Co-expression of granulocyte-macrophage colony-stimulating factor with antigen enhances humoral and tumor immunity after DNA vaccination

Granulocyte-macrophage colony-stimulating factor (GM-CSF) was used to enhance humoral and tumor immunity resulting from DNA immunization. The genes encoding GM-CSF and antigen were cloned onto the same plasmid backbone, but separate promoters drove expression of each gene. beta-Galactosidase was used as the model antigen to generate antibody responses while the human tumor antigen, MAGE-1, was used to monitor tumor resistance. Immunization with a DNA vaccine co-expressing GM-CSF and beta-gal resulted in higher antigen-specific IgG responses than immunization with antigen encoding plasmid alone or co-inoculated with GM-CSF expressing plasmid. Similarly, DNA vaccines expressing both MAGE-1 antigen and GM-CSF were more effective in protecting against B16-MAGE-1 melanoma. However, both GM-CSF co-expressing DNA vaccines and co-inoculation with plasmids encoding the cytokine or antigen enhanced the generation antigen-specific IFN-gamma and IL-6 responses. These results demonstrate that co-expressing both GM-CSF and antigen on a DNA vaccine enhances humoral and tumor immune responses.     

Co-delivery of plasmid-encoded cytokines modulates the immune response to a DNA vaccine delivered by in vivo electroporation

In this study, in vivo electroporation of a DNA vaccine adjuvanted with plasmids encoding different cytokines was investigated in large animals. Sheep were injected intramuscularly with a DNA vaccine encoding an antigen of Haemonchus contortus (pNPA) and plasmids encoding different cytokines followed by in vivo electroporation. Plasmids (pCI) carrying the genes of different cytokines including ovine IL-4(pCI-IL4), IL-10(pCI-IL10), GM-CSF(pCI-GMCSF), and MCP-1alpha(pCI-MCP1alpha), and pCI-IL4+pCI-GMCSF were co-delivered with pNPA. The results showed that co-delivery of pCI-GMCSF or pCI-IL4+pCI-GMCSF significantly enhanced both antibody responses and T cell proliferation responses to the antigen after two DNA immunisations compared to co-delivery of pCI. In contrast, antibody responses of the sheep that received pCI-IL10 were decreased significantly. Other cytokine expressing plasmids did not significantly alter the measured immune responses. Furthermore, co-delivery of pCI-GMCSF increased IgG2 response more than IgG1 responses, suggesting a Th1 bias. However, the increase in IgG2 over IgG1 was less apparent when co-delivery of pCI-IL4 with pCI-GMCSF. Interestingly, the co-delivery of pCI-IL4 alone did not increase the IgG1 titre, suggesting that both pCI-GMCSF and pCI-IL4 are required for optimal IgG1 production. Thus, co-delivery of plasmid-encoded cytokine genes with in vivo electroporation has the ability to effectively modulate immune responses to a DNA vaccine in a large animal.     

The comparative efficacy of CTLA-4 and L-selectin targeted DNA vaccines in mice and sheep

The access of antigens to antigen presenting cells (APCs) appears to be a rate-limiting step in the generation of immune responses to DNA vaccines. The cytotoxic T lymphocyte antigen 4 (CTLA-4) and L-selectin represent attractive ligands for use in the targeting of antigen to APCs and lymph nodes. CTLA-4 binds with high affinity to the B7 membrane antigen on APCs, while L-selectin functions as a lymphocyte homing marker and binds to CD34 on the surface of high endothelial venule cells. DNA vaccines encoding human immunoglobulin (HIg), fused to either CTLA-4 or L-selectin, have been shown to generate up to 10,000-fold higher anti-HIg antibody responses than DNA vaccines encoding HIg alone. In this study, the ability of CTLA-4 or L-selectin mediated targeting to enhance the humoral immune response to an alternate vaccine antigen was investigated. DNA vaccines encoding CTLA-4-HIg and L-selectin-HIg fused to the host-protective 45W antigen from Taenia ovis were constructed. In BALB/c mice, the L-selectin targeted vaccine did not improve either the magnitude or speed of antibody responses of vaccinated mice. In contrast, the CTLA-4 targeted DNA vaccine generated 45W-specific antibody responses which were up to 30-fold higher than those achieved with non-targeted DNA vaccination. The kinetic of the antibody response generated following CTLA-4 targeted DNA vaccination was also significantly faster than that achieved with non-targeted DNA vaccination, or with adjuvanted protein vaccination. Vaccination of outbred sheep with DNA vaccines expressing either murine or ovine CTLA-4 targeted antigen failed to enhance immune responses. These findings indicate that CTLA-4 targeting may find application in the improvement of DNA vaccines, but requires further development for applications in large animal species.     

