Search Results (150)

Background: Fowl typhoid (FT), a septicemic infection caused by Salmonella Gallinarum (SG), and H9N2 avian influenza are two economically important diseases that significantly affect the global poultry industry. Methods: We exploited the live attenuated Salmonella Gallinarum (SG) mutant JOL3062 (SG: ∆lon ∆pagL ∆asd) as a delivery system for H9N2 antigens to induce an immunoprotective response against both H9N2 and FT. To enhance immune protection against H9N2, a prokaryotic and eukaryotic dual expression plasmid, pJHL270, was employed. The hemagglutinin (HA) consensus sequence from South Korean avian influenza A virus (AIV) was cloned under the Ptrc promoter for prokaryotic expression, and the B cell epitope of neuraminidase (NA) linked with matrix protein 2 (M2e) was placed for eukaryotic expression. In vitro and in vivo expressions of the H9N2 antigens were validated by qRT-PCR and Western blot, respectively. Results: Oral immunization with JOL3121 induced a significant increase in SG and H9N2-specific serum IgY and cloacal swab IgA antibodies, confirming humoral and mucosal immune responses. Furthermore, FACS analysis showed increased CD4+ and CD8+ T cell populations. On day 28 post-immunization, there was a substantial rise in the hemagglutination inhibition titer in the immunized birds, demonstrating neutralization capabilities of immunization. Both IFN-γ and IL-4 demonstrated a significant increase, indicating a balance of Th1 and Th2 responses. Intranasal challenge with the H9N2 Y280 strain resulted in minimal to no clinical signs with significantly lower lung viral titer in the JOL3121 group. Upon SG wildtype challenge, the immunized birds in the JOL3121 group yielded 20% mortality, while 80% mortality was recorded in the PBS control group. Additionally, bacterial load in the spleen and liver was significantly lower in the immunized birds. Conclusions: The current vaccine model, designed with a host-specific pathogen, SG, delivers a robust immune boost that could enhance dual protection against FT and H9N2 infection, both being significant diseases in poultry, as well as ensure public health. Full article

A novel bivalent oral vaccine candidate against H5N1 and H9N2 avian influenza virus (AIV) was developed using Lactobacillus surface display technology without genetic modification. The hemagglutinin subunit 1 (HA1) antigens from both subtypes were fused to the surface layer-binding domain of Lactobacillus crispatus K313, expressed in Escherichia coli, and purified. Wild-type Lactobacillus johnsonii H31, isolated from chicken intestine, served as a delivery vehicle by adsorbing and stably displaying the HA1 proteins on its surface. This approach eliminates the need for bacterial engineering while utilizing lactobacilli’s natural capacity to protect surface-displayed antigens, as evidenced by HA1’s protease resistance. Mouse immunization studies demonstrated induction of strong systemic IgG and mucosal IgA responses against both H5N1 and H9N2 HA1. The system offers several advantages, including safety through non-GMO probiotics, potential for multivalent vaccine expansion, and intrinsic antigen protection by lactobacilli. These findings suggest this platform could enable development of cost-effective, multivalent AIV vaccines. Full article

Mucosal immunization represents a promising strategy for preventing enteric infections. Rotavirus (RV), a leading gastrointestinal pathogen distinguished by its remarkable stability and segmented double-stranded RNA genome, has been engineered into a versatile oral vaccine vector through advanced reverse genetics systems. The clinical efficacy of live-attenuated RV vaccines highlights their unique capacity to concurrently induce mucosal IgA responses and systemic neutralizing antibodies, positioning them as a multiple action vector for multiple immune protection. In this review, we summarize the RV colonization of the intestine and stimulation of intestinal immunity, as well as recent advancements in RV reverse genetics, and focus on their application in the rational design of a multivalent mucosal vaccine vector targeting enteric pathogens considering the advantages and challenges of RV as a vector. We further propose molecular strategies to overcome genetic instability in recombinant RV vectors, including the codon optimization of heterologous inserts. These insights provide a theoretical foundation for developing next-generation mucosal immunization platforms with enhanced safety, stability, and cross-protective efficacy. Full article

