BackgroundProstate cancer (PCa) cells preferentially metastasize to bone at least in part by acquiring osteomimetic properties. Runx2, an osteoblast master transcription factor, is aberrantly expressed in PCa cells, and promotes their metastatic phenotype. The transcriptional programs regulated by Runx2 have been extensively studied during osteoblastogenesis, where it activates or represses target genes in a context-dependent manner. However, little is known about the gene regulatory networks influenced by Runx2 in PCa cells. We therefore investigated genome wide mRNA expression changes in PCa cells in response to Runx2.ResultsWe engineered a C4-2B PCa sub-line called C4-2B/Rx2dox, in which Doxycycline (Dox) treatment stimulates Runx2 expression from very low to levels observed in other PCa cells. Transcriptome profiling using whole genome expression array followed by in silico analysis indicated that Runx2 upregulated a multitude of genes with prominent cancer associated functions. They included secreted factors (CSF2, SDF-1), proteolytic enzymes (MMP9, CST7), cytoskeleton modulators (SDC2, Twinfilin, SH3PXD2A), intracellular signaling molecules (DUSP1, SPHK1, RASD1) and transcription factors (Sox9, SNAI2, SMAD3) functioning in epithelium to mesenchyme transition (EMT), tissue invasion, as well as homing and attachment to bone. Consistent with the gene expression data, induction of Runx2 in C4-2B cells enhanced their invasiveness. It also promoted cellular quiescence by blocking the G1/S phase transition during cell cycle progression. Furthermore, the cell cycle block was reversed as Runx2 levels declined after Dox withdrawal.ConclusionsThe effects of Runx2 in C4-2B/Rx2dox cells, as well as similar observations made by employing LNCaP, 22RV1 and PC3 cells, highlight multiple mechanisms by which Runx2 promotes the metastatic phenotype of PCa cells, including tissue invasion, homing to bone and induction of high bone turnover. Runx2 is therefore an attractive target for the development of novel diagnostic, prognostic and therapeutic approaches to PCa management. Targeting Runx2 may prove more effective than focusing on its individual downstream genes and pathways.
The transcription factors Runx2 and estrogen receptor-alpha (ERalpha) are involved in numerous normal and disease processes, including postmenopausal osteoporosis and breast cancer. Using indirect immunofluorescence microscopy and pull-down techniques, we found them to colocalize and form complexes in a ligand-dependent manner. Estradiol-bound ERalpha strongly interacted with Runx2 directly through its DNA-binding domain and only indirectly through its N-terminal and ligand-binding domains. Runx2's amino acids 417-514, encompassing activation domain 3 and the nuclear matrix targeting sequence, were sufficient for interaction with ERalpha's DNA-binding domain. As a consequence of the interaction, Runx2's transcriptional activation activity was strongly repressed, as shown by reporter assays in COS7 cells, breast cancer cells, and late-stage MC3T3-E1 osteoblast cultures. Metaanalysis of gene expression in 779 breast cancer biopsies indicated negative correlation between the expression of ERalpha and Runx2 target genes. Selective ER modulators (SERM) induced ERalpha-Runx2 interactions but led to various functional outcomes. The regulation of Runx2 by ERalpha may play key roles in osteoblast and breast epithelial cell growth and differentiation; hence, modulation of Runx2 by native and synthetic ERalpha ligands offers new avenues in selective ER modulator evaluation and development.
Background:The transcriptional corepressor G9a also activates genes by an unknown mechanism. Results: The N-terminal region of G9a binds estrogen receptor ␣ and is necessary and sufficient for enhancing estrogen-induced gene activation and for occupancy of G9a on target genes. Conclusion: The domains of G9a responsible for activation and inhibition of transcription are different. Significance: G9a has inherent coactivator as well as corepressor activity.