Efficient vaccination by intradermal or intramuscular inoculation of plasmid DNA expressing hepatitis B surface antigen under desmin promoter/enhancer control

The small surface antigen of the hepatitis B virus (HB5Ag) was cloned into expression plasmid pCI under either a viral (CMV) promoter;enhancer sequence control (plasmid pCI/S), or a human desmin promoter/enhancer sequence control (plasmid pDes/S). Cells of different species and tissue origin transiently transfected in vitro with pCI/S or pDes/S plasmid DNA expressed readily detectable amounts of HBsAg, either intracellularly (precipitated from cell lysates), or as secreted products (detectable in ELISA). When these plasmids were used in DNA vaccination, both efficiently primed humoral and/or cellular immune responses to HBsAg after a single injection in Balb/c mice. Intramuscular injection of a high dose of DNA (100 rig/mouse) of both plasmids primed MHC-I-restricted cytotoxic T lymphocyte (CTL) responses and Thi serum antibody responses (IgGlIgG2a ratio O.4C0.7) of comparable magnitude in all vaccinated mice. Intradermal injection of low doses of (particle-coated) DNA (1 microgm/mouse) of both plasmids with the gene gun primed Th2 serum antibody responses (IgGl/IgG2a ratio > 100) but no CTL responses. The data indicate that antigens can be efficiently expressed under viral or eukaryotic promoter/enhancer control for immunogenic in vivo presentation, but that the technique, dose and/or route of DNA injection have a decisive role in determining the type of immune response elicited.     

Electroporation-based DNA transfer enhances gene expression and immune responses to DNA vaccines in cattle

Despite the potential of DNA vaccines to induce strong, balanced immune responses in small experimental species, the immune responses to DNA immunization in larger species have generally been moderate and inconsistent. In this study, the TriGridtrade mark Delivery System (TDS), an electroporation-based DNA delivery platform, was evaluated for administration of DNA vaccines to calves. When compared to conventional intramuscular delivery, TDS-based delivery markedly and consistently enhanced gene expression from a plasmid encoding a reporter gene, secreted alkaline phosphatase, and improved cell-mediated and humoral immune responses to a plasmid encoding a model antigen, hepatitis B surface antigen. Importantly, the TDS-based procedure was well tolerated by the calves, which did not need to be anesthetized or sedated. These results suggest that the TDS is a useful delivery method for DNA vaccines in cattle.     

Oral administration of low doses of plant-based HBsAg induced antigen-specific IgAs and IgGs in mice,without increasing levels of regulatory T cells

Plant-based oral vaccines run the risk of activating regulatory T cells (Tregs) and suppressing the antigen-specific immune response via oral tolerance. Mice humanized for two HLA alleles (HLA-A2.1 and HLA-DR1) were used to measure changes in Tregs and antigen-specific immune responses induced by the oral administration of tobacco (Nicotiana tabacum), expressing the hepatitis B surface antigen (HBsAg). Antigen-specific CD8+ T cell activation was not detected, but the plant-based oral immunization, without adjuvant, resulted in humoral responses comparable to those obtained by adjuvanted DNA immunization. Treg titers did not increase with DNA immunization. In contrast, with plant immunization, Tregs increased linearly to reach a plateau at high antigen doses. The highest humoral IgA and IgG responses correlated with the lowest plant antigen dose (0.5 ng), while for DNA immunization the best antibody responses were obtained at higher antigen doses. These experiments suggest that plant-based oral vaccines could be adjusted to minimize tolerance, while still inducing an immune response. Oral tolerance and adjuvant engineering in plants are discussed.     

