The double-layered protein nanoparticle vaccine, which is constructed with a stabilized portion of the influenza virus (the hemagglutinin (HA) stalk), induced broadly reactive immune responses and conferred robust and sustained cross-immune protection against influenza B virus strains of both lineages. The findings are published in the journal Biomaterials.
Influenza epidemics pose a major threat to public health, and type B influenza has coincided with several severe flu outbreaks. About one-fourth of clinical infection cases are caused by influenza B viruses each year. Influenza B viruses are sometimes the dominant circulating strains during influenza seasons, such as the 2019-20 U.S. flu season when influenza B caused more than 50 percent of the infections.
Influenza B has two lineages that are genetically distinct and trigger different immune responses. Seasonal flu vaccines are developed with one or both lineages of influenza B viruses, but they’re limited by the ability of circulating strains to escape the immune system or vaccination. These vaccines are often ineffective because the variable portion of the influenza virus (the HA head) evolves. As a result, seasonal influenza vaccines need to be reformulated and updated frequently. To overcome these limitations, a universal influenza vaccine containing conserved parts of the virus and providing substantial broad cross-protection against diverse virus strains is urgently needed.
“In this study, we generated structure-stabilized HA stalk antigens from influenza B and fabricated double-layered protein nanoparticles as universal influenza B vaccine candidates,” said Dr. Baozhong Wang, senior author of the study and Distinguished University Professor in the Institute for Biomedical Sciences at GeorgiaState University. “We found that layered protein nanoparticles incorporated with structure-stabilized constant antigens have potential as a universal influenza vaccine with improved immune protective potency and breadth.”
The nanoparticle vaccine was tested in cell culture and in mice. Studies in cell culture found the protein nanoparticles were effectively taken up to activate dendritic cells, which are critical for inducing protective immune responses against pathogens. The vaccine was found to be safe, biocompatible, biodegradable and highly immunogenic in animals.
“Our next aim is to combine the influenza A nanoparticles from our previous study with the influenza B nanoparticles we have fabricated and tested here to create a multivalent universal influenza nanoparticle vaccine against both influenza A and B,” Wang said.
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