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J. Biol. Chem., Vol. 280, Issue 46, 38544-38555, November 18, 2005

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A Novel Role for GADD45 as a Mediator of MMP-13 Gene Expression during Chondrocyte Terminal Differentiation^*

Kosei Ijiri1, Luiz F. Zerbini, Haibing Peng, Ricardo G. Correa, Binfeng Lu¶, Nicole Walsh, Yani Zhao¶, Noboru Taniguchi||, Xu-Ling Huang, Hasan Otu, Hong Wang, Jian Fei Wang, Setsuro Komiya||, Patricia Ducy**, Mahboob U. Rahman2, Richard A. Flavell, Ellen M. Gravallese, Peter Oettgen, Towia A. Libermann, and Mary B. Goldring3

From the Beth Israel Deaconess Medical Center, New England Baptist Bone and Joint Institute and Beth Israel Deaconess Medical Center Genomics Center, and Harvard Medical School, Boston, Massachusetts 02115, Laboratory of Genetics, The Salk Institute for Biological Studies, La Jolla, California 92037, the ^¶Department of Immunology, University of Pittsburgh School of Medicine, Pittsburgh, Pennsylvania 15261, the ^||Department of Neuro-Musculoskeletal Disorders, Orthopaedic Surgery, Graduate School of Medicine and Dentistry, Kagoshima University, Kagoshima 890-8520, Japan, the ^**Department of Molecular and Human Genetics, Baylor College of Medicine, Houston, Texas 77030, the Center for Immunology and Inflammatory Diseases, Massachusetts General Hospital and Harvard Medical School, Boston, Massachusetts 02114, and Howard Hughes Medical Institute, Yale University School of Medicine, New Haven, Connecticut 06520-8011

Received for publication, April 18, 2005 , and in revised form, August 19, 2005.

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
The growth arrest and DNA damage-inducible 45 (GADD45) gene product has been implicated in the stress response, cell cycle arrest, and apoptosis. Here we demonstrated the unexpected expression of GADD45 in the embryonic growth plate and uncovered its novel role as an essential mediator of matrix metalloproteinase-13 (MMP-13) expression during terminal chondrocyte differentiation. We identified GADD45 as a prominent early response gene induced by bone morphogenetic protein-2 (BMP-2) through a Smad1/Runx2-dependent pathway. Because this pathway is involved in skeletal development, we examined mouse embryonic growth plates, and we observed expression of Gadd45 mRNA coincident with Runx2 protein in pre-hypertrophic chondrocytes, whereas GADD45 protein was localized prominently in the nucleus in late stage hypertrophic chondrocytes where Mmp-13 mRNA was expressed. In Gadd45^-/- mouse embryos, defective mineralization and decreased bone growth accompanied deficient Mmp-13 and Col10a1 gene expression in the hypertrophic zone. Transduction of small interfering RNA-GADD45 in epiphyseal chondrocytes in vitro blocked terminal differentiation and the associated expression of Mmp-13 and Col10a1 mRNA in vitro. Finally, GADD45 stimulated MMP-13 promoter activity in chondrocytes through the JNK-mediated phosphorylation of JunD, partnered with Fra2, in synergy with Runx2. These observations indicated that GADD45 plays an essential role during chondrocyte terminal differentiation.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Growth arrest and DNA damage-inducible (GADD)⁴ 45 is a member of the GADD45 family of small (18 kDa) proteins, also including GADD45 and GADD45. The GADD45 family is known to be associated with cell growth control, apoptotic cell death, and the cellular response to DNA damage (1, 2). Initially, GADD45, encoded by MyD118, was identified as a myeloid differentiation primary response gene activated by IL-6 in murine myeloid leukemia cells upon induction of terminal differentiation (1, 3). More recently, GADD45, which is induced by TGF- in a SMAD-dependent manner, has been identified as a positive regulator of TGF--induced apoptosis (4). Although GADD45 has been identified on DNA microarrays as prominently expressed genes in chondrocytes from adult articular cartilage and in chondrosarcoma or immortalized chondrocyte cell lines (5, 6), a role for GADD45 family members, including GADD45, during cartilage development has not been reported previously.

Formation of the vertebrate skeleton through endochondrial ossification, involving progressive differentiation of proliferating chondrocytes to growth-arrested hypertrophic cells, is one of the most complex processes in biology. In the embryonic or postnatal growth plate, terminal chondrocyte differentiation occurs during conversion of cartilage to a vascularized tissue that supports matrix remodeling, cartilage calcification, and recruitment of osteogenic precursors. Cascades of growth and differentiation factors act through positive and negative signaling kinases and transcription factors to tightly control this process. Bone morphogenetic proteins (BMPs), which were identified originally as molecules that induce ectopic endochondral ossification (7), set the stage for bone morphogenesis by initiating chondrogenesis and by regulating chondrocyte maturation and terminal differentiation to the hypertrophic phenotype (8-11). The actions of the BMPs are determined by spatial and temporal differences in the distribution of BMP-binding proteins, such as noggin and chordin, BMP receptors, and the associated signal-transducing acceptor proteins, Smads 1 and 5, and inhibitory Smads 6 and 7.

BMP-2, -4, -6, and -7 are known to stimulate the expression of markers of the hypertrophic phenotype, including type X collagen and alkaline phosphatase (11, 12), and these responses to BMPs in the growth plate are restricted to pre-hypertrophic chondrocytes derived from regions where endochondral bone will form (13). Previous studies have demonstrated that BMP-induced Smad1 and interactions with the Runt domain transcription factor, Runx2, or Cbfa1, are important for chondrocyte hypertrophy (14-16). Runx2 is required for bone formation (17, 18), serving as a positive regulatory factor in chondrocyte maturation to the hypertrophic phenotype (15). Matrix metalloproteinase (MMP)-13, a downstream target of Runx2, is expressed by terminal hypertrophic chondrocytes during endochondral ossification (19-22). Recent evidence indicates that MMP-13 deficiency results in significant interstitial collagen accumulation leading to the delay of endochondral ossification in the growth plate (23, 24). Although the induction of MMP-13 expression by cytokines in chondrocytes (25) and by parathyroid hormone-related protein in osteoblasts (26, 27) is known to involve cooperation between AP-1 and Runx2 transcription factors, the exact molecular mechanism of MMP-13 induction in hypertrophic chondrocytes remains unclear. Runx2 is expressed mainly in prehypertrophic and less in late hypertrophic chondrocytes (28, 29), whereas MMP-13 is expressed only in the late hypertrophic zone (30, 31). This spatial discrepancy suggests that unknown intermediate molecules may synchronize with Runx2 to regulate Mmp-13 gene expression.

During the course of a study to identify the BMP-2-induced early genes that might be involved in signaling and transcriptional regulation in human chondrocytes, we identified GADD45 as one of the most highly induced genes. We further showed specific induction of GADD45, but not GADD45 and GADD45, by BMP-2, but not by EGF, FGF-2, or IGF-I, by a mechanism involving Smad1-dependent signaling and synergism with Runx2. Because BMP-2 is an important regulator of skeletal development, we examined mouse embryos and demonstrated for the first time that Gadd45 mRNA is expressed by pre-hypertrophic chondrocytes coincident with the Runx2 protein, whereas GADD45 protein accumulates in hypertrophic chondrocytes. Analysis of Gadd45^-/- mouse embryos showed defective mineralization and decreased bone growth accompanied by decreased levels of Mmp-13 and Col10a1 mRNA in hypertrophic chondrocytes. In addition, lentiviral expression of siRNA-GADD45 blocked Mmp-13 gene expression during hypertrophic differentiation of epiphyseal chondrocytes in vitro. Furthermore, we show that GADD45 induces AP-1 transcriptional activity through JNK-mediated phosphorylation of JunD partnered with Fra2 and stimulates Mmp-13 promoter activity in synergism with Runx2. These results indicate that GADD45 has a critical role in mediating matrix remodeling during the final stages of chondrocyte terminal differentiation.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Cell Culture—The immortalized human chondrocyte cell line, C-28/I2, was cultured in Dulbecco's modified Eagle's medium (DMEM)/Ham's F-12 (1/1, v/v; Invitrogen) containing 10% fetal calf serum (FCS) (BioWhittaker), as described previously (32, 33). For experiments with growth factors, subconfluent cultures were changed to medium containing 1% Nutridoma-SP (Roche Applied Science) for 24 h prior to incubation in the presence of growth factors. Primary chondrocytes were isolated from human articular cartilage, obtained from intact regions of femoral condyles at the time of total knee replacement surgery, and cultured for 7-10 days in DMEM/Ham's F-12 containing 10% FCS. ATDC5 cells were grown in DMEM/Ham's F-12 containing 5% FCS, 10 µg/ml human insulin, 10 µg/ml human transferrin, and 10 µg/ml selenious acid, as described (34). After incubation in the presence of growth factors for 1 h, cells were harvested for RNA isolation. Three-dimensional pellet cultures of murine rib growth plate chondrocytes were prepared by the method of Ballock and Reddi (35). Chondrocytes from the ventral parts of rib cartilage of 2-day-old C57BL/6 mice were cultured in monolayer for 1 day followed by infection with lentiviral vector and culture for 2 days. Using trypsin/EDTA, the cells were resuspended at 1.6 x 10⁵ cells/ml, pelleted at 1 ml per tube in 15-ml conical polypropylene tubes by centrifugation at 1,000 rpm for 5 min at 4 °C, and cultured at 37 °C for periods of up to 21 days.

