[HTML][HTML] Measuring two-dimensional receptor-ligand binding kinetics by micropipette

SE Chesla, P Selvaraj, C Zhu - Biophysical journal, 1998 - cell.com
SE Chesla, P Selvaraj, C Zhu
Biophysical journal, 1998cell.com
We report a novel method for measuring forward and reverse kinetic rate constants, k fo and
kr 0, for the binding of individual receptors and ligands anchored to apposing surfaces in cell
adhesion. Not only does the method examine adhesion between a single pair of cells; it also
probes predominantly a single receptor-ligand bond. The idea is to quantify the dependence
of adhesion probability on contact duration and densities of the receptors and ligands. The
experiment was an extension of existing micropipette protocols. The analysis was based on …
Abstract
We report a novel method for measuring forward and reverse kinetic rate constants, kfo and kr0, for the binding of individual receptors and ligands anchored to apposing surfaces in cell adhesion. Not only does the method examine adhesion between a single pair of cells; it also probes predominantly a single receptor-ligand bond. The idea is to quantify the dependence of adhesion probability on contact duration and densities of the receptors and ligands. The experiment was an extension of existing micropipette protocols. The analysis was based on analytical solutions to the probabilistic formulation of kinetics for small systems. This method was applied to examine the interaction between Fcγ receptor IIIA (CD16A) expressed on Chinese hamster ovary cell transfectants and immunogobulin G (IgG) of either human or rabbit origin coated on human erythrocytes, which were found to follow a monovalent biomolecular binding mechanism. The measured rate constants are Ackfo=\(2.6±0.32\)×10−7μm4 s−1 and kr0=\(0.37±0.055\) s−1 for the CD16A-hIgG interaction and Ackfo=\(5.7±0.31\)×10−7μm4 s−1 and kr0=\(0.20±0.042\) s−1 for the CD16A-rIgG interaction, respectively, where Ac is the contact area, estimated to be a few percent of 3μm2.
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