DNA immunization of dairy cows with the clumping factor A of Staphylococcus aureus

Blocking the primary stages of Staphylococcus aureus infection, specifically the bacterial adhesion to cell and the colonization of the mucosal surface, may be the most effective strategy for preventing infections. Clumping factor A (ClfA) is considered to be one of the most important adhesions factors of S. aureus to host cells. The present study describes the immune response of dairy cattle to a DNA vaccine against ClfA and evaluates the ability of specific genetic adjuvants, targeting sequences (granulocyte macrophage colony-stimulating factor and cytotoxic T lymphocyte antigen-4) and transporter molecules (chitosan and copolymer) to modify the immune response of cows. The results show that vaccination of cows with fibrinogen-binding region A induced a strong and specific antibody response to ClfA in comparison with a control group injected with the pCI vector alone. Although the co-expression of both genetic adjuvants and the addition copolymer transporter did not augment the overall antibody response, these approaches decreased the number of non-responsive cows. Chitosan was the only factor that did not enhance the immune response. Three months after the last DNA immunization, three cows from each of the pGM-CSF, internal ribosomal entry site (IRES), pCTLA and pCI groups were injected with 200 microg of recombinant ClfA protein in incomplete Freund's adjuvant. A strong humoral response was observed in all groups following this protein boost, with the response occurring slightly earlier in DNA-primed protein boost cows. Sera and milk samples taken from cows after the second DNA injection or after the protein boost (sera only) were analyzed for their ability to block adherence and increase phagocytosis. Pre-incubation of S. aureus with sera or milk from vaccinated cows significantly reduced the pathogen's ability to adhere to MAC-T cells relative to the sera and milk samples from the pCI-injected control cows. Similarly, pools of sera and milk from vaccinated cows increased phagocytosis of S. aureus by neutrophils. After the protein boost, sera were more efficient promoters of phagocytosis, reflecting the higher anti-ClfA antibody level of these sera. DNA-prime/protein boost regimes combined with molecular adjuvants appeared to be effective in generating a strong immune response to S. aureus antigens in cattle.     

Oral administration of polymer-grafted starch microparticles activates gut-associated lymphocytes and primes mice for a subsequent systemic antigen challenge

The mucosal and systemic humoral immune systems can function essentially independent of each other, responding to mucosal and parenteral antigens, respectively. Nevertheless, antigen administered by one route can modify responsiveness to subsequent immunization by an alternate route. Here we demonstrated, in mice, in addition to stimulating rapid and robust sera antibody responses, intragastric (i.g.) immunization with human serum albumin (HSA)-containing starch microparticles (MP) grafted with 3-(triethoxysilyl)-propyl-terminated polydimethylsiloxane (TS-PDMS) primed for enhanced specific sera IgG following a parenteral antigen boost. After as little as one i.g. immunization with microentrapped, but not with soluble, HSA antigen-specific proliferation and antibody secretion were detected in Peyer's pathches (PP); this activity peaked after three i.g. MP immunizations. We observed a progressive dissemination of antigen-specific lymphocyte reactivity from PP to splenic tissue following oral MP immunization. Similarly, we observed a shift in HSA-specific antibody-secreting cells from PP and mesenteric lymph nodes to splenic tissue following i.g. MP immunization. We also demonstrated that oral immunization with microentrapped, but not with soluble HSA, resulted in enhanced numbers of spontaneous Th2-cytokine secreting lymphocytes which disseminated from mucosal to systemic lymphoid compartments. This observation coincided with our findings that HSA-specific sera IgG1 responses in animals given HSA in MP were significantly higher than those detected in the sera of mice given soluble HSA i.g., both before and after parenteral antigen challenge. These findings suggest that orally-administered TS-PDMS-grafted MP, by stimulating elements of the mucosal immune system, are a valuable addition to mucosal and systemic vaccine delivery systems.     

Immune response to caprine arthritis-encephalitis virus surface protein induced by coimmunization with recombinant vaccinia viruses expressing the caprine arthritis-encephalitis virus envelope gene and caprine interleukin-12

The objective of this study was to determine if interleukin (IL)-12 can focus an antigen specific type 1 immune response characterized by activation of Th1 lymphocytes and production of IgG2 antibodies in vivo. Saanen goats co-immunized with recombinant vaccinia viruses expressing caprine IL-12 (rRB-IL12) and the caprine arthritis-encephalitis virus (CAEV) envelope (env) gene (rWR-63) were evaluated for development of immune responses to the CAEV env encoded surface glycoprotein (SU). Immune responses were defined by: (i) SU antibody titers; (ii) the ratio of SU IgG1 and IgG2 antibodies; (iii) interferon gamma (IFNgamma) and IL-4 gene expression and proliferative response of SU stimulated lymph node mononuclear cells (LNMC). Apart from enhancement of IFNgamma and IL-4 gene expression in SU stimulated LNMC, rRB-IL12 did not affect the immune response to rWR-63 encoded SU. Thus, localized production of exogenous species specific IL-12 at the site of immunization did not focus initial priming of antigen reactive Th lymphocytes. These results are in contrast to previous studies using inbred mice and raise questions regarding the use of cytokine adjuvants to focus immune responses in outbred animals.     

