Protection against influenza virus infection in BALB/c mice immunized with a single dose of neuraminidase-expressing DNAs by electroporation

The ability of a single dose of plasmid DNA encoding neuraminidase (NA) or hemagglutinin (HA) from influenza virus A/PR/8/34 (PR8) (H1N1) to protect against homologous virus infection was examined in BALB/c mice. In the present study, mice were immunized once with 30 microg of NA or HA DNA by electroporation. Four weeks or 28 weeks after immunization, mice were challenged with a lethal dose of homologous virus and the ability of NA or HA DNA to protect the mice from influenza was evaluated. We found that a single inoculation of NA DNA could provide protection against influenza virus challenge as well as long-term protection against viral infection. Whereas, the mice immunized with a single dose of HA DNA could not be protected. In addition, neonatal mice immunized with a single dose of 30 microg of NA DNA could be provided with significant protection against viral infection.     

Cross-protection against a lethal influenza virus infection by DNA vaccine to neuraminidase

Cross-protection against a lethal influenza virus infection was examined in BALB/c mice immunized with plasmid DNAs encoding the neuraminidase (NA) from different subtype A viruses. Each NA-DNA was administered twice, 3 weeks apart, at the dose of 1 μg per mouse by particle-mediated DNA transfer to the epidermis (gene gun) or at a dose of 30 μg per mouse by electroporation into the muscle. Three weeks after the second vaccination, the mice were challenged with lethal doses of homologous or heterologous viruses and the ability of each NA-DNA to protect the mice from influenza was evaluated by determining the lung virus titers, body weight and survival rates. The H3N2 virus NA-DNA conferred cross-protection against lethal challenge with antigenic variants within the same subtype, but failed to provide protection against infection by a different subtype virus (H1N1). The degree of cross-protection against infection was related to titers of the cross-reacting antibodies. These results suggest that NA-DNA can be used as a vaccine component to provide effective protection against infection not only with homologous virus but also with drift viruses.     

Antibody responses and protection against influenza virus infection in different congenic strains of mice immunized intranasally with adjuvant-combined A/Beijing/262/95 (H1N1) virus hemagglutinin or neuraminidase

Antibody (Ab) responses and protection against influenza virus infection in mice immunized intranasally with hemagglutinin (HA) or neuraminidase (NA) purified from the A/Beijing/262/95 (A/Beijing) (H1N1) virus were compared among B10 congenic mouse strains. Mice were immunized intranasally with 0.1, 0.3 or 1microg of HA or NA together with the cholera toxin adjuvant, and then boosted intranasally with 0.3 microg of the adjuvant-combined HA or NA 4 weeks later. Two weeks after the second immunization, the mice were challenged by an infection of the upper respiratory tract with the homologous virus. After 3 days, nasal wash and serum specimens were collected for virus and Ab titration. The HA immunization induced HA-specific IgG Ab responses against A/Beijing HA, which depended on the H-2 haplotype of the strain: The B10.A (H-2(a)), B10.D2 (H-2(d)), B10.BR (H-2(k)) and B10 (H-2(b)) strains were the highest, high, intermediate and low responders, respectively. The nasal IgA responses were induced in the B10.A, B10.D2 and B10.BR strains, but not in the B10 strain. In parallel with Ab responses, the B10.A, B10.BR and B10.D2 strains were conferred significant protection at any dose of primary immunization, but the B10 strain was provided protection only at 1microg of HA. On the other hand, the NA immunization induced NA-specific Ab responses, which depended on the the H-2 haplotype of the strain: the B10.A, B10.D2, B10 and B10.BR strains were the highest, high, intermediate and low responders, respectively. In parallel with Ab responses, all the strains were conferred significant protection at any dose of primary immunization. These results indicate that the MHC-restricted responsiveness of mice to HA is different from that to NA, suggesting that the use of high-HA dose or NA as a component of the nasal influenza A (H1N1 subtype) virus vaccine improves the protective efficacy against influenza among low responder populations.     

