Runx1/AML1/Cbfa2 mediates onset of mesenchymal cell differentiation toward chondrogenesis.

Runx proteins mediate skeletal development. We studied the regulation of Runx1 during chondrocyte differentiation by real-time RT-PCR and its function during chondrogenesis using overexpression and RNA interference. Runx1 induces mesenchymal stem cell commitment to the early stages of chondrogenesis. INTRODUCTION: Runx1 and Runx2 are co-expressed in limb bud cell condensations that undergo both cartilage and bone differentiation during murine development. However, the cooperative and/or compensatory effects these factors exert on skeletal formation have yet to be elucidated. MATERIALS AND METHODS: Runx1/Cbfa2 and Runx2/Cbfa1 were examined at different stages of embryonic development by immunohistochemistry. In vitro studies used mouse embryonic limb bud cells and assessed Runx expressions by immunohistochemistry and real-time RT-PCR in the presence and absence of TGFbeta and BMP2. Runx1 was overexpressed in mesenchymal cell progenitors using retroviral infection. RESULTS: Immunohistochemistry showed that Runx1 and Runx2 are co-expressed in undifferentiated mesenchyme, had similar levels in chondrocytes undergoing transition from proliferation to hypertrophy, and that there was primarily Runx2 expression in hypertrophic chondrocytes. Overall, the expression of Runx1 remained significantly higher than Runx2 mRNA levels during early limb bud cell maturation. Treatment of limb bud micromass cultures with BMP2 resulted in early induction of both Runx1 and Runx2. However, upregulation of Runx2 by BMP2 was sustained, whereas Runx1 decreased in later time-points when type X collagen was induced. Although TGFbeta potently inhibits Runx2 and type X collagen, it induces type II collagen mRNA and mildly but significantly inhibits Runx1 isoforms in the early stages of chondrogenesis. Virus-mediated overexpression of Runx1 in mouse embryonic mesenchymal cells resulted in a potent induction of the early chondrocyte differentiation markers but not the hypertrophy marker, type X collagen. Knockdown or Runx1 potently inhibits type II collagen, alkaline phosphatase, and Runx2 and has a late inhibitory effect on type X collagen. CONCLUSION: These findings show a distinct and sustained role for Runx proteins in chondrogenesis and subsequent chondrocyte maturation. Runx1 is highly expressed during chondrogenesis in comparison with Runx2, and Runx1 gain of functions stimulated this process. Thus, the Runx genes are uniquely expressed and have distinct roles during skeletal development.     

CCN1 Regulates Chondrocyte Maturation and Cartilage Development

WNT/β‐CATENIN signaling is involved in multiple aspects of skeletal development, including chondrocyte differentiation and maturation. Although the functions of β‐CATENIN in chondrocytes have been extensively investigated through gain‐of‐function and loss‐of‐function mouse models, the precise downstream effectors through which β‐CATENIN regulates these processes are not well defined. Here, we report that the matricellular protein, CCN1, is induced by WNT/β‐CATENIN signaling in chondrocytes. Specifically, we found that β‐CATENIN signaling promotes CCN1 expression in isolated primary sternal chondrocytes and both embryonic and postnatal cartilage. Additionally, we show that, in vitro, CCN1 overexpression promotes chondrocyte maturation, whereas inhibition of endogenous CCN1 function inhibits maturation. To explore the role of CCN1 on cartilage development and homeostasis in vivo, we generated a novel transgenic mouse model for conditional Ccn1 overexpression and show that cartilage‐specific CCN1 overexpression leads to chondrodysplasia during development and cartilage degeneration in adult mice. Finally, we demonstrate that CCN1 expression increases in mouse knee joint tissues after meniscal/ligamentous injury (MLI) and in human cartilage after meniscal tear. Collectively, our data suggest that CCN1 is an important regulator of chondrocyte maturation during cartilage development and homeostasis. © 2015 American Society for Bone and Mineral Research.     

