Specific inhibition of FAK signaling attenuates subchondral bone deterioration and articular cartilage degeneration during osteoarthritis pathogenesis

Osteoarthritis (OA), a disease of the entire joint, is characterized by abnormal bone remodeling and coalescent degradation of articular cartilage. We have previously found that elevated levels of H-type vessels in subchondral bone correlate with OA and that focal adhesion kinase (FAK) is critical for H-type vessel formation in osteoporosis. However, the potential role of FAK in OA remains unexplored. Here, we demonstrate that the p-FAK level was dramatically elevated in subchondral bone following anterior cruciate ligament transection (ACLT) in rats. Specific inhibition of FAK signaling with Y15 in subchondral bone resulted in the suppression of subchondral bone deterioration and this effect was mediated by H-type vessel-induced ectopic bone formation. Further, articular cartilage degeneration was also alleviated after Y15 treatment. In vitro, the p-FAK level was significantly elevated in mesenchymal stem cells (MSCs) from vehicle-treated ACLT rats as compared to that in MSCs from sham controls and Y15-treated ACLT rats. Elevated p-FAK level in MSCs promoted vascular endothelial growth factor (VEGF) expression, as demonstrated from the high VEGF level in the blood, subchondral bone, and conditioned medium (CM) of MSCs from vehicle-treated ACLT rats. The CM of MSCs from vehicle-treated ACLT rats might promote the angiogenesis of endothelial cells and the catabolic response of chondrocytes through the FAK-growth factor receptor-bound protein 2-mitogen-activated protein kinase-mediated expression of VEGF. The effect of the CM from MSCs of Y15-treated ACLT rats or that treated with a VEGF-neutralizing antibody on vessel formation and the catabolic response was lowered. Thus, the specific inhibition of FAK signaling may be a promising avenue for the prevention or early treatment of OA.     

Osteoblast recruitment to sites of bone formation in skeletal development,homeostasis, and regeneration

During endochondral bone development, bone‐forming osteoblasts have to colonize the regions of cartilage that will be replaced by bone. In adulthood, bone remodeling and repair require osteogenic cells to reach the sites that need to be rebuilt, as a prerequisite for skeletal health. A failure of osteoblasts to reach the sites in need of bone formation may contribute to impaired fracture repair. Conversely, stimulation of osteogenic cell recruitment may be a promising osteo‐anabolic strategy to improve bone formation in low bone mass disorders such as osteoporosis and in bone regeneration applications. Yet, still relatively little is known about the cellular and molecular mechanisms controlling osteogenic cell recruitment to sites of bone formation. In vitro, several secreted growth factors have been shown to induce osteogenic cell migration. Recent studies have started to shed light on the role of such chemotactic signals in the regulation of osteoblast recruitment during bone remodeling. Moreover, trafficking of osteogenic cells during endochondral bone development and repair was visualized in vivo by lineage tracing, revealing that the capacity of osteoblast lineage cells to move into new bone centers is largely confined to undifferentiated osteoprogenitors, and coupled to angiogenic invasion of the bone‐modeling cartilage intermediate. It is well known that the presence of blood vessels is absolutely required for bone formation, and that a close spatial and temporal relationship exists between osteogenesis and angiogenesis. Studies using genetically modified mouse models have identified some of the molecular constituents of this osteogenic–angiogenic coupling. This article reviews the current knowledge on the process of osteoblast lineage cell recruitment to sites of active bone formation in skeletal development, remodeling, and repair, considering the role of chemo‐attractants for osteogenic cells and the interplay between osteogenesis and angiogenesis in the control of bone formation. Birth Defects Research (Part C) 99:170–191, 2013. © 2013 Wiley Periodicals, Inc.     

