Title: Regulation of Osteoarthritis Development by Wnt–β-catenin Signaling Through the Endochondral Ossification Process
Abstract: Journal of Bone and Mineral ResearchVolume 24, Issue 1 p. 8-11 Research-ArticleFree Access Regulation of Osteoarthritis Development by Wnt–β-catenin Signaling Through the Endochondral Ossification Process† Hiroshi Kawaguchi, Hiroshi Kawaguchi Sensory and Motor System Medicine, Faculty of Medicine, University of Tokyo, Tokyo, JapanSearch for more papers by this author Hiroshi Kawaguchi, Hiroshi Kawaguchi Sensory and Motor System Medicine, Faculty of Medicine, University of Tokyo, Tokyo, JapanSearch for more papers by this author First published: 04 December 2009 https://doi.org/10.1359/jbmr.081115Citations: 45 † The author states that he has no conflicts of interest. AboutSectionsPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Share a linkShare onFacebookTwitterLinked InRedditWechat Osteoarthritis, a joint disorder characterized by cartilage degradation and osteophyte formation, is considered a major public health issue causing chronic disability worldwide with the increasing number of aging people today.1, 2 Although the social impact of this disorder has been compared with osteoporosis,3 osteoarthritis is far behind osteoporosis in the development of disease-modifying treatments. This is mainly because little is known about the underlying molecular mechanism that can be the therapeutic target. Recent animal studies have shown that osteoarthritis is initiated by production of proteinases such as matrix metalloproteinases (MMPs) and aggrecanases that sever type II collagen (COL2) and proteoglycan, the principal matrix of articular cartilage.4-6 However, trials applying the proteinase inhibitors for clinical use as a disease-modifying treatment have to date been unsuccessful because of insufficient efficiency and severe adverse events,7, 8 turning the interest of researchers to the upstream signals of the proteinases in chondrocytes. Cartilage matrix proteins, especially undegraded COL2, are shown to induce proteinases through a receptor tyrosine kinase discoidin domain receptor 2 (DDR-2).9-11 This causes the degradation of the matrix proteins, and the product fragments induce proteinases through integrins α2β1 and α5β1.9 Another possible signal is pro-inflammatory factors such as prostaglandins, TNF-α, interleukin-1 (IL-1), IL-6, and NOs that are produced mainly by synovial cells, similarly to rheumatoid arthritis12; however, accumulating evidence using experimental osteoarthritis models in knockout mice has not supported that these factors play a central role in the pathogenesis of osteoarthritis.13, 14 Our previous study also showed that levels of TNF-α, IL-1, and IL-6 in the synovial fluid from knee joints of osteoarthritis patients were much lower than those from patients with rheumatoid arthritis.15 Endochondral ossification including chondrocyte maturation and apoptosis is an essential process for skeletal development and growth at the embryonic cartilage and growth plate cartilage, respectively, but should not occur under physiological conditions in the joint cartilage, which is a permanent cartilage and is not destined to be replaced by bone. Recently, chondrocyte maturation has been implicated to be deeply involved in the pathogenesis of osteoarthritis. In articular cartilage of osteoarthritis patients, pathologic expression of type X collagen (COL10) and other differentiation markers, including annexin VI, alkaline phosphatase, osteopontin, and osteocalcin, have been reported,16-20 indicating that the osteoarthritis articular cartilage cannot maintain the characteristics of the permanent cartilage but adds those of the embryonic or growth plate cartilage. A mouse genetic study found the induction of Runx2, an essential transcription factor for chondrocyte hypertrophy,21, 22 in articular chondrocytes during osteoarthritis progression under mechanical stress, which led to cartilage degradation and osteophyte formation through the chondrocyte maturation and MMP production.23, 24 Carminerin, an inducer of chondrocyte calcification,25 is also reported to contribute to osteophyte formation during the osteoarthritis progression by studies on the deficient mice.26 In addition to chondrocyte maturation, chondrocyte apoptosis has also recently been reported to be involved in osteoarthritis development.27 Intra-articular injection of a pan-caspase inhibitor suppresses cartilage degradation under osteoarthritis induction in rabbits.28 Osteoprotegerin (OPG) is also suggested to prevent osteoarthritis progression through functional inhibition of its ligand TNF-related apoptosis-inducing ligand (TRAIL).29 The canonical Wnt–β-catenin signal, a potent regulator of skeletal development and homeostasis of adult bone mass,30 is also known to induce chondrocyte maturation. During skeletal development and growth, activation of the Wnt–β-catenin signal in chondrocytes in limb buds or growth plates stimulates hypertrophy, calcification, and expressions of MMP and vascular endothelial growth factor.31-33 The inhibition of Dickkopf-1 (Dkk1), a negative regulator of the Wnt–β-catenin signal, has been reported to allow conversion of a mouse model of