The optimized fusion protein HA1-2-FliCΔD2D3 promotes mixed Th1/Th2 immune responses to influenza H7N9 with low induction of systemic proinflammatory cytokines in mice

Enhanced Humoral and Cellular Immune Responses Elicited by Salmonella Flagellin-Adjuvanted SARS-CoV-2 S1 Subunit Vaccine

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), the virus that causes COVID-19, has been spreading and changing globally. Adjuvant-based vaccines can improve vaccine protection by enhancing the immune response. Bacterial flagellin is a potent adjuvant and promotes protective immune responses. Here, we successfully expressed and purified the S1 subunit of SARS-CoV-2. The adjuvanticity of flagellin (FliC) of Salmonella Typhimurium in mice was determined by combining it with the recombinant S1 subunit vaccine. FliC-adjuvanted S1 vaccine could induce significantly enhanced S1-specific Immunoglobulin G (IgG), IgG1 and IgG2a titers, SARS-CoV-2-neutralizing antibodies, and levels of Th1 type (TNF-α and IFN-γ) and Th2 type (Interleukin-5 (IL-5), IL-4, IL-10, and IL-13) cytokines in splenocytes compared with the S1 alone group. Additionally, the titers of S1-specific IgG antibodies in the FliC adjuvant group could maintain a high level for at least 2 months. These results indicated that the FliC-adjuvanted S1 subunit vaccine could trigger strong humoral and cellular immune responses, which could promote the ongoing development of COVID-19 vaccines.

Recombinant African swine fever virus p30-flagellin fusion protein promotes p30-specific humoral and cellular immune responses in mice

African swine fever (ASF) is a transmissible and deadly viral disease caused by the African swine fever virus (ASFV) that has considerably affected the global pig industry. Vaccination is considered a potentially effective method to control ASF. However, live attenuated vaccines can't protect against all circulating virus isolates. Subunit vaccines can induce both cellular and humoral immune responses, but often require the addition of adjuvants. Flagellin, a stimulator of Toll-like receptor 5 (TLR5), functions as a potent adjuvant by enhancing cellular and humoral immune responses. However, its high antigenicity may cause severe systemic inflammation. In this study, an Escherichia coli expression system was used to express ASFV p30 protein (p30) fused with Salmonella Typhimurium FliCΔD2D3 (without the D2 and D3 domains of FliC). The immunological effect of p30-FlicΔD2D3 protein in mice was evaluated. Results revealed that the ASFV p30 protein and the p30-FlicΔD2D3 fusion protein were effectively expressed by the E. coli expression system. In vitro activity analysis showed that the p30-FlicΔD2D3 fusion protein could be recognized by ASFV-positive serum, had good immunoreactivity, and remarkably promoted IL-8 secretion related to TLR5 activity in HEK293-mTLR5 cells. However, p30-FlicΔD2D3 induced significantly lower levels of inflammatory factor IL-8 than that induced by wild-type flagellin. Immunization with the p30-FlicΔD2D3 fusion protein considerably promoted cellular and humoral immune responses in mice. Therefore, the p30-FlicΔD2D3 protein retained good immune reactivity and TLR5 agonist efficacy. It also enhanced humoral and cellular immune responses in mice. This work offered valuable information that will be helpful to develop ASF subunit vaccines.

M2e nanovaccines supplemented with recombinant hemagglutinin protect chickens against heterologous HPAI H5N1 challenge

Current poultry vaccines against influenza A viruses target the globular head region of the hemagglutinin (HA1), providing limited protection against antigenically divergent strains. Experimental subunit vaccines based on the conserved ectodomain of the matrix protein 2 (M2e) induce cross-reactive antibody responses, but fail to fully prevent virus shedding after low pathogenic avian influenza (LPAI) virus challenge, and are ineffective against highly pathogenic avian influenza (HPAI) viruses. This study assessed the benefits of combining nanoparticles bearing three tandem M2e repeats (NR-3M2e nanorings or NF-3M2e nanofilaments) with an HA1 subunit vaccine in protecting chickens against a heterologous HPAI H5N1 virus challenge. Chickens vaccinated with the combined formulations developed M2e and HA1-specific antibodies, were fully protected from clinical disease and mortality, and showed no histopathological lesions or virus shedding, unlike those given only HA1, NR-3M2e, or NF-3M2e. Thus, the combined vaccine formulations provided complete cross-protection against HPAI H5N1 virus, and prevented environmental virus shedding, crucial for controlling avian influenza outbreaks.