Janus kinase inhibitors role in bone remodeling

Janus kinases (JAKs) play a pleiotropic role in several important physiological processes, such as cell maturation, cell proliferation, and cell death, via providing transmission signals from several molecules, such as cytokines, interferons, hormones, and growth factors, to the nucleus. Bone physiology and remodeling are markedly influenced by proinflammatory cytokines. Among them, interleukin-1 (IL-1) and IL-6 are considered potent stimulator of bone resorption. Several cytokine receptors, such as IL-6 receptors, are characterized by tyrosine kinases of the JAK family associated with their intracellular domains. There is an emerging interest in the effects of JAKs inhibition on the cells involved in bone remodeling. JAK inhibitors represent a new class of molecules involved in the therapy of numerous immune-mediated inflammatory diseases. In this review, we want to focus on the role of JAKs inhibitors on bone remodeling and on RANKL-RANK-OPG signal and inflammatory cytokines which are involved in the regulation of bone cells, such as osteoblasts and osteoclasts.     

Functional role of hedgehog pathway in osteoarthritis

The hedgehog signalling pathway is one of the key regulators of metazoan development, and it plays an important role in the regulation of a variety of developmental and physiological processes. But it is aberrantly activated in many human diseases, including osteoarthritis (OA). In this study, we have reviewed the association of hedgehog signalling pathway in the development and progression of OA and evaluated the efforts to target this pathway for the prevention of OA. Usually in OA, activation of hedgehog induces up-regulation of the expression of hypertrophic markers, including type X collagen, increases production of nitric oxide and prostaglandin E2, several matrix-degrading enzymes including matrix metalloproteinase and a disintegrin and metalloproteinase with thrombospondin motifs in human knee joint cartilage leading to cartilage degeneration, and thus contributes in OA. Targeting hedgehog signalling might be a viable strategy to prevent or treat OA. Chemical inhibitors of hedgehog signalling is promising, but they cause severe side effects. Knockdown of HH gene is not an option for OA treatment in humans because it is not possible to delete HH in larger animals. Efficient knockdown of HH achieved by local delivery of small interfering RNA in future studies utilizing large animal OA models might be a more efficient approach for the prevention of OA. However, it remains a major problem to develop one single scaffold due to the different physiological functions of cartilage and subchondral bones possess. More studies are necessary to identify selective inhibitors for efficiently targeting the hedgehog pathway in clinical conditions.     

Regulation of Osteoblast Gene Expression and Phenotype by Polylactide-fatty Acid Surfaces

Cell function is influenced by surface structure and molecules. Molecules that enhance cellular differentiation can be applied to tissue scaffold surfaces to stimulate endogenous tissue regeneration. The application of this approach to bone implants yields surfaces coated with factors (proteins, peptides, etc...) that promote the differentiation of osteoblasts, the cells that make bone. Increased bone formation leads to increased healing and union of the implant with endogenous bone. To obtain better control over surface coating we developed PLLA copolymers with allyl (PLLA-co-DAG) and 3-hydroxypropyl (PLLA-co-HP) side chains to which we can attach functional groups. Given the potential of fatty acids being able to incorporate into lipid bilayers and/or influence gene expression, we grafted different fatty acid side chains to PLLA-co-HP by esterifying the corresponding fatty acids with the PLLA-co-HP 3-hydroxypropyl side chains. The effects of the polymer modifications on osteoblasts were then evaluated. While cellular morphology differed between surface coatings, they did not reflect changes in cellular phenotype. Changes in gene expression were most evident with arachidonate and 3-hydroxypropyl side-chains which exhibited osteoblast differentiating capabilities. Linoleate, myristate, oleate, and stearate ester side-chains did not have a significant influence on osteoblast phenotype. Growth characteristics of osteoblasts did not differ between the fatty acid copolymer films, although cells grown on PLLA-co-HP exhibited a trend toward increased growth. Taken together our findings demonstrate that surface fatty acid composition can impact osteoblast phenotype.     

