Abstract
Since the introduction of H3N2 influenza A viruses in the human population, these viruses have continuously evolved to escape human immunity, with mutations occurring in and around the receptor binding site. This process, called antigenic drift, recently resulted in viruses that recognize elongated glycans that are not abundantly displayed in the human respiratory tract. Such receptor specificities hampered our ability to pick and propagate vaccine strains. Using ELISA, glycan array, tissue staining, flow cytometry, and hemagglutinin assays, this study revealed that the most recent H3N2 viruses have expanded receptor specificity by regaining effective recognition to shorter glycans. In recent H3 strains, Y159 and T160 are responsible for restricted binding to elongated glycans; in contemporary strains, however, Y159N and T160I dominate with a consequent loss of strength in receptor binding. Yet, effective receptor interaction is rescued by a remote mutation in the 190-helix, Y195F. The results demonstrate epistasis of critical residues in three of the four structural elements composing the HA receptor-binding site (the 130-loop, 150-loop, and 190-helix), which synergistically contribute to shape receptor binding specificity. Interestingly, a positive correlation exists between binding to an asymmetrical N-glycan containing an α2,6 sialylated tri-LacNAc arm and binding to human and ferret respiratory tract tissues. Together, these results elucidate the epistatic nature of receptor binding specificity during influenza A virus H3N2 evolution.