Runx2, a bone-specific transcriptional regulator, is abnormally expressed in highly metastatic prostate cancer cells. Here we identified the functional activities of Runx2 in facilitating tumor growth and osteolysis. Our studies demonstrate that negligible Runx2 is found in normal prostate epithelial and non-metastatic LNCaP prostate cancer cells. In the intra-tibial metastasis model, high Runx2 levels are associated with development of large tumors, increased expression of metastasis-related genes (MMP9, MMP13, VEGF, Osteopontin), and secreted bone resorbing factors (PTHrP, IL-8) promoting osteolytic disease. Runx2 siRNA treatment of PC3 cells decreased cell migration and invasion through Matrigel in vitro, and in vivo shRunx2 expression in PC3 cells blocked their ability to survive in the bone microenvironment. Mechanisms of Runx2 function were identified in co-culture studies demonstrating that PC3 cells promote osteoclastogenesis and inhibit osteoblast activity. The clinical significance of these findings is supported by human tissue microarray studies of prostate tumors at stages of cancer progression, where Runx2 is expressed in both adenocarcinomas and metastatic tumors. Together these findings indicate that Runx2 is a key regulator of events associated with prostate cancer metastatic bone disease.
The WW domain-containing oxidoreductase (WWOX) spans the second most common fragile site of the human genome, FRA16D, located at 16q23, and its expression is altered in several types of human cancer. We have previously shown that restoration of WWOX expression in cancer cells suppresses tumorigenicity. common fragile site ͉ FHIT ͉ knockout ͉ osteosarcoma ͉ lung cancer T he WW domain-containing oxidoreductase (WWOX) encodes a 46-kDa protein that contains two WW domains and a short-chain dehydrogenase/reductase domain (1-3). The WWOX gene is altered by deletions or translocations in a large fraction of many cancer types including breast, prostate, esophageal, lung, stomach, and pancreatic carcinomas (2, 4-9). WWOX protein is lost or reduced in the majority of these cancers and in a large fraction of other cancer types (10, 11). WWOX spans the second most active common fragile sites, FRA16D (reviewed in ref. 12). Common fragile sites are large regions of profound genomic instability found in all individuals. Following partial inhibition of DNA synthesis, those regions show site-specific gaps or breaks on metaphase chromosomes. In addition, common fragile sites exhibit induction of sister chromatid exchange and show a high rate of translocations and deletions in somatic cell hybrids (13). Because FRA16D maps within regions of frequent loss of heterozygosity, and is associated with homozygous deletions in various adenocarcinomas and with chromosomal translocations in multiple myeloma (2), these rearrangements have been suggested to inactivate the WWOX gene. On the other hand, ectopic overexpression of WWOX in cancer cells lacking expression of endogenous WWOX results in significant growth inhibition and prevents the development of tumors in athymic nude mice (14,15). In addition, we reported that restoration of WWOX expression in cancer cells results in caspase-mediated apoptosis (15). Thus, these data suggest that WWOX may act as a tumor suppressor Biochemical and functional characterization of WWOX has shown that it interacts with proline-tyrosine rich motifcontaining proteins. WWOX associates via its first WW domain with p73 and enhances p73-mediated apoptosis (16). WWOX also binds to the PPPY motif of AP2␥ and ErbB4, established oncogenes in breast cancer (17,18). Interestingly, WWOX suppresses the transcriptional ability of these target proteins by sequestering them in the cytoplasm (16)(17)(18). Taken together, accumulating evidence, both in cell culture and in nude mice, suggests that WWOX functions as a tumor suppressor, although no direct in vivo proof has yet been reported to verify WWOX as a bona fide tumor suppressor. To define the role of WWOX protein in cancer development, we generated mice carrying a targeted deletion of the Wwox gene. The murine Wwox locus is similar to its human homolog (19), spans the Fra8E1 common fragile site, and is highly conserved. Here, we demonstrate that the loss of both alleles of Wwox results in osteosarcomas in some early postnatal mice, whereas loss of one allele signifi...
