Laoise M. McNamara scite author profile

Mesenchymal stem cells (MSCs) within their native environment of the stem cell niche in bone receive biochemical stimuli from surrounding cells. These stimuli likely infl uence how MSCs differentiate to become bone precursors. The ability of MSCs to undergo osteogenic differentiation is well established in vitro; however, the role of the natural cues from bone's regulatory cells, osteocytes and osteoblasts in regulating the osteogenic differentiation of MSCs in vivo are unclear. In this study we delineate the role of biochemical signalling from osteocytes and osteoblasts, using conditioned media and co-culture experiments, to understand how they direct osteogenic differentiation of MSCs. Furthermore, the synergistic relationship between osteocytes and osteoblasts is examined by transwell co-culturing of MSCs with both simultaneously. Osteogenic differentiation of MSCs was quantified by monitoring alkaline phosphatase (ALP) activity, calcium deposition and cell number. Intracellular ALP was found to peak earlier and there was greater calcium deposition when MSCs were co-cultured with osteocytes rather than osteoblasts, suggesting that osteocytes are more infl uential than osteoblasts in stimulating osteogenesis in MSCs. Osteoblasts initially stimulated an increase in the number of MSCs, but ultimately regulated MSC differentiation down the same pathway. Our novel coculture system confi rmed a synergistic relationship between osteocytes and osteoblasts in producing biochemical signals to stimulate the osteogenic differentiation of MSCs. This study provides important insights into the mechanisms at work within the native stem cell niche to stimulate osteogenic differentiation and outlines a possible role for the use of co-culture or conditioned media methodologies for tissue engineering applications.

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Biomimetic approaches in bone tissue engineering: Integrating biological and physicomechanical strategies

Fernández‐Yagüe

Abbah

McNamara

et al. 2015

Advanced Drug Delivery Reviews

435

316

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Bone mechanical properties and changes with osteoporosis

Osterhoff

Morgan

Shefelbine

et al. 2016

Injury

412

279

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A model for the role of integrins in flow induced mechanotransduction in osteocytes

Wang

McNamara

Schaffler

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

230

217

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A fundamental paradox in bone mechanobiology is that tissuelevel strains caused by human locomotion are too small to initiate intracellular signaling in osteocytes. A cellular-level strainamplification model previously has been proposed to explain this paradox. However, the molecular mechanism for initiating signaling has eluded detection because none of the molecules in this previously proposed model are known mediators of intracellular signaling. In this paper, we explore a paradigm and quantitative model for the initiation of intracellular signaling, namely that the processes are attached directly at discrete locations along the canalicular wall by ␤3 integrins at the apex of infrequent, previously unrecognized canalicular projections. Unique rapid fixation techniques have identified these projections and have shown them to be consistent with other studies suggesting that the adhesion molecules are ␣v␤3 integrins. Our theoretical model predicts that the tensile forces acting on the integrins are <15 pN and thus provide stable attachment for the range of physiological loadings. The model also predicts that axial strains caused by the sliding of actin microfilaments about the fixed integrin attachments are an order of magnitude larger than the radial strains in the previously proposed strain-amplification theory and two orders of magnitude greater than whole-tissue strains. In vitro experiments indicated that membrane strains of this order are large enough to open stretch-activated cation channels.bone mechanotransduction ͉ integrin attachments ͉ osteocyte cell process ͉ strain amplification ͉ bone fluid flow A fundamental paradox in bone biology is that tissue-level strains, which rarely exceed 0.1% in vivo (1, 2), are too small to initiate intracellular signaling in bone cells in vitro (3,4), where the necessary strains (typically 1.0%) would cause bone fracture. Osteocytes, the most abundant cells in adult bone, are widely believed to be the primary sensory cells for mechanical loading because of their ubiquitous distribution throughout the bone tissue and their dendritic interconnections with both neighboring osteocytes and osteoblasts (5, 6), but osteocytes also require high local strains for mechanical stimulation. You et al. (7) developed an intuitive strain-amplification model to explain this paradox wherein osteocyte processes are attached to the canalicular wall by transverse tethering elements in the pericellular matrix. According to this model, the drag generated by load-induced fluid flow through the pericellular matrix would create tensile forces along the transverse elements supporting the pericellular matrix. These resulting tensions then were transmitted by transmembrane proteins to the central actin filament bundle in the osteocyte cell process leading to circumferential expansion of the cell process. The basic structural features in this model, the transverse tethering elements, and the organization of the actin filament bundle in the dendritic cell process were shown experimentally by You et...

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Attachment of Osteocyte Cell Processes to the Bone Matrix

McNamara

Majeska

Weinbaum

et al. 2009

The Anatomical Record

179

170

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In order for osteocytes to perceive mechanical information and regulate bone remodeling accordingly they must be anchored to their extracellular matrix (ECM). To date the nature of this attachment is not understood. Osteocytes are embedded in mineralized bone matrix, but maintain a pericellular space (50-80 nm) to facilitate fluid flow and transport of metabolites. This provides a spatial limit for their attachment to bone matrix. Integrins are cell adhesion proteins that may play a role in osteocyte attachment. However, integrin attachments require proximity between the ECM, cell membrane, and cytoskeleton, which conflicts with the osteocytes requirement for a pericellular fluid space. In this study, we hypothesize that the challenge for osteocytes to attach to surrounding bone matrix, while also maintaining fluid-filled pericellular space, requires different ''engineering'' solutions than in other tissues that are not similarly constrained. Using novel rapid fixation techniques, to improve cell membrane and matrix protein preservation, and transmission electron microscopy, the attachment of osteocyte processes to their canalicular boundaries are quantified. We report that the canalicular wall is wave-like with periodic conical protrusions extending into the pericellular space. By immunohistochemistry we identify that the integrin avb3 may play a role in attachment at these complexes; a punctate pattern of staining of b3 along the canalicular wall was consistent with observations of periodic protrusions extending into the pericellular space. We propose that during osteocyte attachment the pericellular space is periodically interrupted by underlying collagen fibrils that attach directly to the cell process membrane via integrin-attachments. Anat Rec, 292:355-363, 2009. 2009

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