Enhanced protection against a lethal influenza virus challenge by immunization with both hemagglutinin- and neuraminidase-expressing DNAs

The ability of plasmid DNA encoding hemagglutinin (HA), neuraminidase (NA) or matrix protein (M1) from influenza virus A/PR/8/34 (PR8) (H1N1), and mixtures of these plasmid DNAs (HA + NA and HA + NA + M1) to protect against homologous or heterologous virus infection was examined in BALB/c mice. Each DNA was inoculated twice, 3 weeks apart, or four times, 2 weeks apart, at a dose of 1 microg of each component per mouse by particle-mediated DNA transfer to the epidermis (gene gun). Seven days after the last immunization, mice were challenged with a lethal homologous or heterologous virus and the ability of each DNA to protect the mice from influenza was evaluated by observing lung virus titers and survival rates. The administration of a plasmid DNA mixture of either (HA + NA) or (HA + NA + M1) provided almost complete protection against the PR8 virus challenge, and this protection was accompanied by high levels of specific antibody responses to the respective components. The degree of protection afforded in these groups is significantly higher than that in mice given either HA- or NA-expressing DNA alone, which provided only a partial protection against PR8 challenge or that in mice given M1-expressing DNA, which failed to provide any protection. In addition, both of the plasmid DNA mixtures (HA + NA) and (HA + NA + M1) showed a slight tendency to provide cross-protection against an A/Yamagata/120/86 (H1N1) virus challenge, and this was accompanied by a relatively high level of cross-reacting antibodies. Thus, there was no clear difference between the ability of the HA + NA and HA + NA + M1 plasmid DNA mixtures in providing protection against either a PR8 or heterologous virus challenge. These results suggest that in mice immunized by gene gun, a mixture of plasmid DNAs encoding HA and NA can provide the most effective protection against the virus challenge. The addition of the M -expressing plasmid DNA to this mixture does not enhance the degree of protection afforded.     

Evaluation of conserved and variable influenza antigens for immunization against different isolates of H5N1 viruses

The combination of rapid evolution and high mortality in human cases of infections has raised concerns that the H5N1 avian influenza virus may become a new, possibly severe, pandemic virus. Vaccination is likely to be the most efficient strategy to mitigate the impact of the next influenza pandemic. The present study evaluates B and T cell immune responses generated by the H5N1 viral antigens, hemagglutinin (HA), neuraminidase (NA), nucleoprotein (NP), or the M2 ion channel in parallel, expressed from a DNA vaccine vehicle. Protection studies of immunized mice challenged with 100 LD50 of homologous or heterologous H5N1 viruses indicate that HA afforded better protection than the NA, NP or M2 DNA vaccines. The antibody response was also higher in HA-vaccinated mice as determined by hemagglutination inhibition (HI) and neutralizing antibodies (NAB) assays. Interestingly, the T cell response was higher against HA than against NA, NP or M2 and was detectable at low doses of the DNA–HA vaccine capable of inducing complete protection, despite the absence of a detectable B cell response. This study emphasizes the need to evaluate the relationship between both arms of the adaptive immune responses in regards to protective efficacy against influenza virus.     

Mutant influenza A virus nucleoprotein is preferentially localized in the cytoplasm and its immunization in mice shows higher immunogenicity and cross-reactivity

Many influenza vaccines targeted to hemagglutinin (HA) show efficient immunogenicity for protecting subjects against influenza virus infection. Major antigenic changes to HA molecules can help influenza virus to develop resistance against HA-targeted vaccines. DNA vaccines encoding conserved antigens protect animals against diverse subtypes, but their potency requires further improvement. We generated a DNA-based nucleoprotein (NP)-targeted vaccine using an N-terminal mutant of NP (NPm) that efficiently localized in the cytoplasm, and examined the immune responses in mice immunized with NPm or wild-type (WT) NP DNA vaccine. Importantly, the NPm vaccine showed 1.5-2-fold higher immunogenicity than the WT NP vaccine in mice. Furthermore, NPm vaccination efficiently protected the mice against lethal challenge with influenza viruses and showed cross-reactivity toward heterologous viruses. Therefore, DNA-based vaccination with NPm may contribute to the development of protective immunity against diverse influenza virus through its ability to stimulate cellular immunity.     

