Biophysical characterization of the adhesion between enveloped virus and phosphatidylserine-binding proteins

Abstract

Abstract Enveloped viruses are viruses that have a lipid membrane. Many enveloped viruses, such as the emerging virus Ebola, are pathogenic and of great clinical importance. Recent studies have shown that the outer lipid leaflets of viral envelopes contain phosphatidylserine (PS), which serves as an important attachment factor for enveloped virus entry into host cells. The envelope PS interacts with cellular PS receptors in a manner that mimics apoptotic body-PS receptor interactions during the engulfment of dead cell debris by phagocytes. The PS receptors utilized by enveloped viruses for viral internalization are designated phosphatidylserine-mediated virus entry enhancing receptors (PVEERs). While the importance of PVEERs in mediating viral entry has been demonstrated, the biophysical properties of the PVEER-virus interactions, including the detailed kinetics of PVEER-virion-associated PS binding, have not been comprehensively evaluated and compared. Using Ebola virus (EBOV) as the model system, this study investigated and compared the interactions between model Ebola viral particles and PVEER family proteins that are known to mediate enveloped virus attachment and entry. We used single-molecule force spectroscopy to quantify the specific interaction forces between PS or model EBOV viral particles and PVEERs. Based on the dynamic force spectra of various PS-receptor interactions, our results suggest that PS-PVEER interactions are mechanically comparable to antibody-antigen interactions, and that Gas6 and MFG-E8 may generate more force-resistant intersections than TIM-1 and ProteinS. The findings can help explain the biophysical mechanisms underlying the PVEER-mediated entry of enveloped virus into cells.