Hormonal regulation of H19 gene expression in prostate epithelial cells.

The H19 gene is transcribed in an mRNA-like noncoding RNA. When tumors of various organs or cell types are considered, H19 oncogene or tumor-suppressor status remains controversial. To address the potential regulation of H19 gene expression by an androgen steroid hormone (DHT: dihydrotestosterone) or by a peptidic hormone (PRL: prolactin), we performed experiments in rats systemically treated with chemical mediators. This range of in vivo experiments demonstrated that chronic hyperprolactinemia upregulated the H19 expression in epithelial and stromal cells whereas DHT downregulated the gene. PRL and DHT appeared to be opposite mediators in the H19 RNA synthesis. We investigated these hormonal effects in three human prostate epithelial cell lines. In LNCaP cancer cells, the opposite effect of PRL and DHT was corroborated. However, in normal cells (PNT1A), H19 remained insensitive to the hormones in fetal calf serum (FCS) medium but became responsive in a serum-stripped medium. In the DU-145 cancer cell line, tested for its androgen-independence and aggressiveness, the hormones had no effect on H19 expression whatever the culture conditions. Finally, we demonstrated that PRL upregulated the H19 expression in LNCaP cells by the JAK2-STAT5 transduction pathway. We conclude that H19 expression is regulated by both a peptidic and a male steroid hormone.

Normal breast epithelial cells induce apoptosis of MCF-7 breast cancer cells through a p53-mediated pathway.

Cancer development depends not only on the nature of the tumor cells themselves but also on the regulatory effects of various normal cells. The present study was performed to better understand the mechanism by which normal breast epithelial cells (NBEC) can control the growth of MCF-7 breast cancer cells. When MCF-7 cells were treated with NBEC conditioned medium, cell growth was inhibited in a concentration-dependent manner. This inhibition was due to an induction of apoptosis without any change in cell cycle progression. The induction of apoptosis was correlated with increased levels of p53, p21(waf1) and decreased levels of bcl-2. Transient transfections of MCF-7 cells with two p53 cDNA constructs demonstrated the induction of apoptosis was mediated by endogenous p53. Taken together, our results indicate that NBEC inhibit the growth of MCF-7 breast cancer cells by inducing apoptosis in them via endogenous p53.

Steroid hormones modulate H19 gene expression in both mammary gland and uterus.

H19 is an imprinted and developmentally regulated gene whose product remains apparently untranslated. In a previous study on breast adenocarcinomas, we reported that overexpression of the H19 gene was significantly correlated with the presence of steroid receptors, suggesting the putative role of hormones in H19 transcription. To determine the mode of steroid action, we have detected levels of H19 RNA synthesis during mammary gland development by in situ hybridization (ISH): two peaks of H19 transcription occur during puberty and pregnancy. Furthermore, we demonstrated by ISH that in the uterus H19 RNA synthesis is high during estrus and metestrus phases. To test steroid control of H19 transcription, ovariectomized and adrenalectomized mice were supplemented, 1 week after surgery, with 17-beta-estradiol (E2, 20 microg/kg/day), progesterone (P, 1 mg/kg/day) or corticosterone (B, 0.3 mg/ kg/day) for 2 weeks. According to ISH data, E2 and to a lesser extent B stimulated H19 transcription in the uterus, whereas P inhibited it. To confirm the in vivo results, in vitro experiments were performed using cultures of MCF-7 cells (a hormone-sensitive mammary cell line). E2 stimulated the endogenous H19 gene of this cell line and tamoxifen inhibited this effect. Furthermore, we performed transient cotransfections in MCF-7, in HBL-100 (another hormone-sensitive mammary cell line) and in BT-20 (a hormone-insensitive mammary cell line) with various constructs of ERalpha (WT or mutated) and PR-A, in presence or absence of steroid hormones. We demonstrated that ERalpha up-regulated the H19 promoter in MCF-7 and in HBL-100, whereas PR-A did not have any effect per se. Moreover, in MCF-7, PR-A antagonized clearly the ERalpha-mediated promoter enhancement, but in HBL-100 this counteracting effect on the ERalpha up-regulation was not found. Interestingly, the same experiments performed in BT-20 cell line provided very similar results as those obtained in MCF-7 cells, with a clear down-regulation mediated by PR-A on the H19 promoter. All these in vitro data are in agreement with in vivo results. In addition, data obtained with ERalpha mutants indicate that H19 promoter activation is both ligand-dependent and ligand-independent. We have thus demonstrated that H19 gene expression is controlled by steroid hormones; furthermore, this gene is highly expressed in hormone-sensitive organs when the hormonal stimulation is accompanied with a morphological repair.

H19 overexpression in breast adenocarcinoma stromal cells is associated with tumor values and steroid receptor status but independent of p53 and Ki-67 expression.

In a previous study we described the expression of the H19 gene by in situ hybridization (ISH) in normal breast and in benign or malignant breast tumors (Dugimont T, Curgy JJ, Wernert N, Delobelle A, Raes MB, Joubel A, Stehelin D, Coll J: Biol Cell 1995, 85:117-124). In the present work, 1) we extend the previous one to a statistically useful number of adenocarcinomas, including 10 subclasses, 2) we provide information on the precise ISH localization of the H19 RNA by using, on serial tissue sections, antibodies delineating specifically the stromal or the epithelial component of the breast, and 3) we consider relationships between the H19 gene expression and various clinicopathological information as tumor values (T0 to T4), grades, steroid receptors, lymph node status, and molecular features as the p53 gene product and the Ki-67/MIB1 protein, which is specific to proliferating cells. Data indicate that 1) in 72.5% of studied breast adenocarcinomas an overall H19 gene expression is increased when compared with healthy tissues, 2) the H19 gene is generally overexpressed in stromal cells (92.2%) and rarely in epithelial cells (2.9% only), 3) an up-regulation of the H19 gene is significantly correlated with the tumor values and the presence of both estrogen and progesterone receptors, and 4) at the cellular level, the H19 gene demonstrates an independent expression versus accumulation of both the p53 protein and the Ki-67/MIB-1 cell-cycle marker.

The H19 TATA-less promoter is efficiently repressed by wild-type tumor suppressor gene product p53.

The developmentally regulated H19 gene displays several remarkable properties: expression of an apparently non-translated mRNA, genomic imprinting (maternal allele only expressed), relaxation of the imprinting and/or epigenetic lesions demonstrated in some tumors. Despite several observations after relaxation of imprinting status of the gene, data on trans and cis-acting factors required for the human H19 gene expression are still missing. As a first approach to address identification of factors involved in the regulation of the gene, we found that cells from a p53 antisense-transfected HeLa clone displayed increased amounts of H19 transcripts when compared to the non-transfected cells. Moreover, a HeLa clone stably transfected with a temperature sensitive (ts) 143 Ala p53 mutant exhibited temperature-dependent regulation of H19 expression. This preliminary indication of the repressing effect of the p53 protein on H19 expression has been confirmed by transient cotransfection experiments in HeLa cells, using luciferase surrogate constructs under the control of the 823 bp sequence immediately upstream of the transcription start point of the H19 gene, and different constructs containing sense, antisense or a ts 143 Ala mutant p53 cDNA. We observed an increase of H19 promoter-driven activity in transient cotransfections with the antisense p53 cDNA and the temperature sensitive mutant p53 at the non-permissive temperature, but a decrease with sense wild-type p53 cDNA. Furthermore, the cotransfection experiments were repeated in a cell line lacking endogenous p53. (Calu 6 cells) and the results provided additional evidence for a down regulation of the expression of the H19 gene by the p53 protein.