Combined Effect of Matrix Topography and Stiffness on Neutrophil Shape and Motility

Baeckkyoung Sung, Deok Ho Kim, Min Ho Kim, Daniele Vigolo

Research output: Contribution to journalArticlepeer-review

Abstract

The crawling behavior of leukocytes is driven by the cell morphology transition, which is a direct manifestation of molecular motor machinery. The topographical anisotropy and mechanical stiffness of the substrates are the main physical cues that affect leukocytes’ shape generation and migratory responses. However, their combined effects on the cell morphology and motility have been poorly understood, particularly for neutrophils, which are the fastest reacting leukocytes against infections and wounds. Here, spatiotemporally correlated physical parameters are shown, which determine the neutrophil shape change during migratory processes, in response to surface topography and elasticity. Guided crawling and shape generation of individual neutrophils, activated by a uniform concentration of a chemoattractant, are analyzed by adopting elasticity-tunable micropatterning and live cell imaging techniques. Whole cell-level image analysis is performed based on a planar geometric quantification of cell shape and motility. The findings show that the pattern anisotropy and elastic modulus of the substrate induce synergic effects on the shape anisotropy, deformability, and polarization/alignment of crawling neutrophils. How the morphology–motility relationship is affected by different surface microstructures and stiffness is demonstrated. These results imply that the neutrophil shape-motility correlations can be utilized for controlling the immune cell functions with predefined physical microenvironments.

Original languageEnglish (US)
Article number2101312
JournalAdvanced Biology
Volume6
Issue number6
DOIs
StatePublished - Jun 2022

Keywords

  • cell–matrix interaction
  • leukocyte migration
  • morphodynamics
  • surface compliance
  • topography sensing

ASJC Scopus subject areas

  • General Biochemistry, Genetics and Molecular Biology
  • Biomedical Engineering
  • Biomaterials

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