Wdr5 is required for chick skeletal development

Wdr5, a bone morphogenetic protein 2 (BMP‐2)–induced protein belonging to the family of the WD repeat proteins, is expressed in proliferating and hypertrophic chondrocytes of the growth plate and in osteoblasts. Although previous studies have provided insight into the mechanisms by which Wdr5 affects chondrocyte and osteoblast differentiation, whether Wdr5 is required in vivo for endochondral bone development has not been addressed. In this study, using an avian replication competent retrovirus (RCAS) system delivering Wdr5 short hairpin (sh) RNA to silence Wdr5 in the developing limb, we report that reduction of Wdr5 levels delays endochondral bone development and consequently results in shortening of the skeletal elements. Shortening of the skeletal elements was due to impaired chondrocyte maturation, evidenced by a significant reduction of Runx2, type X collagen, and osteopontin expression. A decrease in Runx2, type collagen I, and ostepontin expression in osteoblasts and a subsequent defect in mineralized bone was observed as well when Wdr5 levels were reduced. Most important, retroviral misexpression of Runx2 rescued the phenotype induced by Wdr5 shRNA. These findings suggest that during limb development, Wdr5 is required for endochondral bone formation and that Wdr5 influences this process, at least in part, by regulating Runx2 expression. © 2010 American Society for Bone and Mineral Research.     

Cbfb Regulates Bone Development by Stabilizing Runx Family Proteins

Runx family proteins, Runx1, Runx2, and Runx3, play important roles in skeletal development. Runx2 is required for osteoblast differentiation and chondrocyte maturation, and haplodeficiency of RUNX2 causes cleidocranial dysplasia, which is characterized by open fontanelles and sutures and hypoplastic clavicles. Cbfb forms a heterodimer with Runx family proteins and enhances their DNA‐binding capacity. Cbfb‐deficient (Cbfb^?/?) mice die at midgestation because of the lack of fetal liver hematopoiesis. We previously reported that the partial rescue of hematopoiesis in Cbfb^?/? mice revealed the requirement of Cbfb in skeletal development. However, the precise functions of Cbfb in skeletal development still remain to be clarified. We deleted Cbfb in mesenchymal cells giving rise to both chondrocyte and osteoblast lineages by mating Cbfb^fl/fl mice with Dermo1 Cre knock‐in mice. Cbfb^fl/fl/Cre mice showed dwarfism, both intramembranous and endochondral ossifications were retarded, and chondrocyte maturation and proliferation and osteoblast differentiation were inhibited. The differentiation of chondrocytes and osteoblasts were severely inhibited in vitro, and the reporter activities of Ihh, Col10a1, and Bglap2 promoter constructs were reduced in Cbfb^fl/fl/Cre chondrocytes or osteoblasts. The proteins of Runx1, Runx2, and Runx3 were reduced in the cartilaginous limb skeletons and calvariae of Cbfb^fl/fl/Cre embryos compared with the respective protein in the respective tissue of Cbfb^fl/fl embryos at E15.5, although the reduction of Runx2 protein in calvariae was much milder than that in cartilaginous limb skeletons. All of the Runx family proteins were severely reduced in Cbfb^fl/fl/Cre primary osteoblasts, and Runx2 protein was less stable in Cbfb^fl/fl/Cre osteoblasts than Cbfb^fl/fl osteoblasts. These findings indicate that Cbfb is required for skeletal development by regulating chondrocyte differentiation and proliferation and osteoblast differentiation; that Cbfb plays an important role in the stabilization of Runx family proteins; and that Runx2 protein stability is less dependent on Cbfb in calvariae than in cartilaginous limb skeletons. © 2014 American Society for Bone and Mineral Research.     

