A 3-D Computational Model Predicts that Cell Deformation Affects Selectin-Mediated Leukocyte Rolling

doi:10.1529/biophysj.104.051029

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BIOPHYSICAL THEORY AND MODELING

A 3-D Computational Model Predicts that Cell Deformation Affects Selectin-Mediated Leukocyte Rolling

Sameer Jadhav ¹, Charles D Eggleton ² and Konstantinos Konstantopoulos ¹^*

¹ Johns Hopkins University
² UMBC

^* To whom correspondence should be addressed. E-mail: kkonsta1{at}jhu.edu.

Submitted on August 3, 2004
Revised on August 28, 2004
Accepted on 7 October 2004

Abstract
Leukocyte recruitment to sites of inflammation is initiatedby their tethering and rolling on the activated endotheliumunder flow. Even though the fast kinetics and high tensile strengthof selectin-ligand bonds are primarily responsible for leukocyterolling, experimental evidence suggests that cellular propertiessuch as cell deformability and microvillus elasticity activelymodulate leukocyte rolling behavior. Previous theoretical modelseither assumed cells as rigid spheres or were limited to 2-Drepresentations of deformable cells with deterministic receptor-ligandkinetics, thereby failing to accurately predict leukocyte rolling.We therefore developed a 3-D computational model based on theimmersed boundary method to predict receptor-mediated rollingof deformable cells in shear flow coupled to a Monte Carlo methodsimulating the stochastic receptor-ligand interactions. Ourmodel predicts for the first time that the rolling of more compliantcells is relatively smoother and slower compared to cells withstiffer membranes, due to increased cell-substrate contact area.At the molecular level, we show that the average number of bondsper cell as well as per single microvillus decreases with increasingmembrane stiffness. Moreover, the average bond lifetime decreaseswith shear rate and with increasing membrane stiffness, dueto higher hydrodynamic force experienced by the cell. Takentogether, our model captures the effect of cellular propertieson the coupling between hydrodynamic and receptor-ligand bondforces, and successfully explains the stable leukocyte rollingat a wide range of shear rates over that of rigid microspheres.

Key Words: Monte Carlo, P-selectin, PSGL-1, cell adhesion, fluid shear, immersed boundary method

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