Selectin-ligand interactions mediate tethering and rolling of circulating leukocytes on the vessel wall during inflammation. Extensive study has been devoted to elucidating the kinetic and mechanical constraints of receptor-ligand-interaction-mediated leukocyte adhesion, yet many questions remain unanswered. Here, we describe our design of an inverted flow chamber to compare adhesions of HL-60 cells to E-selectin in the upright and inverted orientations. This new, to our knowledge, design allowed us to evaluate the effect of gravity and to investigate the mechanisms of flow-enhanced adhesion. Cell rolling in the two orientations was qualitatively similar, and the quantitative differences can be explained by the effect of gravity, which promotes free-flowing cells to tether and detached cells to reattach to the surface in the upright orientation but prevents such attachment from happening in the inverted orientation. We characterized rolling stability by the lifetime of rolling adhesion and detachment of rolling cells, which could be easily measured in the inverted orientation, but not in the upright orientation because of the reattachment of transiently detached cells. Unlike the transient tether lifetime of E-selectin-ligand interaction, which exhibited triphasic slip-catch-slip bonds, the lifetime of rolling adhesion displayed a biphasic trend that first increased with the wall shear stress, reached a maximum at 0.4 dyn/cm(2), and then decreased gradually. We have developed a minimal mathematical model for the probability of rolling adhesion. Comparison of the theoretical predictions to data has provided model validation and allowed evaluation of the effective two-dimensional association on-rate, kon, and the binding affinity, Ka, of the E-selectin-ligand interaction. kon increased with the wall shear stress from 0.1 to 0.7 dyn/cm(2). Ka first increased with the wall shear stress, reached a maximum at 0.4 dyn/cm(2), and then decreased gradually. Our results provide insights into how the interplay between flow-dependent on-rate and off-rate of E-selectin-ligand bonds determine flow-enhanced cell rolling stability.
Integrin αvβ3 interacting with the short Arg-Gly-Asp (RGD) motif plays a critical role in the progression of several types of tumors. However, the effects of the RGD structure (cyclic or linear) with integrin αvβ3 at the atomic level remain poorly understood. Here, we performed association and dissociation dynamic simulations for integrin αvβ3 in complex with a linear or cyclic pentapeptide by steered molecular dynamics simulations. Compared with cyclic RGD, the linear RGD peptide triggers instability of the configurational changes, mainly resting with the RGD domain due to its flexibility. The main interaction energy between Mg2+ and cyclic RGD is much stronger than that of the linear RGD system by the well shield to lessen attacks by free water molecules. The force-dependent dissociation results show that it is easier for linear RGD peptides to leave the active site and much quicker than the cyclic RGD ligand, whereas it is harder to enter the appropriate active binding site in linear RGD. The Ser123-AspRGD bond may play a critical role in the allosteric pathway. Our findings provide insights into the dynamics of αvβ3 interactions with linear and cyclic RGD ligands and contribute to the application of RGD-based strategies in preclinical therapy.
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