Bone is one of the most highly adaptive tissues in the body, possessing the capability to alter its morphology and function in response to stimuli in its surrounding environment. The ability of bone to sense and convert external mechanical stimuli into a biochemical response, which ultimately alters the phenotype and function of the cell, is described as mechanotransduction. This review aims to describe the fundamental physiology and biomechanisms that occur to induce osteogenic adaptation of a cell following application of a physical stimulus. Considerable developments have been made in recent years in our understanding of how cells orchestrate this complex interplay of processes, and have become the focus of research in osteogenesis. We will discuss current areas of preclinical and clinical research exploring the harnessing of mechanotransductive properties of cells and applying them therapeutically, both in the context of fracture healing and de novo bone formation in situations such as nonunion. Cite this article: Bone Joint Res 2019;9(1):1–14

The expression of the mechanosensor, integrin αvβ3, is reduced in osteoporotic bone cells compared to controls. MLO-Y4 osteocytes experience altered mechanotransduction under estrogen deficiency and it is unknown whether this is associated with defective αvβ3 expression or signalling. The objectives of this study are to (1) investigate αvβ3 expression and spatial organisation in osteocytes during estrogen deficiency, and (2) establish whether altered responses of osteocytes under estrogen deficiency correlate to defective αvβ3 expression and functionality. MLO-Y4 cells were cultured as follows: Ctrl (no added estradiol), E+ (10nM 17β-estradiol for 5 days), and Ew (10nM 17β-estradiol for 3 days and withdrawal for 2 days). Cells were cultured with/without 0.5µM IntegriSense750 (αvβ3 antagonist). Laminar oscillatory fluid flow of 1Pa at 0.5Hz was applied for 1hr. αvβ3 content was quantified using an ELISA. The location and quantity of αvβ3 and focal-adhesions was determined by immunocytochemistry. Estrogen withdrawal under static conditions led to lower cell and focal-adhesion area (p<0.05), compared to E+ cells. Fluid flow led to higher αvβ3 content (p<0.05) in all groups, compared to static counterparts, with αvβ3 blocking altering this response. Fluid flow on Ew cells had the highest αvβ3 levels (p<0.05), but αvβ3 did not localise at focal-adhesions sites. Cell morphologies were similar after treatment with the αvβ3 antagonist to the Ew group. These results suggest there are fewer functional focal-adhesion sites at which αvβ3 integrins localise to facilitate mechanotransduction. To further understand these results, we are analysing osteocyte mechanotransduction by quantifying PGE2 and gene expression (COX-2, RANKL, OPG, SOST)

During in vitro sub-culturing, tenocytes lose their phenotype which ultimately affects their functioning. As spindle-shaped fibroblasts, tenocytes have a unique thin elongated phenotype and they possess more spread-out shape through phenomena named dedifferentiation1. Given the link between cell shape and cell function, in this study, we first aimed to dedifferentiate tenocytes through in vitro sub-culturing in order to have a model system for dedifferentiation. For this, we isolated human flexor tendon cells from healthy female flexor digitorum longus and seeded at 5000 cells/cm² cell density, passaged every two days for six passages. In order to assess cell phenotype, we fixed with 4% paraformaldehyde and stained with phalloidin and DAPI to visualize the actin cytoskeleton and DNA respectively. We noted that in each passage, cells lost their spindle-shaped phenotype and became more pancake-shaped. At passage 1 and 2, the main cell phenotype is spindle-shaped. However, as the cells are further passaged, the phenotype of the cell population becomes more heterogeneous and at passage 5 and 6, they already display a more spread-out shape. Based on these results, we further hypothesized that they can be re-differentiated through matrix-mediated mechano-transduction and regain their morphology and function. For this aim, we generated decellularized tendon from porcine Achilles tendon and setup a mechanical loading system where we can provide mechanical loadings at physiological levels. This system will provide a new approach on in vitro tenocyte culturing.

Introduction

Mechanical loading has been hypothesized to play an important role in the development, remodeling and in diseases of many skeletal tissues, including cartilage. In order to study the metabolic response of cartilage to physical forces, in vitro systems have often been used because of the precise control with which mechanical loads can be applied. We developed a new mechanical loading system, in which we were able to load the intact femoral condyle in order to preserve the native cartilage/subchondral bone structure. This system represents a more ‚in vivo‘ situation than cartilage explants or chondrocyte cell culture systems.

Our approach focused on changes in mRNA expression of type II collagen, type VI collagen, and aggrecan in loaded versus adjacent unloaded cartilage in order to analyse the early response of chondrocytes to well-defined mechanical stresses.

