FUSION OF INFLUENZA-VIRUS WITH SIALIC ACID-BEARING TARGET MEMBRANES

We have monitored the fusion of intact A/PR/8/34 influenza virus with glycophorin-bearing liposomes and with ganglioside- (GD1a-) containing liposomes. The lipid bilayers of the glycophorin-bearing liposomes had several compositions, including pure dioleoylphosphatidylethanolamine (DOPE), pure egg phosphatidylethanolamine (EPE), and pure dioleoylphosphatidylcholine (DOPC). Examination of the temperature dependence of fusion for these and other compositions showed that even if the lipids are competent to form inverted hexagonal phases (H-II), there is no enhancement of the fusion rate constant at the L(alpha)-H-II phase transition temperature of the lipids, T-H. Thus, the H-II phase transition is not involved in the HA-mediated fusion mechanism. However, this mechanism is sensitive to lipid composition, in that PC bilayers fused more slowly than PE-containing bilayers above 20 degrees C. These results show that the HA-mediated fusion mechanism depends primarily upon specific lipid-protein interactions, although the fundamental parameters of lipid phase stability (interstice stabilization and monolayer spontaneous radius of curvature) may also be important. The fact that H-II phase-competent lipid bilayers in the glycophorin liposomes do not enhance the HA-mediated fusion rate strongly suggests that substantial bilayer-bilayer contact is not involved in HA-mediated fusion. Previously, we have shown that glycoprotein-bearing liposomes bind to HA-expressing cells specifically through HA-glycophorin interactions and that fusion is mediated by HAs not bound to glycophorin. Thus, with respect to the target membrane, the fusion site involves just the lipid bilayer. Our results with GD1a-containing liposomes strongly suggest that HAs bound to this sialic acid-bearing molecule are likewise incapable of participating in the fusion site. This could be due to a diminished lateral mobility of the HAs simultaneously bound to both closely apposed membranes. Finally, we find that the low-pH-induced viral inactivation is inhibited by binding to either glycophorin- or GD1a-containing target membranes.