A protective immune response in mice to viral components other than hemagglutinin in a live influenza A virus vaccine model

Previously, we generated influenza A viruses that possess chimeric type (A/B) hemagglutinins (HA), in which immunogenic regions of type A HA were replaced with those of type B HA, and showed that these viruses were attenuated in mice (J. Virol. 77 (2003) 8031). Here, we intranasally immunized mice with these viruses and then challenged them with a wild-type A virus to assess a protective immune response to viral components other than HA in the form of a live virus. All immunized mice survived challenge with a lethal dose of wild-type virus; none or a limited amount of virus, if any, was recovered from nasal turbinates or lungs of the mice 3 days post-challenge. These results provide direct evidence that immune responses to viral components other than HA confer protection against influenza A virus infection in a mouse model, suggesting the usefulness of live vaccines for viruses that have undergone antigenic drift with respect to HA, or for viruses with heterosubtypic HAs.     

Strategies for inducing protection against avian influenza A virus subtypes with DNA vaccines

The cross-species transfer of a H5N1 influenza virus from birds to humans, and the systemic spread of this virus in mice, has accelerated the efforts to devise protective strategies against lethal influenza viruses. DNA vaccination with the highly conserved nucleoprotein gene appears to provide cross protection against influenza A viruses in murine models. Whether such vaccines would protect human hosts against different influenza A viruses, including strains with pandemic potential, is unclear. Our aim in this study is to evaluate the ability of a combination DNA vaccine consisting of two plasmids encoding the HA genes from two different subtypes and a DNA vaccine encoding the viral nucleoprotein gene from a H5 virus to induce protection against highly lethal infection caused by H5 and H7 influenza viruses in chickens. Chickens given a single dose of plasmids expressing H5 and H7 hemagglutinins protected the birds from infection by either subtype. However, birds immunized with nucleoprotein DNA and challenged with either A/Ck/Vic/1/85(H7N7) or A/Ty/Ir/1/83 (H5N8) showed definite signs of infection, suggesting inadequate immunity against viral infection. Fifty percent of the nucleoprotein DNA immunized birds survived infection by influenza A/Ty/Ir/1/83 (H5N8) virus (virus of same subtype) while 42% survived infection by influenza A/Ck/Vic/1/85/(H7N7) virus (virus of a different subtype). These studies demonstrate that immunization with DNA encoding a type-specific gene may not be effective against either homologous or heterologous strains of virus, particularly if the challenge virus causes a highly lethal infection. However, the combination of HA subtype vaccines are effective against lethal infection caused by viruses expressing any of the HA subtypes used in the combination preparation.     

Protection against influenza virus infection in mice immunized by administration of hemagglutinin-expressing DNAs with electroporation

Electroporation for the transfer of plasmid DNA encoding influenza virus hemagglutinin (HA) into muscle or nasal mucosa was tried in BALB/c mice to examine the efficacy of this method for inducing anti-HA immune responses and providing protection against homologous A/PR/8/34 (PR8) virus infection. Mice were immunized by two injections, 3 weeks apart, of HA-DNA with electroporation into the muscle wherein a pair of electrode needles was inserted to deliver the electric pulses. One or 3 weeks after the immunization, the mice were infected with a lethal dose of the PR8 virus. Ten micrograms or more of HA-DNA/dose induced strong serum anti-HA IgG antibody (Ab) responses, in which both IgG1 and IgG2a were predominant, and weak cytotoxic T lymphocyte responses. These immune responses were sufficient to provide efficient protection against the lethal infection. In addition, mice were immunized by dropping HA-DNA (12 microg) three times, 2 weeks between each dose into nostrils where each of two electrode needles was placed on the right nostril or the palate. One week after the immunization, the mice were infected with a sublethal dose of the PR8 virus. The DNA immunization by electroporation provided reduced nasal virus titers, in parallel with a relatively high levels of serum anti-HA IgG Ab and a slight nasal anti-HA IgA Ab production. The intranasal administration of cholera toxin before HA-DNA immunization by electroporation enhanced the nasal IgA Ab production together with enhancement of the efficiency of protection. These results suggest that electroporation can be used as one of the efficient gene delivery systems for the transfer of influenza DNA-vaccine into muscle or nasal mucosa to provide protection against influenza virus infection.     

