LAUSR

Rolling adhesion is the behaviour that leukocytes and circulating tumour cells exhibit as they passively roll along blood vessel walls under flow. It plays a critical role in capturing cells in the blood, guiding them toward inflammation sites, and activating cell signalling pathways to enable their subsequent transmigration. Rolling adhesion is mediated by catch-bond-like interactions between selectins expressed on endothelial cells lining blood vessels and P-selectin glycoprotein ligand-1 found at microvilli tips of leukocytes. Despite our understanding of individual components of this process, how the molecular details of adhesion bonds scale to cell-surface adhesion and rolling behaviour remains poorly understood. Here, we developed 2 label-free methods that map the functional adhesion sites and their strength on a leukocyte surface. The first method relies on tracking the rotational angle of a single rolling cell, which confers advantages over standard methods that track the centre-of-mass alone. Constructing the adhesion map from the instantaneous angular velocity reveals that the adhesion profile along the rolling circumference is inhomogeneous. We corroborated these findings with a second method that allowed us to obtain a footprint of molecular adhesion events using DNA-based molecular force probes. Our results reveal that adhesion at the functional level is not uniformly distributed over the leukocyte surface as previously assumed, but is instead patchy.