Uncoupling of chondrocyte differentiation and perichondrial mineralization underlies the skeletal dysplasia in tricho-rhino-phalangeal syndrome.

Tricho-rhino-phalangeal syndrome (TRPS) is an autosomal dominant craniofacial and skeletal dysplasia that is caused by mutations involving the TRPS1 gene. Patients with TRPS have short stature, hip abnormalities, cone-shaped epiphyses and premature closure of growth plates reflecting defects in endochondral ossification. The TRPS1 gene encodes for the transcription factor TRPS1 that has been demonstrated to repress transcription in vitro. To elucidate the molecular mechanisms underlying skeletal abnormalities in TRPS, we analyzed Trps1 mutant mice (Trps1DeltaGT mice). Analyses of growth plates demonstrated delayed chondrocyte differentiation and accelerated mineralization of perichondrium in Trps1 mutant mice. These abnormalities were accompanied by increased Runx2 and Ihh expression and increased Indian hedgehog signaling. We demonstrated that Trps1 physically interacts with Runx2 and represses Runx2-mediated trans-activation. Importantly, generation of Trps1(DeltaGT/+);Runx2(+/-) double heterozygous mice rescued the opposite growth plate phenotypes of single mutants, demonstrating the genetic interaction between Trps1 and Runx2 transcription factors. Collectively, these data suggest that skeletal dysplasia in TRPS is caused by dysregulation of chondrocyte and perichondrium development partially due to loss of Trps1 repression of Runx2.

Molecular heterogeneity of inflammatory breast cancer: a hyperproliferative phenotype.

PURPOSE: Inflammatory breast cancer (IBC) is associated with very poor prognosis. The aims of this study are (a) to prospectively identify differential gene expression patterns associated with IBC and (b) to confirm these pathways using tissue arrays. EXPERIMENTAL DESIGN: For gene expression analysis, IBC (n=14) was clinically defined as rapid-onset cancer associated with erythema and skin changes, whereas non-IBC patients (n=20) had stage III breast cancers, and cDNA analysis was carried out using the Affymetrix (Santa Clara, CA) HG-U133A microarrays. Tissue arrays were constructed from paraffin-embedded material, and the molecular phenotype of 75 IBC was compared with results from>2,000 non-IBC. RESULTS: Gene expression analyses indicated that IBC has higher expression of genes associated with increased metabolic rate, lipid signaling, and cell turnover relative to non-IBC tumors. Consistent with the expression analysis, IBC had statistically higher Ki-67 (93% versus 11%; P<0.001). BAX expression, reflecting increased apoptosis and cell turnover, was significantly uniformly higher in almost all IBC (98% versus 66%; P<0.05), whereas the expression of Bcl-2 was not significantly different. IBC tumors were more likely to be steroid hormone receptor negative (estrogen receptor, 49% versus 30%; P=0.002; progesterone receptor, 68% versus 42%; P=0.001). The expression of tyrosine kinases was not significantly different. E-cadherin was found to be expressed in 87% of IBC, whereas the expression p53 was not significantly different. CONCLUSION: This study is one of the largest molecular analyses of IBC. Both IBC and non-IBC are genetically heterogeneous with consistent differences in the molecular phenotype of IBC.

Mutations and promoter SNPs in RUNX2, a transcriptional regulator of bone formation.

Cleidocranial dysplasia (CCD) is a dominantly inherited skeletal malformation syndrome with high penetrance and variable expressivity. It is caused by loss of function mutations in the RUNX2 gene that encodes for a transcription factor essential for osteoblast differentiation and chondrocyte maturation. To identify new pathogenic mutations associated with CCD we screened 38 CCD patients for mutations in the RUNX2 coding sequence. We also report the mutation screening of the "bone-related" RUNX2 promoter in CCD patients without mutation in the RUNX2 coding region. We identify eight new and three previously described mutations in the RUNX2 gene. Additionally, a total of five sequence variants in the RUNX2 promoter were detected. Three of them occur within putative zinc finger transcription factor binding sites. DHPLC analysis of chromosomes from the control population and CCD patients showed that two promoter sequence variants were unique for CCD families. Electrophoretic mobility shift assay (EMSA) with protein extracts from ROS17/2.8 and C3H10T1/2 cell lines demonstrated that the promoter sequence variants altered DNA-protein binding specificity. Moreover, one of the variants significantly decreased the expression of a RUNX2 reporter gene in osteoblastic ROS17/2.8 cells, but not in multipotent, mesenchymal C3H10T1/2 cells. Interestingly, one of these sites bound the TRPS1 transcription factor and we demonstrated that TRPS1 is able to repress the RUNX2 promoter. The in vitro functional studies in conjunction with analysis of clinical phenotype of CCD patients suggest that these promoter sequence variants may affect transcriptional activity of the RUNX2 gene. Analysis of the promoter variants and RUNX2-interacting proteins may help to identify important cis-elements and trans-factors that regulate the RUNX2 transcriptional network and identify new susceptibility markers for more common bone disorders.