TY - JOUR
T1 - Fluid shear stress-induced mechanotransduction in myoblasts
T2 - Does it depend on the glycocalyx?
AU - Haroon, Mohammad
AU - Bloks, Niek G. C.
AU - Deldicque, Louise
AU - Koppo, Katrien
AU - Seddiqi, Hadi
AU - Bakker, Astrid D.
AU - Klein-Nulend, Jenneke
AU - Jaspers, Richard T.
N1 - Funding Information: This study was funded by European Commission through MOVE-AGE, an Erasmus Mundus Joint Doctorate programme (Grant number: 2014-069 1). Publisher Copyright: © 2022 The Authors
PY - 2022/8/1
Y1 - 2022/8/1
N2 - Muscle stem cells (MuSCs) are involved in muscle maintenance and regeneration. Mechanically loaded MuSCs within their native niche undergo tensile and shear deformations, but how MuSCs sense mechanical stimuli and translate these into biochemical signals regulating function and fate is still poorly understood. We aimed to investigate whether the glycocalyx is involved in the MuSC mechanoresponse, and whether MuSC morphology affects mechanical loading-induced pressure, shear stress, and fluid velocity distribution. FSS-induced deformation of active proliferating MuSCs (myoblasts) with intact or degraded glycocalyx was assessed by live-cell imaging. Glycocalyx-degradation did not significantly affect nitric oxide production, but reduced FSS-induced myoblast deformation and modulated gene expression. Finite-element analysis revealed that the distribution of FSS-induced pressure, shear stress, and fluid velocity on myoblasts was non-uniform, and the magnitude depended on myoblast morphology and apex-height. In conclusion, our results suggest that the glycocalyx does not play a role in NO production in myoblasts but might impact mechanotransduction and gene expression, which needs further investigation. Future studies will unravel the underlying mechanism by which the glycocalyx affects FSS-induced myoblast deformation, which might be related to increased drag forces. Moreover, MuSCs with varying apex-height experience different levels of FSS-induced pressure, shear stress, and fluid velocity, suggesting differential responsiveness to fluid shear forces.
AB - Muscle stem cells (MuSCs) are involved in muscle maintenance and regeneration. Mechanically loaded MuSCs within their native niche undergo tensile and shear deformations, but how MuSCs sense mechanical stimuli and translate these into biochemical signals regulating function and fate is still poorly understood. We aimed to investigate whether the glycocalyx is involved in the MuSC mechanoresponse, and whether MuSC morphology affects mechanical loading-induced pressure, shear stress, and fluid velocity distribution. FSS-induced deformation of active proliferating MuSCs (myoblasts) with intact or degraded glycocalyx was assessed by live-cell imaging. Glycocalyx-degradation did not significantly affect nitric oxide production, but reduced FSS-induced myoblast deformation and modulated gene expression. Finite-element analysis revealed that the distribution of FSS-induced pressure, shear stress, and fluid velocity on myoblasts was non-uniform, and the magnitude depended on myoblast morphology and apex-height. In conclusion, our results suggest that the glycocalyx does not play a role in NO production in myoblasts but might impact mechanotransduction and gene expression, which needs further investigation. Future studies will unravel the underlying mechanism by which the glycocalyx affects FSS-induced myoblast deformation, which might be related to increased drag forces. Moreover, MuSCs with varying apex-height experience different levels of FSS-induced pressure, shear stress, and fluid velocity, suggesting differential responsiveness to fluid shear forces.
KW - Cell deformation
KW - Fluid shear stress
KW - Glycocalyx
KW - Mechanotransduction
KW - Myoblast
KW - Nitric oxide
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U2 - https://doi.org/10.1016/j.yexcr.2022.113204
DO - https://doi.org/10.1016/j.yexcr.2022.113204
M3 - Article
C2 - 35588795
SN - 0014-4827
VL - 417
SP - 1
EP - 13
JO - Experimental cell research
JF - Experimental cell research
IS - 1
M1 - 113204
ER -