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Calcium dynamically alters erythrocyte mechanical response to shear

Title:	Calcium dynamically alters erythrocyte mechanical response to shear
Authors:	Kuck, L; Peart, JN; Simmonds, MJ
Publisher Information:	Elsevier
Publication Year:	2020
Collection:	Griffith University: Griffith Research Online
Subject Terms:	Biochemistry and cell biology; Medical microbiology; Calcium signaling; Cell deformability; Mechanobiology; Mechanotransduction; Red blood cell
Description:	Red blood cells (RBC) are constantly exposed to varying mechanical forces while traversing the cardiovascular system. Upon exposure to mechanical stimuli (e.g., shear stress), calcium enters the cell and prompts potassium-efflux. Efflux of potassium is accompanied by a loss of intracellular fluid; thus, the volume of RBC decreases proportionately (i.e., 'Gárdos effect'). The mechanical properties of the cell are subsequently impacted due to complex interactions between cytosolic viscosity (dependent on cell hydration), the surface-area-to-volume ratio, and other molecular processes. The dynamic effects of calcium on RBC mechanics are yet to be elucidated, although accumulating evidence suggests a vital role. The present study thus examined the effects of calcium on contemporary biomechanical properties of RBC in conjunction with high-precision geometrical analyses with exposure to shear. Mechanical stimulation of RBC was performed using a co-axial Couette shearing system to deform the cell membrane; intracellular signaling events were observed via fluorescent imaging. Calcium was introduced into RBC using ionophore A23187. Increased intracellular calcium significantly impaired RBC deformability; these impairments were mediated by a calcium-induced reduction of cell volume through the Gárdos channel. Extracellular calcium in the absence of the ionophore only had an effect under shear, not at stasis. Under low shear, the presence of extracellular calcium induced progressive lysis of a sub-population of RBC; all remaining RBC exhibited exceptional capacity to deform, implying preferential removal of potentially aged cells. Collectively, we provide evidence of the mechanism by which calcium acutely regulates RBC mechanical properties. ; No Full Text
Document Type:	article in journal/newspaper
Language:	English
Relation:	Biochimica et Biophysica Acta (BBA) - Molecular Cell Research; Kuck, L; Peart, JN; Simmonds, MJ, Calcium dynamically alters erythrocyte mechanical response to shear, Biochimica et Biophysica Acta (BBA) - Molecular Cell Research, 2020, pp. 118802; https://hdl.handle.net/10072/396065
DOI:	10.1016/j.bbamcr.2020.118802
Availability:	https://hdl.handle.net/10072/396065; https://doi.org/10.1016/j.bbamcr.2020.118802
Rights:	open access
Accession Number:	edsbas.FCF9F726
Database:	BASE