rheumatoid arthritis to osteoarthritis, indicating a regulation of joint remodeling.34 Furthermore, recent human genomic studies have shown that polymorphisms in the FrzB gene encoding the secreted frizzled-related protein 3 (sFRP3), an extracellular inhibitor of the Wnt–β-catenin signal, is associated with an increased susceptibility to osteoarthritis.35-37 The polymorphisms were at least partly associated with a reduced ability to limit β-catenin signaling. Increased levels of β-catenin have been reported in chondrocytes within areas of degenerative cartilage.38, 39 These suggest a possible involvement of β-catenin in the pathogenesis of osteoarthritis.40, 41 In this issue of the JBMR, Zhu et al.42 for the first time provide direct evidence of the role of β-catenin in the development of osteoarthritis. They created mutant mice using an elegant breeding scheme by crossing mice floxed for exon 3 of β-catenin with cartilage specific and tamoxifen regulated Cre mice to produce mice with a stabilized β-catenin protein resistant to phosphorylation by GSK-3β. The conditional activation of β-catenin in articular chondrocytes of adult mice caused osteoarthritis-like cartilage degradation and osteophyte formation, and this was associated with accelerated chondrocyte maturation and MMP expressions. Interestingly, the authors recently reported that selective suppression of β-catenin signaling in articular chondrocytes also causes osteoarthritis-like cartilage degradation in Col2a1-ICAT (inhibitor of β-catenin and T-cell factor) transgenic mice, and this was mediated by enhancement of apoptosis of the chondrocytes.43 These seem somewhat contradictory because both gain- and loss-of-functions of β-catenin in articular cartilage exhibited a similar osteoarthritis-like phenotype, although the underlying mechanisms were different. Under physiological conditions, β-catenin may maintain the moderate maturation of articular chondrocytes, which is consistent with the role in skeletal development and growth, and prevent apoptosis. Both excessive and insufficient β-catenin levels may therefore impair the homeostasis of articular chondrocytes by enhancing pathological maturation and apoptosis, respectively, both of which are endochondral ossification processes. Figure 1 summarizes the hypothesis of the mechanism whereby β-catenin regulates osteoarthritis development. β-catenin induces chondrocyte maturation similarly to Runx2, whereas it suppresses chondrocyte apoptosis similarly to OPG. The proteinases produced during the endochondral ossification process cause cartilage degradation at the center of the joint and osteophyte formation at the periphery. The difference of the two sites may depend on the vascularity. At the periphery, vascularity is accessible from the synovium or tendon, which completes endochondral ossification and forms osteophytes, just as it does at the embryonic and growth plate cartilage. However, in the center, the vascularity is not accessible from the edge, so that it may end up with cartilage degradation without being replaced by bone. Figure FIG. 1.Open in figure viewerPowerPoint Possible mechanism underlying the regulation of cartilage degradation and osteophyte formation by β-catenin. β-catenin induces chondrocyte maturation and suppresses chondrocyte apoptosis. Hence, the gain- and loss-of-functions of β-catenin cause chondrocyte maturation and apoptosis, both of which are essential processes for endochondral ossification. The produced proteinases cause cartilage degradation at the center of the articular cartilage, where endochondral ossification remains incomplete because of insufficient vascular supply from the edge. Meanwhile, at the periphery of the articular cartilage, vascularity is accessible from synovium or tendon, so that endochondral ossification is completed and osteophytes are formed. As described by the authors, the Wnt–β-catenin signal and the related molecules may regulate the osteoarthritis development through an endochondral ossification process including chondrocyte maturation and apoptosis. Although further human genomic and clinical studies are needed to elucidate the influence of the molecules on the pathogenesis of osteoarthritis, they might become therapeutic targets altering the course of this disabling disease. In addition, because serum levels of sFRP-3 and Dkk1, secreted antagonists of the Wnt–β-catenin signal, are known to be associated with the radiographic joint space narrowing,44 the molecules might be surrogate markers for cartilage loss during osteoarthritis progression. REFERENCES 1 Hunter DJ, Felson DT 2006 Osteoarthritis. BMJ 332: 639– 642. CrossrefPubMedWeb of Science®Google Scholar 2 Sharma L, Kapoor D 2007 Epidemiology of osteoarthritis. RW Moskowitz, RD Altman, MC Hochberg, JA Buckwalter, VM Goldberg (eds.) Osteoarthritis, Diagnosis and Medical/Surgical Management, 4th ed. Lippincott Williams & Wilkins, Philadelphia, PA, USA, 3– 26. 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Publication Year: 2009
Publication Date: 2009-01-01
Language: en
Type: letter
Indexed In: ['crossref', 'pubmed']
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Cited By Count: 62
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