RNA Isolation and Microarray Analysis—Total RNA was isolated using RNase-free DNase and RNeasy mini kit (Qiagen). Transcriptional profiling was performed at the Genomics Center of the Beth Israel Deaconess Medical Center on HU133A Affymetrix GeneChips containing 22,283 genes, according to protocols supplied by Affymetrix, with 8 µg of total RNA per sample. For each sample, 20 µg of fragmented cDNA was hybridized with a pre-equilibrated HU133A Affymetrix chip, washed, stained, and scanned in the HP ChipScanner (Affymetrix Inc., Santa Clara, CA), as described (36).

Microarray data pre-processing was carried out by assigning each sample a quality measure based on criteria such as 3'-5' ratios, strength of hybridization, and image analysis. The samples that passed these a priori quality control criteria were analyzed using dChip software (37), by which smoothing spline normalization was applied prior to obtaining model-based gene expression indices or signal values. When comparing two groups of samples to identify the genes enriched in a given phenotype, we used the lower confidence bound of the fold change between the experiment and the base line. If the 90% lower confidence bound of the fold change between the experiment and the base line was above 1.2, the corresponding gene was considered to be differentially expressed (38).

Real Time PCR—For each sample, cDNA was generated as described previously (33, 39). Amplifications were carried out using SYBR Green I-based real time PCR on the MJ Research DNA Engine OpticonTM Continuous Fluorescence Detection System (MJ Research Inc., Waltham, MA), as described previously (40).

Immunoprecipitation and Western Blotting Analysis—After incubation without or with BMP-2 at 100 ng/ml for 1 h, the C-28/I2 cells were collected by scraping, and total protein was extracted with 50 mM Tris-HCl buffer (pH 7.4) containing 150 mM NaCl, 5 mM EDTA, 1% Nonidet P-40, 0.5% sodium deoxycholate, 0.1% SDS, protease inhibitor mixture (Roche Applied Science). The cell lysates were analyzed on Western blots using antibody against total Smad1 or phospho-Smad1/5/8 (Cell Signaling). For immunoprecipitations, the capture protein for the Runx2 antibody (PEBP2aA, Santa Cruz Biotechnology) was coated at 200 µl/well in a 96-well flat bottom, high binding microplate (Costar Corp., Cambridge, MA) at a final protein concentration of 2.4 µg/ml in 50 mM carbonate/bicarbonate buffer (pH 9.6) and incubated overnight at 4 °C. The plate was washed with phosphate-buffered saline (pH 7.4) containing 0.05% Tween 20 (PBST), blocked by applying 200 µl of 1% bovine serum albumin in PBST to each well, and incubated at room temperature for 1 h. Plates were washed three times with PBST. Cell lysate (1.1 mg of protein) was applied to each well, incubated at room temperature for 4 h, and washed three times with PBST. The bound protein was eluted with 1x SDS sample buffer and carefully loaded on a Tris-glycine SDS-10% polyacrylamide gel followed by Western blotting with rabbit anti-phosphoserine antibody (Zymed Laboratories Inc.) or the total Smad1 antibody (Cell Signaling).

Immunohistochemistry (IHC) and in Situ Hybridization—Hind limbs were collected from C57BL/6 mouse embryos fixed for 24 h in 4% paraformaldehyde. Limbs were embedded in paraffin, and 5-µm sections were obtained. Tissue sections were deparaffinized in xylene and rehydrated through an ethanol series for use in either IHC or in situ hybridization. For IHC, tissue sections were subjected to microwave antigen retrieval in 10 mM EDTA (pH 7.5) at 93 °C for 7 min and allowed to cool for at least 2 h. Sections were blocked with normal horse serum (for GADD45 IHC) or normal swine serum (for Runx2 IHC). IHC for GADD45 was performed as described previously (41), using goat polyclonal anti-GADD45 (sc-8776, Santa Cruz Biotechnology; 1:400 dilution, 0.5 µg/ml final concentration), rabbit biotinylated anti-goat IgG (Sigma), and the Vectastain Elite ABC kit (Vector Laboratories, Inc.). Anti-Runx2 antibody (PEBP2A, sc-10758, Santa Cruz Biotechnology; 1:25 dilution, 8 µg/ml final concentration), swine biotinylated anti-rabbit F(ab)₂, and streptavidin/horseradish peroxidase-conjugated (DAKO, Denmark) were used to detect Runx2 by IHC. Sections were counterstained with hematoxylin. For negative controls, normal goat IgG (sc-2028) and normal rabbit IgG (sc-2027) were used in place of the primary antibodies against GADD45 and Runx2, respectively. We optimized the staining methods for detection of cytoplasmic and nuclear staining with each antibody by testing both microwave and enzyme retrieval of each antigen.

For in situ hybridization, a 391-bp fragment of human GADD45 cDNA (sense, 5'-CTGGTTGTTGCCCCGGCTTTCTTC-3'; antisense, 5'-CGCGGTGGAGGAGCTTTTGGTG-3') and a 1006-bp fragment of mouse MMP-13 cDNA (sense, 5'CATCCACATGGTTGGGAAGTTCTG-3';antisense,5'-CATTCAGCTATCCTGGCCACCTTC-3') were obtained by reverse transcription-PCR and subcloned in the pCR II vector (Invitrogen). Plasmids were linearized using either HindIII or NotI for GADD45 and either KpnI or XhoI for MMP-13, respectively. The linearized plasmids served as templates for riboprobe synthesis using either T7 or SP6 RNA polymerases and digoxigenin-UTP RNA labeling nucleotide mix (Roche Applied Science) according to the manufacturer's instructions. The cDNA encoding type X collagen was a kind gift of Dr. Bjorn Olsen, Harvard Medical School, Boston. Hybridization was performed according to the method described previously (42).

Analysis of Gadd45^-/- Mice—Gadd45^-/- mice were generated on the C57BL/6 background, as described previously (43). Briefly, the targeting vector was constructed to replace exons 3 and 4, encoding the region crucial for interaction with MTK-1/MEKK4 (44), with the neomycin resistance cassette. Gadd45^-/- embryos and wild type littermates at 14.5, 15.5, 16.5, and 17.5 days post-conception (dpc), generated with the approval of the University of Pittsburgh Institutional Animal Care and Use Committee, were fixed in 4% paraformaldehyde/phosphate-buffered saline overnight at 4 °C and stored in 70% ethanol at room temperature. Whole embryos were stained with Alcian Blue and Alizarin Red. Long bones were sectioned and stained with toluidine blue or von Kossa or analyzed by in situ hybridization as described above.

Plasmids—The human GADD45 promoter fragment spanning -1604 to +141 was prepared by PCR using human genomic DNA (Clontech) as template. The PCRs were carried out using the Pfu Turbo DNA polymerase (Stratagene), and the products were subcloned in the pGL2-basic vector (Promega, Madison WI) and verified by DNA sequencing. Smad1, Smad4, and alk6 expression vectors were gifts from Dr. Xu Cao (University of Alabama). The Runx2 and Runx2 expression vectors were described previously (45). The pcDNA3-GADD45-FLAG plasmid was generated as described previously (40). The pAP-1 Luc plasmid was obtained from Stratagene. The MMP-13 promoter sequence spanning-1007/+26 bp was prepared by PCR using a pCAT-MMP-13 promoter construct⁵ as a template, and cloned in the pGL2-B vector in the XmaI and XhoI sites. Expression vectors for JunD, JunB, Fra1, and Fra2 were kindly provided by Dr. Paul R. Dobner (University of Massachusetts Medical Center, Worcester, MA). The dominant negative JunD was described previously (46).

Transient Transfections and Luciferase Assay—Transient transfection experiments were performed in C-28/I2 cells and ATDC5 cells using Lipofectamine Plus (Invitrogen), as described (33, 40), but in 12-well plates. Cells were plated at 100,000 cells per well and transfected with 300 ng of pGL2-promoter plasmid and 10-100 ng of expression plasmid. Luciferase activity was measured 24 h later using the dualluciferase reporter assay system (Promega). Cotransfection with pRL-TK Renilla luciferase control vector was used for controlling transfection efficiency. Cotransfections of the promoter-less pGL2-B vector with expression plasmids did not significantly increase activity compared with promoter-containing vectors. This is in contrast to a study showing that 1 µg of Runx2 expression vector increased luciferase activity when cotransfected with 1 µg of promoter-less pGL2 or pGL3 vector in cells plated in 6-well plates (47). Transfections were performed in triplicate, and experiments were repeated three times with different plasmid preparations with similar results.

