The virulence factors cagA and vacA of H. pylori are crucial for cytotoxin production (62). These genes are part of the type IV secretion system (T4SS), which is vital for bacterial pathogenicity (63). T4SSs are complex structures that penetrate bacterial cell walls, aiding survival and protein or DNA translocation (64). Approximately 60–70% of H. pylori strains express the cagA protein, which produces a specific cytotoxin (65). Phosphorylation of tyrosine motifs in cagA allows its translocation into gastric epithelial cells via T4SSs. Research by Yamaoka et al. (61), Selbach et al. (66), and Stein et al. (67) indicates that variations in these motifs are linked to gastric degeneration and increased gastric cancer risk. Phosphorylated cagA triggers pathological responses in host cells, enhancing motility, actin polymerization, and cell stretching and disrupting physiological signals (68). cagA influences Th17 cell differentiation by interacting with the STAT3 protein, which is crucial for T and B lymphocyte development. It also interacts with NF-κB, a key regulator of innate immune responses (69). cagA activates Th1 and Th17 cells to eliminate H. pylori and promotes proinflammatory cytokine expression in gastric epithelial cells (70). H. pylori strains with cagA enhance IL-8 secretion (71). The high immunogenicity of cagA is linked to increased gastric inflammation (72), which negatively affects H. pylori survival (73). Furthermore, cagA promotes a Th1-polarized immune response that aids infection clearance (74). This dual role indicates that H. pylori must regulate cagA expression during gastric colonization. The cagA gene is vital for vaccine development beyond its pathogenic properties. Paydarnia et al. (75) studied the effects of mixed immunization with H. pylori LPS and recombinant cagA on immune responses in a murine model. The recombinant cagA protein, given with a cytosine phosphoguanine adjuvant, maintained its antigenic properties and triggered strong Th1-biased immune responses throughout the experiment. These findings suggest that cagA may be key to an effective vaccine for H. pylori infection.

Most H. pylori isolates contain the vacA gene, which targets epithelial and immune cells in the digestive tract (76, 77). Like the cagA gene, vacA is unique to type I H. pylori. The vacA protein not only facilitates intracellular vacuole formation but also has toxic effects on various cells (78, 79) and survives the acidity of the stomach via multiple exit routes (79). Although the exact mechanisms by which vacA induces autophagy are not fully understood, it has been shown that the autophagy triggered by vacA is dependent on its interaction with low-density lipoprotein receptor-related protein 1 (80). The vacA protein affects apoptotic signaling in host cells, limiting apoptosis. Its influence can be proapoptotic or antiapoptotic, depending on the cell type and environment. The vacA toxin also alters host cell morphology and function by inducing vacuole formation (78). Additionally, toxins hinder T cells and other immune cells, impacting the overall immune response (81, 82). In most H. pylori-infected patients, anti-vacA antibodies are found in their blood and gastric juice (83). The growth of CD4⁺ lymphocytes from the gastric epithelium is antigen dependent when vacA is present (84, 85). While vacA-induced T and B-cell responses are detectable, they do not eliminate H. pylori infection. However, these immune responses indicate that vacA is immunogenic in humans and may be a candidate for vaccines. Therefore, the vacA gene also plays a role as a protective factor against H. pylori infection (86). Moyat and Velin (85) reported that a vacA-based vaccine showed significant protective effects on infected mice that received therapeutic intragastric immunization with a nontoxic recombinant version of vacA and the LT mutant LTK63. For the majority of vaccinated individuals, it effectively eliminates H. pylori infection and reduces the risk of reinfection (87). Preventive vaccination in animal models has also shown promise, with recombinant vacA and mucosal adjuvants providing protection (88).

The interaction between the cagA and vacA proteins significantly contributes to H. pylori-associated gastric cancer. Abdullah et al. (89) reported that the absence of vacA allows the host immune system to degrade cagA, preventing its accumulation in gastric epithelial cells. H. pylori infection increases the risk of gastric cancer, posing a major public health challenge. There is a strong link between cancer progression and the growth of other gastric malignancies, driven by inflammation, genotoxic factors, and genomic instability (90). This relationship is influenced by host genetics, environmental conditions, and H. pylori virulence genes such as oipA, vacA, and cagA (62). Understanding these pathways is crucial for developing effective treatments and preventing future infections. Recent advancements are improving our knowledge of H. pylori-related diseases and aiding the development of innovative therapies, including potential vaccines.