Methods

Femoral condyles were obtained from two-year-old cows. The integrity of the cartilage surface was controlled by staining with safranin O. The femoral condyles were compressed in an Instron 8501 material testing machine. Cyclic compression pressure was applied for 2000 cycles in a sinusoidal waveform of 0. 5 Hz-frequency with a peak stress of 0. 2 to12. 5 MPa. Following loading, full depth cartilage sections were cut out and one half immediately frozen in liquid nitrogen for RNA isolation and the other half soaked in 4% paraformaldehyde for paraffin embedding. As control, the adjacent unloaded cartilage was collected and treated in the same way. Total RNA was isolated and changes in mRNA expression were quantitated by competitive quantitative PCR, using an internal standard of a C-terminal truncated version of the corresponding genes. The PCR-reactions were separated by agarose gel electrophoresis and amplified fragments quantified using video-densitometry analysis. The results were expressed as the ratio of mRNA from loaded to unloaded cartilage

Results

Cyclic compression with peak stresses of 12. 5, 6. 3, 2. 5 and 0. 6 MPa lead to a two-fold decrease in the mRNA expression of type II collagen and aggrecan and a threefold decrease of type VI collagen, in consideration of the intra-assay variability of about 30%. Compression with peak stresses of 0. 3 and 0. 2 MPa lead to a three-fold increase of the mRNA expression of type II collagen, a four-fold increase of aggrecan and a slight decrease of type VI collagen.

Low compression strength leads to an increase of the mRNA expression of the major components of cartilage, type II collagen and aggrecan, whereas high loading leads to a decrease of the mRNA expression.

Conclusion

The results show that our system can be used to analyze early responses of chondrocytes to well-defined mechanical stresses in an intact cartilage/bone-system and therefore will enable us to investigate the role of physiological and non-physiological high loading on the induction of cartilage degradation and regeneration in joint trauma and osteoarthritis. Since the cartilage/bone samples are incubated in medium during the experiment, this system will also offer us the opportunity to investigate additives to the medium as potential pharmacological therapeutics in osteoarthritis.

Distal arthrogryposis (DA) is a collection of rare developmental disorders characterized by congenital joint contractures. Most arthrogryposis mutations are in muscle- and joint-related genes, and the anatomical defects originate cell-autonomously within the musculoskeletal tissues. However, gain-of-function (GOF) mutations in PIEZO2, a principal mechanosensor in somatosensation, cause DA subtype 5 via unknown mechanisms. We show that expression of a GOF PIEZO2 mutation in proprioceptive sensory neurons mainly innervating muscle spindles and tendons is sufficient to induce DA5-like phenotypes in mice. Overactive PIEZO2 causes anatomical defects via increased activity within the peripheral nervous system during postnatal development. Surprisingly, overactive PIEZO2 is likely to cause joint abnormalities via increased exocytosis from sensory neuron endings without involving motor circuitry. This reveals a role for somatosensory neurons: excessive mechanosensation within these neurons disrupts musculoskeletal development. We also present proof-of-concept that Botox injection or dietary treatment can counteract the effect of overactive PIEZO2 function to evade DA-like phenotypes in mice when applied during a developmental critical period. These approaches might have clinical applications. Beyond this, our findings call attention to the importance of considering sensory mechanotransduction when diagnosing and treating other musculoskeletal disorders. Acknowledgements: Our work is supported by National Institutes of Health grant (R35 NS105067, R01 DE022358, R25 SC3GM127195, R25 GM07138, R01GM133845, intramural) and Howard Hughes Medical Institute

Stimulation of the mechanosensitive ion channel, Piezo1 promotes bone anabolism and SNPs in the Piezo1 locus are associated with changes in fracture risk. Osteocytes function as critical regulators of bone homeostasis by sensing mechanical signals. The current study used a human, cell-based physiological, 3D in vitro model of bone to determine whether loading of osteocytes in vitro results in upregulation of the Piezo1 pathway. Human Y201 MSCs, embedded in type I collagen gels and differentiated to osteocytes for 7-days, were subjected to pathophysiological load (5000 µstrain, 10Hz, 5 mins; n=6) with unloaded cells as controls (n=4). RNA was extracted 1-hr post load and assessed by RNAseq analysis. To mimic mechanical load and activate Piezo1, cells were differentiated to osteocytes for 13 days and treated ± Yoda1 (5µM, 2- and 24-hs, n=4); vehicle treated cells served as controls (n=4). RNA was subjected to RT-qPCR and data normalised to the housekeeping gene, YWHAZ. Media was analysed for IL6 release by ELISA. Mechanical load upregulated Piezo1 gene expression (16.5-fold, p<0.001) and expression of the transcription factor NFATc1, and matricellular protein CYR61, known regulators of Piezo1 mechanotransduction (3-fold; p= 5.0E-5 and 6.8-fold; p= 6.0E-5, respectively). After 2-hrs, Yoda1 increased the expression of the early mechanical response gene, cFOS (11-fold; p=0.021), mean Piezo1 expression (2.3-fold) and IL-6 expression (103-fold, p<0.001). Yoda1 increased the release of IL6 protein after 24 hours (7.5-fold, p=0.001). This study confirms Piezo1 as an important mechanosensor in osteocytes. Piezo1 activation mediated an increase in IL6, a cytokine that drives inflammation and bone resorption providing a direct link between mechanical activation of Piezo1, bone remodeling and inflammation, which may contribute to mechanically induced joint degeneration in diseases such as osteoarthritis. Mechanistically, we hypothesize this may occur through promoting Ca2+ influx and activation of the NFATc1 signaling pathway