Intranasal immunization with synthetic recombinant vaccine containing multiple epitopes of influenza virus

The oligonucleotides coding for three epitopes (HA91-108, NP55-69, and NP 147-158) of influenza virus, stimulating B-cells, T-helper cells and cytotoxic T lymphocytes (CTLs), respectively, were previously employed for expressing each epitope in flagella that induced specific humoral and cellular immune responses. We have constructed new plasmids expressing all three epitopes as a single recombinant product. Two versions have been prepared-a longer one (Fla-HNN) comprising hybrid flagella containing the epitopes, and a shorter version (HNN). Immunization of BALB/c mice with either constructs induced significant humoral immune response against influenza virus. The mice immunized with these peptides also induced higher T-helper activity, including Th1 type-cytokine (IL-2 and IFN-gamma) release. In addition, the mice immunized with HNN peptide demonstrated significant protection against sublethal viral challenge. Furthermore, this vaccine fully protected mice from lethal challenge and enhanced their recovery process. Our results indicate that a single construct expressing multiple epitopes, which stimulate different arms of the immune system, might be an appropriate candidate when the synthetic recombinant vaccine approach is considered.     

Long- and short-time immunological memory in different strains of mice given nasally an adjuvant-combined nasal influenza vaccine

Immunological memory induced by nasal immunization with adjuvant-combined influenza vaccine was analyzed in different ages and strains of mice. The memory activities were assessed by secondary nasal-wash IgA and serum IgG antibody (Ab) responses and protection against challenge infection with a lethal dose of influenza virus. Mice were primed with 0.1 microg of vaccine and boosted with 0.1 or 1.0 microg vaccine 1 (short-term memory)- or 17 (long-term memory)-months later. Influenza-specific short-term memory responses in young adult BALB/c mice (2-month-old) were significantly higher than those of long-term memory activities in mice boosted at 19 months of age. However, those influenza-specific long-term memory responses provided protective immunity against influenza virus challenge and were higher than short-term memory in aged mice primed at 18-month-old and boosted 1 month later. These results show that the age at which initial nasal immunization is given is critically important in order to induce protective immunity in aged mice. Similar findings were noted in the C3H mouse strain; however, C57BL/6 mice failed to induce influenza-specific immune responses in both young adult and aged mice. These results indicate that low doses of cholera toxin B subunit (supplemented with 0.2% of hole toxin) combined nasal vaccine may required further improvement in order to provide protective immunity in human use.     

Evaluation of seasonal influenza vaccines for H1N1pdm09 and type B viruses based on a replication-incompetent PB2-KO virus

Vaccination is the first line of protection against influenza virus infection in humans. Although inactivated and live-attenuated vaccines are available, each vaccine has drawbacks in terms of immunogenicity and safety. To overcome these issues, our group has developed a replication-incompetent PB2-knockout (PB2-KO) influenza virus that replicates only in PB2-expressing cells. Here we generated PB2-KO viruses possessing the hemagglutinin (HA) and neuraminidase (NA) segments from H1N1pdm09 or type B viruses and tested their vaccine potential. The two PB2-KO viruses propagated efficiently in PB2-expressing cells, and expressed chimeric HA as expected. Virus-specific IgG and IgA antibodies were detected in mice immunized with the viruses, and the immunized mice showed milder clinical signs and/or lower virus replication levels in the respiratory tract upon virus challenge. Our results indicate that these PB2-KO viruses have potential as vaccine candidates.     

