The swine CD81 enhances E2-based DNA vaccination against classical swine fever

Classical swine fever (CSF) is a highly contagious and economically important viral disease that affects the pig industry worldwide. The glycoprotein E2 of CSFV can induce neutralizing antibodies and protective immunity, and is widely used for novel vaccine development. The objective of this study was to explore whether a tetraspanin molecule CD81 could improve the immune responses of an E2-based DNA vaccine. Plasmids pVAX-CD81, pVAX-E2 and pVAX-CD81-E2 were constructed and the expression of target proteins was confirmed in BHK-21 cells by indirect immunofluorescence assay. BALB/c mice were divided into 5 groups and immunized with different plasmids (pVAX-E2, pVAX-CD81-E2, pVAX-E2 + pVAX-CD81, pVAX-CD81 and PBS) three times with two weeks interval. The results showed that the introduction of CD81 promoted higher humoral and cellular immune responses than E2 expression alone (P < 0.05). In addition, immunization with pVAX-CD81-E2 induced stronger immune responses than pVAX-E2 + pVAX-CD81. Furthermore, four groups of pigs were immunized with pVAX-E2, pVAX-CD81-E2, pVAX-CD81 and PBS, respectively. Humoral and cellular immune responses detection showed similar results with those in mice. Compared to pVAX-E2, pVAX-CD81-E2 induced higher titers of neutralizing antibodies after viral challenge and conferred stronger protection. These results confirmed the capacity of swine CD81 enhancing the humoral and cellular responses with an adjuvant effect on CSFV DNA vaccine. This is the first report demonstrating the adjuvant effect of CD81 to enhance the DNA vaccination for swine pathogen.     

Glycoprotein E2 of classical swine fever virus expressed by baculovirus induces the protective immune responses in rabbits

Classical swine fever (CSF) caused by CSF virus (CSFV) is a highly contagious and devastating disease that affects the pig industry worldwide. The glycoprotein E2 of CSFV is the principal immunogenic protein that induces neutralizing antibodies and protective immunity. Several CSFV genotypes, including 1.1, 2.1, 2.2, and 2.3, have been identified in Mainland China. The glycoprotein E2 of genotypes 1.1 and 2.1 was expressed by using a baculovirus system and tested for its protective immunity in rabbits to develop novel CSF vaccines that elicit a broad immune response. Twenty CSFV seronegative rabbits were randomly divided into five groups. Each rabbit was intramuscularly immunized with E2 of genotypes 1.1 (CSFV-1.1E2), 2.1 (CSFV-2.1E2), or their combination (CSFV-1.1 + 2.1E2). A commercial CSF vaccine (C-strain) and phosphate-buffered saline (PBS) were used as positive or negative controls, respectively. All animals were challenged with CSFV C-strain at 4 weeks and then boosted with the same dose. All rabbits inoculated with CSFV-1.1E2, CSFV-2.1E2, and CSFV-1.1 + 2.1E2 elicited high levels of ELISA antibody, neutralizing antibody, and lymphocyte proliferative responses to CSFV. The rabbits inoculated with CSFV-1.1E2 and CSFV-1.1 + 2.1E2 received complete protection against CSFV C-strain. Two of the four rabbits vaccinated with CSFV-2.1E2 were completely protected. These results demonstrate that CSFV-1.1E2 and CSFV-1.1 + 2.1E2 not only elicit humoral and cell-mediated immune responses but also confer complete protection against CSFV C-strain in rabbits. Therefore, CSFV-1.1E2 and CSFV-1.1 + 2.1E2 are promising candidate subunit vaccines against CSF.     