Helicobacter pylori (H. pylori) is one of the most prevalent chronic bacterial infections globally, significantly contributing to gastritis, peptic ulcers, and gastric malignancies. Its pathogenesis involves a complex array of virulence factors—including cagA, vacA, and urease—which facilitate mucosal colonization, immune evasion, and persistent inflammation. A major challenge in vaccine development is the bacterium’s ability to manipulate both innate and adaptive immune responses, resulting in limited natural clearance and long-term persistence. This review synthesizes H. pylori pathogenesis and host immune dynamics, highlighting their implications for vaccine design. By elucidating the molecular and cellular mechanisms underlying host–pathogen interactions, we explore how these insights inform antigen selection, adjuvant optimization, and delivery strategies. By integrating basic science with translational objectives, this review aims to support the development of an effective H. pylori vaccine, addressing global health needs, particularly in regions with a high infection burden and limited access to treatment. Full article

Background:Salmonella Typhimurium is a major zoonotic pathogen, in which type 1 fimbriae play a crucial role in intestinal colonization and immune modulation. This study aimed to improve the protective immunity of a previously developed growth-deficient strain—a double auxotroph for D-glutamate and D-alanine—by engineering the inducible expression of type 1 fimbriae. Methods: P_tetA-driven expression of the fim operon was achieved by λ-Red mutagenesis. fimA expression was quantified by qRT-PCR, and fimbriation visualized by transmission electron microscopy. Adhesive properties were evaluated through FimH sequence analysis, yeast agglutination, mannose-binding/inhibition assays, and HT-29 cell adherence. BALB/c mice were immunized orogastrically with IRTA ΔΔΔ or IRTA ΔΔΔ P_tetA::fim. Safety and immunogenicity were assessed by clinical monitoring, bacterial load, fecal shedding, ELISA tests, and adhesion/blocking assays using fecal extracts. Protection was evaluated after challenging with wild-type and heterologous strains. Results: IRTA ΔΔΔ P_tetA::fim showed robust fimA expression, dense fimbrial coverage, a marked mannose-sensitive adhesive phenotype and enhanced HT-29 attachment. Fimbrial overexpression did not alter intestinal colonization or translocation to mesenteric lymph nodes (mLNs). Immunization elicited a mixed IgG1/IgG2a, significantly increased IgA and IgG against type 1 fimbriae-expressing Salmonella, and enhanced the ability of fecal extracts to inhibit the adherence of wild-type strains. Upon challenge (IRTA wild-type/20220258), IRTA ΔΔΔ P_tetA::fim reduced infection burden in the cecum (−1.46/1.47-log), large intestine (−1.35/2.17-log), mLNs (−1.32/0.98-log) and systemic organs more effectively than IRTA ΔΔΔ. Conclusions: Inducible expression of type 1 fimbriae enhances mucosal immunity and protection, supporting their inclusion in next-generation Salmonella vaccines. Future work should assess cross-protection and optimize FimH-mediated targeting for mucosal delivery. Full article

This review examines the potential and challenges of using hydrogel vaccine delivery systems in animal immunization. Traditional methods face issues like low immunogenicity, reliance on cold chains, and inefficient delivery, limiting their use in modern animal husbandry. Hydrogels offer a promising solution due to their biocompatibility, controlled drug release, and immune regulation. This paper highlights hydrogels’ benefits, such as mimicking natural infection through sustained antigen release, boosting antigen-presenting cell activity, activating immune responses, and forming barriers at mucosal sites to prevent pathogen invasion. Additionally, innovative delivery methods like microneedle patches and nasal sprays show promise in enhancing convenience and compliance in animal vaccination. By combining interdisciplinary efforts and technological advancements, the hydrogel vaccine delivery system is anticipated to be crucial in preventing animal diseases, supporting sustainable animal husbandry, and ensuring global animal health and food safety. Full article

Background: Self-administered orally dissolving films (ODFs) encapsulating inactivated influenza vaccines represent an effective strategy for stimulating mucosal immunity. While this vaccination method offers several advantages over conventional influenza vaccines, a comparative efficacy study remains lacking. Methods: Female BALB/c mice were immunized with inactivated A/PR/8/34 (H1N1) either via orogastric inoculation or through the oral mucosal delivery using pullulan and trehalose-based ODF vaccines. Each group received equivalent antigen doses across three immunizations. Humoral responses and antibody functionality were assessed using sera collected post-immunization. After lethal viral challenge, other immunological and virological parameters were determined in corresponding tissues. Body weight and survival were monitored over a 14-day period after challenge. Results: ODF vaccination elicited significantly higher virus-specific IgA levels, HAI titers, and neutralizing antibody activity than oral gavage. After the viral challenge, ODF-immunized mice exhibited stronger IgG and IgA responses in respiratory tissues, increased antibody-secreting cells in lungs and spleen, and elevated germinal center B cells and CD8⁺ T cell responses. Both vaccination methods reduced lung pro-inflammatory cytokines and provided full protection against lethal challenge; however, the ODF group showed lower cytokine levels, better weight maintenance, and reduced viral loads. Conclusions: ODF vaccination elicits more robust systemic and mucosal immune responses than oral vaccination and may serve as a promising alternative method of influenza vaccine delivery. Full article