Introduction. Fusion represents an effective treatment option in patients affected by end-stage arthritis. To minimise the risk of non-union following fusion, biological preparations such as bone marrow aspirate concentrate (BMAC) are commonly used intra-operatively. Mechanotransduction represents an emerging field of research whereby physical stimuli can be used to modulate the behaviour and differentiation of cells. Blast waves (a subtype of shock waves) are one such physical stimulus. The aim of this study was to investigate whether the osteogenic potential of BMAC can be enhanced using a blast wave, and thus improve its efficacy in fusion surgery. Methods. Human BMAC samples were obtained from three healthy patients and exposed to a single blast wave (peak overpressure= 50psi), before being placed in a suspension of mesenchymal stem cells, to represent the biological environment of the fusion site. Three test groups were used: MSC (the experimental control); MSC + BMAC; MSC + BMAC + blast wave. Calcium mineralisation assays were performed on the MSCs on Day 7 and 14 to assess for osteoblastic transformation. Results. Calcium mineralisation on Day 7 was significantly increased in the MSC + BMAC group compared to the MSC group (mean percentage change 42.12 vs 0.0, p=0.012). The MSC + BMAC + blast wave group also demonstrated significantly increased levels compared to the MSC + BMAC group (84.56 vs. 42.14, p = 0.039). The difference in calcium mineralisation between the MSC and MSC + BMAC + blast wave groups was strongly significant (0.00 vs. 84.56, p = 0.003). Conclusion. Exposure of BMAC to a single blast wave enhances its osteogenic potential. This represents a potential novel way to improve healing following fusion surgery and reduce the rates of non-union

Abstract. Objectives. Osteocytes function as critical regulators of bone homeostasis by sensing mechanical signals. Stimulation of the mechanosensitive ion channel, Piezo1 promotes bone anabolism and deletion of Piezo1 in osteoblasts and osteocytes decreases bone mass and bone strength in mice. This study determined whether loading of osteocytes in vitro results in upregulation of the Piezo1 pathway. Methods. Human MSC cells (Y201), embedded in type I collagen gels and differentiated to osteocytes in osteogenic media for 7-days, were subjected to pathophysiological load (5000 µstrain, 10Hz, 5 mins; n=6) with unloaded cells as controls (n=4). RNA was extracted 1-hr post load and Piezo1 activation assessed by RNAseq analysis (NovaSeq S1 flow cell 2 × 100bp PE reads). To mimic mechanical load and activate Piezo1, Y201s were differentiated to osteocytes in 3D gels for 13 days and treated, with Yoda1 (5µM, 2 hours, n=4); vehicle treated cells served as controls (n=4). Extracted RNA was subjected to RT-qPCR and data analysed by Minitab. Results. Low mRNA expression of PIEZO1 in unloaded cells was upregulated 5-fold following 1-hr of mechanical load (p=0.003). In addition, the transcription factor NFATc1, a known regulator of Piezo1 mechanotransduction, was also upregulated by load (2.4-fold; p=0.03). Y201 cells differentiated in gels expressed the osteocyte marker, SOST. Yoda1 upregulated PIEZO1 (1.7-fold; p=0.057), the early mechanical response gene, cFOS (4-fold; p=0.006), COL1A1 (3.9-fold; p=0.052), and IL-6 expression (7.7-fold; p=0.001). Discussion. This study reveals PIEZO1 as an important mechanosenser in osteocytes. Piezo 1 mediated increases in the bone matrix protein, type I collagen, and IL-6, a cytokine that drives inflammation and bone resorption. This provides a direct link between mechanical activation of Piezo 1, bone remodelling and inflammation, which may contribute to mechanically-induced joint degeneration in osteoarthritis. Mechanistically, we hypothesise this may occur through promoting Ca2+ influx and activation of the NFAT1 signalling pathway