Progesterone receptor (PgR) controls the menstrual cycle, pregnancy, embryonic development, and homeostasis, and it plays important roles in breast cancer development and progression. However, the requirement of coregulators for estrogen-induced expression of the PgR gene has not been fully explored. Here we used RNA interference to demonstrate dramatic differences in requirements of 10 different coregulators for estrogen-regulated expression of six different genes, including PgR and the well-studied TFF1 (or pS2) gene in MCF-7 breast cancer cells. Full estrogen-induced expression of TFF1 required all ten coregulators, but PgR induction required only four of the 10 coregulators. Chromatin immunoprecipitation studies demonstrated several mechanisms responsible for the differential coregulator requirements. Actin-binding coregulator Flightless-I, required for TFF1 expression and recruited to that gene by estrogen receptor-α (ERα), is not required for PgR expression and not recruited to that gene. Protein acetyltransferase tat-interactive protein 60 and ATP-dependent chromatin remodeler Brahma Related Gene 1 are recruited to both genes but are required only for TFF1 expression. Histone methyltransferase G9a is recruited to both genes and required for estrogen-induced expression of TFF1 but negatively regulates estrogen-induced expression of PgR. In contrast, histone methyltransferase myeloid/lymphoid or mixed-lineage leukemia 1 (MLL1), pioneer factor Forkhead box A1, and p160 coregulator steroid receptor coactivator-3 are required for expression of and are recruited to both genes. Depletion of MLL1 decreased ERα binding to the PgR and TFF1 genes. In contrast, depletion of G9a enhanced ERα binding to the PgR gene but had no effect on ERα binding to the TFF1 gene. These studies suggest that differential promoter architecture is responsible for promoter-specific mechanisms of gene regulation.
Protein arginine methyltransferase 1 (PRMT1) is an arginine-specific protein methyltransferase that methylates a number of proteins involved in transcription and other aspects of RNA metabolism. Its role as a transcriptional coactivator for nuclear receptors involves its ability to bind to other coactivators, such as glucocorticoid receptor-interacting protein 1 (GRIP1), as well as its ability to methylate histone H4 and coactivators such as peroxisome proliferator-activated receptor gamma coactivator-1alpha. Its ability to form homodimers or higher-order homo-oligomers also is important for its methyltransferase activity. To understand the function of PRMT1 further, 19 surface residues were mutated, based on the crystal structure of PRMT1. Mutants were characterized for their ability to bind and methylate various substrates, form homodimers, bind GRIP1, and function as a coactivator for the androgen receptor in cooperation with GRIP1. We identified specific surface residues that are important for methylation substrate specificity and binding of substrates, for dimerization/oligomerization, and for coactivator function. This analysis also revealed functional relationships between the various activities of PRMT1. Mutants that did not dimerize well had poor methyltransferase activity and coactivator function. However, surprisingly, all dimerization mutants exhibited increased GRIP1 binding, suggesting that the essential PRMT1 coactivator function of binding to GRIP1 may require dissociation of PRMT1 dimers or oligomers. Three different mutants with altered substrate specificity had widely varying coactivator activity levels, suggesting that methylation of specific substrates is important for coactivator function. Finally, identification of several mutants that exhibited reduced coactivator function but appeared normal in all other activities tested, and finding one mutant with very little methyltransferase activity but normal coactivator function, suggested that these mutated surface residues may be involved in currently unknown protein-protein interactions that are important for coactivator function.
Runx2, best known for its role in regulating osteoblast-specific gene expression, also plays an increasingly recognized role in prostate and breast cancer metastasis. Using the C4-2B/Rx2dox prostate cancer cell line that conditionally expressed Runx2 in response to doxycycline treatment, we identified and characterized G9a, a histone methyltransferase, as a novel regulator for Runx2 activity. G9a function was locus-dependent. Whereas depletion of G9a reduced expression of many Runx2 target genes, including MMP9, CSF2, SDF1, and CST7, expression of others, such as MMP13 and PIP, was enhanced. Physical association between G9a and Runx2 was indicated by co-immunoprecipitation, GST-pulldown, immunofluorescence, and fluorescence recovery after photobleaching (FRAP) assays. Since G9a makes repressive histone methylation marks and is primarily known as a corepressor, we further investigated the mechanism by which G9a functioned as a positive regulator for Runx2 target genes. Transient reporter assays indicated that the histone methyltransferase activity of G9a was not required for transcriptional activation by Runx2. Chromatin immunoprecipitation assays for Runx2 and G9a showed that G9a was recruited to endogenous Runx2 binding sites. We conclude that a subset of cancer-related Runx2 target genes require recruitment of G9a for their expression, but do not depend on its histone methyltransferase activity.