Runx2 contributes to murine Col10a1 gene regulation through direct interaction with its cis-enhancer

We have recently shown that a 150‐bp Col10a1 distal promoter (?4296 to ?4147 bp) is sufficient to direct hypertrophic chondrocyte‐specific reporter (LacZ) expression in vivo. More recently, through detailed sequence analysis we identified two putative tandem‐repeat Runx2 binding sites within the 3′‐end of this 150‐bp region (TGTGGG‐TGTGGC, ?4187 to ?4176 bp). Candidate electrophoretic mobility shift assay (EMSA), chromatin immunoprecipitation, and transfection studies demonstrate that these putative Runx2 sites bind Runx2 and mediate upregulated Col10a1/reporter activity in vitro. Transgenic studies using the 5′‐sequence without Runx2 sites were not able to drive the cell‐specific LacZ reporter activity, suggesting the in vivo requirement of the Runx2 sites located in the 3′‐end in mediating Col10a1/reporter expression. Indeed, mutating the Runx2 sites in the context of the 150‐bp promoter abolishes its capacity to drive hypertrophic chondrocyte‐specific reporter expression in transgenic mice. We have also generated multiple transgenic mouse lines using only the 3′‐sequence containing the Runx2 sites to drive the LacZ gene. Interestingly, no hypertrophic chondrocyte‐specific blue staining was observed in these transgenic mice. Together, our data support that Runx2 directly interacts with murine Col10a1 cis‐enhancer. This interaction is required but not sufficient for cell‐specific Col10a1 promoter activity in vivo. Additional cooperative/repressive elements within the 5′‐ or 3′‐sequences of this 150‐bp promoter are needed to work with Runx2 together to mediate cell‐specific Col10a1 expression. Further delineation of these elements/factors has the potential to identify novel therapeutic targets for multiple skeletal disorders, including osteoarthritis, that show abnormal Col10a1 expression and altered chondrocyte maturation. © 2011 American Society for Bone and Mineral Research     

ALK2 functions as a BMP type I receptor and induces Indian hedgehog in chondrocytes during skeletal development.

Growth plate chondrocytes integrate multiple signals during normal development. The type I BMP receptor ALK2 is expressed in cartilage and expression of constitutively active (CA) ALK2 and other activated type I BMP receptors results in maturation-independent expression of Ihh in chondrocytes in vitro and in vivo. The findings suggest that BMP signaling modulates the Ihh/PTHrP signaling pathway that regulates the rate of chondrocyte differentiation. INTRODUCTION: Bone morphogenetic proteins (BMPs) have an important role in vertebrate limb development. The expression of the BMP type I receptors BMPR-IA (ALK3) and BMPR-IB (ALK6) have been more completely characterized in skeletal development than ALK2. METHODS: ALK2 expression was examined in vitro in isolated chick chondrocytes and osteoblasts and in vivo in the developing chick limb bud. The effect of overexpression of CA ALK2 and the other type I BMP receptors on the expression of genes involved in chondrocyte maturation was determined. RESULTS: ALK2 was expressed in isolated chick osteoblasts and chondrocytes and specifically mediated BMP signaling. In the developing chick limb bud, ALK2 was highly expressed in mesenchymal soft tissues. In skeletal elements, expression was higher in less mature chondrocytes than in chondrocytes undergoing terminal differentiation. CA ALK2 misexpression in vitro enhanced chondrocyte maturation and induced Ihh. Surprisingly, although parathyroid hormone-related peptide (PTHrP) strongly inhibited CA ALK2 mediated chondrocyte differentiation, Ihh expression was minimally decreased. CA ALK2 viral infection in stage 19-23 limbs resulted in cartilage expansion with joint fusion. Enhanced periarticular expression of PTHrP and delayed maturation of the cartilage elements were observed. In the cartilage element, CA ALK2 misexpression precisely colocalized with the expression with Ihh. These findings were most evident in partially infected limbs where normal morphology was maintained. In contrast, BMP-6 had a normal pattern of differentiation-related expression. CA BMPR-IA and CA BMPR-IB overexpression similarly induced Ihh and PTHrP. CONCLUSIONS: The findings show that BMP signaling induces Ihh. Although the colocalization of the activated type I receptors and Ihh suggests a direct BMP-mediated signaling event, other indirect mechanisms may also be involved. Thus, while BMPs act directly on chondrocytes to induce maturation, this effect is counterbalanced in vivo by induction of the Ihh/PTHrP signaling loop. The findings suggest that BMPs are integrated into the Ihh/PTHrP signaling loop and that a fine balance of BMP signaling is essential for normal chondrocyte maturation and skeletal development.     