NF-κB Signaling Negatively Regulates Osteoblast Dedifferentiation during Zebrafish Bone Regeneration

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Osteoblast Recruitment and Bone Formation Enhanced by Cell Matrix–associated Heparin-binding Growth-associated Molecule (HB-GAM)

Bone has an enormous capacity for growth, regeneration, and remodeling. This capacity is largely due to induction of osteoblasts that are recruited to the site of bone formation. The recruitment of osteoblasts has not been fully elucidated, though the immediate environment of the cells is likely to play a role via cell– matrix interactions. We show here that heparin-binding growth-associated molecule (HB-GAM), an extracellular matrix–associated protein that enhances migratory responses in neurons, is prominently expressed in the cell matrices that act as target substrates for bone formation. Intriguingly, N-syndecan, which acts as a receptor for HB-GAM, is expressed by osteoblasts/osteoblast precursors, whose ultrastructural phenotypes suggest active cell motility. The hypothesis that HB-GAM/N-syndecan interaction mediates osteoblast recruitment, as inferred from developmental studies, was tested using osteoblast-type cells that express N-syndecan abundantly. These cells migrate rapidly to HB-GAM in a haptotactic transfilter assay and in a migration assay where HB-GAM patterns were created on culture wells. The mechanism of migration is similar to that previously described for the HB-GAM–induced migratory response of neurons. Our hypothesis that HB-GAM/N-syndecan interaction participates in regulation of osteoblast recruitment was tested using two different in vivo models: an adjuvant-induced arthritic model and a transgenic model. In the adjuvant-induced injury model, the expression of HB-GAM and of N-syndecan is strongly upregulated in the periosteum accompanying the regenerative response of bone. In the transgenic model, the HB-GAM expression is maintained in mesenchymal tissues with the highest expression in the periosteum. The HB-GAM transgenic mice develop a phenotype characterized by an increased bone thickness. HB-GAM may thus play an important role in bone formation, probably by mediating recruitment and attachment of osteoblasts/osteoblast precursors to the appropriate substrates for deposition of new bone.     

In Toto Imaging of Dynamic Osteoblast Behaviors in Regenerating Skeletal Bone

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Autophagy Is Possibly Involved in Osteoblast Responses to Mechanical Loadings

Both mechanical loading and autophagy play important roles in regulating bone growth and remodeling, but the relationship between the two remains unclear. In this study, we examined bone structure with micro-CT imaging and measured bone mechanical properties with three-point bending experiments using bones from wild-type (WT) mice and conditional knockout (cKO) mice with Atg7 deletion in their osteoblasts. We found that the knockout mice had significantly less bone volume, bone thickness, bone ultimate breaking force, and bone stiffness compared to wild-type mice. Additionally, bone marrow cells from knockout mice had reduced differentiation and mineralization capacities in terms of alkaline phosphatase and calcium secretion, as well as Runx2 and osteopontin expression. Knockout mice also had significantly less relative bone formation rate due to mechanical loading. Furthermore, we found that the osteoblasts from wild-type mice had stronger responses to mechanical stimulation compared to autophagy-deficient osteoblasts from knockout mice. When inhibiting autophagy with 3 MA in wild-type osteoblasts, we found similar results as we did in autophagy-deficient osteoblasts. We also found that mechanical loading-induced ATP release is able to regulate ERK1/2, Runx2, alkaline phosphatase, and osteopontin activities. These results suggest that the ATP pathway may play an important role in the possible involvement of autophagy in osteoblast mechanobiology.     

Improved Cellular Response of Osteoblast Cells Using Recombinant Human Osteopontin Protein Produced by <Emphasis Type="Italic">Escherichia coli</Emphasis>

Osteopontin is a major non-collagenous bone matrix protein secreted into the mineralizing extracellular matrix by osteoblasts during bone development. Recombinant human osteopontin (hOPN) that includes the Arg-Gly-Asp (RGD) cell recognition site was expressed in Escherichia coli and the purified osteopontin increased cell adhesion, proliferation and differentiation of osteoblast cells (p<0.05). Revisions requested 26 July 2005; Revisions received 31 August 2005     

Baicalein alleviates osteoarthritis by protecting subchondral bone,inhibiting angiogenesis and synovial proliferation