Knockdown of GADD45 Expression by siRNA—Two approaches were used. First, chemically synthesized complementary RNA oligonucleotides (siRNA-GADD45 sense-strand sequence, 5'-AAGTTGATGAATGTGGACCCA) were annealed, deprotected, and desalted as recommended by the manufacturer (Qiagen). A total of 50 µM RNA duplexes was transfected into cells using TKO transfection reagent (Mirus, Madison, WI) and tested for specificity and efficiency, as described previously (40). Second, a lentiviral vector containing siRNA-GADD45 was constructed using single 83-mer oligonucleotides containing an XbaI site at the 5' end, an intermediate short spacer, and a partial sequence of the H1-RNA promoter at the 3' end, as described previously (40). Standard PCR procedures (Advantage 2 PCR kit, Clontech) were performed using specific siRNA oligonucleotides and T3 primer plus pSuper-like plasmid as template to provide H1-mediated siRNA cassettes with an additional XbaI site at the 3' end (48). PCR products were purified (Qiagen), digested with XbaI, and cloned into the 3'-long terminal repeat NheI site of a CMV-GFP lentiviral vector as described (48). The LV-siRNAGFP construct (control) was kindly donated by Dr. Oded Singer (Salk Institute). The following siRNA oligonucleotide for GADD45 was used, 5'-CTGTCTAGACAAAAAGTTGATGAATGTGGACCCAtctcttgaaTGGGTCCACATTCATCAACGGGGATCTGTGGTCTCATACA-3'. Vesicular stomatitis virus G envelope protein-pseudotyped lentiviruses were prepared and purified as described previously (48-50). Vector concentrations were analyzed by immunocapture p24 gag enzyme-linked immunosorbent assay (Alliance, PerkinElmer Life Sciences) (49). The C-28/I2, ATDC5, or murine epiphyseal chondrocytes were plated in monolayer at 25,000 cells/cm² for 1 or 2 days, followed by infection with LV-siRNA-GFP or LV-siRNA-GADD45 at a multiplicity of infection of 10. In tests for specificity and efficiency, cells were transfected with GFP-FLAG and GADD45-FLAG. Cells infected with LV-siRNA-GFP showed no staining for GFP, whereas GFP staining was not affected in cells infected with LV-siRNA-GADD45. On Western blots, transfected GADD45-FLAG was detected on Western blots using anti-FLAG antibody in cells infected with LV-siRNA-GFP, but not in cells infected with LV-siRNA-GADD45. (see supplemental Fig. S1).

EMSA and Supershift Assay—Whole cell extracts were made from uninfected, LV-siRNA-GFP-infected (GFP KD), or LV-siRNA-GADD45-infected (GADD45 KD) C-28/I2 cells, and DNA binding reactions and EMSAs were performed using a ³²P-labeled oligonucleotide containing the AP-1 consensus (Santa Cruz Biotechnology), as described (33, 46). Extracts from DU145 cells were used as a positive control for activated AP-1 (data not shown) (46). For supershift analysis, the cell extracts were preincubated with specific antibodies against different members of the AP-1 family (Santa Cruz Biotechnology) for 20 min before the incubation with labeled probe for an additional 20 min (46).

Analysis of Protein Kinases—To examine protein kinase activities, the C-28/I2 cells without or with siRNA-GADD45 were transfected with pcDNA3 expression vectors encoding control-FLAG or GADD45-FLAG. After transfection, the cells were cultured for 12 h with DMEM/F-12, 1% Nutridoma, followed by addition of BMP-2 (100 ng/ml) and further incubation for 12 h before collection of total cell lysates. Western blots were performed using antibodies against JunD (Santa Cruz Biotechnology) and phospho-c-Jun (Ser-73) (Cell Signaling) according to the manufacturers' protocols. PD98059 (10 µM), SB203580 (10 µM), or SP600125 (100 µM) was added to cultures 1 h before BMP-2. JNK, ERK and p38 kinase activities were measured by using the SAPK/JNK, p44/42, and p38 MAPK assay kit (Cell Signaling) according to the manufacturer's protocol.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Specific Up-regulation of GADD45 by BMP-2 in Human Chondrocytes—To characterize the genes involved in the early response to BMP-2 in chondrocytes, we performed oligonucleotide microarray-based gene expression profiling using RNA isolated from the immortalized human chondrocyte cell line, C-28/I2, after treatment with BMP-2 for 1 h. BMP-2 induced distinct patterns of coordinated changes in a wide range of transcripts, which encode cell cycle-related and anti-apoptotic molecules and transcription factors that are known to regulate growth and survival cascades. Identification of highly expressed genes induced by BMP-2 (more than 2 times > control) yielded 249 transcript variants. Actin-related protein 2/3 complex subunit 4 was the most highly expressed gene stimulated by BMP-2 (18.4 times). Analysis of gene ontology molecular function revealed 31 transcription factors, including ZNF238 (7.5 times), JunD (5.3 times), JunB (4 times), ID3 (4 times), and DLX2 (3.7 times) and 11 kinases, such as phosphatidylinositol 3-kinase regulatory subunit 3 (7.5 times), AKT2 (6.5 times), TK 2 (4 times), and AXL (3 times), which were induced by BMP-2 after 1 h. A complete set of the microarray data is provided as supplemental material. GADD45, which was among the most highly up-regulated BMP-2-induced genes, was detected by all three representative probe sets present on the Affymetrix GeneChip Human Genome U133A, whereas GADD45 and GADD45 transcripts were not altered by the treatment with BMP-2 (TABLE ONE). Real time PCR corroborated the microarray data showing that BMP-2 at concentrations of 50 and 100 ng increased GADD45 mRNA (Fig. 1A). Other growth and differentiation factors, including epidermal growth factor (EGF), basic fibroblast growth factor (bFGF), and insulin-like growth factor (IGF)-I, had no effect (Fig. 1A), indicating the specificity of the BMP-2 response. Real time PCR also confirmed that BMP-2 had no effect on GADD45 or GADD45 mRNA (Fig. 1, B and C). Furthermore, the peak of induction was 1 h after the addition of BMP-2 with a gradual decline thereafter, such that there was no difference between treated and untreated at 24 h (Fig. 1D). Finally, the BMP-2-induced increase in GADD45 mRNA was confirmed in primary human articular chondrocytes (Fig. 1E).

Expression of GADD45 in the Mouse Embryonic Growth Plate—Because Runx2 is expressed in the growth plate as a major transcriptional regulator of chondrocyte terminal differentiation, we asked whether GADD45 is also expressed during skeletal development. Therefore, we performed in situ hybridization and immunohistochemical assays in the mouse embryonic limb. We detected expression of Gadd45 mRNA at 14.5 (data not shown) and 15.5 dpc (Fig. 3, A and B) primarily in prehypertrophic chondrocytes, where Runx2 protein was localized most prominently in the nucleus (Fig. 3C). On the other hand, immunoreactive GADD45 protein was detected most strongly in the nuclei of intact hypertrophic chondrocytes (Fig. 3, D, F, and J). Runx2 persisted through this region into the late hypertrophic zone of the femur (Fig. 3C), where Mmp-13 mRNA was also detected (Fig. 3, H and K). As shown in Fig. 3 (H and K), Mmp-13 mRNA colocalized with nuclear GADD45 protein in the late hypertrophic zone of the tibia. These data demonstrate that Gadd45 mRNA is induced in prehypertrophic chondrocytes coincident with prominent nuclear Runx2 protein, whereas GADD45 protein accumulates in the nuclei of hypertrophic chondrocytes in the region destined to undergo ossification, where Mmp-13 mRNA is also expressed.

View larger version (19K): [in this window] [in a new window]   FIGURE 1. Specific up-regulation of GADD45 mRNA by BMP-2 in chondrocytes. Monolayer cultures of the human chondrocyte cell line C-28/I2 were treated as indicated, and total RNA extracts were analyzed by real time PCR. Each value was normalized to glyceraldehyde-3-phosphate dehydrogenase (GAPDH) in the same sample and shown as the mean ± S.D. of triplicate cultures. A, GADD45 mRNA levels were increased in cultures of the human chondrocyte cell line, C-28/I2, after treatment with BMP-2 for 1 h but not with EGF, bFGF, or IGF-I. B and C, incubation of C-28/I2 cells with BMP-2 for 1 h did not increase the levels of GADD45 or GADD45 mRNA. D, time course of BMP-2-induced GADD45 mRNA in C-28/I2 cells showed transient induction with a peak at 1 h. E, treatment of primary human articular chondrocytes with BMP-2 for 1 h increased the levels of GADD45 mRNA by 2-fold.