The feasibility of a novel bioreactor for vaccine production of classical swine fever virus

The performance of a new type of tide mode culture system was investigated in this study. This novel bioreactor provides two separated stages, liquid and gas, for cell growth requirements. The immobilized cells absorbed the nutrient from medium during the liquid stage and subsequently were exposed directly to fresh air to absorb oxygen during the gas stage. Operating with PK15 cells under optimal conditions, we obtained 2.3 × 10⁹ cells in 500 ml reactor. It is 30 times higher than the initial inoculum and about 11 times higher than the production by roller bottle. For the vaccine production of classical swine fever (CSFV), a high virus titer of 2.1 × 10⁹ median tissue culture infective dose (TCID₅₀) was yielded which provided exceed 300 doses per milliliter of CSFV solution. Therefore, this new cultural system performed well not only for cell production but also for virus yield. It should be a highly efficient production for the CSFV vaccine and have practical potential in other animal cell culture vaccine.     

Modified live marker vaccine candidate CP7_E2alf provides early onset of protection against lethal challenge infection with classical swine fever virus after both intramuscular and oral immunization

Due to the vast economic consequences of classical swine fever (CSF) outbreaks, emergency vaccination plans are under discussion in European Union Member States. However, animals vaccinated with the conventional C-strain vaccine are subject to trade restrictions. To ease these restrictions, potent marker vaccines are required. One promising candidate is the chimeric pestivirus CP7_E2alf. For emergency vaccination in a CSF outbreak scenario, early onset of immunity is required. Here, the studies performed with a CP7_E2alf virus stock produced under good manufacturing conditions (GMP) are reported. In challenge experiments, CP7_E2alf induced full clinical protection 1 week after intramuscular vaccination, and 2 weeks after oral immunization. Furthermore, even after application of diluted vaccine preparations complete protection could be achieved if challenge infection was carried out 4 weeks after vaccination. In conclusion, GMP-produced CP7_E2alf proved to be a suitable marker vaccine candidate – also for emergency vaccination – both after intramuscular and oral application.     

Enhanced elicitation of potent neutralizing antibodies by the SARS-CoV-2 spike receptor binding domain Fc fusion protein in mice

The development of an effective vaccine against SARS-CoV-2 is urgently needed. We generated SARS-CoV-2 RBD-Fc fusion protein and evaluated its potency to elicit neutralizing antibody response in mice. RBD-Fc elicited a higher neutralizing antibodies titer than RBD as evaluated by a pseudovirus neutralization assay and a live virus based microneutralization assay. Furthermore, RBD-Fc immunized sera better inhibited cell–cell fusion, as evaluated by a quantitative cell–cell fusion assay. The cell–cell fusion assay results correlated well with the virus neutralization potency and could be used for high-throughput screening of large panels of anti-SARS-CoV-2 antibodies and vaccines without the requirement of live virus infection in BSL3 containment. Moreover, the anti-RBD sera did not enhance the pseudotyped SARS-CoV-2 infection of K562 cells. These results demonstrate that Fc fusion can significantly improve the humoral immune response to recombinant RBD immunogen, and suggest that RBD-Fc could serve as a useful component of effective vaccines against SARS-CoV-2.     

Yeast expressed classical swine fever E2 subunit vaccine candidate provides complete protection against lethal challenge infection and prevents horizontal virus transmission

Classical swine fever (CSF) caused by the classical swine fever virus (CSFV) is a highly contagious swine disease resulting in large economical losses worldwide. The viral envelope glycoprotein E(rns) and E2 are major targets for eliciting antibodies against CSFV in infected animals. A Pichia pastoris yeast expressed E2 protein (yE2) has been shown to induce a protective immune response against CSFV challenge. The purpose of this study is to determine the optimal dose of yE2 and its efficacy on the prevention of virus horizontal transmission. A yeast-expressed E(rns) (yE(rns)) protein was also included to evaluate its immunogenicity. The yE(rns) vaccinated pigs seroconverted to CSFV-E(rns)-specific antibody but no neutralizing antibody was detected and none survived after challenge infection, suggesting yE(rns) and yE2 retain correct immunogenicity but only the yE2 is able to induce a protective immune response. All three doses of yE2 (200, 300, and 400μg) could elicit high titers of neutralizing antibodies and protective responses after challenge. The yE2/200 group demonstrated a mild fever response but recovered soon, and none of the yE2/300 and yE2/400 pigs became febrile. The optimal dose of yE2 was recommended to be 300μg of the total amount of secreted proteins. In addition, the yE2 vaccine could cross-protect from all three genotypes of viruses. Further, the yE2 vaccine efficacy in preventing virus horizontal transmission was evaluated by cohabitation of unimmunized sentinels 3 days after challenge infection. All the sentinel pigs were alive and had no clinical symptoms confirming yE2 vaccine could confer a protective immune response and prevent horizontal transmission of CSFV.     

