Bilayer acoustic force spectroscopy (BAFS) for quantifying receptor-antigen binding strength in immune synapses
Jukic, N.; Evers, T. M. J.; Walters, A.; Nguyen, C.; Vuong, M.; Heroven, A. C.; Fernandes, R. A.; Tans, S. J.; Ganzinger, K. A.
Show abstract
Immune cell receptor - ligand interactions are key to cancer immunotherapy. However, receptor-ligand affinities often fail to predict T-cell mediated cancer killing, while immune-target cell binding strength measurements are limited by low precision and high non-specific binding. Here we present bilayer acoustic force spectroscopy (BAFS), a method to quantify the binding strength of receptors in immune synapses that virtually eliminates non-specific binding and increases the resolving power by up to 50-fold. By replacing target cells with a supported lipid bilayer functionalized with antigens, BAFS avoids antigen-independent interactions and target cell heterogeneity, while maintaining the spatial self-organization of receptors that typifies active immune synapses. We demonstrate the high sensitivity and control by showing how CAR T-cell synapse strength depends on CD19 antigen density, and by revealing that CD8 synergistically strengthens {beta}TCR-pMHC synapses independently of Lck recruitment to CD8. BAFS is a general method that can be used broadly in immunotherapy screening and to dissect the complex molecular interactions that underpin immune synapse activation.
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