Hemagglutinin from multiple divergent influenza A and B viruses bind to a distinct branched, sialylated poly-LacNAc glycan by surface plasmon resonance.

Influenza viruses initiate infection via specific interactions of hemagglutinin (HA) with host cell surface sialic acid-containing glycans. Antigenic drift has resulted in HA amino acid sequence changes that affect binding properties for sialic acids. Further, viral propagation in eggs and cell culture for vaccine production can yield variants with mutations that affect the conformation and affinity of HA for sialic acids. Therefore, influenza vaccine researchers and manufacturers need robust analytical methods to assess directly the ability of vaccine candidates to bind to their specific sialic acid ligand. We developed a surface plasmon resonance method that uses an extended, biantennary glycan terminating with α-2,6 linked sialic acids to bind influenza HA and assess this interaction. Recombinant HA (rHA) from both influenza A and B viruses isolated from 1999 to 2017 strongly and specifically bind this sialic acid ligand, suggesting the binding ability of divergent HA for this ligand is resistant to antigenic drift. Importantly, the method can differentiate between wild type and mutant rHA for which binding to this sialylated glycan and red blood cells in hemagglutination assays is compromised. We believe this method can be a powerful tool to screen influenza A and B vaccine candidates and final vaccine preparations for their functional ability to bind sialic acids, which allows manufacturers to identify preparations in which mutations that affect sialic acid binding have arisen during propagation. Evaluation of vaccine rHA antigen integrity by confirmation of the receptor binding site functionality is a prudent cautionary step to assure the antigenic quality of seasonal influenza vaccines.

Cas, Fak and Pyk2 function in diverse signaling cascades to promote Yersinia uptake.

The interplay between pathogen-encoded virulence factors and host cell signaling networks is critical for both the establishment and clearance of microbial infections. Yersinia uptake into host cells serves as an in vitro model for exploring how host cells respond to Yersinia adherence. In this study, we provide insight into the molecular nature and regulation of signaling networks that contribute to the uptake process. Using a reconstitution approach in Fak(-/-) fibroblasts, we have been able to specifically address the interplay between Fak, Cas and Pyk2 in this process. We show that both Fak and Cas play roles in the Yersinia uptake process and that Cas can function in a novel pathway that is independent of Fak. Fak-dependent Yersinia uptake does not appear to involve Cas-Crk signaling. By contrast, Cas-mediated uptake in the absence of Fak requires Crk as well as the protein tyrosine kinases Pyk2 and Src. In spite of these differences, the requirement for Rac1 activity is a common feature of both pathways. Furthermore, blocking the function of either Fak or Cas induces similar morphological defects in Yersinia internalization, which are manifested by incomplete membrane protrusive activity that is consistent with an inhibition of Rac1 activity. Pyk2 also functions in Yersinia uptake by macrophages, which are physiologically important for clearing Yersinia infections. Taken together, these data provide new insight into the host cellular signaling networks that are initiated upon infection with Y. pseudotuberculosis. Importantly, these findings also contribute to a better understanding of other cellular processes that involve actin remodeling, including the host response to other microbial pathogens, cell adhesion and migration.