View larger version (27K): [in this window] [in a new window]   FIGURE 2. The induction of GADD45 promoter activity by BMP-2 requires signaling by Smad1 interacting with Runx2. A, the pGL2-GADD45 promoter (-1604/+141 bp) was cotransfected with expression vectors encoding the BMP type IB receptor (alk6), Smad1, or Smad6 alone or in combination, or Runx2 or Runx2 alone or in combination. The results show the means ± S.D. of determinations of samples from three or more separate wells. B, the C-28/I2 cells were incubated without (-) or with (+) BMP-2 for 1 h, and total lysates were analyzed on Western blots (WB) using antibodies against phospho-Smad1/5/8 and total Smad1. C, total cell lysates were subjected to immunoprecipitation (IP) with anti-Runx2 and analyzed on Western blots using anti-phosphoserine or Smad1 antibody.

The defective mineralization and deficient Mmp-13 mRNA expression at the site of the primary ossification center at 15 dpc preceded the decreased bone growth observed in Gadd45^-/- mouse embryos at 16.5 dpc (Fig. 5). A delay in mineralization, indicated by Alizarin Red staining was noted in the ribs of Gadd45^-/- embryos (arrows, Fig. 5A) and in both fore and hind limbs (Fig. 5, B and C). The hypertrophic zone of the tibia of the Gadd45^-/- embryo was decreased in length compared with WT (Fig. 5D). Decreased expression of type X collagen (Col10a1) mRNA, a specific marker of the hypertrophic phenotype (14), throughout the hypertrophic zone accompanied the markedly decreased Mmp-13 mRNA expression in the late hypertrophic zone (Fig. 5E). These data suggest that GADD45 is involved in terminal differentiation of hypertrophic chondrocytes and may contribute to Mmp-13 gene regulation.

Requirement of GADD45 for Expression of Mmp-13 mRNA during Hypertrophic Chondrocyte Differentiation in Vitro—To confirm the results in Fig. 5 and to determine the extent of dependence of Mmp-13 gene expression in hypertrophic chondrocytes upon GADD45, we used murine rib growth plate chondrocytes in three-dimensional pellet culture, an established model in which terminal chondrocyte differentiation occurs spontaneously (35). In control GFP knockdown (KD) cultures infected with a lentiviral vector encoding siRNA-GFP, chondrocytes with hypertrophic morphology were present at days 14 and 21 and were surrounded by matrix that stained metachromatically with toluidine blue (pink staining in matrix in Fig. 6A), evidence of the early proteoglycan deposition that occurs in this model. Strong expression of Mmp-13 and Col10a1 mRNA was confirmed by in situ hybridization in the GFP KD cultures at day 21 (Fig. 6B). In contrast, GADD45 KD cells, which were infected with a lentivirus encoding siRNA-GADD45, did not develop hypertrophic morphology or increase metachromatic staining with toluidine blue even after 21 days of culture (Fig. 6A). Furthermore, in situ hybridization analysis showed that the levels of Mmp-13 mRNA, as well as Col10a1 mRNA, specific marker of the hypertrophic phenotype, were decreased markedly in the GADD45 KD cells compared with the GFP KD cells (Fig. 6B). These results support the in vivo data, where GADD45 expression is restricted in a temporal-spatial manner, and suggest that GADD45 is an essential regulator of chondrocyte terminal differentiation that may influence, directly or indirectly, Mmp-13 gene expression during hypertrophy.

View larger version (72K): [in this window] [in a new window]   FIGURE 3. Expression of Gadd45 mRNA together with Runx2 protein in prehypertrophic chondrocytes and intracellular GADD45 protein in the hypertrophic chondrocytes that express Mmp-13 mRNA. Adjacent longitudinal sections from mouse embryonic femurs or tibiae (15.5 dpc) were analyzed by immunohistochemistry and in situ hybridization to illustrate the expression of GADD45 in relation to Runx2 protein and MMP-13 mRNA in proliferating (pro), prehypertrophic (pre-hy), and hypertrophic (hyp) zones indicated in A. Antisense Gadd45 (A and B) and anti-GADD45 antibody (D) were used to detect Gadd45 mRNA, and protein and anti-Runx2 antibody (C) detected Runx2 protein in mouse femurs. Sense Gadd45 (insets, A and B), normal goat IgG (inset, C), and normal rabbit IgG (inset, D) were applied as negative controls. Tibiae at 15.5 dpc were stained with toluidine blue (T.Blue, E). GADD45 protein was detected in late stage hypertrophic chondrocytes (F and J), in which Mmp-13 mRNA was also detected using antisense MMP-13 (H and K). Normal goat IgG (G) and sense Mmp-13 (I) were applied as negative controls. Brown staining indicates immunodetectable protein, and purple staining indicates a positive signal using antisense probe. Original magnification: A, E-I, x40; B-D, F, and G, x200.

View larger version (37K): [in this window] [in a new window]   FIGURE 4. Defective mineralization accompanies decreased Mmp-13 mRNA expression in hypertrophic chondrocytes of Gadd45-/- mouse embryos at 15 dpc. Tibiae from WT and Gadd45-/- mouse embryos at 15.5 dpc were examined by toluidine blue staining (A and D), von Kossa staining (B and E), and in situ hybridization for Mmp-13 mRNA (C, F, G, and H). Original magnifications: A-F, x40; G and H, x200.

View larger version (62K): [in this window] [in a new window]   FIGURE 5. Gadd45-/- mouse embryos at 16. 5 dpc exhibit decreased bone growth associated with decreased levels of Mmp-13 and Col10a1 mRNA in hypertrophic chondrocytes. Whole mounted embryos at 16.5 dpc were stained with Alcian Blue and Alizarin Red to show decreased cartilage matrix and mineralization in ribs (A, arrowheads), forearms (B), and hind limbs (C) of Gadd45-/- compared with WT mice. Adjacent longitudinal sections from the tibia at 16.5 dpc showed a smaller hypertrophic zone by toluidine blue (T.Blue) staining (D) accompanied by markedly decreased levels of Mmp-13 mRNA (E, arrowhead) and Col10a1 mRNA in Gadd45-/- mouse embryos compared with WT. Original magnifications: D, x40; E, x200.

View larger version (49K): [in this window] [in a new window]   FIGURE 6. GADD45 is required for hypertrophic chondrocyte differentiation in vitro and associated expression of Mmp-13 and Col10a1 mRNA. A, murine rib growth plate chondrocytes were infected with lentivirus encoding siRNA-GFP to generate GFP KD cells or with siRNA-GADD45 to generate GADD45 KD cells and cultured as three-dimensional pellets for 3, 14, and 21 days. Toluidine blue staining showed the progressive hypertrophy in cultures of GFP KD chondrocytes but not in the cultures of GADD45 KD chondrocytes. Magnification is x40. B, after 21 days of culture, toluidine blue (T.Blue) staining and the levels of Col10a1 and Mmp-13 mRNA, detected by in situ hybridization using antisense probes, were markedly decreased in GADD45 KD compared with GFP KD cells. Magnification is x200.

JNK Activity Is Necessary for JunD Activation by GADD45—To unravel the mechanism of JunD activation by GADD45, we evaluated the phosphorylation status of JunD in GADD45-expressing and GADD45 KD chondrocytes. We analyzed cell extracts from C-28/I2 cells for kinase activation using antibodies against phospho-c-Jun, phospho-Elk-1, and phospho-ATF-2, specific substrates for JNK, ERK, and p38, respectively. As shown in Fig. 8A, transduction of GADD45 induced JunD phosphorylation at serine 100, which is reported as a direct JNK target residue (53). The phosphorylation was completely blocked in the presence of the JNK inhibitor, SP600125, but not by the ERK inhibitor, PD98059, or by the p38 inhibitor, SB203580. Transduction of siRNA-GADD45 blocked the GADD45-dependent JunD phosphorylation (Fig. 8A). JNK activity, detected as phospho-c-Jun, was clearly increased in GADD45-expressing cells and siRNA-GADD45 blocked its activity, whereas ERK was activated only slightly by GADD45, and p38 activity was not altered (Fig. 8B). These results are consistent with previous studies reporting that GADD45 family members are upstream activators of the JNK pathway (2, 54-56).

JunD-dependent MMP-13 Promoter Activation by GADD45 in ATDC5 Cells and Synergism with Runx2—To determine the functional consequences of GADD45-induced AP-1 transcriptional activity in hypertrophic chondrocytes, we investigated the response of the MMP-13 promoter using ATDC5 cells, a well characterized chondrogenic cell line that undergoes terminal differentiation to the hypertrophic phenotype in vitro (34). Because MMP-13 gene transcription is known to involve Runx2 and AP-1 (25-27), we performed cotransfection experiments using FLAG-GADD45, Runx2, and JunD expression vectors in various combinations with the pGL2-MMP-13 reporter vector containing promoter sequences spanning -1007 to +26 bp. As shown in Fig. 9A, overexpression of either GADD45 or Runx2 up-regulated MMP-13 promoter activity by 2.5-3-fold. Cotransfection with both Runx2 and GADD45 expression vectors enhanced promoter activity by around 4-fold (Fig. 9A). Furthermore, transduction of siRNA-GADD45 reduced MMP-13 promoter activity to 25% of the constitutive activity in ATDC5 cells (Fig. 9B).