In all strains of H. pylori, a 150 kDa multimeric protein, referred to as neutrophil-activating protein (HP-NAP), has been identified (5, 91, 92). Research indicates that HP-NAP enhances the penetration and generation of oxygen radicals and the adhesion of neutrophils and monocytes to gastric endothelial cells while also increasing their motility (93). This activity contributes to long-term inflammatory conditions in the gastrointestinal epithelium. HP-NAP activation leads to increased interleukin-12 (IL-12) production, triggering a T helper 1 (Th1) immune response (94). Immunodominant antigens associated with the H. pylori G27 strain were identified through two-dimensional gel electrophoresis in a patient suffering from various gastric diseases, with this protein being significantly recognized in the serum of infected individuals (95). Furthermore, animals immunized with HP-NAP have demonstrated immunity against subsequent infections, indicating that this virulent gene may serve as a promising candidate for vaccine development. Owing to its high antigenicity, HP-NAP is frequently incorporated into vaccines aimed at preventing H. pylori infection (94). In addition to its application in vaccines, HP-NAP may also hold potential as an immunotherapeutic agent in cancer treatment, as its immunomodulatory properties enable dendritic cells to promote Th1 responses and enhance the immune responses of recipients (94).

OMPs of H. pylori are essential for physiological processes, assisting in material transport and host interactions (96, 97). They are promising targets for vaccines and medications (9, 98, 99). H. pylori has diverse OMPs, such as lipoproteins, porins, and adhesins, which are vital for survival and pathogenicity (27). OMP expression varies among strains, contributing to pathogenicity through adherence, invasion, and immune evasion (26, 96). Genome sequencing revealed that approximately 4% of H. pylori genetic material encodes OMPs, which are categorized into five gene families: Hop, Hor, Hom, Hof, and iron-regulated proteins (27, 100, 101). This section summarizes recent advancements in understanding well-characterized OMPs.

H. pylori urease (ure), comprising 10 to 15% of a bacterium’s total protein, consists of 12 heterodimers formed by the ureA and ureB enzymes (135). This catalytic enzyme hydrolyzes urea into carbon dioxide and ammonia, which neutralizes excess stomach acid, inhibits neutrophil activity (136–138), promotes the production of toxic ammonia-derived compounds (139), and disrupts stomach epithelial cell interactions (140), fostering bacterial colonization. The peroxynitrite anion can harm bacteria, but carbon dioxide mitigates this effect, aiding colonization (93, 141). The unique surface structure of the urease complex allows H. pylori to interact with host immune elements, ensuring its indefinite colonization. Inhibiting urease function prevents H. pylori from thriving, providing therapeutic and preventive strategies against infection (135). In numerous studies, urease has been identified as a potential antigen candidate for vaccine production. In a laboratory model of H. pylori infection, Nasr-Esfahani et al. (142) demonstrated that the recombinant plasmid pcDNA3.1 (+)-ureA could induce an immune response in murine models. Furthermore, the vaccination of mice with a recombinant ureB vaccine, which incorporates plant polysaccharides as adjuvants, was found to confer immunity against H. pylori infection. This protective effect may be attributed to the enhancement of Th1/Th17 CD4⁺ T-cell activation and the promotion of gastrointestinal-specific secretory immunoglobulin A (143). Most vaccines that have advanced to the clinical trial phase include the urease antigen (37, 135, 144–146).