Introduction. Hyaluronan (HA) is assumed to have a regulatory role in the bone remodelling process by influencing the behaviour of mesenchymal stem cells (MSCs), osteoblasts and osteoclasts. The hyaluronan synthases (HAS1, HAS2 and HAS3) which are responsible for the formation of HA are expressed in human MSCs (hMSCs). Although HAS are only active when they are located in the plasma membrane and an intracellular storage pool of the HAS is assumed, the mechanisms controlling the intracellular traffic of HAS are hardly investigated. Since chitin synthases and cellulose synthases, members of the same enzyme family like the HAS, are regulated by interaction with the cytoskeleton, we hypothesize that HAS interrelate somehow with the cytoskeleton and that their expression, their transport and/or their activity are regulated via mechanotransduction. Methods and Results. We generated immortalized hMSCs (SCP-1) constitutively expressing eGFP-tagged HAS by lentiviral gene transfer (SCP1-HAS1-eGFP, SCP1-HAS2-eGFP and SCP1-HAS3-eGFP). The expression of the transgene HAS was verified by RT-PCR, western blot, FACS analysis and direct fluorescence microscopy or immunofluorence. The enzymatic activity of the transgene HAS was determined by HA-ELISA and by staining of HA. hMSCs expressing lifeact-RFPruby and HAS-eGFP were investigated in a video timelapse analysis in order to study the putative interaction of HAS-eGFP with the actin cytoskeleton. The HAS-eGFP proteins are globular structured and aligned along the actin filaments. The timelapse pictures show that the HAS-eGFP moves without loss of their alignment to actin. In addition we investigated the impact of shear stress on hMSCs under defined flow conditions. The upregulation of the expression levels of the three HAS isoforms was shown by quantitative real time RT-PCR after exposure to the stimulus. Discussion. Here, we were able to show the regulation of HAS expression via mechanotransduction. At the moment we investigate if HAS activity and their transport towards the plasma membrane are changed by shear stress. Furthermore we generate hMSCs expressing eGFP tagged HAS in their active form. We have first hints for an interaction of the transgene HAS with the actin cytoskeleton. Our cells can be used for further investigation of the functional and regulatory role of HAS in the bone microenvironment. In some bone diseases such as osteogenesis imperfecta, multiple myeloma and osteoporosis, the HA content in the bone or HAS expression in the hMSCs are changed. Understanding the role of HA in bone regeneration and the regulatory mechanisms of HAS in the hMSCs will provide therapeutic starting points for an improved fracture healing in patients suffering from one of these bone diseases

Tendon injuries are a worldwide problem affecting several age groups and stem cell based therapies hold potential for tendon strategies guiding tendon regeneration. Tendons rely on mechano-sensing mechanisms that regulate homeostasis and influence regeneration. The mechanosensitive receptors available in cell membranes sense the external stimuli and initiate mechanotransduction processes. Activins are members of the TGF-β superfamily which participate in several tendon biological processes. It is envisioned that the activation of the activin receptor, trigger downstream Smad2/3 pathway thus regulating the transcription of tenogenic genes driving stem cell differentiation. In this work, we propose to target the Activin receptor type IIA (ActRIIA) in human adipose stem cells (hASCs), inducing hASCs commitment towards the tenogenic lineage. Since mechanotransduction can be remotely triggered through magnetic actuation combined with magnetic nanoparticles (MNPs), we stimulated hASCs tagged complexes using a vertical oscillating magnetic bioreactor (MICA Biosystems Ltd). Carboxyl functionalised MNPs (Micromod) were coated with anti-ActRIIA antibody (Abcam) by carbodiimide activation. hASCs were then cultured with MNPs-anti-ActRIIA for 14days with or without magnetic exposure (1Hz, 1h/every other day). hASCs cultured alone in αMEM (negative control) or in αMEM supplemented with ActivinA (R&D systems) (positive control of ActRIIA activation) were used as experimental controls. The tenogenic commitment of hASCs was assessed by real time RT-PCR, immunocytochemistry and quantification of collagen and non-collagenous proteins. Moreover, the phosphorylation of Smad2/3 was also evaluated on hASCs incubated for 2, 10, or 30min under magnetic stimulated (1Hz) and non-stimulated conditions. The increased gene expression of tendon related markers and higher ECM proteins deposition suggests that remote magnetic activation of ActRIIA promotes effectively hASCs tenogenic commitment. Furthermore, the detection of phospho-Smad2/3 proteins by ELISA (Cell Signaling Technology) was significantly more intense after 10min in hASCs under magnetic stimulation and in comparison to the control groups. These outcomes suggest that ActRIIA is a mechanosensitive receptor that can be remotely activated upon magnetic stimulation. In conclusion, remotely activation of MNPs tagged hASCs has potential for modulating tenogenic differentiation of stem cells envisioning successful cell therapies for tendon regeneration. Acknowledgements. FCT/MCTES PD/59/2013 (fellowship PD/BD/113802/2015), FCT post-doctoral grant SFRH/BPD/111729/2015, FCT grant IF/00685/2012, and EU-ITN MagneticFun