Enhanced immunogenicity elicited by a novel DNA vaccine encoding the SARS-CoV-2 S1 protein fused to the optimized flagellin of Salmonella typhimurium in mice

IMPORTANCE

The development of safe and effective vaccines is needed to control the transmission of coronavirus disease 2019 (COVID-19). Synthetic DNA vaccines represent a promising platform in response to such outbreaks. Here, DNA vaccine candidates were developed using an optimized antibiotic-resistance gene-free asd-pVAX1 vector. An optimized flagellin (FliC) adjuvant was designed by fusion expression to increase the immunogenicity of the S1 antigen. S1 and S1-FliCΔD2D3 proteins were strongly expressed in mammalian cells. The FliCΔD2D3-adjuvanted DNA vaccine induced Th1/Th2-mixed immune responses and high titers of neutralizing antibodies. This study provides crucial information regarding the selection of a safer DNA vector and adjuvant for vaccine development. Our FliCΔD2D3-adjuvanted S1 DNA vaccine is more potent at inducing both humoral and cellular immune responses than S1 alone. This finding provides a new idea for the development of novel DNA vaccines against COVID-19 and could be further applied for the development of other vaccines.

Recombinant HA1-ΔfliC enhances adherence to respiratory epithelial cells and promotes the superiorly protective immune responses against H9N2 influenza virus in chickens

H9N2 subtype avian influenza virus (AIV) is an ongoing threat causing substantial loss to the poultry industry and thus necessitating the development of safe and effective vaccines against AIV. Given that inactivated vaccines are less effective in activating the mucosal immune system, we aimed to generate a vaccine that can actively engage the mucosal immunity which is the front line of the immune system. We generated a group of flagellin-based hemagglutinin globular head (HA1) fusion proteins and characterized their immunogenicity and efficacy. We found that Salmonella typhimurium flagellin (fliC) lacking the hypervariable domain (called herein as HA1-ΔfliC) was recognized by TLR5 and induced a moderate innate immune response compared to N-terminus of fliC (HA1-fliC) and C-terminus of fliC (fliC-HA1). The HA1-ΔfliC protein had increased adherence to the nasal cavity and trachea than HA1-fliC and fliC-HA1 and significantly increased the HA-specific sIgA titers. Our in vivo results revealed that chickens treated with HA1-ΔfliC had a significantly reduced level of viral loads in the cloaca and throat compared with chickens treated with inactivated vaccine. Overall, these results revealed that HA1-ΔfliC can protect chickens against H9N2 AIV by eliciting the efficient mucosal immune responses.

In Silico Design and Evaluation of PRAME+FliCΔD2D3 as a New Breast Cancer Vaccine Candidate

Background

The most prevalent cancer in women over the world is breast cancer. Immunotherapy is a promising method to effectively treat cancer patients. Among various immunotherapy methods, tumor antigens stimulate the immune system to eradicate cancer cells. Preferentially expressed antigen in melanoma (PRAME) is mainly overexpressed in breast cancer cells, and has no expression in normal tissues. FliCΔD2D3, as truncated flagellin (FliC), is an effective toll-like receptor 5 (TLR5) agonist with lower inflammatory responses. The objective of the present study was to utilize bioinformatics methods to design a chimeric protein against breast cancer.

Methods

The physicochemical properties, solubility, and secondary structures of PRAME+FliCΔD2D3 were predicted using the tools ProtParam, Protein-sol, and GOR IV, respectively. The 3D structure of the chimeric protein was built using I-TASSER and refined with GalaxyRefine, RAMPAGE, and PROCHECK. ANTIGENpro and VaxiJen were used to evaluate protein antigenicity, and allergenicity was checked using AlgPred and Allergen FP. Major histocompatibility complex )MHC( and cytotoxic T-lymphocytes )CTL( binding peptides were predicted using HLApred and CTLpred. Finally, B-cell continuous and discontinuous epitopes were predicted using ABCpred and ElliPro, respectively.

Results

The stability and solubility of PRAME+FliCΔD2D3 were analyzed, and its secondary and tertiary structures were predicted. The results showed that the derived peptides could bind to MHCs and CTLs. The designed chimeric protein possessed both linear and conformational epitopes with a high binding affinity to B-cell epitopes.

Conclusion

PRAME+FliCΔD2D3 is a stable and soluble chimeric protein that can stimulate humoral and cellular immunity. The obtained results can be utilized for the development of an experimental vaccine against breast cancer.