Catalase is a key enzyme that protects bacteria from hydrogen peroxide. In H. pylori, this tetrameric protein makes up approximately 1% of the total protein and has an isoelectric point of 9.0–9.3 (135, 147). It shields H. pylori from host-produced reactive oxygen species and helps bacteria evade macrophages (148, 149). Its role in various pathological processes contributes to inflammation, apoptosis, and tumor formation, with mutagenesis occurring in the cytoplasm, periplasm, and occasionally on the surface (150). H. pylori catalase is one of its most highly expressed proteins and shows greater resistance to cyanide and amino triazole suppression than do catalases from other bacteria (124). Recent studies have provided detailed characterizations of immunodominant Th1 epitopes associated with catalase (151). Through the production of IFN-γ, seven novel catalase epitopes have been identified as potent inducers of a robust Th1 immune response (152). The LHUC vaccine is a multivalent epitope vaccine that incorporates the adjuvant heat-labile enterotoxin B subunit, along with five B-cell epitopes and three Th-cell epitopes (HpaA, ureB, and catalase), designed to create an effective multivalent epitope vaccine against H. pylori (135). Following the administration of the LHUC vaccine to mice, serum analysis revealed the presence of antibodies specific to the antigen, accompanied by a significant increase in the production of IFN-γ, IL-4, and IL-17 by lymphocytes. Studies have demonstrated that LHUC is highly effective in preventing H. pylori infections in murine models (153).

Inactivated whole-cell vaccines for H. pylori are created by disrupting the bacteria with ultrasonic waves and inactivating them with formalin (29). These vaccines reduce H. pylori proliferation and elicit strong immune responses in the gastric mucosa. Kotloff et al. (154) suggested that the administration of an oral H. pylori whole-cell vaccine can effectively stimulate both mucosal and systemic immune responses in humans. Murine experiments performed with whole-cell vaccines demonstrated that these vaccines can elicit a dose-dependent response, including the production of cross-reactive IgG, against H. pylori. The high-dose Hp 26695 whole-cell vaccine group presented reduced bacterial colonization in challenge experiments with SS1 (155). Oral vaccination is preferred for its ease of use and high adherence rates (156–159). However, it requires higher antigen dosages than intramuscular injections do, which may cause immunological tolerance. Researchers often use lower antigen doses with mucosal adjuvants to improve efficacy (160, 161), especially against H. pylori (29).

Aluminum adjuvants are essential in vaccine formulations, enhancing systemic immunity and promoting a Th2-type response (162, 163). Cholera toxin is a potent mucosal adjuvant (164) that activates a Th2 response (165) but poses toxicity risks (35). Cholera toxin B is a safer alternative (157, 166). Oral immunization with cholera toxin and bacterial antigens increased antibody levels in a germ-free mouse model of H. felis infection (167), and Lee et al. (168) reported that this combination was more effective than the H. felis antigen or adjuvant alone. Holmgren’s et al. (164) developed a novel adjuvant with mutant cholera toxins for H. pylori infections. A formalin-inactivated whole-cell Helicobacter vaccine increased serum IgG, mucosal IgA, IFN-γ, and IL-17 levels while reducing H. pylori colonization (169, 170). Improving vaccine delivery methods is vital for effective mucosal vaccination (171). Techniques such as liposomes, viral vectors, and attenuated bacterial vectors offer unique benefits. However, no commercially available vaccine exists for inactivated whole-cell H. pylori, and enhancing the immune response while ensuring safe delivery is challenging.

Antigenic subunit vaccines use purified pathogen components to trigger a strong immune response (172). They contain only antigenic elements, enhancing safety by removing live components (173). These vaccines are suitable for individuals with compromised immune systems (174) and have a complex manufacturing process that often requires booster doses, adjuvants, and significant time to determine optimal antigen combinations (175). The development of a subunit vaccine for H. pylori is particularly challenging and costly (29). Genetic engineering improves the purification and large-scale production of specific antigens, enhancing vaccine efficacy (176, 177). Key antigens for an H. pylori vaccine include urease, catalase, cagA, babA, vacA, and fliD (110, 178, 179). Urease was one of the first antigens recognized as beneficial for vaccine development (145, 180). Urease subunits A and B (ureA and ureB) are vital for colonization and are therapeutic targets (110, 181). While ureB is well studied as a vaccine candidate (145, 182, 183), research on ureA is limited. ureA activates urease via interactions with HSP60, which is crucial for protein balance (184). Murine studies suggest that ureA-specific CD4⁺ T cells provide protective immunity (185), and oral immunization with Bacillus subtilis spores expressing ureA has shown protective effects in trials (186).

