Abstract
The current paradigm for receptor-ligand dissociation kinetics assumes off-rates as functions of instantaneous force without impact from its prior history. This a priori assumption is the foundation for predicting dissociation from a given initial state using kinetic equations. Here we have invalidated this assumption by demonstrating the impact of force history with single-bond kinetic experiments involving selectins and their ligands that mediate leukocyte tethering and rolling on vascular surfaces during inflammation. Dissociation of bonds between L-selectin and P-selectin glycoprotein ligand-1 (PSGL-1) loaded at a constant ramp rate to a constant hold force behaved as catch-slip bonds at low ramp rates that transformed to slip-only bonds at high ramp rates. Strikingly, bonds between L-selectin and 6-sulfo-sialyl Lewis X were impervious to ramp rate changes. This ligand-specific force history effect resembled the effect of a point mutation at the L-selectin surface (L-selectinA108H) predicted to contact the former but not the latter ligand, suggesting that the high ramp rate induced similar structural changes as the mutation. Although the A108H substitution in L-selectin eliminated the ramp rate responsiveness of its dissociation from PSGL-1, the inverse mutation H108A in P-selectin acquired the ramp rate responsiveness. Our data are well explained by the sliding-rebinding model for catch-slip bonds extended to incorporate the additional force history dependence, with Ala-108 playing a pivotal role in this structural mechanism. These results call for a paradigm shift in modeling the mechanical regulation of receptor-ligand bond dissociation, which includes conformational coupling between binding pocket and remote regions of the interacting molecules.
Highlights
L-selectin is expressed on leukocytes and binds to P-selectin glycoprotein ligand-1 (PSGL-1),4 a leukocyte mucin, and to 6-sulfo-sialyl Lewis X (6-sulfo-sLex), a terminal component of glycans on a group of mucins expressed on endothelial cells in lymph nodes and some sites of inflammation [1]
atomic force microscopy (AFM) and biomembrane force probe (BFP) were functionalized using molecules and immobilization methods depicted in Fig. 1, A and B, respectively
Selectins and their ligands were brought into contact to allow bond formation, retracted at a constant rate, and held at a given position, thereby subjecting the bonds to a well defined force history described by two independent parameters: ramp rate and hold force (Fig. 1C)
Summary
The new concept should not be confused with the concept of a bond transitioning among multiple stable states and dissociating along multiple pathways, which have been proposed to explain transition between catch and slip bonds (9 –11, 14, 16, 33) The latter concept requires more involved models than Equation 1 and more kinetic rates than just a single kϪ1, but they are all assumed to be single-valued functions of force. We could trace the structural basis for this unusual kinetic property to a single residue in L-selectin (Ala-108), suggesting that the observed force history effect was probably related to changes in molecular conformation These findings call for a paradigm shift in modeling receptor-ligand dissociation kinetics. Like catch-slip bonds that are found in many molecular systems, a similar force history regulation mechanism may be operative in the interaction kinetics of other molecular systems such as integrins
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