Structural and immunological characterization of the H3 influenza hemagglutinin during antigenic drift

The quest for a universal influenza vaccine holds great promise for mitigating the global burden of influenza-related morbidity and mortality. However, challenges persist in identifying conserved epitopes capable of inducing protection. In this study, we explore the influence of glycan evolution on H3 hemagglutinin from 1968 to present day and its impacts on antigenicity and immunogenicity. We observe that the appearance of potential N-linked glycosylation sites in Sing/16 hemagglutinin head domain reduces the binding of broadly neutralizing antibodies and shifts the polyclonal immune response upon vaccination to target the stem. Furthermore, structural characterization of HK/68 and Sing/16 by cryo-electron microscopy shows that while HK/68 is resistant to enzymatic deglycosylation, removal of glycans destabilizes the hyperglycosylated head and membrane-proximal region in Sing/16. These insights expand our understanding of glycans beyond their role in protein folding and highlight the interplay among glycan integration and immune recognition to design a universal influenza vaccine.