A highly stable prefusion RSV F vaccine derived from structural analysis of the fusion mechanism

Respiratory syncytial virus (RSV) causes acute lower respiratory tract infections and is the leading cause of infant hospitalizations. Recently, a promising vaccine antigen based on the RSV fusion protein (RSV F) stabilized in the native prefusion conformation has been described. Here we report alternative strategies to arrest RSV F in the prefusion conformation based on the prevention of hinge movements in the first refolding region and the elimination of proteolytic exposure of the fusion peptide. A limited number of unique mutations are identified that stabilize the prefusion conformation of RSV F and dramatically increase expression levels. This highly stable prefusion RSV F elicits neutralizing antibodies in cotton rats and induces complete protection against viral challenge. Moreover, the structural and biochemical analysis of the prefusion variants suggests a function for p27, the excised segment that precedes the fusion peptide in the polypeptide chain. Respiratory syncytial virus (RSV) is a highly contagious childhood pathogen of the respiratory tract for which no vaccine is currently available. Here the authors present a strategy to stabilize the RSV F protein in a prefusion conformation that can elicit a strong protective immune response in animal models.