The concept that fluid percolating through bone matrix is the basis for mechanotransduction of stress stimuli to modeling and remodeling has proved challenging. 4. Traditional solid mechanical models in which piezoelectricity is the mechanotransduction process are more intuitive to orthopaedic practitioners nurtured on the fundamentalism of Wolff’s “Law”. However, the scientific evidence from Anderson and Ericksson. 1. , Piekarski and Munro. 5. , and Hillsley and Frangos. 3. strongly support a bone fluid flow (BFF) paradigm, which, when coupled with the Utah paradigm of Frost. 2. forms the most scientifically validated explanation to date of osteon response to mechanical stress in vivo. In order to make this explanation more intuitive we have developed a metaphorical rendering of the model. The rendering adds an extension to include our current model for the effects of skeletal muscle contraction on the basic multicellular unit (BMU). In the metaphor, cortical bone is the continent nation HaroldFrostland. Its cities are fed by waterways which serve as metaphors for each of the fluid transporting pathways from arteries to inter-collagen spaces of bone matrix. Bounding the continent are oceans wherein underwater earthquakes—metaphors for skeletal muscle contractions—generate solitary pressure waves (tsunamis) and a ripple effect in continental waterways. Critical for penetration by and effectiveness of such solutions is that flow resistance in the waterways must allow pressure buildup. Locks/valves serve to provide this resistance. When pressure is sufficient filtration at transfer points—metaphors for where nutrient exchange occurs--is enhanced. By this means, muscle contraction enhances delivery of fluid not only to bone cells; but around them as well, stimulating mechanotransduction

Adherent cells are known to respond to physical characteristics of their surrounding microenvironment, adapting their cytoskeleton and initiating signaling cascades specific to the type of cue encountered. Scaffolds mimicking native biophysical cues have proven to differentiate stem cells towards tissue-specific lineages and to maintain the phenotype of somatic cells for longer periods of time in culture. Biomaterial-based tendon implants are designed to withstand high physiological loads but often lack the appropriate biochemical, biophysical and biological structure to drive tendon regeneration by populating cells. The objective of this study is to use tendon main component, collagen type I, to create scaffolds that reproduce tendon natural anisotropy and rigidity, in an effort to engineer functional tendon tissue with native organization and strength, able to maintain tenocyte phenotype and to differentiate stem cells towards the tenogenic lineage. Porcine collagen type I in solution was treated with one of the following cross-linkers: glutaraldehyde, genipin or 4-arm polyethylene glycol (4SP). The resulting mixture was poured on micro-grooved (2×2×2 um) or planar PDMS moulds and air-dried to obtain 5 mg/ml collagen films. Surface topography and elastic modulus were analyzed using SEM/AFM and rheometry, respectively. Human tendon cells were cultured on the micro-grooved/planar scaffolds for up to 10 days. Cell morphology, collagen III and tenascin C expression were analyzed by immunocytochemistry. Among the different cross-linkers used, only the treatment with 4SP resulted in scaffolds with a recognizable micro-grooved surface topography. Precise control over the micro-grooved topography and the rigidity of the scaffolds was achieved by cross-linking the collagen with varying concentrations of 4SP (0, 0.5, 1 and 1.5mM) at low pH and temperature. The elastic modulus of the scaffolds cross-linked with 4SP (0.5mM) matched the values previously reported to induce tenogenic differentiation in stem cells (50–90 kPa). Approximately eighty percent of the human tendon cells cultured on the micro-grooved collagen films aligned in the direction of the anisotropy for 10 days in culture, mimicking the alignment of tenocytes in the native tissue. Cell nuclei morphology, known to play a central role in the process of mechanotransduction, was significantly more elongated for the tenocytes cultured on the micro-grooved scaffolds after 4 days in culture for all the 4SP concentrations. Synthesis, deposition and alignment of collagen III and tenascin C, two important tenogenic markers, were up regulated selectively on the micro-grooved and rigid scaffolds after 10 days in culture, respectively. These results highlight the synergistic effect of matrix rigidity and cell alignment on tenogenic cell lineage commitment. Collectively, this study provides new insights into how collagen can be modulated to create scaffolds with precise imprinted topographies and controlled rigidities