View larger version (31K): [in this window] [in a new window]   FIGURE 7. GADD45 positively regulates AP-1 activity and JunD/Fra2 binding in chondrocytes. The AP-1-driven luciferase reporter vector (pAP-1-Luc) was cotransfected in C-28/I2 cells with the GADD45 expression vector (GADD45-FLAG) at 50 and 100 ng/ml (A) or with GADD45-FLAG alone or together with siRNA-GADD45 (B). C, extracts were prepared from uninfected C-28/I2 cells (1st and 2nd lanes), cells infected with lentiviral siRNA-GFP (GFP KD; 3rd and 5th lanes), or siRNA-GADD45 (GADD45 KD; 4th and 6th lanes). Cells were then transfected with GFP-FLAG (control) or GADD45-FLAG, as indicated. AP-1 binding activity was examined by EMSA using the double-stranded AP-1 consensus oligonucleotide as labeled probe. The cells extracted for the 5th and 6th lanes (lower exposure of gel shift using probe labeled at different time) were not transfected to show that decreasing endogenous GADD45 also decreases AP-1 binding activity. D, supershift analysis of binding activities in GADD45-expressing C-28/I2 cells was performed using antibodies against different AP-1 family members. Note that the Fra1, JunB, and JunD antibodies produce supershifts, whereas the Fra2 antibody produces a block shift. E, the C-28/I2 cells were cotransfected with pAP-1-Luc together with expression vectors encoding Fra1, Fra2, JunD, and JunB alone or in combination in the absence or presence of the GADD45-FLAG. Luciferase activities are shown as means ± S.D. of replicates from representative transfections. *, p < 0.05; **, p < 0.01; by analysis of variance with subsequent Dunnett test in multiple comparisons. Comparisons in E are with respective controls containing single expression vectors.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
In this study, we have highlighted a new function of GADD45, a member of a group of stress-response proteins that are associated with growth arrest and cell survival. We initially identified GADD45 as a candidate target of BMP-2 using microarray analysis. Because BMP-2 is known to be involved in hypertrophic differentiation of chondrocytes, we asked whether GADD45 could play a role during endochondral ossification in the mouse embryo. Thus, we made the novel observation that Gadd45 mRNA is expressed by pre-hypertrophic chondrocytes in the mouse embryonic growth plate, where Runx2 is also detected, whereas GADD45 protein accumulates in the nuclei of chondrocytes of the hypertrophic zone, where Runx2 protein also persists, prominently in late hypertrophic chondrocytes expressing Mmp13 mRNA prior to mineralization. In further studies, we found that GaddD45^-/- mice embryos display defective mineralization accompanied with a decreased number of Mmp-13- and Col10a1-expressing hypertrophic chondrocytes with the consequence of decreased bone growth. By using models of chondrocyte hypertrophic differentiation in vitro and siRNA technology, we provide clear evidence to support an essential role for GADD45 in the regulation of Mmp-13 gene expression. Finally, we reveal that GADD45-mediated up-regulation of MMP-13 promoter activity is because of an increase in AP-1 activity through the JNK/JunD pathway and that Runx2 cooperates with GADD45 and JunD to enhance this response.

View larger version (44K): [in this window] [in a new window]   FIGURE 8. JNK activity is necessary for JunD activation by GADD45. A, extracts from C-28/I2 cells expressing GADD45-FLAG or siRNA-GADD45 were analyzed by Western blotting using antibodies against phosphorylated (phospho) or total JunD. GADD45-expressing cells were also treated with inhibitors of ERK (PD98059), p38 (SB203580), and JNK (SP600125) to examine the roles of the different kinases in JunD phosphorylation by GADD45. B, kinase activities were analyzed on Western blots to show increased JNK (phospho-c-Jun) and ERK (phospho-Elk) activities in GADD45-FLAG cells and decreased activities in cells expressing siRNA-GADD45. Note that p38 activity (phospho-ATF-2) did not change.

Runx2, or Cbfa1, belongs to the family of Runt domain genes, which play fundamental roles in organ development and cell differentiation (17), and together with SMAD proteins is involved in the regulation of phenotypic gene expression during osteogenesis (51). We demonstrate in our study that GADD45 promoter activity is regulated by Smad1-dependent signaling in cooperation with Runx2. Previous studies have focused on regulation by NF-Bof GADD45 gene expression, which is induced by interleukin (IL)-6, IL-1, TGF-, TNF-, IL-18, and genotoxic and oxidative stress in various cell types (44, 66). Three B elements at positions -447/-438 bp, -426/-417 bp, and -377/-368 bp are responsive to the NF-B subunit RelA (66). Yoo et al. (4) suggested the existence of a TGF--responsive sequence within the GADD45 -220/-1-bp promoter region, and potential SMAD enhancesomes have been identified in both the murine and human promoters (67). Recent studies suggest that both SMAD-dependent and -independent mechanisms could be involved in BMP-2-induced GADD45 expression (68, 69). Thus, analysis of the GADD45 promoter will require a more extensive study in our chondrocyte models.

Regarding the specific function of Runx2 during endochondral ossification, it serves as a positive regulatory factor in chondrocyte maturation to the hypertrophic phenotype (15, 19, 20) and is expressed in the adjacent perichondrium and in prehypertrophic chondrocytes but less in late hypertrophic chondrocytes (28, 29), overlapping with Col10a1 (70, 71). Our findings indicate that Runx2 plays a synergistic role in both the induction and activity of GADD45 by enhancing BMP-2-induced Smad1 signaling and AP-1-dependent MMP-13 gene expression. The distinct spatial localization of Gadd45 mRNA compared with the accumulated intracellular protein in the late hypertrophic zone suggests that it acts in a temporal-spatial manner to regulate the duration of chondrocyte terminal differentiation.

In studies using Mmp-13^-/- mice, MMP-13 deficiency results in significant interstitial collagen accumulation leading to the delay of endochondral ossification in the growth plate and increased length of the hypertrophic zone (23, 24). In Gadd45^-/- mice, we observe defective mineralization at 15.5 and 16.5 dpc persisting at least until 18.5 dpc (data not shown), but decreased length of the hypertrophic zone. This discrepancy may be due to regulation by GADD45 of other activities in hypertrophic chondrocytes, but also the selective loss of MMP-13 in the hypertrophic zone of the Gadd45^-/- growth plate appears to affect the late stage of terminal differentiation only. Furthermore, GADD45 is not the only determinant of the expression of MMP-13, which is expressed also in osteoblasts, osteoclasts, and periosteal cells below the inner periosteal region of ossification (72). Consistent with the persistent mineralization in the bone collar surrounding the Gadd45^-/- growth plate, abundant tartrate-resistant acid phosphatase (TRAP)-positive osteoclast-like cells were present in the diaphyseal collar in Gadd45^-/- mice.⁶

In contrast to Mmp-13 knock-out mice but similar to the Gadd45 knock-out mice, both Col10a1 knock-out mice and transgenic mice with a dominant interference Col10a1 mutation have subtle growth plate phenotypes with compressed proliferative and hypertrophic zones and altered mineral deposition (73, 74). The decreased Col10a1 expression because of GADD45 deficiency suggests that GADD45 plays a role in matrix remodeling at the late hypertrophic stage The chondrodysplasia (cho/cho) mouse, which carries a loss of function mutation in the Col11a1 gene, has wider long bones and shorter length possibly because type XI collagen influences the formation of type II collagen fibrils at early stages of chondrogenesis (75). Other ECM proteins, including osteocalcin and osteopontin, are known to play functional roles in cell-matrix adhesion during endochondral ossification. Thus, the tight regulation of matrix composition at different stages is required for normal development of long bones.

View larger version (20K): [in this window] [in a new window]   FIGURE 9. JunD-dependent MMP-13 promoter activation by GADD45 in cooperation with Runx2 in the ATDC5 chondrogenic cell line. The ATDC5 cells were cotransfected with the pGL2-MMP-13 promoter (-1007 bp/+26 bp) construct and expression vectors encoding GADD45 and Runx2 (A), siRNA-GADD45 (B), Runx2 and JunD (C), or GADD45 and dominant negative (DN) JunD (D). The results show the means ± S.D. of determinations in triplicate wells from representative experiments. Empty expression vector controls or promoter-less pGL2-B did not induce or express any significant luciferase activity (not shown).

Although our analyses of Gadd45^-/- mice did not demonstrate complete suppression of hypertrophic differentiation itself, our finding that GADD45 silencing decreases the expression of Mmp-13 as well as Col10a1 during terminal differentiation in vitro supports a role of GADD45 as a crucial regulator in this process. Col10a1 is also a Runx2-responsive gene in hypertrophic chondrocytes (14). Thus, GADD45 may be involved, directly or indirectly, in the regulation of other key processes in hypertrophic differentiation through cooperation with Runx2. GADD45 is associated with cell cycle G₂-M arrest (79), suggesting that it may act as a switch to inhibit chondrocyte proliferation during the transition to hypertrophy. The remodeling of matrix proteins induces an alteration in the environmental stress experienced by hypertrophic chondrocytes (12, 30). Our data suggest that GADD45, which is highly expressed in response to environmental stresses (44), is an essential stress-response protein during chondrocyte hypertrophy.

