BACKGROUND: For treatment and prevention of metastatic disease, one of the premier challenges is the identification of pathways and proteins to target for clinical intervention. Micro RNAs (miRNAs) are short, non-coding RNAs, which regulate cellular activities by either mRNA degradation or translational inhibition. Our studies focused on the invasive properties of hsa-mir30c based on its high expression in MDA-MB-231 metastatic cells and our bioinformatic analysis of the Cancer Genome Atlas that identified aberrant hsa-mir-30c to be associated with poor survival. METHODS: Contributions of hsa-mir-30c to breast cancer cell invasion were examined by Matrigel invasion transwell assays following modulation of hsa-mir-30c or hsa-mir-30c* levels in MDA-MB-231 cells. hsa-mir-30c in silico predicted targets linked to cell invasion were screened for targeting by hsa-mir-30c in metastatic breast cancer cells by RT-qPCR. The contribution to invasion by a target of hsa-mir-30c, Nephroblastoma overexpressed (NOV), was characterized by siRNA and invasion assays. Significant effects were determined using Student's T-tests with Welch's correction for unequal variance. RESULTS: MCF-7 and MDA-MB-231 cells were used as models of poorly invasive and late-stage metastatic disease, respectively. By modulating the levels of hsa-mir-30c in these cells, we observed concomitant changes in breast cancer cell invasiveness. From predicted targets of hsa-mir-30c that were related to cellular migration and invasion, NOV/CCN3 was identified as a novel target of hsa-mir-30c. Depleting NOV by siRNA caused a significant increase in the invasiveness of MDA-MB-231 cells is a regulatory protein associated with the extracellular matrix. CONCLUSIONS: NOV/CCN3 expression, which protects cells from invasion, is known in patient tumors to inversely correlate with advanced breast cancer and metastasis. This study has identified a novel target of hsa-mir-30c, NOV, which is an inhibitor of the invasiveness of metastatic breast cancer cells. Thus, hsa-mir-30c-mediated inhibition of NOV levels promotes the invasive phenotype of MDA-MB-231 cells and significantly, the miR-30/NOV pathways is independent of RUNX2, a known target of hsa-mir-30c that promotes osteolytic disease in metastatic breast cancer cells. Our findings allow for mechanistic insight into the clinical observation of poor survival of patients with elevated hsa-mir-30c levels, which can be considered for miRNA-based translational studies.

BACKGROUND: Osteogenesis is a highly regulated developmental process and continues during the turnover and repair of mature bone. Runx2, the master regulator of osteoblastogenesis, directs a transcriptional program essential for bone formation through genetic and epigenetic mechanisms. While individual Runx2 gene targets have been identified, further insights into the broad spectrum of Runx2 functions required for osteogenesis are needed. RESULTS: By performing genome-wide characterization of Runx2 binding at the three major stages of osteoblast differentiation--proliferation, matrix deposition and mineralization--we identify Runx2-dependent regulatory networks driving bone formation. Using chromatin immunoprecipitation followed by high-throughput sequencing over the course of these stages, we identify approximately 80,000 significantly enriched regions of Runx2 binding throughout the mouse genome. These binding events exhibit distinct patterns during osteogenesis, and are associated with proximal promoters and also non-promoter regions: upstream, introns, exons, transcription termination site regions, and intergenic regions. These peaks were partitioned into clusters that are associated with genes in complex biological processes that support bone formation. Using Affymetrix expression profiling of differentiating osteoblasts depleted of Runx2, we identify novel Runx2 targets including Ezh2, a critical epigenetic regulator; Crabp2, a retinoic acid signaling component; Adamts4 and Tnfrsf19, two remodelers of the extracellular matrix. We demonstrate by luciferase assays that these novel biological targets are regulated by Runx2 occupancy at non-promoter regions. CONCLUSIONS: Our data establish that Runx2 interactions with chromatin across the genome reveal novel genes, pathways and transcriptional mechanisms that contribute to the regulation of osteoblastogenesis.