Introduction. The hierarchical structure of tendon results in a complex mechanical strain environment, with tenocytes experiencing both tension and shear during loading. The mechanotransduction mechanisms involved in sensing these environments is currently unclear. To better understand the effects of shear and tension on cell behaviour, a fibre composite system able to recapitulate the physiological shear-tension ratio found in tendons, was used. Cell attachment within the composite was achieved by using either a collagen type I mimetic peptide, DGEA, or a fibronectin associated peptide, YRGDS, and the gene expression response analysed after loading. Materials and Methods. Fibre composites with 4 different shear-tension (S-T) ratios were made using both PEG-DGEA and PEG-YRGDS fibres. 4 composites were made for each S-T ratio, of which 2 were loaded and 2 used as non-strained controls. Bovine digital extensor tendon tenocytes were seeded within composites, with 3 biological repeats from different donors. Loaded samples were exposed to 5% cyclic strain (1Hz) for 24 hours maintained in an incubator. The gene expression of 14 matrix related genes were analysed after loading via RT-qPCR. Results. Tenocytes seeded on PEG-DGEA fibres were more mechano-sensitive than those seeded on PEG-YRGDS fibres; tenocytes in PEG-DGEA composites exhibited upregulation of COL-3, MMP-3 and IL-6, and downregulation of SCX with shear, while tenocytes in PEG-YRGDS composites downregulated TIMP-3 with shear. Discussion. The main integrin involved in DGEA binding is α2β1 while the integrins associated with YRGDS attachment include α5β1, αVβ3 and αIIbβ3. Consequently, the findings of this study emphasise the importance of integrins in the role of mechanotransduction, and suggest integrins involved in collagen type I binding induce functionally different responses in tenocytes to those not involved in collagen type I binding when sensing mechanical stimuli comprised of shear and tension. This information is critical in future studies investigating tenocyte behaviour and tissue engineering approaches, as physiological integrin binding may be key in maintaining normal tenocyte pathways

Osteoarthritis (OA) is the most common joint disease, which is characterized by a progressive loss of proteoglycans and the destruction of extracellular matrix (ECM), leading to a loss of cartilage integrity and joint function. During OA development, chondrocytes alter ECM synthesis and change their gene expression profile including upregulation of hypertrophic markers known from the growth plate. Although physiological mechanical loading can support cartilage formation and maintenance, mechanical overload represents one major risk factor for OA development. To date, little is known on how an OA-like hypertrophic chondrocyte phenotype alters the response of cartilage tissue to mechanical loading. The aim of this study was to investigate whether a hypertrophic phenotype change of chondrocytes affects the response to physiological mechanical loading and to reveal differences compared to normal control cartilage. Cartilage replacement tissue was generated using human articular chondrocytes (normal control cartilage, n=3–5) or human mesenchymal stromal cells which develop a hypertrophic phenotype similar to the one observed in OA (OA cartilage model, n=3–6). Cells were seeded in a collagen type I/III carrier and attached to a beta-TCP bone replacement phase, building an osteochondral unit for simulation of natural conditions. After 21 and 35 days of chondrogenic (re)differentiation, a single physiological mechanical compression episode (1 Hz, 25 %, 3 h) was applied, imitating three hours of normal walking in ten-minute intervals. Proteoglycan and collagen synthesis, gene expression and activation of signaling pathways were assessed. Cartilage replacement tissue of both groups had similar proteoglycan and collagen type II content as well as hardness properties. During (re)differentiation, both cell types showed a comparable upregulation of the chondrogenic marker genes COL2A1 and ACAN. As expected, hypertrophic marker genes (COL10A1, ALPL, MEF2C, IBSP) were only upregulated in the OA cartilage model. Mechanotransduction in both tissues was confirmed by load-induced activation of pERK1/2 signaling. While the 3 h loading episode significantly increased proteoglycan synthesis in normal control cartilage at day 35, the same protocol resulted in a suppression of proteoglycan and collagen synthesis in the OA cartilage model, which was accompanied by a downregulation of COL2A1 gene expression. In addition, hypertrophic marker genes COL10A1, ALPL and IBSP were significantly reduced after loading. Along lower load-induced SOX9 mRNA and protein stimulation in the OA cartilage tissue, a weaker induction of mechanosensitive BMP2, BMP6, FOS and FOSB gene expression was observed. While stable cartilage showed anabolic effects after physiological loading, the hypertrophic chondrocytes reacted with a reduced extracellular matrix synthesis. This could be explained by a lower mechanoinduction of the BMP signaling cascade and insufficient SOX9 stimulation. Progressive OA development could thus be influenced by a reduced mechanocompetence of osteoarthritic chondrocytes

Construction of a functional skeleton is accomplished through co-ordination of the developmental processes of chondrogenesis, osteogenesis, and synovial joint formation. Infants whose movement in utero is reduced or restricted and who subsequently suffer from joint dysplasia (including joint contractures) and thin hypo-mineralised bones, demonstrate that embryonic movement is crucial for appropriate skeletogenesis. This has been confirmed in mouse, chick, and zebrafish animal models, where reduced or eliminated movement consistently yields similar malformations and which provide the possibility of experimentation to uncover the precise disturbances and the mechanisms by which movement impacts molecular regulation. Molecular genetic studies have shown the important roles played by cell communication signalling pathways, namely Wnt, Hedgehog, and transforming growth factor-beta/bone morphogenetic protein. These pathways regulate cell behaviours such as proliferation and differentiation to control maturation of the skeletal elements, and are affected when movement is altered. Cell contacts to the extra-cellular matrix as well as the cytoskeleton offer a means of mechanotransduction which could integrate mechanical cues with genetic regulation. Indeed, expression of cytoskeletal genes has been shown to be affected by immobilisation. In addition to furthering our understanding of a fundamental aspect of cell control and differentiation during development, research in this area is applicable to the engineering of stable skeletal tissues from stem cells, which relies on an understanding of developmental mechanisms including genetic and physical criteria. A deeper understanding of how movement affects skeletogenesis therefore has broader implications for regenerative therapeutics for injury or disease, as well as for optimisation of physical therapy regimes for individuals affected by skeletal abnormalities. Cite this article: Bone Joint Res 2015;4:105–116

