Nonlinear elasticity of the extracellular matrix fibers facilitates efficient inter-cellular mechanical communication

TL;DR

This study investigates how the nonlinear elastic properties of extracellular matrix fibers influence the efficiency and directionality of mechanical communication between cells, revealing that nonlinearity enhances long-distance load transfer and structural alignment.

Contribution

The paper introduces a finite-element model incorporating nonlinear fiber behaviors, demonstrating their role in facilitating inter-cellular mechanical signaling and matrix remodeling.

Findings

Compression buckling directs loads toward neighboring cells.

Tension-stiffening enhances load directionality and force magnitude.

Nonlinear elasticity promotes fiber alignment and inter-cellular structural remodeling.

Abstract

Biological cells embedded in fibrous matrices have been observed to form inter-cellular bands of dense and aligned fibers, through which they mechanically interact over long distances. Such matrix-mediated cellular interactions have been shown to regulate a variety of biological processes. The current study was aimed at exploring the effects of elastic nonlinearity of the fibers contained in the extracellular matrix (ECM) on the transmission of mechanical loads between contracting cells. Based on our biological experiments, we developed a finite-element model of two contracting cells embedded within a fibrous network. The individual fibers were modeled as showing either linear elasticity, compression-microbuckling, tension-stiffening or both of the latter. Compression-buckling resulted in smaller loads occurring in the ECM, but these were more directed toward the neighboring cell. The latter decreased with increasing cell-to-cell distance; when cells were >15 cell-diameters apart, no such inter-cellular interaction was observed. Tension-stiffening further contributed to directing the loads toward the neighboring cell, though to a smaller extent. The contraction of two neighboring cells resulted in mutual attraction forces, which were considerably increased by tension-stiffening, and decayed with increasing cell-to-cell distances. Nonlinear elasticity contributed also to the onset of force polarity on the cell boundary. The density and alignment of the fibers within the inter-cellular band were considerably greater when fibers buckled under compression, with tension-stiffening further contributing to this structural remodeling. Our model demonstrates the contribution of nonlinear elasticity of biological gels to directionality and efficiency of mechanical-signal transfer between distant cells.