Michetti et al. (180) demonstrated that an oral H. pylori urease vaccine, along with Escherichia coli heat-labile enterotoxin as an adjuvant, elevated anti-urease serum immunoglobulin A titers in twenty-six H. pylori-infected participants. Zhong et al. (187) developed a recombinant fusion protein, ureA-ureB-NAP, as a preventive vaccine, showing improved protection in mice compared with a bacterial lysate vaccine. Skakic et al. (179) examined protein nanocapsules with the A subunit of H. pylori-ureA and reported that TiterMax with SC/MS nanocapsules significantly reduced gastric H. pylori infections in murine models, indicating effective immune response stimulation. The role of H. pylori oipA in promoting the proinflammatory cytokine IL-8 and its effect on inflammation has been studied (188). While oipA is vital for host protection against H. pylori (134), selecting an effective adjuvant is crucial for a strong immune response. Many vaccines still use oil emulsions or aluminum salts, but research into alternatives continues due to the adverse effects of oil-based adjuvants (189). Natural adjuvants such as propolis have shown promise in animal models (190) and may enhance vaccination strategies. A 2021 study revealed that propolis combined with recombinant oipA increased IFN-γ production and strengthened the immune response (133).

The H. pylori-NAP gene is a key virulence factor and a potential target for gastrointestinal disorder treatments (5, 191). Its immunological properties also suggest potential for cancer treatment and H. pylori infections (94). Guo et al. (192) studied multivalent epitope-based vaccines in Mongolian gerbils in 2017 and 2019 (193). The first vaccine combines H. pylori-NAP with various antigens, while the second includes epitopes from cagA, vacA, and urease, both of which effectively reduce bacterial colonization and gastritis. Liu et al. (194) developed a multivalent vaccine with H. pylori-NAP, a mucosal adjuvant, and ureA and ureB, which stimulate mucosal IgA and specific humoral immune responses. Chen et al. (195) reported that cyclic guanosine monophosphate-adenosine monophosphate provided protection against H. pylori at lower dosages via intranasal immunization. The immunogenic properties of H. pylori-NAP are promising for vaccine development (94), but mixed results indicate that more research is needed to understand H. pylori evasion of host antibody responses.

cagA is a potential antigen that triggers immune responses in clinical trials (196, 197). Like other H. pylori proteins, such as ureA, babA, sabA, and oipA, cagA is an effective vaccine antigen that inhibits H. pylori proliferation when combined with suitable adjuvants (198, 199). In animal models, vaccination with recombinant antigens such as cagA, vacA, and NAP has shown protective effects, enhancing T-cell memory and cell-mediated immune responses. A study of healthy volunteers vaccinated with a cagA-positive strain revealed limited protection after exposure (197). Paydarnia et al. (75) revealed that recombinant cagA and H. pylori LPS stimulate host immunity in murine models. The recombinant cagA protein with the CpG adjuvant maintained its antigenicity and induced strong Th1-biased immune responses. Other antigens, such as HpaA, FlaA, SOD, and Hsp, may also enhance the immune response to H. pylori infection.

Researchers are exploring ways to increase DNA vaccine efficacy through adjuvants, cytokines, chemokines, CpG incorporation, and electroporation (200). Nonmethylated CpG motifs in plasmid backbones increase vaccination success by stimulating immune responses in B cells and natural killer cells (201). The protective antigen of H. pylori is encoded by cDNA in an expression vector that is absorbed by host cells, activating the immune response (29). Kumari et al. (202) stated that the absence of cagW disrupts pilus formation, preventing cagA from entering the bacterial membrane. babA is crucial for H. pylori adherence to gastric epithelial cells and may worsen gastritis by promoting cagA translation (107), making it a promising vaccination target (29, 203, 204). Xue et al. (205) developed plasmid vaccines targeting cagA, vacA, and babA in albino mice, which showed potential anticancer properties for gastric cancer immunotherapy. Figure 3 presents recent advancements in H. pylori DNA vaccines, including cagW, cagA-vacA-babA (205), and flaA (206). However, challenges such as degradation by deoxyribonucleases, delivery issues, and limited immune responses in some primates hinder DNA vaccine efficacy. Future advancements are expected to improve clinical trial prospects for these vaccines.