The process of chondrocyte death subsequent to terminal differentiation to hypertrophy is also one of the most complicated steps during endochondral ossification, but the mechanism remains unknown. The GADD45 family members are indispensably involved in the mechanism of cell survival and apoptosis in cancer cells (54). Recently, we reported that NF-B-mediated repression of GADD45 and GADD45 is essential for the survival of cancer cells, but we found no relevance for GADD45 in cell survival and apoptosis (40). In fibroblasts, GADD45 is essential for JNK-mediated blockade of TNF--induced apoptosis (80). Although our present study does not address whether GADD45 is an anti-apoptotic or pro-apoptotic protein in chondrocytes, its intracellular localization in intact hypertrophic chondrocytes suggests a role as a survival factor that maintains expression of critical genes prior to apoptosis. The decreased length of the hypertrophic zone in Gadd45^-/- mice suggests that GADD45 may prolong survival of hypertrophic chondrocytes at later stages.

AP-1 transcription factors, including c-Jun, JunB, and JunD, are substrates of the JNK signaling pathway (81), and GADD45 is known to activate the JNK pathway in response to environmental stress (44). This interaction activates MEKK4 kinase leading to MKK4 and, subsequently, JNK activation. However, GADD45 also mediates the NF-B suppression of JNK signaling in the apoptotic response to TNF- (54, 80). This controversy surrounding GADD45 and JNK has left open the question of how GADD45 contributes to cell differentiation. We applied a mass spectrometric assay (MALDI-TOF MS) to identify protein-protein interaction partners of GADD45 proteins in vivo resulting in identification of MEKK4, the upstream kinase of JNK, as an in vivo interactor of GADD45,⁷ as reported previously (44). Several mitogen-activated protein kinase cascades are involved in BMP-induced signaling during skeletal development. The p38 pathway contributes to the initiation of chondrogenic cellular condensation (82), and ERK1/2 activation cross-interacts with BMP-2-induced signaling to regulate chondrogenesis in a positive manner (83). Our results indicate that chondrocytes also use the JNK/MEKK4 pathway during terminal differentiation.

Several genetic studies have provided insight into the role of AP-1 family members, including c-Fos, Fra-1, c-Fos, FosB, JunB, and ATF-2 in skeletal development in vivo (84-89). MMP-13 is also a target of c-Maf, which can form heterodimers with AP-1 family members and regulates the differentiation of hypertrophic chondrocytes (90). Our results show that GADD45-induced AP-1/JunD activity is essential for MMP-13 expression in hypertrophic chondrocytes and are consistent with previous findings of functional interaction between AP-1 and Runx2 during parathyroid hormone-related protein-dependent MMP-13 expression in osteoblasts (26, 27). The nuclear localization of GADD45 in hypertrophic chondrocytes also suggests a direct mechanism by which AP-1 family members could regulate terminal differentiation.

In conclusion, our data demonstrate a novel role in chondrocyte hypertrophy for GADD45, which has been implicated in the stress response and cell survival during terminal differentiation of other cell types. It appears to be a major BMP-2-responsive gene induced in chondrocytes by Smad1-dependent signaling in cooperation with Runx2, which immunolocalizes with GADD45 mRNA in the prehypertrophic zone of the embryonic growth plate. The intracellular accumulation of Gadd45 protein prominently in the nucleus in intact hypertrophic chondrocytes in the mouse embryonic growth plate and the consequences of GADD45 deficiency in vivo and in vitro indicate that Gadd45 is required for MMP-13 expression in the late hypertrophic zone where Runx2 is also expressed. Our observations that GADD45 can stimulate MMP-13 gene transcription via the JNK/JunD pathway in synergy with Runx2 provides a new concept regarding a temporal and spatial link between BMP-2-induced pathways upstream and the expression of genes required at terminal stages. Together, our findings support a previously undiscovered role for GADD45 as a critical mediator of chondrocyte hypertrophy during endochondral ossification.

	FOOTNOTES

 
^* This work was supported in part by National Institutes of Health Grants R01-AR45378 and R01-AG22021 (to M. B. G.) and R01-AI49527 (to T. A. L.) and a Biomedical Science Grant from the Arthritis Foundation (to M. B. G.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

The on-line version of this article (available at http://www.jbc.org) contains Fig. S1.

¹ Present address: Dept. of Orthopaedic Surgery, Graduate School of Medical and Dental Sciences, Kagoshima University, Kagoshima 890-8520, Japan.

² Present address: Centocor, Inc., 200 Great Valley Pkwy., Malvern, PA 19355-1307.

³ To whom correspondence should be addressed: Harvard Institutes of Medicine, HIM246, 4 Blackfan Circle, Boston, MA 02115-5713. Tel.: 617-667-0742; Fax: 617-975-5299; E-mail: mgoldrin{at}bidmc.harvard.edu.

⁴ The abbreviations used are: GADD45, growth arrest and DNA damage-inducible 45; BMP, bone morphogenetic protein; MMP, matrix metalloproteinase; EMSA, electrophoretic mobility shift assays; JNK, c-Jun N-terminal kinase; siRNA, small interfering RNA; EGF, epidermal growth factor; VEGF, vascular endothelial growth factor; IGF, insulin-like growth factor; bFGF, basic fibroblast growth factor; IL, interleukin; TGF, transforming growth factor; TNF, tumor necrosis factor; DMEM, Dulbecco's modified Eagle's medium; FCS, fetal calf serum; IHC, immunohistochemistry; GFP, green fluorescent protein; ECM, extracellular matrix; WT, wild type; dpc, days post-conception; KD, knockdown; ERK, extracellular signal-regulated kinase.

⁵ M. Rahman, unpublished data.

⁶ K. Ijiri, N. Walsh, and M. B. Goldring, unpublished data.

⁷ L. F. Zerbini, K. Ijiri, M. B. Goldring, and T. A. Libermann, unpublished data.

	ACKNOWLEDGMENTS

 
We are grateful to Dr. Inder M. Verma for help with the generation of LV-siRNA-GADD45, to Dr. Elisabeth Morris (Wyeth, Cambridge, MA) for providing recombinant human BMP-2, and to Dr. Benjamin Bierbaum (New England Baptist Hospital) for providing human articular cartilage. We also thank Dr. Bob Choy for technical advice.