Targeting of nucleoprotein to chemokine receptors by DNA vaccination results in increased CD8+-mediated cross protection against influenza

Vaccination is at present the most efficient way of preventing influenza infections. Currently used inactivated influenza vaccines can induce virus-neutralizing antibodies that are protective against a particular influenza strain, but hamper the induction of cross-protective T-cell responses to later infections. Thus, influenza vaccines need to be updated annually in order to confer protection against circulating influenza strains. This study aims at developing an efficient vaccine that can induce broader protection against influenza. For this purpose, we have used the highly conserved nucleoprotein (NP) from an influenza A virus subtype H7N7 strain, and inserted it into a vaccine format that targets an antigen directly to relevant antigen presenting cells (APCs). The vaccine format consists of bivalent antigenic and targeting units, linked via an Ig-based dimerization unit. In this study, NP was linked to MIP-1α, a chemokine that targets the linked antigen to chemokine receptors 1, 3 and 5 expressed on various APCs. The vaccine protein was indirectly delivered by DNA. Mice were vaccinated intradermally with plasmids, in combination with electroporation to enhance cellular uptake of DNA. We found that a single DNA vaccination was sufficient for induction of both antibody and T cell responses in BALB/c mice. Targeting of nucleoprotein to chemokine receptors enhanced T cell responses but not antibody responses. Moreover, a single dose of MIP1α-NP conferred protection in BALB/c mice against a lethal challenge with an H1N1 influenza virus. The observed cross-protection was mediated by CD8⁺ T cells.     

Cross-protection against influenza B type virus infection by intranasal inoculation of the HA vaccines combined with cholera toxin B subunit

The relationship between the antibody responses to various influenza B type virus HA vaccines and protection against live B virus infection was investigated in Balb/c mice which had been inoculated intranasally with a combination of the HA vaccines and B subunit of cholera toxin (CTB) 4 weeks previously. The inoculation of HA vaccine, prepared from B/Ibaraki/2/85 (B/Ibaraki), B/Nagasaki/1/87 (B/Nagasaki) or B/Aichi/5/88 (B/Aichi) viruses, combined with CTB induced high levels of both nasal IgA and serum HI antibodies to any of B/Ibaraki, B/Nagasaki and B/Aichi viral antigens. Simultaneous inoculation of each CTB-combined HA vaccine provided complete protection against B/Ibaraki virus infection which is demonstrated by both rapid clearance of pulmonary virus and complete survival. On the other hand, the inoculation of HA vaccine prepared from B/Yamagata/16/88 (B/Yamagata) virus together with CTB induced only a low level of nasal IgA antibodies, cross-reactive to B/Ibaraki, B/Nagasaki and B/Aichi viral antigens and protected only partially against B/Ibaraki virus challenge. The involvement of the B type virus-specific immunity in this protection was suggested by the absence of protection against B/Ibaraki virus infection in mice previously inoculated with both A/PR/8/34 (H1N1) virus HA vaccine and CTB. These results suggest that antibodies to various influenza B viruses are cross-reactive to each B type virus antigens and that cross-protection against B virus infection could be conferred depending on the degree of B type virus cross-reactive immunity including secretory IgA antibodies.     

Immune responses and protection in different strains of aged mice immunized intranasally with an adjuvant-combined influenza vaccine.

Immune responses and protection against influenza virus infection were compared between young (2 months) and aged (18 months) BALB/c, C3H and C57BL/6 (B6) mice after intranasal vaccination. The mice were immunized with 2.5 microg protein of A/PR/8/34 (PR8) (H1N1) virus vaccine containing a cholera toxin adjuvant. In both the young and aged BALB/c mice, high levels of PR8-specific antibody-forming cell (AFC) responses were induced in the nasal-associated lymphoid tissue (NALT) 7 days after immunization. Nasal wash IgA and serum IgG antibody (Ab) responses to the PR8 haemagglutinin (HA) 4 weeks after immunization were slightly higher in the young mice than in the aged mice. The young mice showed complete protection against challenge infection, while the aged mice showed only a partial protection. In the C3H mice, NALT-AFC, and IgA and IgG Ab responses were higher in the young mice than those in the aged mice in parallel with the more efficient protection in the young mice than in the aged mice. Both the young and aged B6 mice showed no NALT-AFC responses, scarce IgA and IgG Ab responses and no protection. In the BALB/c mice, IgG1 and IgG2a levels were significantly lower in the aged mice. On the other hand, in the C3H mice, only IgG2a level was significantly lower in the aged mice. Similar results were obtained in terms of immune responses and protection between the young and aged mice of three different strains of mice after intra-nasal immunization with 0.1 microg of PR8 vaccine containing the adjuvant, two-times at 4-week intervals. In the B6 mice, the immune response was improved by immunization with a higher dose of the adjuvant-combined vaccine. These results suggest that local Ab responses, as well as systemic Ab responses, are downregulated in aged mice, although the degree of the downregulation of immune responses differs from strain to strain.     