The WW domain-containing oxidoreductase (WWOX) gene encodes a tumor suppressor. We have previously shown that targeted ablation of the Wwox gene in mouse increases the incidence of spontaneous and chemically induced tumors. To investigate WWOX function in vivo, we examined Wwox-deficient (Wwox ؊/؊ ) mice for phenotypical abnormalities. Wwox ؊/؊ mice are significantly reduced in size, die at the age of 2-3 weeks, and suffer a metabolic disorder that affects the skeleton. Wwox ؊/؊ mice exhibit a delay in bone formation from a cell autonomous defect in differentiation beginning at the mineralization stage shown in calvarial osteoblasts ex vivo and supported by significantly decreased bone formation parameters in Wwox ؊/؊ mice by microcomputed tomography analyses. Wwox ؊/؊ mice develop metabolic bone disease, as a consequence of reduced serum calcium, hypoproteinuria, and hypoglycemia leading to increased osteoclast activity and bone resorption. Interestingly, we find WWOX physically associates with RUNX2, the principal transcriptional regulator of osteoblast differentiation, and on osteocalcin chromatin. We show WWOX functionally suppresses RUNX2 transactivation ability in osteoblasts. In breast cancer MDA-MB-242 cells that lack endogenous WWOX protein, restoration of WWOX expression inhibited Runx2 and RUNX2 target genes related to metastasis. Affymetrix mRNA profiling revealed common gene targets in multiple tissues. In Wwox ؊/؊ mice, genes related to nucleosome assembly and cell growth genes were down-regulated, and negative regulators of skeletal metabolism exhibited increased expression. Our results demonstrate an essential requirement for the WWOX tumor suppressor in postnatal survival, growth, and metabolism and suggest a central role for WWOX in regulation of bone tissue formation. WW domain-containing oxidoreductase (WWOX)3 is a 46-kDa protein that contains two N-terminal WW domains and a central short-chain dehydrogenase/reductase domain (1, 2). WWOX was identified as a putative tumor suppressor in cancer cells because it lies in a genomic region that is frequently altered in pre-neoplastic and neoplastic lesions (1, 2). Indeed, expression of WWOX is deregulated in several types of cancer, including breast, prostate, lung, stomach, and pancreatic carcinomas (3, 4). Ectopic expression of WWOX in cancer cells lacking expression of endogenous WWOX results in significant growth inhibition and prevents the development of tumors in athymic nude mice (5, 6). Recently, we generated a mouse carrying a targeted deletion of the Wwox gene (7). We reported that loss of both alleles of Wwox resulted in the formation of frequent juvenile osteosarcomas, whereas loss of one allele increased the incidence of spontaneous and chemically induced tumors (7, 8) thus confirming that Wwox is a bona fide tumor suppressor.The identification of WWOX-interacting proteins has provided insights into the potential roles of WWOX in cell signaling and its impact on cell fate. WWOX cytosolic interactions, through its first WW domain that b...
Runx2, required for bone formation, is ectopically expressed in breast cancer cells. To address the mechanism by which Runx2 contributes to the osteolytic disease induced by MDA-MB-231 cells, we investigated the effect of Runx2 on key components of the ''vicious cycle'' of transforming growth factor B (TGFB)-mediated tumor growth and osteolysis. We find that Runx2 directly up-regulates Indian Hedgehog (IHH) and colocalizes with Gli2, a Hedgehog signaling molecule. These events further activate parathyroid hormone-related protein (PTHrP). Furthermore, Runx2 directly regulates the TGFB-induced PTHrP levels. A subnuclear targeting deficient mutant Runx2, which disrupts TGFB-induced Runx2-Smad interactions, failed to induce IHH and downstream events. In addition, Runx2 knockdown in MDA-MB-231 inhibited IHH and PTHrP expression in the presence of TGFB. In vivo blockade of the Runx2-IHH pathway in MDA-MB-231 cells by Runx2 short hairpin RNA inhibition prevented the osteolytic disease. Thus, our studies define a novel role of Runx2 in upregulating the vicious cycle of metastatic bone disease, in addition to Runx2 regulation of genes related to progression of tumor metastasis.