Evaluation of immune response to recombinant potential protective antigens of Mycoplasma hyopneumoniae delivered as cocktail DNA and/or recombinant protein vaccines in mice

Intramuscular immunization of mice with DNA cocktail vaccines, comprising potential protective antigens P36, P46, NrdF, and P97or P97R1 of Mycoplasma hyopneumoniae, induced strong Th1-polarized immune responses against each antigen, with only P46 eliciting a serum IgG response. Subcutaneous immunization with protein cocktail vaccines, surprisingly, induced both Th1-polarized immune response as well as antibody response whereas mice immunized with DNA cocktail vaccines followed by boosting with protein cocktail vaccines generated strong Th1-polarized and humoral immune responses. P97 was not recognized by serum antibodies from commercial bacterin-immunized mice indicating potential lack of expression of this important antigen in inactivated whole-cell vaccines.     

Vaxfectin enhances antigen specific antibody titers and maintains Th1 type immune responses to plasmid DNA immunization

Antigen specific immune responses were characterized after intramuscular immunization of BALB/c mice with 5 antigen encoding plasmid DNAs (pDNAs) complexed with Vaxfectin, a cationic lipid formulation. Vaxfectin increased IgG titers for all of the antigens with no effect on the CTL responses to the 2 antigens for which CTL assays were performed. Both antigen specific IgG1 and IgG2a were increased, although IgG2a remained greater than IgG1. Furthermore, Vaxfectin had no effect on IFN-gamma or IL-4 production by splenocytes re-stimulated with antigen, suggesting that the Th1 type responses typical of intramuscular pDNA immunization were not altered. Studies with IL-6 -/- mice suggest that the antibody enhancement is IL-6 dependent and results in a correlative increase in antigen specific antibody secreting cells.     

Intradermal DNA immunization by using jet-injectors in mice and monkeys

We have used spring powered jet injectors to deliver a solution of a naked DNA vaccine encoding the influenza hemagglutinin HA into the skin of mice and monkeys. We compared the immune responses induced by this needleless injection technique into the skin to the responses induced by a classical i.m. immunization. Both routes of immunization induced significant ELISA antibody titers and hemagglutination inhibition (HI) titers that were above the usual threshold values predictive of protection against influenza in mice and monkeys. In mice, both ways of immunization were equally efficient in inducing HA-specific CTL responses. Regarding antibody isotypes, the IgG1/IgG2a ratio was in favour of the IgG2a isotype for i.m. immunization and more balanced for i.d. immunization. The ability of the two injection techniques to induce immunity in mice did not correlate with transgene expression in the site of administration. In fact, local gene expression was 10-100 fold more important in the injected muscle as compared to the jet-injected skin when assessed by using the luciferase reporter system.     

Plasmids encoding granulocyte-macrophage colony-stimulating factor and CD154 enhance the immune response to genetic vaccines

We examined whether plasmids encoding granulocyte-macrophage colony-stimulating factor (pGM-CSF) or CD40-ligand (pCD40L) could modify the immune response to antigen encoded by co-injected plasmid DNA. For this we used as antigen Escherichia coli beta galactosidase (beta-gal), encoded by the plasmid pLacZ. We found that intradermal co-injection of pLacZ with both pGM-CSF and pCD40L enhanced the anti-beta-gal IgG response by approximately two orders of magnitude compared to injections of pLacZ alone. Co-injection of both pGM-CSF and pCD40L with pLacZ significantly enhanced antigen-specific IgG, and in particular IgG(2a), over that of animals co-injected with pLacZ and either pGM-CSF or pCD40L. We found that co-injection of pGM-CSF and pCD40L with pLacZ enhanced the generation of beta-gal-specific cytotoxic T cells, and allowed for a significant expansion of CD8(+) T cells from splenocytes co-cultured with beta-gal expressing stimulator cells. The immunostimulatory effects induced by pGM-CSF or pCD40L required injection of these plasmids to the same site that received pLacZ. 'Priming' experiments, where the site of injection was pre-injected with either plasmid adjuvant, showed that pGM-CSF, but not pCD40L, could enhance the anti-beta-gal immune response induced by subsequently administered plasmid antigen. We conclude that plasmids encoding GM-CSF and CD154 are particularly effective genetic adjuvants when used together to enhance the humoral and cellular immune response to a plasmid-encoded antigen.     