Protection against influenza virus infection by nasal vaccination in advance of sublethal irradiation

The effect of sublethal gamma-ray irradiation on the protection conferred by a nasal influenza vaccine was investigated in BALB/c mice. A radiation dose of 7 Gy was selected as the sublethal dose as this caused exacerbation of the influenza but was not lethal in the mouse model. Mice were irradiated 7 days before, on the same day as, and 7 days after, administration of a nasal influenza vaccine, and were then infected with a lethal dose of the virus 4 weeks after vaccination. Almost all mice irradiated 7 days before or on the same day as vaccination died from viral pneumonia around 7 days after the challenge infection, whereas all mice irradiated 7 days after vaccination survived with no sign of infection. In mice irradiated 7 days after vaccination, both local anti-viral IgA and systemic IgG antibodies were produced in parallel with a marked reduction in lung viral titer, although no antibody production and no reduction in lung viral titer were detected in mice irradiated 7 days before, or on the same day as, vaccination. These results clearly demonstrate that vaccination with influenza virus before irradiation can protect mice from subsequent infection. This may be applicable to patients due to receive sublethal irradiation for bone marrow transplantation.     

Intramuscular immunization with a vesicular stomatitis virus recombinant expressing the influenza hemagglutinin provides post-exposure protection against lethal influenza challenge

Vaccines currently licensed for the prevention of seasonal influenza induce antibodies against the influenza hemagglutinin (HA) and neuraminidase (NA) contained in the vaccine preparation but require at least 2 weeks after immunization for the development of protective immunity. These vaccines do not induce protective responses quickly enough to blunt the effects of infection when administered after exposure. We have developed a novel vaccine based on recombinant vesicular stomatitis virus which expresses the influenza hemagglutinin (rVSV HA) and protects mice from lethal influenza challenge when the vaccine is administered intramuscularly at least 24 h after delivery of the influenza challenge virus. To our knowledge this is the first vaccine that effectively protects animals from lethal influenza challenge when delivered by a systemic route after influenza exposure has occurred. The induction of HA-specific immune responses by the vaccine is necessary for full protection from challenge, because animals immunized with an empty rVSV vector were not protected equally. Our results are consistent with a model in which vaccination induces an immediate antiviral cytokine response, followed by development of humoral and cellular immune responses which act to reduce pulmonary viral loads and accelerate recovery. Consistent with this model, mice vaccinated with the specific vaccine rVSV HA had high levels of IFN-α in the serum by 24 h after challenge/vaccination, developed serum neutralizing Ab to influenza 2 days prior to control animals, and had detectable anti-HA CD8 T cells present in the peripheral blood 3 days prior to control mice.     

Effectiveness and safety of mutant Escherichia coli heat-labile enterotoxin (LT H44A) as an adjuvant for nasal influenza vaccine

