Oligosaccharide Model of the Vascular Endothelial Glycocalyx in Physiological Flow

Overview

Journal Microfluid Nanofluidics

Publisher Springer

Date 2018 Mar 24

PMID 29568255

Citations 9

Authors

Maria Pikoula

Matthew B Tessier

Robert J Woods

Yiannis Ventikos

Affiliations

Soon will be listed here.

Abstract

Experiments have consistently revealed the pivotal role of the endothelial glycocalyx layer in vasoregulation and the layer's contribution to mechanotransduction pathways. However, the exact mechanism by which the glycocalyx mediates fluid shear stress remains elusive. This study employs atomic-scale molecular simulations with the aim of investigating the conformational and orientation properties of highly flexible oligosaccharide components of the glycocalyx and their suitability as transduction molecules under hydrodynamic loading. Fluid flow was shown to have nearly no effect on the conformation populations explored by the oligosaccharide, in comparison with static (diffusion) conditions. However, the glycan exhibited a significant orientation change, when compared to simple diffusion, aligning itself with the flow direction. It is the tethered end of the glycan, an asparagine amino acid, which experienced conformational changes as a result of this flow-induced bias. Our results suggest that shear flow through the layer can have an impact on the conformational properties of saccharide-decorated transmembrane proteins, thus acting as a mechanosensor.

Citing Articles

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