	REFERENCES

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 

1. Abdollahi, A., Lord, K. A., Hoffman-Liebermann, B., and Liebermann, D. A. (1991) Oncogene 6, 165-167[Medline] [Order article via Infotrieve]
2. Amanullah, A., Azam, N., Balliet, A., Hollander, C., Hoffman, B., Fornace, A., and Liebermann, D. (2003) Nature 424, 741-742[Medline] [Order article via Infotrieve]
3. Selvakumaran, M., Lin, H. K., Sjin, R. T., Reed, J. C., Liebermann, D. A., and Hoffman, B. (1994) Mol. Cell. Biol. 14, 2352-2360[Abstract/Free Full Text]
4. Yoo, J., Ghiassi, M., Jirmanova, L., Balliet, A. G., Hoffman, B., Fornace, A. J., Jr., Liebermann, D. A., Bottinger, E. P., and Roberts, A. B. (2003) J. Biol. Chem. 278, 43001-43007[Abstract/Free Full Text]
5. Aigner, T., Zien, A., Gehrsitz, A., Gebhard, P. M., and McKenna, L. (2001) Arthritis Rheum. 44, 2777-2789[CrossRef][Medline] [Order article via Infotrieve]
6. Sironen, R. K., Karjalainen, H. M., Elo, M. A., Kaarniranta, K., Torronen, K., Takigawa, M., Helminen, H. J., and Lammi, M. J. (2002) Biochim. Biophys. Acta 1591, 45-54[Medline] [Order article via Infotrieve]
7. Urist, M. R. (1965) Science 150, 893-899[Abstract/Free Full Text]
8. Hogan, B. L. (1996) Genes Dev. 10, 1580-1594[Free Full Text]
9. Enomoto-Iwamoto, M., Iwamoto, M., Mukudai, Y., Kawakami, Y., Nohno, T., Higuchi, Y., Takemoto, S., Ohuchi, H., Noji, S., and Kurisu, K. (1998) J. Cell Biol. 140, 409-418[Abstract/Free Full Text]
10. Valcourt, U., Gouttenoire, J., Moustakas, A., Herbage, D., and Mallein-Gerin, F. (2002) J. Biol. Chem. 277, 33545-33558[Abstract/Free Full Text]
11. Ballock, R. T., and O'Keefe, R. J. (2003) J. Bone Jt. Surg. Am. 85, 715-726[Free Full Text]
12. Colnot, C. I., and Helms, J. A. (2001) Mech. Dev. 100, 245-250[CrossRef][Medline] [Order article via Infotrieve]
13. Volk, S. W., Luvalle, P., Leask, T., and Leboy, P. S. (1998) J. Bone Miner. Res. 13, 1521-1529[CrossRef][Medline] [Order article via Infotrieve]
14. Zheng, Q., Zhou, G., Morello, R., Chen, Y., Garcia-Rojas, X., and Lee, B. (2003) J. Cell Biol. 162, 833-842[Abstract/Free Full Text]
15. Enomoto, H., Enomoto-Iwamoto, M., Iwamoto, M., Nomura, S., Himeno, M., Kitamura, Y., Kishimoto, T., and Komori, T. (2000) J. Biol. Chem. 275, 8695-8702[Abstract/Free Full Text]
16. Leboy, P., Grasso-Knight, G., D'Angelo, M., Volk, S. W., Lian, J. V., Drissi, H., Stein, G. S., and Adams, S. L. (2001) J. Bone Jt. Surg. Am. 83, Suppl. 1, 15-22
17. Komori, T., Yagi, H., Nomura, S., Yamaguchi, A., Sasaki, K., Deguchi, K., Shimizu, Y., Bronson, R. T., Gao, Y. H., Inada, M., Sato, M., Okamoto, R., Kitamura, Y., Yoshiki, S., and Kishimoto, T. (1997) Cell 89, 755-764[CrossRef][Medline] [Order article via Infotrieve]
18. Otto, F., Thornell, A. P., Crompton, T., Denzel, A., Gilmour, K. C., Rosewell, I. R., Stamp, G. W., Beddington, R. S., Mundlos, S., Olsen, B. R., Selby, P. B., and Owen, M. J. (1997) Cell 89, 765-771[CrossRef][Medline] [Order article via Infotrieve]
19. Jimenez, M. J., Balbin, M., Lopez, J. M., Alvarez, J., Komori, T., and Lopez-Otin, C. (1999) Mol. Cell. Biol. 19, 4431-4442[Abstract/Free Full Text]
20. Inada, M., Yasui, T., Nomura, S., Miyake, S., Deguchi, K., Himeno, M., Sato, M., Yamagiwa, H., Kimura, T., Yasui, N., Ochi, T., Endo, N., Kitamura, Y., Kishimoto, T., and Komori, T. (1999) Dev. Dyn. 214, 279-290[CrossRef][Medline] [Order article via Infotrieve]
21. Porte, D., Tuckermann, J., Becker, M., Baumann, B., Teurich, S., Higgins, T., Owen, M. J., Schorpp-Kistner, M., and Angel, P. (1999) Oncogene 18, 667-678[CrossRef][Medline] [Order article via Infotrieve]
22. Wu, C. W., Tchetina, E. V., Mwale, F., Hasty, K., Pidoux, I., Reiner, A., Chen, J., Van Wart, H. E., and Poole, A. R. (2002) J. Bone Miner. Res. 17, 639-651[CrossRef][Medline] [Order article via Infotrieve]
23. Inada, M., Wang, Y., Byrne, M. H., Rahman, M. U., Miyaura, C., Lopez-Otin, C., and Krane, S. M. (2004) Proc. Natl. Acad. Sci. U. S. A. 101, 17192-17197[Abstract/Free Full Text]
24. Stickens, D., Behonick, D. J., Ortega, N., Heyer, B., Hartenstein, B., Yu, Y., Fosang, A. J., Schorpp-Kistner, M., Angel, P., and Werb, Z. (2004) Development (Camb.) 131, 5883-5895[Abstract/Free Full Text]
25. Mengshol, J. A., Vincenti, M. P., and Brinckerhoff, C. E. (2001) Nucleic Acids Res. 29, 4361-4372[Abstract/Free Full Text]
26. Hess, J., Porte, D., Munz, C., and Angel, P. (2001) J. Biol. Chem. 276, 20029-20038[Abstract/Free Full Text]
27. D'Alonzo, R. C., Selvamurugan, N., Karsenty, G., and Partridge, N. C. (2002) J. Biol. Chem. 277, 816-822[Abstract/Free Full Text]
28. Kim, I. S., Otto, F., Zabel, B., and Mundlos, S. (1999) Mech. Dev. 80, 159-170[CrossRef][Medline] [Order article via Infotrieve]
29. Takeda, S., Bonnamy, J. P., Owen, M. J., Ducy, P., and Karsenty, G. (2001) Genes Dev. 15, 467-481[Abstract/Free Full Text]
30. Ortega, N., Behonick, D. J., and Werb, Z. (2004) Trends Cell Biol. 14, 86-93[CrossRef][Medline] [Order article via Infotrieve]
31. Colnot, C., Lu, C., Hu, D., and Helms, J. A. (2004) Dev. Biol. 269, 55-69[CrossRef][Medline] [Order article via Infotrieve]
32. Goldring, M. B., Birkhead, J. R., Suen, L. F., Yamin, R., Mizuno, S., Glowacki, J., Arbiser, J. L., and Apperley, J. F. (1994) J. Clin. Investig. 94, 2307-2316[Medline] [Order article via Infotrieve]
33. Tan, L., Peng, H., Osaki, M., Choy, B. K., Auron, P. E., Sandell, L. J., and Goldring, M. B. (2003) J. Biol. Chem. 278, 17688-17700[Abstract/Free Full Text]
34. Shukunami, C., Ohta, Y., Sakuda, M., and Hiraki, Y. (1998) Exp. Cell Res. 241, 1-11[CrossRef][Medline] [Order article via Infotrieve]
35. Ballock, R. T., and Reddi, A. H. (1994) J. Cell Biol. 126, 1311-1318[Abstract/Free Full Text]
36. Spentzos, D., Levine, D. A., Ramoni, M. F., Joseph, M., Gu, X., Boyd, J., Libermann, T. A., and Cannistra, S. A. (2004) J. Clin. Oncol. 22, 4648-4658[Free Full Text]
37. Li, C., and Wong, W. H. (2001) Proc. Natl. Acad. Sci. U. S. A. 98, 31-36[Abstract/Free Full Text]
38. Ramalho-Santos, M., Yoon, S., Matsuzaki, Y., Mulligan, R. C., and Melton, D. A. (2002) Science 298, 597-600[Abstract/Free Full Text]
39. Xu, L., Peng, H., Wu, D., Hu, K., Goldring, M. B., Olsen, B. R., and Li, Y. (2005) J. Biol. Chem. 280, 548-555[Abstract/Free Full Text]
40. Zerbini, L. F., Wang, Y., Czibere, A., Correa, R. G., Cho, J. Y., Ijiri, K., Wei, W., Joseph, M., Gu, X., Grall, F., Goldring, M. B., Zhou, J. R., and Libermann, T. A. (2004) Proc. Natl. Acad. Sci. U. S. A. 101, 13618-13623[Abstract/Free Full Text]
41. Qiu, W., David, D., Zhou, B., Chu, P. G., Zhang, B., Wu, M., Xiao, J., Han, T., Zhu, Z., Wang, T., Liu, X., Lopez, R., Frankel, P., Jong, A., and Yen, Y. (2003) Am. J. Pathol. 162, 1961-1974[Abstract/Free Full Text]
42. Kartsogiannis, V., Moseley, J., McKelvie, B., Chou, S. T., Hards, D. K., Ng, K. W., Martin, T. J., and Zhou, H. (1997) Bone (NY) 21, 385-392
43. Lu, B., Ferrandino, A. F., and Flavell, R. A. (2004) Nat. Immun. 5, 38-44[CrossRef][Medline] [Order article via Infotrieve]
44. Takekawa, M., and Saito, H. (1998) Cell 95, 521-530[CrossRef][Medline] [Order article via Infotrieve]
45. Ducy, P., Starbuck, M., Priemel, M., Shen, J., Pinero, G., Geoffroy, V., Amling, M., and Karsenty, G. (1999) Genes Dev. 13, 1025-1036[Abstract/Free Full Text]
