Identification of the estrogen sensitive marker in human endometrial carcinoma RL95-2 cells

Up-regulation of hepatocyte growth factor receptor: an amplification and targeting mechanism for hepatocyte growth factor action in acute renal failure

BACKGROUND

Hepatocyte growth factor (HGF) and its c-met receptor comprise a signaling system that has been implicated in tissue repair and regeneration. HGF action is specifically targeted to the damaged organ following injury; however, the mechanism underlying this important targeting process remains to be elucidated. We reasoned that induction of c-met expression might be a critical factor in determining the site specificity of this receptor-ligand system. To test this hypothesis, we examined changes in activity of the HGF/c-met system in the folic acid model of acute tubular injury and repair.

METHODS

Tissue HGF and c-met mRNA levels were detected by RNase protection assay and Northern blot analysis following acute renal injury induced by a single injection of folic acid. HGF and c-met proteins were examined by a specific enzyme immunoassay and Western blotting, respectively. C-met expression and trans-activation were investigated by exposing renal epithelial mIMCD-3 cells to various cytokines in vitro.

RESULTS

Extremely rapid induction of renal HGF and c-met mRNA was observed beginning one hour following injection of folic acid. Circulating plasma HGF protein level rose dramatically (approximately 16-fold), peaking first at two hours and again at 24 hours following injection. Despite elevated HGF mRNA in the kidney, total kidney HGF protein actually decreased significantly at 24 hours following injury. On the other hand, both c-met mRNA and c-met protein were markedly increased in the kidney, where active renal tubule repair and regeneration take place. In vitro studies suggested that increased levels of HGF, as well as other cytokines, might account for enhanced c-met expression in renal tubular epithelial cells. Pretreatment of the cells with actinomycin D totally blocked c-met induction, suggesting that induced c-met expression occurs primarily at the transcriptional level. Using a cloned region of the c-met promoter coupled to a reporter gene, we demonstrated that HGF directly stimulated c-met promoter transactivation in renal epithelial cells.

CONCLUSION

These results suggest that local up-regulation of c-met transcription in the kidney is crucial to renal tubule repair and regeneration, not only because it increases overall activity of this receptor-ligand system, but also as a mechanism targeting HGF action specifically to renal epithelia.

Estrogen-related receptor, hERR1, modulates estrogen receptor-mediated response of human lactoferrin gene promoter

We have shown previously that estrogen-stimulated transcription from the human lactoferrin gene in RL95-2 endometrium carcinoma cells is mediated through an imperfect estrogen response element (ERE) at the 5 -flanking region of the gene. Upstream from the ERE, a DNA sequence (-418 to -378, FP1) was selectively protected from DNase I digestion by nuclear extracts from endometrial and mammary gland cell lines. In this report, using the electrophoresis mobility shift assay, site-directed mutagenesis, and DNA methylation interference analyses, we show that three different nuclear proteins bind to the FP1 region (C1, C2, and C3 sites). The nuclear receptor, COUP-TF, binds to the C2 site. Mutations in the C1 binding region abolish C1 complex formation and reduce estrogen-dependent transcription from the lactoferrin ERE. When the imperfect ERE of the lactoferrin gene is converted to a perfect palindromic structure, the enhancing effect of the C1 binding element for estrogen responsiveness was abolished. We isolated a complementary DNA (cDNA) clone from an RL95-2 expression library that encodes the C1 site-binding protein. The encoded polypeptide maintains 99% amino acid identity with the previously described orphan nuclear receptor hERR1. A 2.2-kilobase mRNA was detected in RL95-2 cells by the newly isolated cDNA but not by the first 180 base pair of the published hERR1 sequence. By Western analysis, a major 42-kDa protein is detected in the RL95-2 nuclear extract with antibody generated against GST-hERR1 fusion protein. Finally, we show that the hERR1 interacts with the human estrogen receptor through protein-protein contacts.

Estrogen action in target cells: selective requirements for activation of different hormone response elements

RENE1 cells, an estrogen receptor positive rat uterine endometrial cell line immortalized with the E1A oncogene, were analyzed for the presence of estrogen-dependent signal transduction pathways using the induction of transfected as well as endogenous genes. RENE1 cells express the estrogen receptor as analyzed by Northern blots and ligand binding assays (40 fmoles/mg protein). The receptor system appears functional, based on the induction of reporter constructs containing the consensus estrogen response element (ERE) in transient transfection assays and alterations in endogenous transcripts visualized by utilizing differential display methodology. However, neither transfected repoter constructs containing the c-fos ERE, nor the endogenous c-fos, c-jun, or c-myc genes are induced by estrogens in these cells despite being induced by estrogens in the uterus in vivo. In addition, estradiol did not induce endogenous c-fos expression or the activity of CAT reporters containing the c-fos ERE in a stable transfectant of RENE1 cells with a 3-fold elevation in estrogen receptor content. Under identical conditions, TPA and serum rapidly induce c-fos transcription in RENE1 cells, indicating that the lack of inducibility by estradiol is not due to a general inhibitor of transcription of these genes. These results suggest that RENE1 cells lack factors present in normal uterine cells which are required for the estrogenic induction of a specific subset(s) of EREs. These observations support the generally evolving hypothesis that steroid hormones may act through composite response elements via interactions with other transcription factors, in addition to functioning as homodimers at classical palindromic response elements.