Osteoarthritis (OA) is one of the most frequent chronic joint diseases with the increasing life expectancy. The main characteristics of the disease are loss of articular cartilage, subchondral bone sclerosis and synovium inflammation. Physical measures, drug therapy and surgery are the mainstay of treatments for OA, whereas drug therapies are mainly limited to analgesics, glucocorticoids, hyaluronic acids and some alternative therapies because of single therapeutic target of OA joints. Baicalein, a traditional Chinese medicine extracted from Scutellaria baicalensis Georgi, has been widely used in anti-inflammatory therapies. Previous studies revealed that baicalein could alleviate cartilage degeneration effectively by acting on articular chondrocytes. However, the mechanisms involved in baicalein-mediated protection of the OA are not completely understood in consideration of integrality of arthrosis. In this study, we found that intra-articular injection of baicalein ameliorated subchondral bone remodelling. Further studies showed that baicalein could decrease the number of differentiated osteoblasts by inhibiting pre-osteoblasts proliferation and promoting pre-osteoblasts apoptosis. In addition, baicalein impaired angiogenesis of endothelial cells and inhibited proliferation of synovial cells. Taken together, these results implicated that baicalein might be an effective medicine for treating OA by regulating multiple targets.     

丹皮酚对过氧亚硝基阴离子致大鼠成骨细胞分化抑制的影响

探讨丹皮酚（Pae）拮抗过氧亚硝基阴离子（ONOO^-）对体外培养大鼠成骨细胞分化的影响。用改良的组织块法分离培养新生大鼠颅骨成骨细胞,采用淬灭流动反应方法体外制备ONOO^-,以不同终浓度加入成骨细胞培养体系,在作用不同时间后,用对硝基苯二钠动力学（PNPP）法检测细胞内碱性磷酸酶（ALP）的活性,用Lowry法测定蛋白含量,并以不同终浓度Pae消除ONOO^-（1000μmoL/L）对成骨细胞分化的影响。结果显示,不同浓度的ONOO^-（50-1000μmoL/L）均能抑制碱性磷酸酶的活性,影响分化;高浓度的丹皮酚（10^-3-10^-6mol/L）能消除ONOO^-（1000μmoL/L）对碱性磷酸酶活性的抑制,拮抗ONOO^-抑制成骨细胞分化的作用。     

Oxymatrine exerts protective effects on osteoarthritis via modulating chondrocyte homoeostasis and suppressing osteoclastogenesis

Osteoarthritis (OA) is a common degenerative disease characterized by the progressive destruction both articular cartilage and the subchondral bone. The agents that can effectively suppress chondrocyte degradation and subchondral bone loss are crucial for the prevention and treatment of OA. Oxymatrine (OMT) is a natural compound with anti‐inflammatory and antitumour properties. We found that OMT exhibited a strong inhibitory effect on LPS‐induced chondrocyte inflammation and catabolism. To further support our results, fresh human cartilage explants were treated with LPS to establish an ex vivo degradation model, and the results revealed that OMT inhibited the catabolic events of LPS‐stimulated human cartilage and substantially attenuated the degradation of articular cartilage ex vivo. As subchondral bone remodelling is involved in OA progression, and osteoclasts are a unique cell type in bone resorption, we investigated the effects of OMT on osteoclastogenesis, and the results demonstrated that OMT suppresses RANKL‐induced osteoclastogenesis by suppressing the RANKL‐induced NFATc1 and c‐fos signalling pathway in vitro. Further, we found that the anti‐inflammatory and anti‐osteoclastic effects of oxymatrine are mediated via the inhibition of the NF‐κB and MAPK pathways. In animal studies, OMT suppressed the ACLT‐induced cartilage degradation, and TUNEL assays further confirmed the protective effect of OMT on chondrocyte apoptosis. MicroCT analysis revealed that OMT had an attenuating effect on ACLT‐induced subchondral bone loss in vivo. Taken together, these results show that OMT interferes with the vicious cycle associated with OA and may be a potential therapeutic agent for abnormal subchondral bone loss and cartilage degradation in osteoarthritis.     

