A meta-analysis and systematic review

Vaccines for avian influenza (AI) can protect poultry against disease, mortality, and virus transmission. Numerous factors, including: vaccine platform, immunogenicity, and relatedness to the field strain, are known to be important to achieving optimal AI vaccine efficacy. To better understand how these factors contribute to vaccine protection, a systematic meta-analysis was conducted to evaluate efficacy data for vaccines in chickens challenged with highly pathogenic (HP) AI. Data from a total of 120 individual trials from 25 publications were selected and evaluated. Two vaccine criteria were evaluated for their effects on two metrics of protection. The vaccine criteria were: 1) the relatedness of the vaccine antigen and challenge strain in the hemagglutinin 1 domain (HA1) protein sequence; 2) vaccine-induced antibody titers to the challenge virus (VIAC). The metrics of protection were: A) survival of vaccinated chickens vs unvaccinated controls; and B) reduction in oral virus-shedding by vaccinated vs unvaccinated controls 2–4 days post challenge. Three vaccine platforms were evaluated: oil-adjuvanted inactivated whole AI virus, recombinant herpes virus of turkeys (rHVT) vectored, and a non-replicating alpha-virus vectored RNA particle (RP) vaccine. Higher VIAC correlated with greater reduction of virus-shed and vaccine efficacy by all vaccine platforms. Both higher HA1 relatedness and higher VIAC using challenge virus as antigen correlated with better survival by inactivated vaccines and rHVT-vectored vaccines. However, rHVT-vectored and RP based vaccines were more tolerant of variation in the HA1; the relatedness of the HA1 of the vaccine and challenge virus did not significantly correlate with survival with rHVT-vectored vaccines. Protection was achieved with the lowest aa similarity for which there was data, 90–93 % for rHVT vaccines and 88 % for the RP vaccine.     

Influenza virus-like particles elicit broader immune responses than whole virion inactivated influenza virus or recombinant hemagglutinin

Influenza virus is a highly infectious respiratory pathogen that results in severe morbidity and mortality. The current licensed trivalent vaccine formulations in the U.S. are made from virus grown in allantoic fluid from infected hen eggs that is then chemically inactivated and split into subunit components. These vaccines elicit antibodies, primarily to the viral hemagglutinin (HA), which are efficacious in healthy adults, but are limited in protecting high risk individuals, such as the elderly and immunocompromised. To address the need for improved influenza vaccines and the limitations of egg-based manufacturing, we have engineered an influenza virus-like particle (VLP) as a new generation of non-egg or non-mammalian cell culture-based candidate vaccine against influenza infection. VLPs, based on the A/Fujian/411/2002 (H3N2) isolate, were purified from the supernatants of Spodoptera frugiperda Sf9 insect cells following infection of baculovirus vectors encoding an expression cassette comprised of only three influenza virus structural proteins, hemagglutinin (HA), neuraminidase (NA), and matrix (M1). Mice or ferrets were vaccinated intramuscularly with VLPs in a dose sparing experiment, based on HA concentration (3 microg-24 ng), and the immune responses were compared to responses elicited in animals vaccinated with recombinant HA (rHA) or inactivated whole influenza virions (WIV). All vaccinated animals had high titer anti-HA antibodies regardless of the vaccine immunogen and animals vaccinated with the highest doses of VLPs (3 microg and 600 ng) also had antibodies against NA. Purified rHA elicited primarily IgG1 antibodies, which is indicative of a T helper (Th) type 2 response, whereas mice vaccinated with the VLPs or WIV were associated with a dominant Th1 immune response (IgG2a and IgG2b). Interestingly, VLPs elicited antibodies that recognized a broader panel of antigenically distinct H3N2 viral isolates compared to rHA or WIV in a hemagglutination-inhibition (HAI) assay.     

Squalene-containing licensed adjuvants enhance strain-specific antibody responses against the influenza hemagglutinin and induce subtype-specific antibodies against the neuraminidase

While seasonal influenza vaccines are usually non-adjuvanted, H1N1pdm09 vaccines were formulated with different squalene-containing adjuvants, to enable the reduction of antigen content thus increasing the number of doses available. To comparatively assess the effects of these adjuvants on antibody responses against matched and mismatched strains, and to correlate antibody levels with protection from disease, ferrets were immunized with 2 μg of commercial H1N1pdm09 vaccine antigen alone or formulated with different licensed adjuvants. The use of squalene-containing adjuvants increased neutralizing antibody responses around 100-fold, and resulted in a significantly reduced viral load after challenge with a matched strain. While all animals mounted strong total antibody responses against the homologous H1N1 hemagglutinin (HA) protein, which correlated with the respective neutralizing antibody titers, no reactivity with the divergent H3, H5, H7, and H9 proteins were detected. Only the adjuvanted vaccines also induced antibodies against the neuraminidase (NA) protein, which were able to also recognize NA proteins from other N1 carrying strains. These findings not only support the use of squalene-containing adjuvants in dose-sparing strategies but also support speculations that the induction of NA-specific responses associated with the use of these adjuvants may confer partial protection to heterologous strains carrying the same NA subtype.     

Purified influenza A virus N2 neuraminidase vaccine is immunogenic and non-toxic in humans

The immunogenicity and toxicity of a purified influenza virus (N2) neuraminidase vaccine (NAV) were investigated in 88 human subjects aged 18–40, and compared to response to a conventional trivalent influenza vaccine, Fluogen (Parke-Davis). NAV doses ranged from 2.6 to 69.9 μg and were given intramuscularly. Serologic neuraminidase-inhibiting (NI) and neuraminidase-specific ELISA responses in this N2-primed population were roughly proportional to the dose administered. Maximal response was seen in 14–21 days and NI antibody titers persisted unabated for the 6-month post-vaccination follow-up period. All doses were well tolerated with respect to local and systemic reactions. NI tests performed with the putative (1975) priming N2 antigen demonstrated anamnestic response but did not reveal responses not already shown with the homologous (1992) antigen. Response to this purified, non-adjuvanted preparation encourages continuing investigation of the induction of infection-permissive immunity with influenza virus neuraminidase.