The rapid expansion of aquaculture is vital for global food security, yet it faces persistent threats from disease outbreaks, vaccine inefficacy, and antibiotic overuse, all of which undermine sustainability. Conventional vaccines often fail to induce robust mucosal immunity, spurring interest in probiotics as adjuvants to enhance immunogenicity. Probiotics such as Bacillus subtilis and Lactobacillus casei modulate fish microbiomes, fortify mucosal barriers, and activate innate immune responses via mechanisms including Toll-like receptor signaling and cytokine production. These actions prime the host environment for prolonged adaptive immunity, improving antigen uptake and pathogen clearance. Experimental advances—such as Bacillus subtilis-engineered spores increasing survival rates to 86% in Vibrio anguillarum-challenged European seabass—demonstrate the potential of this synergy. Innovations in delivery systems, including chitosan–alginate microcapsules and synbiotic formulations, further address oral vaccine degradation, enhancing practicality. Probiotics also suppress pathogens while enriching beneficial gut taxa, amplifying mucosal IgA and systemic IgM responses. However, challenges such as strain-specific variability, environmental dependencies, and unresolved ecological risks persist. Optimizing host-specific probiotics and advancing multi-omics research is critical to unlocking this synergy fully. Integrating probiotic mechanisms with vaccine design offers a pathway toward antibiotic-free aquaculture, aligning with One Health principles. Realizing this vision demands interdisciplinary collaboration to standardize protocols, validate field efficacy, and align policies with ecological sustainability. Probiotic–vaccine strategies represent not merely a scientific advance but an essential evolution for resilient, ecologically balanced aquaculture systems. Full article

Background: Brucellosis poses a significant public health challenge, necessitating effective vaccine development. Current vaccines have limitations such as safety concerns and inadequate mucosal immunity. This study aims to develop an FcRn-targeted mucosal Brucella vaccine by fusing the human Fc domain with Brucella’s multi-epitope protein (MEV), proposing a novel approach for human brucellosis prevention. Methods: The study developed a recombinant antigen (h-tFc-MEV) through computational analyses to validate antigenicity, structural stability, solubility, and allergenic potential. Molecular simulations confirmed FcRn binding. The vaccine was delivered orally via chitosan nanoparticles in murine models. Immunization was compared to MEV-only immunization. Post-challenge assessments were conducted to evaluate protection against Brucella colonization. Mechanistic studies investigated dendritic cell activation and antigen presentation. Results: Computational analyses showed that the antigen had favorable properties without allergenic potential. Molecular simulations demonstrated robust FcRn binding. In murine models, oral delivery elicited enhanced systemic immunity with elevated serum IgG titers and amplified CD4+/CD8+ T-cell ratios compared to MEV-only immunization. Mucosal immunity was evidenced by significant IgA upregulation across multiple tracts. Long-term immune memory persisted for six months. Post-challenge assessments revealed markedly reduced Brucella colonization in visceral organs. Mechanistic studies identified FcRn-mediated dendritic cell activation through enhanced MHC-II expression and antigen presentation efficiency. Conclusions: The FcRn-targeted strategy establishes concurrent mucosal and systemic protective immunity against Brucella infection. This novel vaccine candidate shows potential for effective human brucellosis prevention, offering a promising approach to address the limitations of current vaccines. Full article