Both viruses and bacteria can harm human health. Modifying virulence-associated genes while preserving infectious properties at the mucosal barrier is one strategy to reduce pathogen effects. H. pylori-derived immunogens can stimulate an immune response when delivered to antigen-presenting cells. Vector-based vaccines can mimic natural infections and sustain immune activation, making live vectors a promising alternative to mucosal adjuvants in recombinant subunit vaccines (169). This section reviews vector vaccines for preventing H. pylori infection (see Figure 4).

Intramuscular administration of a replication-defective adenovirus vector can reduce H. felis infection spread (207); however, uncertainties remain about the immune response from poliovirus replicons with the ureB component (208). Research shows that intranasal or oral Salmonella enterica serovar Typhimurium-vectored vaccines effectively prevent H. pylori colonization (209–211). This method allows for needle-free vaccination and promotes the use of recombinant antigens and DNA vaccine vectors (212, 213). While effective in animal models (214, 215), these vaccines have shown limited efficacy in humans. There is a need for Salmonella strains that produce protective antigens for comprehensive host immunization. Ghasemi et al. (216) reported that a vaccine with hpaA, H. pylori-NAP, ureA, and ureB conferred protection against H. pylori SS1 in 70% of tested mice.

Nie et al. (217) developed the intranasal influenza A virus (IAV) vector vaccine IAV-NapA, which uses two live attenuated influenza viruses to express the H. pylori NapA A subunit. The strains WSN-NapA and PR8-NapA exhibited significant attenuation and strong immunogenicity in mice, inducing robust Th1 and Th17 immune responses, as well as antigen-specific humoral and mucosal responses. The vaccine effectively reduced H. pylori colonization and inflammation, suggesting its potential as a dual-purpose vaccine for influenza and H. pylori. Lactic acid bacteria serve as effective carriers for oral vaccines (218, 219), enhancing immunization due to their durability and resistance to gastric acid (220). Furthermore, the recombinant measles virus (MV) vaccine expressing the H. pylori HspA antigen has demonstrated significant cancer efficacy and strong immunogenicity (221), making MV a promising platform for vaccine development.

Vaccines using Lactococcus lactis (L. lactis) increase mucosal immunogenicity (222), and modified strains can trigger immune responses at both the mucosal and systemic levels (223). Zhang et al. (224) studied a recombinant L. lactis LL-plSAM-WAE vaccine in BALB/c mice, which expressed the SAM-WAE antigen. This vaccine induced antibodies against H. pylori virulence factors and activated T cells, indicating strong potential for H. pylori vaccine development in clinical trials. Bacillus subtilis (B. subtilis) spores are effective vectors for mucosal vaccination (186, 225, 226). Oral or nasal administration enhances mucosal immunity, particularly Th1 responses, and increases secretory immunoglobulin A (sIgA) production (227). These spores can germinate under suitable conditions and endure extreme environments, including gastric secretions (228). Thus, animals and humans are likely exposed to low levels of Bacillus (229). In a study by Katsande et al. (186), mice were given genetically modified B. subtilis spores expressing the H. pylori antigens ureA and ureB, leading to specific mucosal responses, increased fecal sIgA levels, and increased antibody production.

Saccharomyces cerevisiae (S. cerevisiae) is a promising candidate for immune studies against various pathogens (230). Cen et al. (231) used S. cerevisiae to express recombinant ureB and vacA, creating an oral vaccine that significantly reduced H. pylori infection in mice. Attenuated Listeria monocytogenes (L. monocytogenes) is an effective vector for enhancing antibody production against H. pylori (232). It stimulates immune responses, especially from CD4⁺ and CD8⁺ T lymphocytes (233), and is widely used as a vaccine carrier in immunotherapy for tumors and infectious diseases (234). The hly gene promoter (P_hIy), encoding listeriolysin O, is often used for developing vaccine strains for foreign antigen production (235), but Ding et al. (236) reported that it is inadequate for optimal antigen expression and strong immune responses. Live attenuated bacteria must survive acidic environments such as macrophage phagosomes and the gastric cancer microenvironment (237). A key limitation is the lack of a well-characterized promoter array for regulating foreign antigen transcription in L. monocytogenes. Ma et al. (238) identified 21 potential promoters from L. monocytogenes cultured at pH 7.4 and 5.5, with seven intrinsic promoters outperforming P_help and five constitutive promoters showing high activity in the production of ureB, an antigen against H. pylori.