Studying the entire membrane significantly increases the system's complexity and complicates data interpretation. Therefore, the project required developing and optimizing stable and reliable in-vitro systems that closely mimic the biological environment in a controlled setting. Spike proteins were immobilized on liposomes, which are small artificial lipid vesicles resembling the viral envelope that surrounds SARS-CoV-2 particles. This system allowed for high purity, precise control over their composition, and easy comparison between variants. The binding of these liposomes was studied on a supported lipid bilayer, a lipid membrane formed above a glass substrate, produced from the cell membrane. These "native" bilayers maintain the cell membrane composition but are stable over time, unlike living cells which react to external stimuli. They are also compatible with highly sensitive biophysical and microscopy techniques needed for measurements at the single particle and molecule level. Throughout the project, we employed total internal reflection microscopy, a technique that focuses on imaging the sample surface with extremely high sensitivity, to study the binding of single particles, and atomic-force microscopy (AFM) to analyse single molecular bonds.
The study included the original SARS-CoV-2 strain isolated in Wuhan and three widespread variants: Alpha, Delta, and Omicron (BA.1). The first result is a clear increase in virus binding to pulmonary cells for Omicron compared to earlier variants. Analysis of the binding kinetics—how fast the virus attaches to and leaves the cell membrane—revealed that the increase is due to faster binding. This suggested the increased use by Omicron of a common molecule on the cell surface, offering many attaching points, and thus fast binding.
HS was identified as a major factor in the increased interaction with the virus. Initially, HS had a weak interaction with early variants of the virus and removing HS from the cell surface increased virus binding for all variants except Omicron. This is likely because HS's long sugar chain hides SARS-CoV-2's main receptor, ACE2. However, Omicron has a 10-fold increase in affinity for HS, making it an important binding factor. Single molecule studies using AFM confirmed this increased affinity for Omicron and revealed subtle differences in the Alpha and Delta variants. These differences may help the virus anchor to the surface via HS but also increase its mobility, improving its chances of engaging ACE2.