The effectiveness and safety of mutant Escherichia coli heat-labile enterotoxin, LT H44A (His to Arg substitution at position 44 from the N-terminus of the A1 fragment of the A subunit) as an adjuvant for nasal influenza vaccine were examined. (1) When 0.2 microg of LT H44A, together with 0.2 microg of influenza A/PR/8/34 virus (PR8, H1N1) vaccine, was administered intranasally into BALB/c mice (twice, 4 weeks apart), anti-PR8 hemagglutinin (HA) IgA and IgG antibody (Ab) responses were induced at levels that were sufficient to provide either complete protection against infection with a small volume of PR8 virus suspension or partial protection against infection with a lethal dose of the suspension. The dose of the mutant LT and vaccine used here (0.2 microg/ 20 g doses mouse) corresponded to the estimated dose per person, i.e. 0.1 mg/10 kg body weight. (2) Using these vaccination conditions, no additional total IgE Ab responses were induced. (3) The mutant was confirmed to be less toxic than the native LT when the toxicity was analyzed either using Y1 adrenal cells in vitro (1/483 EC(50)) or by an ileal loop test. (4) One hundred micrograms of the mutant, administered intranasally or intraperitoneally into guinea-pigs (Heartley strain, 0.3-0.4 kg), caused no body-weight changes 7 days after administration, although 100 microg of the native LT administered intraperitoneally caused death in all guinea-pigs due to diarrhea within 2 days. The intranasal administration of 100 microg of the mutant resulted in almost no pathological changes in the nasal mucosa 3 days after administration. These results suggest that LT H44A, which can be produced in high yields in an E. coli culture (about 5 mg/l), could be used as one of the effective and safe adjuvants for nasal influenza vaccine in humans.     

A replication-incompetent virus possessing an uncleavable hemagglutinin as an influenza vaccine

Vaccination is one of the most effective measures to protect against influenza virus infection. Inactivated and live-attenuated influenza vaccines are available; however, their efficacy is suboptimal. To develop a safe and more immunogenic vaccine, we produced a novel replication-incompetent influenza virus that possesses uncleavable hemagglutinin (HA) and tested its vaccine potential. The uncleavable HA was engineered by substituting the arginine at the C-terminus of HA1 with threonine, which prevents cleavage of HA into its HA1 and HA2 subunits, preventing fusion between the host and viral membranes. Although this fusion-deficient HA influenza virus that possesses uncleavable HA (uncleavable HA virus) could undergo multiple cycles of replication in only wild-type HA-expressing cells, it could infect normal cells and express viral proteins in infected cells, but could not generate infectious virus from infected cells due to the uncleavable HA. When C57BL/6 mice were intranasally immunized with the uncleavable HA virus, influenza-specific IgG and IgA antibodies were detected in nasal wash and bronchoalveolar lavage samples and in serum. In addition, influenza-specific CD8(+) T cells accumulated in the lungs of these mice. Moreover, mice immunized with the uncleavable HA virus were protected against a challenge of lethal doses of influenza virus, unlike mice immunized with a formalin-inactivated virus. These findings demonstrate that this fusion-deficient virus, which possesses uncleavable HA, is a suitable influenza vaccine candidate.     

Protection against lethal enterovirus 71 infection in newborn mice by passive immunization with subunit VP1 vaccines and inactivated virus.

Enterovirus 71 (EV71), the newest member of Enteroviridae, is notable for its etiological role in epidemics of severe neurological diseases in children. Developing effective vaccines is considered a top choice among all control measures. We compared the inactivated virus vaccine (10 microg protein/mouse) with subunit vaccines--VP1 DNA vaccine (100 microg/mouse) or recombinant VP1 protein (10 microg/mouse)--in its ability to elicit maternal antibody and to provide protection against lethal infection of EV71 in suckling mice. Prior to gestation, all three groups of vaccinated dams possessed similar levels of neutralizing antibody. With a challenge dose of 2300 LD(50) virus/mouse, suckling mice born to dams immunized with inactivated virus showed 80% survival. The subunit vaccines provided protection only at a lower challenge dosage of 230 LD(50) per mouse, with 40% survival for DNA vaccine and 80% survival for VP1 protein. The cytokine profile produced by splenocytes showed a high level of IL-4 in the inactivated virus group, high levels of IFN-gamma and IL-12 in the DNA vaccine group, and high levels of IL-10 and IFN-gamma in the VP1 protein group. Overall, the inactivated virus elicited a much greater magnitude of immune response than the subunit vaccines, including total IgG, all four IgG subtypes, and T-helper-cell responses; these antibodies were shown to be protective against lethal infection when passively transferred to susceptible newborn mice. Our data indicated that inactivated virus is the choice of vaccine preparation capable of fulfilling the demand for effective control, and that VP1 subunit vaccines remain promising vaccine strategies that require further refinement.