Background: Enteric disease caused by Shigella, Campylobacter, and enterotoxigenic Escherichia coli (ETEC) represents a significant global health burden, particularly among children in low-resource settings. However, no licensed vaccines are currently available for these bacterial pathogens. Given the wide range of enteric pathogens and the constraints posed by an increasingly crowded infant immunization schedule, the development of combination vaccines or combined administration of individual oral vaccines may offer a practical approach to address this unmet need. Objectives: In this study, we evaluated the combined administration of two multicomponent oral vaccine candidates: ETVAX, targeting ETEC, and a trivalent whole-cell vaccine targeting Shigella. Methods: The vaccine candidates were administered orally in mice, both individually and in combination, with and without the inclusion of the double-mutant heat-labile toxin (dmLT) adjuvant. Results: The results demonstrated systemic and intestinal-mucosal immune responses to the key protective antigens following both individual and combined vaccine administration. Importantly, the combination of the two vaccines did not compromise the elicitation of specific antibody responses. The inclusion of dmLT as an adjuvant significantly enhanced immune responses to several antigens, highlighting its potential to improve vaccine efficacy. Conclusions: These findings underscore the feasibility of combining ETEC and Shigella vaccine candidates into a single formulation without compromising immunogenicity. This combined approach has the potential to provide broad protective coverage, thereby mitigating the global impact of enteric diseases and streamlining vaccine delivery within existing childhood immunization programs. Our results support further development of this combination vaccine strategy as a promising tool in combating enteric infections and improving health outcomes, particularly among young children in endemic regions who are vulnerable to enteric disease. Full article

The oral delivery of DNA/RNA nanoparticles represents a transformative approach in immunotherapy and vaccine development. These nanoparticles enable targeted immune modulation by delivering genetic material to specific cells in the gut-associated immune system, triggering both mucosal and systemic immune responses. Unlike parenteral administration, the oral route offers a unique immunological environment that supports both tolerance and activation, depending on the formulation design. This review explores the underlying mechanisms of immune modulation by DNA/RNA nanoparticles, their design and delivery strategies, and recent advances in their application. Emphasis is placed on strategies to overcome physiological barriers such as acidic pH, enzymatic degradation, mucus entrapment, and epithelial tight junctions. Special attention is given to the role of gut-associated lymphoid tissue in mediating immune responses and the therapeutic potential of these systems in oral vaccine platforms, food allergies, autoimmune diseases, and chronic inflammation. Despite challenges, recent advances in nanoparticle formulation support the translation of these technologies into clinical applications for both therapeutic immunomodulation and vaccination. Full article

Background/Objectives: Mucosal vaccines are rare but commercially desirable because of their real and theoretical biological advantages. Spores and vegetative forms from Bacillus have been used as probiotics due to their stability under various environmental conditions, including heat, gastric acidity, and moisture. Preclinical studies have shown that Bacillus subtilis (B. subtilis) spores can serve as effective mucosal adjuvants. Our study aimed to evaluate B. subtilis spores as a mucosal adjuvant. Methods and Results: We demonstrate in rodents that the fusion protein (F) from respiratory syncytial virus (RSV), when combined with either heat-inactivated or live B. subtilis spores, elicits robust IgG binding and neutralizes antibody titers following both systemic and intranasal administration in mice. The spores facilitate TH-1 and local IgA responses, which could enhance antiviral protection. However, this vaccine failed to elicit measurable antibodies when immunized using a strict intranasal administration method in cotton rats. Conclusions: Our findings illustrate the differing immune responses between the two rodent species, highlighting the need for the careful consideration of validated methods when evaluating intranasal vaccines in preclinical studies. Full article

Background: Tuberculosis (TB) is a respiratory infectious disease, and the current TB vaccine has low local lung protection. We aim to optimize immune pathways to improve the immunogenicity of vaccines. Methods: In the immunogenicity study, 50 BALB/c mice were randomly divided into the following: (1) phosphate buffered saline (PBS)+intramuscular injection combined with electroporation (EP) group (100 μL), (2) pVAX1+EP group (50 μg/100 μL), (3) ag85ab+EP group (50 μg/100 μL), (4) pVAX1+pulmonary delivery (PD) group (50 μg/50 μL), and (5) ag85ab+PD group (50 μg/50 μL). Immunization was given once every 2 weeks for a total of three times. The number of IFN-γ-secreting lung and spleen lymphocytes was determined by enzyme-linked immunospot assay (ELISPOT). The levels of Th1, Th2, and Th17 cytokines in the culture supernatants of lung and spleen lymphocytes were detected with the Luminex method. The proportion of FoxP3 regulatory T cells in splenocytes was determined by flow cytometry. The levels of IgG-, IgG1-, and IgG2a-specific antibodies in plasma and IgA antibody in bronchoalveolar lavage fluid (BALF) were determined by enzyme-linked immunosorbent assay (ELISA). Results: The PD and EP routes of Mycobacterium tuberculosis (M. tb) ag85ab DNA vaccine can effectively induce the responses of IFN-γ-secreting lung and spleen lymphocytes, and induce dominant Th1 and Th17 cell immune responses. The PD route can induce earlier, greater numbers and stronger responses of pulmonary effector T cells, with higher levels of the specific antibody IgA detected in BALF. High levels of the specific antibodies IgG, IgG1, and IgG2α were detected in the plasma of mice immunized by the EP route. Conclusions: The PD route of DNA vaccines can more effectively stimulate the body to produce strong cellular and mucosal immunity than the EP route, especially local cellular immunity in the lungs, which can provide early protection for the lungs. It can significantly improve the immunogenicity of the ag85ab DNA vaccine, suggesting a feasible and effective approach to DNA immunization. Full article