Understanding the role of chondrocytes in osteoarthritis: utilizing proteomics

Introduction: Proteomic analyses have been acknowledged to carry a significant prospective in elucidating the pathogenesis of several diseases, including osteoarthritis (OA). But it has not been an easy road: major technical issues, mainly derived from the complex and rigid nature of the cartilage tissue, had to be faced; an obstacle that led to the development of different approaches.

Areas covered: In this review, we categorized the proteomic studies undertaken (proteomic analyses of the cartilage, cartilage explants, cultured chondrocytes, and chondrocytes’ secretome) as part of the different strategies developed in order to overcome tissue and disease-specific challenges. Essentially these approaches aimed at identifying differences in the proteome of healthy vs diseased tissue. Our aim was to point out the novel players that have emerged from these analyses and highlight the associated mechanism(s) suggested to play a role in the pathogenesis of OA.

Expert commentary: The identified factors indicate the implication of age-associated mechanisms, such as metabolic deregulation, inflammation, and redox imbalance, in OA onset and/or progression. Taken together these results outline the causal network of the disease and place chondrocytes’ senescence at the center of the emerging aetiopathological atlas.     

Production of the chemokine eotaxin-1 in osteoarthritis and its role in cartilage degradation

The expression of the chemokine, eotaxin-1, and its receptors in normal and osteoarthritic human chondrocytes was examined, and its role in cartilage degradation was elucidated in this study. Results indicated that plasma concentrations of eotaxin-1 as well as the chemokines, RANTES, and MCP-1alpha, were higher in patients with osteoarthritis (OA) than those in normal humans. Stimulation of chondrocytes with IL-1beta or TNF-alpha significantly induced eotaxin-1 expression. The production of eotaxin-1 induced expression of its own receptor of CCR3 and CCR5 on the cell surface of chondrosarcomas, suggesting that an autocrine/paracrine pathway is involved in eotaxin-1's action. In addition, eotaxin-1 markedly increased the expressions of MMP-3 and MMP-13 mRNA, but had no effect on TIMP-1 expression in chondrocytes. However, pretreatment of anti-eotaxin-1 antibody significantly decreased the MMP-3 expression induced by IL-1beta. These results first demonstrate that human chondrocytes express the chemokine, eotaxin-1, and that its expression is induced by treatment with IL-1beta and TNF-alpha. The cytokine-triggered induction of eotaxin-1 further results in enhanced expressions of its own receptor of CCR3, CCR5, and MMPs, suggesting that eotaxin-1 plays an important role in cartilage degradation in OA.     

Neglected immunoregulation: M2 polarization of macrophages triggered by low-dose irradiation plays an important role in bone regeneration

Current studies have found that low-dose irradiation (IR) can promote bone regeneration. However, mechanism studies of IR-triggered bone regeneration mainly focus on the effects of osteoblasts, neglecting the role of the surrounding immune microenvironment. Here in this study, in vitro proliferation experiments showed that low-dose IR ≤2 Gy could promote the proliferation of bone marrow mesenchymal stem cells (BMSCs), and qRT-PCR assay showed that low-dose IR ≤2 Gy could exert the M2 polarization of Raw264.7 cells, while IR >2 Gy inhibited BMSC proliferation and triggered M1 polarization in Raw264.7 cells. The ALP and mineralized nodules staining showed that low-dose IR ≤2 Gy not only promoted osteoblast mineralization through IR-triggered osteoblast proliferation but also through M2 polarization of Raw264.7 cells, while high-dose IR >2 Gy had the opposite effect. The co-incubation of BMSC with low-dose IR irradiated Raw264.7 cell supernatants increased the mRNA expression of BMP-2 and Osx. The rat cranial defects model revealed that low-dose IR ≤2 Gy gradually promoted bone regeneration, while high-dose IR >2 Gy inhibited bone regeneration. Detection of macrophage polarity in peripheral blood samples showed that low-dose IR ≤2 Gy increased the expression of CD206 and CD163, but decreased the expression of CD86 and CD80 in macrophages, which indicated M2 polarization of macrophages in vivo, while high-dose IR had the opposite effect. Our finding innovatively revealed that low-dose IR ≤2 Gy promotes bone regeneration not only by directly promoting the proliferation of osteoblasts but also by triggering M2 polarization of macrophages, which provided a new perspective for immune mechanism study in the treatment of bone defects with low-dose IR.     

