Abstract
Osteocytes differentiated from osteoblasts play significant roles as mechanosensors in modulating the bone remodeling process. While the well-aligned osteocyte network along the trabeculae with slender cell processes perpendicular to the trabeculae surface is known to facilitate the sensing of mechanical stimuli by cells and the intracellular communication in the bone matrix, the mechanisms underlying osteocyte network formation remains unclear. Here, we developed a novel in vitro collagen matrix system exerting a uniaxially-fixed mechanical boundary condition on which mouse osteoblast-like MC3T3-E1 cells were subcultured, evoking cellular alignment along the uniaxial boundary condition. Using a myosin II inhibitor, blebbistatin, we showed that the intracellular tension via contraction of actin fibers contributed to the cellular alignment under the influence of isometric matrix condition along the uniaxially-fixed mechanical boundary condition. Furthermore, the cells actively migrated inside the collagen matrix and promoted the expression of osteoblast and osteocyte genes with their orientations aligned along the uniaxially-fixed boundary condition. Collectively, our results suggest that the intracellular tension of osteoblasts under a uniaxially-fixed mechanical boundary condition is one of the factors that determines the osteocyte alignment inside the bone matrix.
Highlights
Osteocytes differentiated from osteoblasts play significant roles as mechanosensors in modulating the bone remodeling process
A part of osteoblasts is known to be captured in the bone matrix and terminally differentiated into osteocytes, followed by the mineralizing process
While the osteocytes are reported to be aligned in the direction along the longitudinal axis of the bone with cellular processes parallel to the surface of the trabecular bone[7], the key factors or mechanisms of this cellular alignment in the bone matrix remain unknown
Summary
Osteocytes differentiated from osteoblasts play significant roles as mechanosensors in modulating the bone remodeling process. The cells actively migrated inside the collagen matrix and promoted the expression of osteoblast and osteocyte genes with their orientations aligned along the uniaxially-fixed boundary condition. Osteocytes are the most abundant cells in the bone and perform a unique function as the commander in sensing changes in the mechanical environment[1,2] They are known to control remodeling activities, including bone resorption by osteoclasts and bone formation by osteoblasts[3,4]. Using this collagen-based system, we evoked cellular alignment and migration of osteoblast-like cells in the collagen matrix with the induction of osteogenesis and shed light on the mechanism of the formation of the aligned osteocytes in the bone matrix
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