Hypervariable antigenic region 1 of classical swine fever virus E2 protein impacts antibody neutralization

Envelope glycoprotein E2 of classical swine fever virus (CSFV) is the major antigen that induces neutralizing antibodies and confers protection against CSFV infection. There are three hypervariable antigenic regions (HAR1, HAR2 and HAR3) of E2 that are different between the group 1 vaccine C-strain and group 2 clinical isolates. This study was aimed to characterize the antigenic epitope region recognized by monoclonal antibody 4F4 (mAb-4F4) that is present in the group 2 field isolate HZ1-08, but not in the C-strain, and examine its impact on neutralization titers when antisera from different recombinant viruses were cross-examined. Indirect ELISA with C-strain E2-based chimeric proteins carrying the three HAR regions showed that the mAb-4F4 bound to HAR1 from HZ1-08 E2, but not to HAR2 or HAR3, indicating that the specific epitope is located in the HAR1 region. Of the 6 major residues differences between C-strain and field isolates, Glu713 in the HAR1 region of strain HZ1-08 is critical for mAb-4F4 binding either at the recombinant protein level or using intact recombinant viruses carrying single mutations. C-strain-based recombinant viruses carrying the most antigenic part of E2 or HAR1 from strain HZ1-08 remained non-pathogenic to pigs and induced good antibody responses. By cross-neutralization assay, we observed that the anti-C-strain serum lost most of its neutralization capacity to RecC-HZ-E2 and QZ-14 (subgroup 2.1d field isolate in 2014), and vice versa. More importantly, the RecC-HAR1 virus remained competent in neutralizing ReC-HZ-E2 and QZ-14 strains without compromising the neutralization capability to the recombinant C-strain. Thus, we propose that chimeric C-strain carrying the HAR1 region of field isolates is a good vaccine candidate for classical swine fever.     

Phylogenetic analysis using E2 gene of classical swine fever virus reveals a new subgenotype in China

Outbreaks of classical swine fever (CSF) have caused serious economic consequences in China. Phylogenetic analysis based on full-length E2 gene sequences showed that five classical swine fever virus (CSFV) isolates collected from Hunan province in 2011 and 2012, together with seven other isolates from neighboring provinces, Guangdong (5) and Guangxi (2), could be classified as a new subgenotype 2.1c, which may have been endemic in the south of China for at least fourteen years. Subgenotype 2.1c isolates share 90.2–94.9% and 89.9–93.8% nucleotide sequence similarity separately with those of subgenotype 2.1a and 2.1b in E2 gene, which are lower than the nucleotide identities between subgenotype 2.1a and 2.1b (91.1–95.7%). Further analysis based on a partial E2 gene sequence (216 nt) indicated that subgenotype 2.1c isolates are also circulating in Thailand. Alignment of E2 amino acid sequences showed that subgenotype 2.1c isolates exhibit a SPA → TPV substitution at positions 777 and 779 compared with subgenotypes 2.1a and 2.1b.     

Induction of systemic and mucosal immunity and maintenance of its memory against influenza A virus by nasal vaccination using a new mucosal adjuvant SF-10 derived from pulmonary surfactant in young cynomolgus monkeys

