Generation of whole-porcine neutralizing antibodies of an alphacoronavirus by single B cell antibody technology.

Porcine epidemic diarrhea virus (PEDV) is an alphacoronavirus that causes severe morbidity and mortality in piglets, resulting in substantial economic losses to the swine industry. While vaccination is currently the most effective preventive measure, existing vaccines fail to provide complete and reliable protection against PEDV infection. Consequently, there is a need to explore alternative or complementary strategies to address this issue. In this study, we utilized single B cell antibody technology to obtain a potent neutralizing antibody, C62, which specifically targets the receptor binding domain S1B of the PEDV-S1 protein. C62 exhibited potent neutralizing activity against PEDV and inhibited viral attachment to the cell surface in vitro. Furthermore, the effectiveness of C62 in mitigating PEDV infection was demonstrated in vivo, as evidenced by the delayed onset of diarrhea and reduced mortality rates observed in piglets following oral administration of C62. Our study provides an alternative approach for controlling PEDV infection. Meanwhile, C62 holds promise as a therapeutic biological agent to complement existing vaccines. More importantly, our study forms a solid foundation for the development of whole-porcine neutralizing antibodies against other swine coronaviruses, thus contributing to the overall improvement of swine health.

Prohibitin1 facilitates viral replication by impairing the RIG-I-like receptor signaling pathway.

IMPORTANCE: Type I interferon (IFN-I), produced by the innate immune system, plays an essential role in host antiviral responses. Proper regulation of IFN-I production is required for the host to balance immune responses and prevent superfluous inflammation. IFN regulatory factor 3 (IRF3) and subsequent sensors are activated by RNA virus infection to induce IFN-I production. Therefore, proper regulation of IRF3 serves as an important way to control innate immunity and viral replication. Here, we first identified Prohibitin1 (PHB1) as a negative regulator of host IFN-I innate immune responses. Mechanistically, PHB1 inhibited the nucleus import of IRF3 by impairing its binding with importin subunit alpha-1 and importin subunit alpha-5. Our study demonstrates the mechanism by which PHB1 facilitates the replication of multiple RNA viruses and provides insights into the negative regulation of host immune responses.

Evaluation of the Mucosal Immunity Effect of Bovine Viral Diarrhea Virus Subunit Vaccine E2Fc and E2Ft.

Classified as a class B infectious disease by the World Organization for Animal Health (OIE), bovine viral diarrhea/mucosal disease is an acute, highly contagious disease caused by the bovine viral diarrhea virus (BVDV). Sporadic endemics of BVDV often lead to huge economic losses to the dairy and beef industries. To shed light on the prevention and control of BVDV, we developed two novel subunit vaccines by expressing bovine viral diarrhea virus E2 fusion recombinant proteins (E2Fc and E2Ft) through suspended HEK293 cells. We also evaluated the immune effects of the vaccines. The results showed that both subunit vaccines induced an intense mucosal immune response in calves. Mechanistically, E2Fc bonded to the Fc γ receptor (FcγRI) on antigen-presenting cells (APCs) and promoted IgA secretion, leading to a stronger T-cell immune response (Th1 type). The neutralizing antibody titer stimulated by the mucosal-immunized E2Fc subunit vaccine reached 1:64, which was higher than that of the E2Ft subunit vaccine and that of the intramuscular inactivated vaccine. The two novel subunit vaccines for mucosal immunity developed in this study, E2Fc and E2Ft, can be further used as new strategies to control BVDV by enhancing cellular and humoral immunity.

AAV-expressed G protein induces robust humoral and cellular immune response and provides durable protection from rabies virus challenges in mice.

Rabies is a highly lethal infectious zoonosis caused by rabies virus (RABV), and the mortality rate is almost 100 % once clinical symptoms appear, which poses a huge threat to public health security across the many parts of the word. Vaccination is reported to be the most effective approach to prevent the disease. G protein is the only protein present on the surface of RABV, it also could induce humoral immunity to produce virus neutralizing antibodies (VNA) and stimulate T cells to produce cellular immunity. Adeno-associated viruses (AAVs) have been used as vectors for gene therapy of different human diseases for its low immunogenicity, high safety and long-term stable expression. To develop a safe and effective vaccine, recombinant AAVs containing different kind of G gene were constructed. After intramuscular (i.m.) immunization in mice, all of these rAAV-G vaccines could induce the production of high levels of VNA and effective cellular immune response. Consistently, all of the rAAV-G vaccines could provide protection against lethal RABV challenge. Our results shown that the rAAV-G vaccines could be potential candidates used in the control of RABV infection. In addition, rAAV-G as a vaccine has many advantages of low preparation cost, simple storage and transportation conditions (4 °C storage and transportation), simple immunization program (only one immunization) and so on. Thence, the rAAV-G vaccines could be potential candidates used in the control of RABV infection.

Development of a DAS-ELISA for detection of H9N2 avian influenza virus.

H9N2 avian influenza virus is threatening animals and public health systems. Effective diagnosis is imperative to control the disease. Thus, we developed a panel of monoclonal antibodies (Mabs) against the H9N2 avian influenza virus (AIV) and implemented a double-antibody sandwich enzyme-linked immunosorbent assay (DAS-ELISA) to detect the H9 viral antigen. Hybridomas 4D10 and 5G2 were screened to secrete immunoglobulin G (IgG) and IgA, respectively. Antibody 4D10 was used as the capture antibodies and HRP labeled 5G2 as the detector antibody. The specificity of the optimized DAS-ELISA was evaluated by using AIV subtypes H1, H3, H5, H9 and H10. Specimens containing AIV H9 subtype yielded a specific and strong signal above the background, whereas specimens containing all other subtypes yielded background signals. The detection limit of the DAS-ELISA is 10-2.3 TCID50 (50% Tissue culture infective doses). Negative-positive threshold was 0.211 (OD630). In comparison with virus isolation the sensitivity and specificity of DAS-ELISA were found to be 98.9% and 98.1% respectively. Taken together, the newly developed Mab-based DAS-ELISA offers an attractive alternative to other diagnostic approaches for the specific detection of H9 subtype AIV.