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Single-cell analysis reveals chemokine-mediated differential regulation of monocyte mechanics

Tom M. J. Evers, Vahid Sheikhhassani, Mariëlle C. Haks, Cornelis Storm, Tom H. M. Ottenhoff, Alireza Mashaghi

2021iScience29 citationsDOIOpen Access PDF

Abstract

Monocytes continuously adapt their shapes for proper circulation and elicitation of effective immune responses. Although these functions depend on the cell mechanical properties, the mechanical behavior of monocytes is still poorly understood and accurate physiologically relevant data on basic mechanical properties are lacking almost entirely. By combining several complementary single-cell force spectroscopy techniques, we report that the mechanical properties of human monocyte are strain-rate dependent, and that chemokines can induce alterations in viscoelastic behavior. In addition, our findings indicate that human monocytes are heterogeneous mechanically and this heterogeneity is regulated by chemokine CCL2. The technology presented here can be readily used to reveal mechanical complexity of the blood cell population in disease conditions, where viscoelastic properties may serve as physical biomarkers for disease progression and response to therapy.

Topics & Concepts

ChemokineMonocyteViscoelasticityCellImmune systemPopulationImmunologyChemotaxisCell biologyBiologyChemistryMedicineMaterials scienceReceptorGeneticsComposite materialEnvironmental healthCellular Mechanics and InteractionsImmune cells in cancerErythrocyte Function and Pathophysiology
Single-cell analysis reveals chemokine-mediated differential regulation of monocyte mechanics | Litcius