Introduction. Low back pain is a major public health problem in our society. Degeneration of intervertebral disc (IVD) appears to be the leading cause of chronic low-back pain [1]. Mechanical stimulations including compressive and tensional forces are directly implicated in IVD degeneration. Several studies have implicated the cytoskeleton in mechanotransduction [2, 3], which is important for communication and transport between the cells and extracellular matrix (ECM). However, the potential roles of the cytoskeletal elements in the mechanotransduction pathways in IVD are largely unknown. Methods. Outer annulus fibrosus (OAF) and nucleus pulposus (NP) cells from skeletally mature bovine IVD were either seeded onto Flexcell¯ type I collagen coated plates or seeded in 3% agarose gels, respectively. OAF cells were subjected to cyclic tensile strain (10%, 1Hz) and NP cells to cyclic compressive strain (10%, 1Hz) for 60 minutes. Post-loading, cells were processed for immunofluorescence microscopy and RNA extracted for quantitative PCR analysis. Results. F-actin reorganisation was evident in OAF and NP cells subjected to tensile and compressive strain respectively and is likely due to load-induced differential mRNA expression of actin-binding proteins. The vimentin network was also more intricately organised in loaded NP cells. Compressive strain increased type II collagen and aggrecan transcription in NP cells, whereas levels decreased in OAF cells under tension. mRNA levels of ECM-degrading enzymes were significantly reduced in both cell populations after loading. Conclusion. Tensile and compressive strains induce different mechano-responses in the organisation/expression of cytoskeletal elements and on markers of IVD metabolism. Differential mechano-regulation of anabolic and catabolic ECM components in the OAF and NP populations reflects their respective mechanical environments in situ

Purpose and Background. The intervertebral disc is constantly subjected to forces generated by movement. But degeneration can disrupt normal biomechanics, generating uneven and complex loading patterns. Evidence suggests that these forces are converted into voltages through different mechanisms, such as streaming potentials. This implicates voltage-gated ion channels in the biological remodelling response of the disc to loading. These signalling pathways have not been studied, and this incomplete understanding of disc mechanotransduction may hinder regenerative therapies. The purpose of this study is to identify and determine the role of voltage-gated ion channels in the intervertebral disc and to investigate any changes in degeneration. Methods and Results. Primary bovine and human disc cells were cultured in monolayer or alginate beads for experiments. Cells were treated with altered osmolarity alone or in combination with IL-1β. Ion flux was measured through calcium influx and will be further investigated using the xCelligence RTCA CardioECR. Immunohistochemistry was performed on human and bovine discs to evaluate expression levels of ion channels. RNA was extracted from bovine NP cells and will be analysed through PCR/Microarray for gene expression. Conclusions. Preliminary results show that the Ca. v. 2.2 channel is expressed across the human disc, and is altered by degree of degeneration. Treatment with IL-1β may partly hinder the increase in calcium signalling of disc cells in response to lower osmolarity conditions. The presence of voltage-gated ion channels in the disc has been demonstrated for the first time. The role of these channels will be investigated through measuring ion flux with channel inhibitors across different culture treatments. No conflicts of interest exist. This research was supported by funding from the Society for Back Pain Research through the Travel Award 2019 and from the Irish Research Council under the Government of Ireland Postgraduate Scholarship Programme (GOIPG/2018/2416)

While the phenomena of bone adaption to mechanical loading has been long observed, the mechanisms governing bone mechanotransduction during health and disease are not well understood. Our multidisciplinary experimental and computational research strives to enhance understanding of bone mechanobiology, and in particular how this process is affected at the onset of osteoporosis. We have provided an enhanced understanding of bone cell mechanosensation. We have characterised the local mechanical environment of MSCs, osteoblasts and osteocytes in vivo. Most importantly, we have discovered that the matrix composition, expression of mechanosensors and the mechanical environment of osteocytes is altered during osteoporosis. Interestingly, a mechanobiological response restores the homeostatic mechanical environment of the cells in the longer term. Our recent in vitro studies have revealed that estrogen withdrawal from bone cells alters calcium signalling, mineralisation, biochemical responses and osteogenic gene expression when these cells are exposed to an applied fluid shear stress. Our ongoing research is investigating mechanobiology-based therapeutic approaches for treatment of bone pathologies, by (1) targeting mechanoregulatory signalling pathways and (2) developing in vitro tissue regeneration strategies that seek to optimise the mechanical environment (through matrix stiffness, bioreactors) to stimulate osteogenesis