Induction of systemic and mucosal immunity and maintenance of its memory was investigated in 12 young male cynomolgus monkeys after intranasal instillation of flu vaccine using a new mucosal adjuvant SF-10 derived from pulmonary surfactant constituents. Split-product of influenza virus A/California/7/2009(H1N1)pdm hemagglutinin vaccine (HAv) at 15 μg with or without SF-10 and the adjuvant alone were instilled intranasally three times every 2 weeks. SF-10-adjuvanted HAv (SF-10-HAv) elicited significantly higher HAv-specific IgG and hemagglutinin inhibition (HI) titers in serum and HAv-specific secretory IgA and its neutralizing activities in nasal washes compared with HAv antigen and SF-10 alone. Significant cross-neutralizing activities of nasal washes after the third vaccination to several other H1N1 and H3N2 strains were observed. HI titers in serum and neutralizing activities in nasal washes reached peak levels at 6 weeks after initial vaccination, then gradually decreased after 10 weeks and returned to the baseline levels at 36 weeks. A single intranasal revaccination of SF-10-HAv at 36 weeks rapidly and significantly increased both immunity in serum and nasal washes compared with naïve monkeys. Revaccination by one or two doses achieved almost maximal immunity at 2 or 4 weeks after instillation. Statistically significant adverse effects (e.g., body weight loss, elevated body temperature, nasal discharge, change in peripheral blood leukocyte and platelet counts) were not observed for 2 weeks after vaccination of SF-10-HAv, HAv or SF-10 and also during the experimental period. These results in young monkey model suggest the potential of clinical use SF-10 for intranasal flu vaccine.     

A single dose of the novel chimeric subunit vaccine E2-CD154 confers early full protection against classical swine fever virus

Classical swine fever is an economically important, highly contagious disease of swine worldwide. Subunit vaccines are a suitable alternative for the control of classical swine fever. However, such vaccines have as the main drawback the relatively long period of time required to induce a protective response, which hampers their use under outbreak conditions. In this work, a lentivirus-based gene delivery system is used to obtain a stable recombinant HEK 293 cell line for the expression of E2-CSFV antigen fused to porcine CD154 as immunostimulant molecule. The E2-CD154 chimeric protein was secreted into the medium by HEK293 cells in a concentration around 50 mg/L in suspension culture conditions using spinner bottles. The E2-CD154 immunized animals were able to overcome the challenge with a high virulent CSF virus strain performed 7 days after a unique dose of the vaccine without clinical manifestations of the disease. Specific anti-CSFV neutralizing antibodies and IFN-γ were induced 8 days after challenge equivalent to 14 days post-vaccination. The present work constitutes the first report of a subunit vaccine able to confer complete protection by the end of the first week after a single vaccination. These results suggest that the E2-CD154 antigen could be potentially used under outbreak conditions to stop CSFV spread and for eradication programs in CSF enzootic areas.     

Chimeric classical swine fever viruses containing envelope protein E(RNS) or E2 of bovine viral diarrhoea virus protect pigs against challenge with CSFV and induce a distinguishable antibody response

Three chimeric classical swine fever virus (CSFV)/bovine viral diarrhoea virus (BVDV) full-length DNA copies were constructed, based on the infectious DNA copy of the CSFV vaccine strain C. The antigenic region of E2 and/or the complete E(RNS) gene were replaced by the analogous sequence of BVDV II strain 5250. Viable chimeric virus Flc11, in which E(RNS) was replaced, was directly recovered from supernatant of SK6.T7 cells transfected with full-length DNA. Viable chimeric virus Flc9, in which E2 was replaced, resulted in recovery of virus only when SK6.T7 transfected cells were maintained for several passages. However, no virus could be recovered after replacement of both E(RNS) and E2, even after 10 cell passages. Both Flc9 and Flc11 grow in swine kidney cells (SK6), stably maintain their heterologous BVDV sequences and, as assessed by monoclonal antibody typing and radio-immunoprecipitation assays, express their heterologous proteins. Flc9 showed a slower growth rate on SK6 cells than Flc11 and wild-type Flc2 virus. Replacement of E(RNS) or E2 of C-strain-based chimeric viruses did not alter cell tropism compared to wild-type C-strain virus for SK6 and FBE cells. Both Flc9 and Flc11 induced E2 or E(RNS) antibodies, which could be discriminated from those induced after wild-type virus infection, even after repeated vaccination. Furthermore, pigs were completely protected against a lethal CSFV challenge. These results indicate the feasibility of introduction of marker antigens in a live-attenuated marker C-strain vaccine for CSFV.