The nuclear matrix (NM) is a fibrogranular network of ribonucleoproteins upon which transcriptional complexes and regulatory genomic sequences are organized. A hallmark of cancer is the disorganization of nuclear architecture; however, the extent to which the NM is involved in malignancy is not well studied. The RUNX1 and RUNX2 proteins form complexes within the NM to promote hematopoiesis and osteoblastogenesis, respectively at the transcriptional level. RUNX1 and RUNX2 are both expressed in breast cancer cells (BrCCs); however, their genome-wide BrCC functions are unknown. RUNX1 and RUNX2 activate many tumor suppressor pathways in blood and bone lineages, respectively, including attenuation of protein synthesis and cell growth via suppression of ribosomal RNA (rRNA) transcription, which appears contrary to Runx-expression in highly proliferative BrCCs. To define roles for RUNX1 and RUNX2 in BrCC phenotype, we examined the involvement of RUNX1 and RUNX2 in rRNA transcription and generated a genome-wide model for RUNX1 and RUNX2-binding and transcriptional regulation. To validate gene expression patterns identified in our screen, we developed a Real-Time qPCR primer design program, which allows rapid, high-throughput design of primer pairs (FoxPrimer). In BrCCs, RUNX1 and RUNX2 regulate genes that promote invasiveness and do not affect rRNA transcription, protein synthesis, or cell growth. We have characterized in vitro functions of Runx proteins in BrCCs; however, the relationships between Runx expression and diagnostic/prognostic markers of breast cancer (BrCa) in patients are not well studied. Immunohistochemical detection of RUNX1 and RUNX2 in BrCa tissue microarrays reveals RUNX1 expression is associated with early, smaller tumors that are ER+ (estrogen receptor), HER2+, p53-, and correlated with androgen receptor (AR) expression; RUNX2 expression is associated with late-stage, larger tumors that are HER2+. These results show that the functions and expression patterns of NM-associated RUNX1 and RUNX2 are context-sensitive, which suggests potential disease-specific roles. Two functionally disparate genomic sequence types bind to the NM: matrix associated regions (MARs) are functionally associated with transcriptional repression and scaffold associated regions (SARs) are functionally associated with actively expressed genes. It is unknown whether malignant nuclear disorganization affects the functions of MARs/SARs in BrCC. We have refined a method to isolate nuclear matrix associated DNA (NM-DNA) from a structurally preserved NM and applied this protocol to normal mammary epithelial cells and BrCCs. To define transcriptional functions for NM-DNA, we developed a computational algorithm (PeaksToGenes), which statistically tests the associations of experimentally-defined NM-DNA regions and ChIP-seq-defined positional enrichment of several histone marks with transcriptome-wide gene expression data. In normal mammary epithelial cells, NM-DNA is enriched in both MARs and SARs, and the positional enrichment patterns of MARs and SARs are strongly associated with gene expression patterns, suggesting functional roles. In contrast, the BrCCs are significantly enriched in the silencing mark H3K27me3, and the NM-DNA is enriched in MARs and depleted of SARs. The MARs/SARs in the BrCCs are only weakly associated with gene expression patterns, suggesting that loss of normal DNA-matrix associations accompanies the disease state. Our results show that structural preservation of the in situ NM allows isolation of both MARs and SARs, and further demonstrate that in a disorganized, cancerous nucleus, normal transcriptional functions of NM-DNA are disrupted. Our studies on nuclear organization in BrCC, show that the disorganized phenotype of the cancer cell nucleus is accompanied by deregulated transcriptional functions of two constituents of the NM. These results reinforce the role of the NM as an important structure-function component of gene expression regulation.

INTRODUCTION: Metastatic breast cancer cells frequently and ectopically express the transcription factor RUNX2, which normally attenuates proliferation and promotes maturation of osteoblasts. RUNX2 expression is inversely regulated with respect to cell growth in osteoblasts and deregulated in osteosarcoma cells. METHODS: Here, we addressed whether the functional relationship between cell growth and RUNX2 gene expression is maintained in breast cancer cells. We also investigated whether the aberrant expression of RUNX2 is linked to phenotypic parameters that could provide a selective advantage to cells during breast cancer progression. RESULTS: We find that, similar to its regulation in osteoblasts, RUNX2 expression in MDA-MB-231 breast adenocarcinoma cells is enhanced upon growth factor deprivation, as well as upon deactivation of the mitogen-dependent MEK-Erk pathway or EGFR signaling. Reduction of RUNX2 levels by RNAi has only marginal effects on cell growth and expression of proliferation markers in MDA-MB-231 breast cancer cells. Thus, RUNX2 is not a critical regulator of cell proliferation in this cell type. However, siRNA depletion of RUNX2 in MDA-MB-231 cells reduces cell motility, while forced exogenous expression of RUNX2 in MCF7 cells increases cell motility. CONCLUSIONS: Our results support the emerging concept that the osteogenic transcription factor RUNX2 functions as a metastasis-related oncoprotein in non-osseous cancer cells.