Osteoporosis affects millions globally and current anti-catabolic treatments are limited by significant side-effects. Osteoporosis arises when skeletal stem cells (SSC) no longer sufficiently replenish osteoblasts, leading to net bone loss. A key regulator of SSC behaviour is physical loading, yet the mechanisms by which SSCs sense and respond to changes in their mechanical environment are virtually unknown. Primary cilia are nearly ubiquitous ‘antennae-like’ cellular organelles that have very recently emerged as extracellular chemo/mechano-sensors and thus, are strong candidates to play an important role in regulating SSC responses in bone. This paper will demonstrate that the SSC primary cilium plays an important role in loading-induced bone formation via initial chemosensation and transduction of the potent chemokine TGFβ1 regulating SSC recruitment to the bone surface and secondly it will be shown that the primary cilium is a cAMP responsive mechanosensor directly regulating SSC mechanotransduction via localisation of adenylyl cyclase 6 to the ciliary microdomain. Finally, it will be shown that targeting the cilium therapeutically can be an effective approach to enhance both biochemical and biophysically induced SSC osteogenesis contributing to bone formation, demonstrating a novel anabolic therapy for bone loss diseases such as osteoporosis

Summary. This study helps to elucidate how ColVI and Dcn within the pericellular matrix (PCM) of differentiating hMSCs directly impacts dynamic cytoskeletal response to load, and demonstrates an important role for the PCM in mechanotransduction during chondrogenesis. Introduction. Mechanosignaling events in differentiating human mesenchymal stem cells (hMSCs) are dependent on their temporally changing micromechanical environment and their dynamic cytoskeleton. During chondrogenic differentiation, hMSCs develop a matrix composed of type VI collagen (ColVI) and proteoglycans such as decorin (Dcn). We have previously demonstrated that this developing PCM is important in cellular mechanotransduction. The aim of this study was to determine the functional roles of ColVI and Dcn in modulating load-induced changes in the organization of vimentin intermediate filaments (VIF), actin microfilaments (AM), and vinculin. Methods. hMSCs were transduced with shRNA targeting either col6a1 (shColVI) or dcn (shDcn) and then cultured in 2% alginate beads for 14 days in chondrogenic media. GFP-transduced hMSCs were cultured in parallel. Cells with their intact PCM were isolated with 100mM sodium citrate, 30mM EDTA, and re-embedded in alginate discs. These hMSC-alginate constructs underwent unconfined compression at 0.1Hz for 1 hour from 0–10% strain. Free Swelling (FS) and loaded discs were fixed either immediately following (0hr) or 4 hours post-load. Discs were cryosectioned and fluorescently labeled for VIF, AM, or vinculin with DAPI counterstain. Confocal image-stacks were collected and corrected total cell fluorescence (CTCF) per area was calculated using ImageJ (NIH) to quantify cytoskeletal organization. Results. VIF fluorescence showed a dynamic cytoskeletal response to load in non-infected and GFP-transduced controls with an increase in intensity. In both ColVI and Dcn knockdown groups, VIF exhibited higher fluorescence in FS, which then didn't significantly change following load, possibly due to its higher baseline concentration. AM showed a similar response to load in shColVI knockdown samples, with a significantly higher intensity in FS samples, which wasn't affected by loading and remained cortically localised in all samples. In shDcn samples, there was a significant increase in actin content immediately following load, similar to control. Vinculin staining showed significantly lower staining intensity in shColVI knockdown samples than non-infected and GFP-transduced samples at all timepoints, and exhibited a different trend in response to loading. Following loading, vinculin was diffusely stained across the cytoskeleton in all samples. Discussion. This study demonstrates through targeted shRNA knockdown that the involvement of ColVI and Dcn in mechanosignaling events of differentiating hMSCs could be due to their interactions with and control over the dynamic cytoskeleton. Vimentin and actin have previously been shown to contribute to the viscoelastic mechanical properties of hMSCs and are important in the ability for cells to resist load. Our experiments indicate that specific components in the PCM can affect cytoskeletal dynamics, with knockdown samples lacking the significantly dynamic response to load seen in control samples. Actin cytoskeletal intensity and vinculin intensity show an inverse relationship to load. Since vinculin mediates interactions between actin cytoskeleton and integrins at focal adhesions, these data suggest that ColVI and Dcn regulation of cytoskeletal response may be governed more by the changing external micromechanical environment, rather than altered cell-matrix interactions. Further studies are needed to elucidate the roles of ColVI and Dcn in downstream intracellular mechanosignaling events of differentiating hMSCs