Physical Biology of the Cancer Cell Glycocalyx

Overview

Journal Nat Phys

Specialty Biophysics

Date 2021 Apr 16

PMID 33859716

Citations 67

Authors

Joe Chin-Hun Kuo

Jay G Gandhi

Roseanna N Zia

Matthew J Paszek

Affiliations

Soon will be listed here.

Abstract

The glycocalyx coating the outside of most cells is a polymer meshwork comprising proteins and complex sugar chains called glycans. From a physical perspective, the glycocalyx has long been considered a simple 'slime' that protects cells from mechanical disruption or against pathogen interactions, but the great complexity of the structure argues for the evolution of more advanced functionality: the glycocalyx serves as the complex physical environment within which cell-surface receptors reside and operate. Recent studies have demonstrated that the glycocalyx can exert thermodynamic and kinetic control over cell signalling by serving as the local medium within which receptors diffuse, assemble and function. The composition and structure of the glycocalyx change markedly with changes in cell state, including transformation. Notably, cancer-specific changes fuel the synthesis of monomeric building blocks and machinery for production of long-chain polymers that alter the physical and chemical structure of the glycocalyx. In this Review, we discuss these changes and their physical consequences on receptor function and emergent cell behaviours.

Citing Articles

Biophysical modeling of membrane curvature generation and curvature sensing by the glycocalyx.

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Mechanobiology of 3D cell confinement and extracellular crowding.

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Influence of the glycocalyx on the size and mechanical properties of plasma membrane-derived vesicles.

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The native glycocalyx ultrastructure in humans and sponges is a self-assembled, lamellar micro- and nanoarray.

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Leucine zipper-based SAIM imaging identifies therapeutic agents to disrupt the cancer cell glycocalyx for enhanced immunotherapy.

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