Induction of mucosal IgA by a novel jet delivery technique for HIV-1 DNA

Novel ways of delivering plasmid DNA to elicit humoral IgA, IgG and cell-mediated immune responses in mice were investigated. Intraoral administration of DNA in the cheek, using a jet immunization technique, elicited the highest IgA mucosal responses. Intranasal immunization gave strong mucosal IgA responses and persistent systemic IgG. Immunoglobulin isotype analysis revealed an IgG1 profile for intramuscular tongue and gene gun immunizations and an IgG2a profile following oral jet injection and intranasal application. The route of delivery was of importance for the characteristics and quality of the mucosal immune response following DNA immunization. For DNA vaccine delivery, the intraoral jet injection technique has the advantages of being a simple and rapid way of administering the DNA in solution and of provoking specific mucosal IgA when administered in the mucosal associated lymphoid tissue.     

Targeting of HIV-p24 particle-based vaccine into differential skin layers induces distinct arms of the immune responses

Skin routes of immunization such as subcutaneous (SC), intradermal (ID) and transcutaneous (TC) administration are utilized for vaccination against various pathogens, without understanding their potential impact on the outcome of immune responses. We demonstrated that SC immunization induced HIV-1 p24 specific IgG in absence of antigen-specific CD8 T cells, whereas the ID route induced both cellular and humoral responses. Interestingly, TC application through empty hair follicular ducts, targeting epidermal Langerhans Cells (LCs), induced major CD8 effector cells, in the absence of IgG. However, high levels of mucosal IgA, were localized in the stratified epithelium of the vagina after TC prime. We propose that re-directing the immune responses by targeting differential skin immunization routes, offers enormous potential for innovative vaccination strategies, especially against HIV.     

Mucosal immunization with liposome-nucleic acid adjuvants generates effective humoral and cellular immunity

Development of effective new mucosal vaccine adjuvants has become a priority with the increase in emerging viral and bacterial pathogens. We previously reported that cationic liposomes complexed with non-coding plasmid DNA (CLDC) were effective parenteral vaccine adjuvants. However, little is known regarding the ability of liposome-nucleic acid complexes to function as mucosal vaccine adjuvants, or the nature of the mucosal immune responses elicited by mucosal liposome-nucleic acid adjuvants. To address these questions, antibody and T cell responses were assessed in mice following intranasal immunization with CLDC-adjuvanted vaccines. The effects of CLDC adjuvant on antigen uptake, trafficking, and cytokine responses in the airways and draining lymph nodes were also assessed. We found that mucosal immunization with CLDC-adjuvanted vaccines effectively generated potent mucosal IgA antibody responses, as well as systemic IgG responses. Notably, mucosal immunization with CLDC adjuvant was very effective in generating strong and sustained antigen-specific CD8⁺ T cell responses in the airways of mice. Mucosal administration of CLDC vaccines also induced efficient uptake of antigen by DCs within the mediastinal lymph nodes. Finally, a killed bacterial vaccine adjuvanted with CLDC induced significant protection from lethal pulmonary challenge with Burkholderia pseudomallei. These findings suggest that liposome-nucleic acid adjuvants represent a promising new class of mucosal adjuvants for non-replicating vaccines, with notable efficiency at eliciting both humoral and cellular immune responses following intranasal administration.     

Targeted lymph node immunization can protect cats from a mucosal challenge with feline immunodeficiency virus

With the rapid spread of human immunodeficiency virus (HIV) infection worldwide it is clear that effective strategies for mucosal vaccination against lentiviruses are urgently required. The aim of the present study is to determine whether protective immune responses against a mucosal challenge by feline immunodeficiency virus (FIV) can be elicited by targeting the immunization to the medial iliac lymph nodes--the principal site of migration of cells from the genital and rectal mucosa. Cats were challenged with homologous FIV via the rectal route. Targeted lymph node immunization was found to be an effective route of immunization eliciting both humoral and proliferative responses to peptide-based and fixed cell vaccines. Vaccination with fixed virus infected cells elicited protection against a cell-free mucosal FIV challenge. In addition, some cats vaccinated with fixed uninfected cells also remained uninfected following a cell-associated FIV challenge.     

