Brunner, C.; Pietsch, L.; vom Sondern, I.; Roehrl, M.; Popov, C.; Trollmann, M.; Taylor, R.; Blessing, M.; Holler, C.; Almahayni, K.; Jaeschke, S. O.; Sandoghdar, V.; Boeckmann, R. A.; Lindhorst, T.; Moeckl, L.

Over recent decades, the glycocalyx, an extracellular organelle comprised of a multitude of glycolipids, glycoproteins, proteoglycans and glycoRNA, has gained considerable interest in cellular biology. While research in this field has re-vealed its tremendous importance in evermore aspects of physiological and pathological cellular processes, many of the principles that govern the role of the glycocalyx in these processes on a molecular level are still unknown. In order to unravel the fundamental laws underlying glycocalyx function, new technologies are required that enable the distinction between individual subprocesses within the intricate environment of the glycocalyx. Here, we establish an experimental platform to investigate the dynamics of the glycocalyx at the nanometer and microsecond length and time scales in a bottom-up fashion. We synthesized defined model glycans and installed them on supported lipid bilayers, assembling glycocalyx model systems with tunable properties. By investigating these tunable model systems with interferometric scattering (iSCAT) microscopy, we gain access to the required spatiotemporal resolution. We found a strong correlation between the molecular structure of several investigated model glycans and global dynamics of the system. Our findings are corroborated by atomistic and coarse-grained molecular dynamics simulations. Our results provide the first direct experimental evidence on the relationship between glycan structure, organization, and dynamics, offering a robust and versatile basis for a quantitative understanding of glycocalyx biology and physics at the molecular level.