MicroRNA attenuation of protein translation has emerged as an important regulator of mesenchymal cell differentiation into the osteoblast lineage. A compelling question is the extent to which miR biogenesis is obligatory for bone formation. Here we show conditional deletion of Dicer in osteoprogenitors by Col1a1-Cre compromised fetal survival after E14.5. A mechanism was associated with the post-commitment stage of osteoblastogenesis, demonstrated by impaired ECM mineralization and expression of mature osteoblast markers in ex vivo deleted Dicerc/c during differentiation of mesenchymal cells. In contrast, in vivo excision of Dicer by Osteocalcin-Cre in mature osteoblasts generated a viable mouse with a perinatal phenotype of delayed bone mineralization which was resolved by 1 month. However, a second phenotype of significantly increased bone mass developed by 2 months, which continued up to 8 months in long bones and vertebrae, but not calvariae. Cortical bone width and trabecular thickness in DicerΔoc/Δoc was twice that of Dicerc/c controls. Normal cell and tissue organization was observed. Expression of osteoblast and osteoclast markers demonstrated increased coupled activity of both cell types. We propose that Dicer generated miRs are essential for two periods of bone formation, to promote osteoblast differentiation before birth, and control bone accrual in the adult.
The WW domain-containing oxidoreductase (WWOX) is a tumor suppressor that is deleted or attenuated in most human tumors. Wwox-deficient mice develop osteosarcoma (OS), an aggressive bone tumor with poor prognosis that often metastasizes to lung. On the basis of these observations, we examined the status of WWOX in human OS specimens and cell lines. In human OS clinical samples, WWOX expression was absent or reduced in 58% of tumors examined (P < 0.0001). Compared with the primary tumors, WWOX levels frequently increased in tumors resected following chemotherapy. In contrast, tumor metastases to lung often exhibited reduced WWOX levels relative to the primary tumor. In human OS cell lines having reduced WWOX expression, ectopic expression of WWOX inhibited proliferation and attenuated invasion in vitro, and suppressed tumorigenicity in nude mice. Expression of WWOX was associated with reduced RUNX2 expression in OS cell lines, whereas RUNX2 levels were elevated in femurs of Wwox-deficient mice. Furthermore, WWOX reconstitution in HOS cells was associated with downregulation of RUNX2 levels and RUNX2 target genes, consistent with the ability of WWOX to suppress RUNX2 transactivation activity. In clinical samples, RUNX2 was expressed in the majority of primary tumors and undetectable in most tumors resected following chemotherapy, whereas most metastases were RUNX2 positive. Our results deepen the evidence of a tumor suppressor role for WWOX in OS, furthering its prognostic and therapeutic significance in this disease. Cancer Res; 70(13); 5577-86. ©2010 AACR.
Cleidocranial dysplasia (CCD) in humans is an autosomal-dominant skeletal disease that results from mutations in the bone-specific transcription factor RUNX2 (CBFA1/AML3). However, distinct RUNX2 mutations in CCD do not correlate with the severity of the disease. Here we generated a new mouse model with a hypomorphic Runx2 mutant allele (Runx2(neo7)), in which only part of the transcript is processed to full-length (wild-type) Runx2 mRNA. Homozygous Runx2(neo7/neo7) mice express a reduced level of wild-type Runx2 mRNA (55-70%) and protein. This mouse model allowed us to establish the minimal requirement of functional Runx2 for normal bone development. Runx2(neo7/neo7) mice have grossly normal skeletons with no abnormalities observed in the growth plate, but do exhibit developmental defects in calvaria and clavicles that persist through post-natal growth. Clavicle defects are caused by disrupted endochondral bone formation during embryogenesis. These hypomorphic mice have altered calvarial bone volume, as observed by histology and microCT imaging, and decreased expression of osteoblast marker genes. The bone phenotype of the heterozygous mice, which have 79-84% of wild-type Runx2 mRNA, is normal. These results show there is a critical gene dosage requirement of functional Runx2 for the formation of intramembranous bone tissues during embryogenesis. A decrease to 70% of wild-type Runx2 levels results in the CCD syndrome, whereas levels>79% produce a normal skeleton. Our findings suggest that the range of bone phenotypes in CCD patients is attributable to quantitative reduction in the functional activity of RUNX2.
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