46. Zerbini, L. F., Wang, Y., Cho, J. Y., and Libermann, T. A. (2003) Cancer Res. 63, 2206-2215[Abstract/Free Full Text]
47. Thirunavukkarasu, K., Miles, R. R., Halladay, D. L., and Onyia, J. E. (2000) BioTechniques 28, 506-510[Medline] [Order article via Infotrieve]
48. Tiscornia, G., Singer, O., Ikawa, M., and Verma, I. M. (2003) Proc. Natl. Acad. Sci. U. S. A. 100, 1844-1848[Abstract/Free Full Text]
49. Naldini, L., Blomer, U., Gallay, P., Ory, D., Mulligan, R., Gage, F. H., Verma, I. M., and Trono, D. (1996) Science 272, 263-267[Abstract]
50. Pfeifer, A., and Verma, I. M. (2001) Annu. Rev. Genomics Hum. Genet. 2, 177-211[CrossRef][Medline] [Order article via Infotrieve]
51. Zaidi, S. K., Sullivan, A. J., van Wijnen, A. J., Stein, J. L., Stein, G. S., and Lian, J. B. (2002) Proc. Natl. Acad. Sci. U. S. A. 99, 8048-8053[Abstract/Free Full Text]
52. Afzal, F., Pratap, J., Ito, K., Ito, Y., Stein, J. L., van Wijnen, A. J., Stein, G. S., Lian, J. B., and Javed, A. (2005) J. Cell. Physiol. 204, 63-72[CrossRef][Medline] [Order article via Infotrieve]
53. Yazgan, O., and Pfarr, C. M. (2002) J. Biol. Chem. 277, 29710-29718[Abstract/Free Full Text]
54. De Smaele, E., Zazzeroni, F., Papa, S., Nguyen, D. U., Jin, R., Jones, J., Cong, R., and Franzoso, G. (2001) Nature 414, 308-313[CrossRef][Medline] [Order article via Infotrieve]
55. Lu, B., Yu, H., Chow, C., Li, B., Zheng, W., Davis, R. J., and Flavell, R. A. (2001) Immunity 14, 583-590[CrossRef][Medline] [Order article via Infotrieve]
56. Mita, H., Tsutsui, J., Takekawa, M., Witten, E. A., and Saito, H. (2002) Mol. Cell. Biol. 22, 4544-4555[Abstract/Free Full Text]
57. Yoon, B. S., and Lyons, K. M. (2004) J. Cell. Biochem. 93, 93-103[CrossRef][Medline] [Order article via Infotrieve]
58. Wan, M., and Cao, X. (2005) Biochem. Biophys. Res. Commun. 328, 651-657[CrossRef][Medline] [Order article via Infotrieve]
59. Goldring, M. B. (2004) in Kelley's Textbook of Rheumatology (Harris, E. D., Ruddy, S., Sledge, C. B., Sergent, J. S., and Budd, R. C., eds) 7th Ed., pp. 203-234, W. B. Saunders Co., Philadelphia
60. Provot, S., and Schipani, E. (2005) Biochem. Biophys. Res. Commun. 328, 658-665[CrossRef][Medline] [Order article via Infotrieve]
61. Locklin, R. M., Riggs, B. L., Hicok, K. C., Horton, H. F., Byrne, M. C., and Khosla, S. (2001) J. Bone Miner. Res. 16, 2192-2204[CrossRef][Medline] [Order article via Infotrieve]
62. Xu, S. C., Harris, M. A., Rubenstein, J. L. R., Mundy, G. R., and Harris, S. E. (2001) DNA Cell Biol. 20, 359-365[CrossRef][Medline] [Order article via Infotrieve]
63. Lai, C. F., and Cheng, S. L. (2002) J. Biol. Chem. 277, 15514-15522[Abstract/Free Full Text]
64. Maeda, Y., Tsuji, K., Nifuji, A., and Noda, M. (2004) J. Cell. Biochem. 93, 337-344[CrossRef][Medline] [Order article via Infotrieve]
65. Fujita, T., Azuma, Y., Fukuyama, R., Hattori, Y., Yoshida, C., Koida, M., Ogita, K., and Komori, T. (2004) J. Cell Biol. 166, 85-95[Abstract/Free Full Text]
66. Jin, R., De Smaele, E., Zazzeroni, F., Nguyen, D. U., Papa, S., Jones, J., Cox, C., Gelinas, C., and Franzoso, G. (2002) DNA Cell Biol. 21, 491-503[CrossRef][Medline] [Order article via Infotrieve]
67. Balliet, A. G., Hollander, M. C., Fornace, A. J., Jr., Hoffman, B., and Liebermann, D. A. (2003) DNA Cell Biol. 22, 457-468[CrossRef][Medline] [Order article via Infotrieve]
68. Ungefroren, H., Groth, S., Ruhnke, M., Kalthoff, H., and Fandrich, F. (2005) J. Biol. Chem. 280, 2644-2652[Abstract/Free Full Text]
69. Qiao, B., Padilla, S. R., and Benya, P. D. (2005) J. Biol. Chem. 280, 17562-17571[Abstract/Free Full Text]
70. Ferguson, C. M., Miclau, T., Hu, D., Alpern, E., and Helms, J. A. (1998) Ann. N. Y. Acad. Sci. 857, 33-42[CrossRef][Medline] [Order article via Infotrieve]
71. Colnot, C. (2005) J. Cell. Biochem. 95, 688-697[CrossRef][Medline] [Order article via Infotrieve]
72. Johansson, N., Saarialho-Kere, U., Airola, K., Herva, R., Nissinen, L., Westermarck, J., Vuorio, E., Heino, J., and Kahari, V. M. (1997) Dev. Dyn. 208, 387-397[CrossRef][Medline] [Order article via Infotrieve]
73. Gress, C. J., and Jacenko, O. (2000) J. Cell Biol. 149, 983-993[Abstract/Free Full Text]
74. Jacenko, O., Chan, D., Franklin, A., Ito, S., Underhill, C. B., Bateman, J. F., and Campbell, M. R. (2001) Am. J. Pathol. 159, 2257-2269[Abstract/Free Full Text]
75. Li, Y., Lacerda, D. A., Warman, M. L., Beier, D. R., Yoshioka, H., Ninomiya, Y., Oxford, J. T., Morris, N. P., Andrikopoulos, K., and Ramirez, F. (1995) Cell 80, 423-430[CrossRef][Medline] [Order article via Infotrieve]
76. Gerber, H. P., Vu, T. H., Ryan, A. M., Kowalski, J., Werb, Z., and Ferrara, N. (1999) Nat. Med. 5, 623-628[CrossRef][Medline] [Order article via Infotrieve]
77. Maes, C., Carmeliet, P., Moermans, K., Stockmans, I., Smets, N., Collen, D., Bouillon, R., and Carmeliet, G. (2002) Mech. Dev. 111, 61-73[CrossRef][Medline] [Order article via Infotrieve]
78. Vu, T. H., Shipley, J. M., Bergers, G., Berger, J. E., Helms, J. A., Hanahan, D., Shapiro, S. D., Senior, R. M., and Werb, Z. (1998) Cell 93, 411-422[CrossRef][Medline] [Order article via Infotrieve]
79. Vairapandi, M., Balliet, A. G., Hoffman, B., and Liebermann, D. A. (2002) J. Cell. Physiol. 192, 327-338[CrossRef][Medline] [Order article via Infotrieve]
80. Papa, S., Zazzeroni, F., Bubici, C., Jayawardena, S., Alvarez, K., Matsuda, S., Nguyen, D. U., Pham, C. G., Nelsbach, A. H., Melis, T., De Smaele, E., Tang, W. J., D'Adamio, L., and Franzoso, G. (2004) Nat. Cell Biol. 6, 146-153[CrossRef][Medline] [Order article via Infotrieve]
81. Davis, R. J. (2000) Cell 103, 239-252[CrossRef][Medline] [Order article via Infotrieve]
82. Nakamura, K., Shirai, T., Morishita, S., Uchida, S., Saeki-Miura, K., and Makishima, F. (1999) Exp. Cell Res. 250, 351-363[CrossRef][Medline] [Order article via Infotrieve]
83. Seghatoleslami, M. R., Roman-Blas, J. A., Rainville, A. M., Modaressi, R., Danielson, K. G., and Tuan, R. S. (2003) J. Cell. Biochem. 88, 1129-1144[CrossRef][Medline] [Order article via Infotrieve]
84. Grigoriadis, A. E., Schellander, K., Wang, Z. Q., and Wagner, E. F. (1993) J. Cell Biol. 122, 685-701[Abstract/Free Full Text]
85. Jochum, W., David, J. P., Elliott, C., Wutz, A., Plenk, H., Jr., Matsuo, K., and Wagner, E. F. (2000) Nat. Med. 6, 980-984[CrossRef][Medline] [Order article via Infotrieve]
86. Reimold, A. M., Grusby, M. J., Kosaras, B., Fries, J. W., Mori, R., Maniwa, S., Clauss, I. M., Collins, T., Sidman, R. L., Glimcher, M. J., and Glimcher, L. H. (1996) Nature 379, 262-265[CrossRef][Medline] [Order article via Infotrieve]
87. Jochum, W., Passegue, E., and Wagner, E. F. (2001) Oncogene 20, 2401-2412[CrossRef][Medline] [Order article via Infotrieve]
88. Karreth, F., Hoebertz, A., Scheuch, H., Eferl, R., and Wagner, E. F. (2004) Development (Camb.) 131, 5717-5725[Abstract/Free Full Text]
89. Hess, J., Hartenstein, B., Teurich, S., Schmidt, D., Schorpp-Kistner, M., and Angel, P. (2003) J. Cell Sci. 116, 4587-4596[Abstract/Free Full Text]
90. MacLean, H. E., Kim, J. I., Glimcher, M. J., Wang, J., Kronenberg, H. M., and Glimcher, L. H. (2003) Dev. Biol. 262, 51-63[CrossRef][Medline] [Order article via Infotrieve]

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