Formulation of aluminum hydroxide adjuvant with TLR agonists poly(I:C) and CpG enhances the magnitude and avidity of the humoral immune response

Subunit vaccines generally require adjuvants to achieve optimal immune responses. Toll-like receptor (TLR) agonists are promising immune potentiators, but rapid diffusion from the injection site reduces their local effective concentration and may cause systemic reactions. In this study, we investigated the potential of aluminum hydroxide adjuvant (AH) to adsorb the TLR3 agonist poly(I:C) and TLR9 agonist CpG and compared the effect of the combination adjuvant on the immune response with either the TLR agonists or AH alone in mice. Poly(I:C) and CpG readily adsorbed onto AH and this combination adjuvant induced a stronger IgG1 and IgG2a immune response with a significant increase of antibody avidity. The combination adjuvant enhanced antigen uptake and activation of dendritic cells in vitro. It induced an inflammatory response at the injection site similar to AH but without eosinophils which are typically observed with AH. A distinctive antigen-containing monocyte/macrophage population with an intermediate level of CD11c expression was identified in the draining lymph nodes after immunization with TLR agonists and the combination adjuvant. Injection of the combination adjuvant did not induce an increase of TNFα and CXCL10 in serum in contrast to the injection of soluble TLR agonists. These results indicate that this combination adjuvant is a promising formulation to solve some of the unmet needs of current vaccines.     

Comparative study of immune responses induced after immunization with plasmids encoding the HIV-1 Nef protein under the control of the CMV-IE or the muscle-specific desmin promoter

The objective of this study was to compare immune responses induced against HIV-1 Nef after DNA immunization with Nef encoding plasmids under the control of an ubiquitous or a muscle-specific promoter. To this end, plasmids containing HIV-1 nef under the control of the Cytomegalovirus or the human desmin promoters, specifically expressed in muscle cells, were constructed. Different groups of BALB/c mice were immunized with 10 or 100 microg of both constructs, controls were the pcDNA3 vector or the Nef protein in Freund's adjuvant (Nef-CFA). Our data showed that both plasmids stimulated anti-Nef humoral responses in a dose-dependent manner. The anti-Nef antibody response, however, was earlier and higher with the CMV-IE promoter than with the desmin promoter. We also showed that Nef expressing plasmids induced high titers of anti-Nef antibodies (10(4)), comparable to those obtained in the Nef-CFA group (4x10(4)). Analysis of the specificity of anti-Nef antibodies revealed no influence of the promoter, and in contrast to Nef-CFA, plasmid immunization elicited anti-Nef antibodies directed principally against conformational-dependent epitopes. Data on the lymphoproliferative response showed that the specificity of expression, or the plasmid dose, did not affect the onset-time or the intensity of the response. The predominant IgG2a isotype of anti-Nef antibodies and the cytokine profile, mostly IL-2 and IFN-gamma, produced by Nef-stimulated spleen cells indicated a Th1 response in plasmid-immunized mice, in contrast to mice immunized with Nef-CFA, where a Th2 response was induced. In conclusion, these data indicate that antigen expression by muscle cells is sufficient to stimulate a Th1 immune response.     

Pulmonary delivery of an inulin-stabilized influenza subunit vaccine prepared by spray-freeze drying induces systemic, mucosal humoral as well as cell-mediated immune responses in BALB/c mice

In this study pulmonary vaccination with a new influenza subunit vaccine powder was evaluated. Vaccine powder was produced by spray-freeze drying (SFD) using the oligosaccharide inulin as stabilizer. Immune responses after pulmonary vaccination of BALB/c mice with vaccine powder were determined and compared to those induced by intramuscular and pulmonary vaccination with a conventional liquid subunit vaccine. All vaccinations were performed without adjuvant. Pulmonary vaccination with liquid subunit vaccine resulted in systemic humoral (IgG) immune responses similar to intramuscular immunization. In contrast, the vaccine powder delivered by the pulmonary route, induced not only systemic humoral (IgG) responses, but also cell-mediated (Il-4, IFN-γ) and mucosal immune responses (IgA, IgG). This study demonstrates that the combination of pulmonary antigen delivery and antigen powder production by SFD improves the immunogenic potential of (influenza subunit) antigen. In conclusion, vaccination with a non-adjuvanted SFD subunit vaccine powder by inhalation might be feasible and could be an alternative to conventional parenteral vaccine administration.