A role for the BMP antagonist chordin in endochondral ossification.

Bone morphogenetic proteins (BMPs) are ubiquitous regulators of cellular growth and differentiation. A variety of processes modulate BMP activity, including negative regulation by several distinct binding proteins. One such BMP antagonist chordin has a role in axis determination and neural induction in the early embryo. In this study, a role for chordin during endochondral ossification has been investigated. During limb development, Chordin expression was detected only at the distal ends of the skeletal elements. In cultured embryonic sternal chondrocytes, Chordin expression was related inversely to the stages of maturation. Further, treating cultured chondrocytes with chordin interfered with maturation induced by treatment with BMP-2. These results suggest that chordin may negatively regulate chondrocyte maturation and limb growth in vivo. To address this hypothesis, chordin protein was expressed ectopically in Hamburger-Hamilton (HH) stage 25-27 embryonic chick limbs. The phenotypic changes and alteration of gene expression in treated limbs revealed that overexpression of chordin protein delayed chondrocyte maturation in developing skeletal elements. In summary, these findings strongly support a role for chordin as a negative regulator of endochondral ossification.     

Overexpression of Smurf2 Stimulates Endochondral Ossification Through Upregulation of β‐Catenin

Ectopic expression of Smurf2 in chondrocytes and perichondrial cells accelerated endochondral ossification by stimulating chondrocyte maturation and osteoblast development through upregulation of β‐catenin in Col2a1‐Smurf2 embryos. The mechanism underlying Smurf2‐mediated morphological changes during embryonic development may provide new mechanistic insights and potential targets for prevention and treatment of human osteoarthritis. Introduction : Our recent finding that adult Col2a1‐Smurf2 mice have an osteoarthritis‐like phenotype in knee joints prompted us to examine the role of Smurf2 in the regulation of chondrocyte maturation and osteoblast differentiation during embryonic endochondral ossification. Materials and Methods : We analyzed gene expression and morphological changes in developing limbs by immunofluorescence, immunohistochemistry, Western blot, skeletal preparation, and histology. A series of markers for chondrocyte maturation and osteoblast differentiation in developing limbs were examined by in situ hybridization. Results : Ectopic overexpression of Smurf2 driven by the Col2a1 promoter was detected in chondrocytes and in the perichondrium/periosteum of 16.5 dpc transgenic limbs. Ectopic Smurf2 expression in cells of the chondrogenic lineage inhibited chondrocyte differentiation and stimulated maturation; ectopic Smurf2 in cells of the osteoblastic lineage stimulated osteoblast differentiation. Mechanistically, this could be caused by a dramatic increase in the expression of β‐catenin protein levels in the chondrocytes and perichondrial/periosteal cells of the Col2a1‐Smurf2 limbs. Conclusions : Ectopic expression of Smurf2 driven by the Col2a1 promoter accelerated the process of endochondral ossification including chondrocyte maturation and osteoblast differentiation through upregulation of β‐catenin, suggesting a possible mechanism for development of osteoarthritis seen in these mice.     

Developmental expression of creatine kinase isoenzymes in chicken growth cartilage.

We have shown previously that creatine kinase (CK) activity is required for normal development and mineralization of chicken growth cartilage and that expression of the cytosolic isoforms of CK is related to the biosynthetic and energy status of the chondrocyte. In this study, we have characterized changes in isoenzyme activity and mRNA levels of CK (muscle-specific CK, M-CK; brain-type CK, B-CK; and mitochondrial CK subunits, MiaCK and MibCK) in the growth plate in situ and in chondrocyte culture systems that model the development/maturation program of the cartilage. The in vitro culture systems analyzed were as follows: tibial chondrocytes, which undergo hypertrophy; embryonic cephalic and caudal sternal chondrocytes, which differ from each other in their mineralization response to retinoic acid; and long-term micromass cultures of embryonic limb mesenchymal cells, which recapitulate the chondrocyte differentiation program. In all systems analyzed, B-CK was found to be the predominant isoform. In the growth plate, B-CK expression was highest in the most calcified regions, and M-CK was less abundant than B-CK in all regions of the growth plate. In tibial chondrocytes, an increase in B-CK expression was seen when the cells became hypertrophic. Expression of B-CK increased slightly over 15 days in mineralizing, retinoic acid-treated cephalic chondrocytes, but it decreased in nonmineralizing caudal chondrocytes, while there was little expression of M-CK. Interestingly, in limb mesenchyme cultures, significant M-CK expression was detected during chondrogenesis (days 2-7), whereas hypertrophic cells expressed only B-CK. Finally, expression of MiaCK and MibCK was low both in situ and in vitro. These observations suggest that the CK genes are differentially regulated during cartilage development and maturation and that an increase in CK expression is important in initiating chondrocyte maturation.     

