Reduction of Influenza A Virus Transmission in Mice by a Universal Intranasal Vaccine Candidate is Long-Lasting and Does Not Require Antibodies.

Vaccination against influenza virus infection can protect the vaccinee and also reduce transmission to contacts. Not all types of vaccines induce sterilizing immunity via neutralizing antibodies; some instead permit low-level, transient infection. There has been concern that infection-permissive influenza vaccines may allow continued spread in the community despite minimizing symptoms in the vaccinee. We have explored that issue for a universal influenza vaccine candidate that protects recipients by inducing T cell responses and nonneutralizing antibodies. Using a mouse model, we have shown previously that an adenoviral vectored vaccine expressing nucleoprotein (NP) and matrix 2 (M2) provides broad protection against diverse strains and subtypes of influenza A viruses and reduces transmission to contacts in an antigen-specific manner. Here, we use this mouse model to further explore the mechanism and features of that reduction in transmission. Passive immunization did not reduce transmission from infected donors to naive contact animals to whom passive serum had been transferred. Vaccination of antibody-deficient mIgTg-JHD-/- mice, which have intact T cell responses and antigen presentation, reduced transmission in an antigen-specific manner, despite the presence of some virus in the lungs and nasal wash, pointing to a role for cellular immunity. Vaccination at ages ranging from 8 to 60 weeks was able to achieve reduction in transmission. Finally, the immune-mediated reduction in transmission persisted for at least a year after a single-dose intranasal vaccination. Thus, this infection-permissive vaccine reduces virus transmission in a long-lasting manner that does not require antibodies. IMPORTANCE Universal influenza virus vaccines targeting antigens conserved among influenza A virus strains can protect from severe disease but do not necessarily prevent infection. Despite allowing low-level infection, intranasal immunization with adenovirus vectors expressing the conserved antigens influenza nucleoprotein (A/NP) and M2 reduces influenza virus transmission from vaccinated to unvaccinated contact mice. Here, we show that antibodies are not required for this transmission reduction, suggesting a role for T cells. We also show that transmission blocking could be achieved in recipients of different ages and remained effective for at least a year following a single-dose vaccination. Such vaccines could have major public health impacts by limiting viral transmission in the community.

Construction of SARS-CoV-2 virus-like particles in plant.

The pandemic of Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) has caused a public health emergency, and research on the development of various types of vaccines is rapidly progressing at an unprecedented development speed internationally. Some vaccines have already been approved for emergency use and are being supplied to people around the world, but there are still many ongoing efforts to create new vaccines. Virus-like particles (VLPs) enable the construction of promising platforms in the field of vaccine development. Here, we demonstrate that non-infectious SARS-CoV-2 VLPs can be successfully assembled by co-expressing three important viral proteins membrane (M), envelop (E) and nucleocapsid (N) in plants. Plant-derived VLPs were purified by sedimentation through a sucrose cushion. The shape and size of plant-derived VLPs are similar to native SARS-CoV-2 VLPs without spike. Although the assembled VLPs do not have S protein spikes, they could be developed as formulations that can improve the immunogenicity of vaccines including S antigens, and further could be used as platforms that can carry S antigens of concern for various mutations.

Senecavirus A 2B protein suppresses type I interferon production by inducing the degradation of MAVS.

Senecavirus A (SVA) is an oncolytic virus, which can propagate in human tumor cells and has been used as an oncolytic virotherapy candidate in humans. Besides, SVA circulates in pigs and causes vesicles and coalescing erosions on the snouts and coronary bands in infected pigs and results in neonatal morbidity. SVA has evolved the ability to suppress host innate immune response to benefit viral replication. SVA 3Cpro and 2C protein inhibit the production of host type I interferon (IFN) by degradation of several components of innate immune pathway. In this study, for the first time, we determined that SVA 2B antagonized host innate immune response in both human and porcine cells. SVA 2B protein degraded mitochondrial antiviral-signaling protein (MAVS), a key host molecule in the innate immune pathway, and a colocalization and interaction between 2B and MAVS was observed in the context of viral infection. Further study showed that the 1-48 and 100-128 regions of 2B were essential for inhibition of type I IFN expression. In addition, we determined that 2B degraded MAVS depending on caspase-9 and caspase-3. In conclusion, our results revealed a novel strategy for SVA 2B protein to antagonize host innate immune response, which will help for clarification of the pathogenesis of SVA and provide an insight for oncolytic virotherapy of SVA.