Purpose: In a previous study, we had detected the presence of mouse mammary tumor virus (MMTV)-like envelope (ENV) gene sequences in both the breast tumors and non-Hodgkin's lymphoma tissue of two of our breast tumor patients who had been diagnosed simultaneously with both malignancies. The aim of this study was to determine if MMTV-like DNA sequences are present in the breast tumors and non-Hodgkin's lymphomas of additional patients suffering from both malignancies and if so to characterize these sequences in detail.Experimental Design: DNA was extracted from formalinfixed, paraffin-embedded tissue sample blocks of breast tumors and non-Hodgkin's lymphomas from patients suffering from both malignancies. A 250-bp region of the MMTV ENV gene and a 630-bp region of the MMTV long terminal repeat (LTR) open reading frame (ORF) that encodes the MMTV superantigen (sag) gene were amplified by PCR from the isolated DNA. Amplified products were analyzed by Southern blotting, cloned, and sequenced.Results: MMTV-like ENV and LTR sequences were detected in both the breast tumors and non-Hodgkin's lymphomas of 6 of 12 patients suffering from both malignancies. A novel mutant of the MMTV ENV gene was identified in these patients. Characterization of the MMTV-like LTR highly variable sag sequences revealed total or nearly total identity to three distinct MMTV proviruses from two different branches of the MMTV phylogenetic tree.Conclusions: The presence of MMTV-like ENV and LTR sequences in both the breast tumors and nonHodgkin's lymphomas of 6 additional patients suggests a possible involvement of these sequences in these two malignancies. MMTV-like LTR sequence homology to different MMTV proviruses revealed the presence of more than one strain of MMTV-like sequences in each individual suggesting the possibility of multiple infections in these patients.
A B S T R A C T A reduction in glomerular capillary endothelial pore size and density has been reported in several models of acute renal failure. It has been suggested that these changes underlie the decrease in glomerular filtration rate and altered glomerular capillary hemodynamics measured in various experimental models of acute renal failure. We have thoroughly quantitated the surface characteristics of glomerular capillaries in control rats and in rats with either mercuric chloride-induced acute renal failure (2 mg/kg body wt) evaluated at 6 and 24 h after administration of the nephrotoxin or with gentamicin (G)'-induced acute renal failure evaluated after 8-9 d of 40 mg/kg body wt twice a day. Despite reductions in glomerular filtration rate in the experimental groups, no significant differences were observed between control (C) and any experimental group with respect to percent areas occupied by fenestrated endothelium (C = 53.6±2.7%; 6 h HgCl2 = 50.9±1.9%; 24 h HgCl2 = 53.9±5.7%; G = 56.7±2.4%), by cytoplasmic ridges (C = 31.2±1.5%; 6 h HgCl2 = 29.8±1.9%; 24 h HgCl2 = 30.6±3.1%; G = 26.5±1.5%), nonfenestrated endothelium (C = 15.5±4.0%; 6 h HgCl2 = 19.3±2.0%; 24 h HgCl2 = 15.6±4.3%; G = 16.9±2.3%), in the individual pore area expressed in square nanometers (C = 1,494±75; 6 h HgCl2 = 1,326±48; 24 h HgCl2 = 1,559±130; G = 1,340±101), or in the percentage of total pore area within fenestrated areas that were measured (C = 12.8±0.8%; 6 h HgCl2 = 11.2+0.7%; 24 h HgCI2 =
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