New target genes for NOV/CCN3 in chondrocytes: TGF-beta2 and type X collagen.

We studied the involvement of NOV/CCN3, whose function is poorly understood, in chondrocyte differentiation. NOV was found to upregulate TGF-beta2 and type X collagen and to act as a downstream effector of TGF-beta1 in ATDC5 and primary chondrocytes. Thus, NOV is a positive modulator of chondrogenesis. INTRODUCTION: NOV/CCN3 is a matricellular protein that belongs to the CCN family. A growing body of evidence indicates that NOV could play a role in cell differentiation, particularly in chondrogenesis. During chick embryo development, NOV expression is tightly regulated in cartilage, and a high expression of NOV has been associated with cartilage differentiation in Wilms' tumors. However, a precise role for NOV and potential target genes of NOV in chondrogenesis are unknown. MATERIALS AND METHODS: ATDC5 cells and primary chondrocytes were either treated with NOV recombinant protein or transfected with a NOV-specific siRNA to determine, using quantitative RT-PCR, the effect of NOV on the expression of several molecules involved in chondrocyte differentiation. Stable ATDC5 clones expressing NOV were also established to show that NOV was a downstream effector of TGF-beta1. RESULTS: We established that NOV/CCN3 expression increases in ATDC5 cells at early stages of chondrogenic differentiation and precedes the appearance of TGF-beta2 and of several chondrocytic markers such as SOX9 or type X collagen. When exogenously administered, NOV recombinant protein up-regulates TGF-beta2 and type X collagen mRNA levels both in ATDC5 cells and in primary mouse chondrocytes but does not influence SOX9 expression. This regulation also occurs at the endogenous level because downregulation of NOV expression is correlated with an inhibition of TGF-beta2 and type X collagen in primary chondrocytes. Furthermore, we found that NOV expression is downregulated when chondrocytes are exposed to TGF-beta1-dedifferentiating treatment in chondrocytes, further providing evidence that NOV may counteract TGF-beta1 effects on chondrocytes. CONCLUSIONS: This study provides the first characterization of two new targets of NOV involved in chondrocyte differentiation, shows that NOV acts with TGF-beta1 in a cascade of gene regulation, and indicates that NOV is a positive modulator of chondrogenesis.     

Runx1 dose-dependently regulates endochondral ossification during skeletal development and fracture healing

Runx1 is expressed in skeletal elements, but its role in fracture repair has not been analyzed. We created mice with a hypomorphic Runx1 allele (Runx1(L148A) ) and generated Runx1(L148A/-) mice in which >50% of Runx1 activity was abrogated. Runx1(L148A/-) mice were viable but runted. Their growth plates had extended proliferating and hypertrophic zones, and the percentages of Sox9-, Runx2-, and Runx3-positive cells were decreased. Femoral fracture experiments revealed delayed cartilaginous callus formation, and the expression of chondrogenic markers was decreased. Conditional ablation of Runx1 in the mesenchymal progenitor cells of the limb with Prx1-Cre conferred no obvious limb phenotype; however, cartilaginous callus formation was delayed following fracture. Embryonic limb bud-derived mesenchymal cells showed delayed chondrogenesis when the Runx1 allele was deleted ex vivo with adenoviral-expressed Cre. Collectively, our data suggest that Runx1 is required for commitment and differentiation of chondroprogenitor cells into the chondrogenic lineage.