Background/Objectives: Human parainfluenza virus type 1 (hPIV-1) is a major cause of serious respiratory diseases in young children. Annually, hPIV-1 results in approximately 10,000 hospitalizations in the United States due to croup, bronchiolitis, and/or pneumonia, and 10,000 deaths worldwide due to acute lower respiratory tract infections among children less than 5 years of age. Despite the burden of disease, no vaccine for hPIV-1 is currently approved. Sendai virus (SeV) is a murine PIV-1. It has structural similarities with hPIV-1 and is currently under clinical development as an hPIV-1 Jennerian vaccine. Attributes of SeV include the following: (a) needleless delivery, (b) rapid and durable serum antibody responses after a single intranasal administration, (c) durable IgG and IgA responses in the nasal mucosa, and (d) use as a platform for recombinant vaccines against multiple pediatric pathogens. Evaluation of the tolerability, safety, and immunogenicity of intranasal SeV in healthy adults and seropositive children 3 to 6 years of age was previously conducted and supported vaccine advancement to evaluation in younger children. Methods: Three seropositive children 1 to 2 years of age received a single intranasal dose of 5 × 10⁵ EID₅₀ SeV (SENDAI, Clinicaltrials.gov NCT00186927). Adverse events were collected for 28 days post-vaccine administration using diary cards and participants were followed for six months in total. Sera were collected longitudinally for clinical laboratory and virus-specific antibody tests. Nasal swabs were collected longitudinally for virus and mucosal antibody tests. Results: Intranasal SeV was well tolerated, with only mild grade 1–2 events that resolved spontaneously. No serious adverse events, medically attended adverse events, or adverse events causing protocol termination were reported. One participant had positive nasal swabs for inoculated SeV during the first week after vaccination. Although children had measurable PIV-1-specific serum antibodies at baseline, intranasal SeV vaccination resulted in significant serum antibody increases in all participants. Similarly, there were significant increases in PIV-1-specific nasal IgG and IgA levels in all participants. Elevated antibody levels persisted through the six months of follow-up. Conclusions: Intranasal SeV was well tolerated and uniformly immunogenic in seropositive children 1 to 2 years of age. Results encourage the further evaluation of SeV and SeV-based recombinants as potential intranasal vaccines for the prevention of infection by hPIV-1 and other serious respiratory pathogens. Full article

Oral vaccines are currently the focus of vaccine development because they are convenient to administer, easy to distribute, and capable of activating mucosal immunity. However, the complexity of the gastrointestinal environment and the lack of delivery vehicles severely limit the stability and effectiveness of oral vaccines. This study established a novel platform for developing oral vaccines based on the surface display system of yeast spores. As a specific example, oral vaccines for COVID-19, designed by displaying the receptor-binding domain (RBD) of the SARS-CoV-2 spike protein on the surface of three Saccharomyces cerevisiae spore types, including AN120, osw2Δ, and dit1Δ, were constructed and evaluated. The displayed RBD showed perfect gastrointestinal stability in vitro and was validated in animal studies to produce effective humoral immunity and significant mucosal immune responses after the vaccination. Notably, the displayed RBD elicited a cellular immune response skewed towards a T-helper type 1 (Th1) cell direction in a mouse model. Our findings proved that the oral vaccines of S. cerevisiae spores could rapidly induce a comprehensive and protective immune response to SARS-CoV-2. This study aims to provide a promising and potentially useful system that can be used to develop other oral vaccines. Full article