Cellular senescence in osteoarthritis pathology

Cellular senescence is a state of stable proliferation arrest of cells. The senescence pathway has many beneficial effects and is seen to be activated in damaged/stressed cells, as well as during embryonic development and wound healing. However, the persistence and accumulation of senescent cells in various tissues can also impair function and have been implicated in the pathogenesis of many age‐related diseases. Osteoarthritis (OA), a severely debilitating chronic condition characterized by progressive tissue remodeling and loss of joint function, is the most prevalent disease of the synovial joints, and increasing age is the primary OA risk factor. The profile of inflammatory and catabolic mediators present during the pathogenesis of OA is strikingly similar to the secretory profile observed in ‘classical’ senescent cells. During OA, chondrocytes (the sole cell type present within articular cartilage) exhibit increased levels of various senescence markers, such as senescence‐associated beta‐galactosidase (SAβGal) activity, telomere attrition, and accumulation of p16ink4a. This suggests the hypothesis that senescence of cells within joint tissues may play a pathological role in the causation of OA. In this review, we discuss the mechanisms by which senescent cells may predispose synovial joints to the development and/or progression of OA, as well as touching upon various epigenetic alterations associated with both OA and senescence.     

生物活性肽-蛋氨酸脑啡肽对成骨细胞增殖的影响

蛋氨酸脑啡肽（Methionine Enkephalin,MENK）作为内源性物质,通过与阿片受体结合,发挥阿片样物质的生物学作用。研究表明,MENK在成熟的骨组织和成骨细胞中均有分布,并且在成骨细胞表面发现了阿片受体。实验旨在进一步研究MENK对成骨细胞增殖的影响。体外培养MC3T3-E1成骨细胞,MTT方法检测MENK对成骨细胞增殖的影响。结果表明,10-7、10-8、10-9mol/L的MENK对成骨细胞的增殖具有促进作用（P〈0.05）。提示MENK可在骨缺损疾病中发挥促进骨组织重建的作用。     

关节软骨与软骨下骨改变在不同骨关节炎动物模型中的特点

目的 探讨不同骨关节炎(osteoarthritis,OA)动物模型中软骨下骨和关节软骨的病理改变特征。方法 采用三种SD大鼠骨关节炎模型,将24只6月龄雌性大鼠随机分为4组:假手术对照组(Sham,n=6),前交叉韧带切除手术组(ACLT,n=6),木瓜蛋白酶关节腔注射组(Papain,n=6),以及卵巢切除术组(OVX,n=6)。造模后8周取膝关节,胫骨平台行Micro-CT扫描分析,关节软骨行甲苯胺蓝染色、Mankin评分,比较软骨下骨和关节软骨改变情况。结果 造模操作后8周,不同OA模型的软骨破坏程度有所不同。ACLT和Papain组软骨破坏比较严重,OVX组软骨变化较轻。所有OA模型中的软骨下松质骨均发生改变,OVX组相对于Sham对照组,软骨下骨微结构显著疏松,而ACLT组与Papain组相对于Sham对照组,软骨下骨微结构没有显著改变,但相对于OVX组,有显著性差异。三种OA模型的软骨下骨板厚度都较Sham组减少。结论 三种动物模型软骨下骨和关节软骨都发生明显病理改变,并且改变有所不同。不同OA模型代表不同病理,预示着软骨下骨所发挥的作用有所不同,这为进一步研究不同类型OA发生发展的机制,以及将软骨下骨作为OA治疗的可能靶点提供了更多的依据。