Down-regulation of estrogen receptor-alpha in MCF-7 human breast cancer cells after proteasome inhibition.

The eukaryotic proteasome is a 26S ATP-dependent proteolytic complex, which possesses chymotrypsin-like, trypsin-like and peptidyl glutamyl peptide hydrolase (PGPH) activities, which enable the proteasome to degrade all short-lived and many long-lived proteins, and consequently regulate a myriad of activities in cells. In this study, we observed that inhibition of the proteasome, and more specifically, inhibition of the chymotrypsin-like activity of the proteasome, in MCF-7 human breast cancer cells resulted in selective down-regulation of the nuclear estrogen receptor-alpha (ERalpha). Our data indicated that estrogen had no effect, whereas the ERalpha antagonist, tamoxifen, reduced the amount of ERalpha that could be subjected to down-regulation after proteasome inhibition. Furthermore, our data demonstrated that protein synthesis was required for the down-regulation of ERalpha to occur. Collectively, these data indicate the existence of a proteasome-dependent mechanism that is utilized by MCF-7 cells to maintain a steady-state level of ERalpha.

Proteasome-independent down-regulation of estrogen receptor-alpha (ERalpha) in breast cancer cells treated with 4,4'-dihydroxy-trans-stilbene.

Treatment of cells with estrogens and several pure ERalpha antagonists rapidly induces down-regulation of the alpha-type estrogen receptor (ERalpha) in the nucleus by mechanisms that are sensitive to the proteasome inhibitors, MG132 and clasto-lactacystin-beta-lactone. Hence, it is believed that these ER ligands induce down-regulation of ERalpha by proteasome-dependent mechanisms, which serve to control both the amount of transcriptional activity and the level of ligand-bound ERalpha in cells. In this study, we observed that treatment of cultured MCF-7 and T47D human breast cancer cells with the low affinity ER ligand, 4,4'-dihydroxy-trans-stilbene (4,4'-DHS), inhibited the transcriptional activity of ERalpha and induced slow and gradual decrease in the amount of ERalpha protein (henceforth referred to as down-regulation of ERalpha). The 4,4'-DHS-induced down-regulation of ERalpha in MCF-7 cells involved a mechanism that was insensitive to the two most specific proteasome inhibitors, clasto-lactacystin-beta-lactone and epoxomycin, but sensitive to MG132 at concentrations exceeding that required for maximal inhibition of the proteasome in MCF-7 cells. Therefore, 4,4'-DHS appears to induce down-regulation of ERalpha by a proteasome-independent mechanism. Here, we present data to show that both 4-OH and 4'-OH are critical for the ability of 4,4'-DHS to induce down-regulation of ERalpha and suggest that 4,4'-DHS provides a useful scaffold for development of novel ERalpha antagonists.

Structure, upstream promoter region, and functional domains of a mouse and human Mix paired-like homeobox gene.

Mix/Bix proteins represent a vertebrate subgroup of paired-like homeodomain proteins which are known to function around the time of gastrulation. Here we report the structures of the genomic and upstream promoter regions of a mouse and human Mix-like gene. Both genes map to syntenic regions of chromosome 1 and contain two coding exons, with the paired-type homeodomain split between the exons within helix 3. Differentiating mouse embryonic stem cells transcribe a messenger RNA of approximately 2.6 kb. The first exon encodes the translation initiation codon and a 5' untranslated region of approximately 90 bp. Sequence analysis of the 960 bp upstream of the transcription start site of the mouse Mix gene revealed the presence of a putative initiator region and TATA box as well as potential Smad, FoxH1/FAST, T-box, COUP-TF, C/EBP, GATA, HNF3 binding sites and retinoic acid response elements. A number of these sites are conserved in the human Mix promoter. We find that most paired-related homeodomain proteins, including mouse and human Mix, contain a proline-rich region within their amino termini which may interact with other proteins. Mouse and human Mix proteins contain highly conserved carboxy-terminal polar/acidic regions with the potential to form an amphipathic helix and the ability to activate transcription in yeast. Mouse Mix expressed in COS cells or in vitro binds a DNA consensus sequence identified previously for paired class homeodomain proteins. These studies suggest that a number of features of paired-like protein structure and function are conserved across diverse species and provide a useful framework for studying the function and regulation of the mouse Mix gene.

Analysis of two distinct retinoic acid response elements in the homeobox gene Hoxb1 in transgenic mice.

Expression of vertebrate Hox genes is regulated by retinoids such as retinoic acid (RA) in cell culture and in early embryonic development. Retinoic acid response elements (RAREs) have been identified in Hox gene regulatory regions, suggesting that endogenous retinoids may be involved in the direct control of Hox gene patterning functions. Previously, two RAREs located 3' of the murine Hoxb1 gene, a DR(2) RARE and a DR(5) RARE, have been shown to regulate Hoxb1 mRNA expression in the neural epithelium and the foregut region, respectively; the foregut develops into the esophagus, liver, pancreas, lungs, and stomach. We have now examined the functional roles of these two types of 3' RAREs in regulating Hoxb1 expression at different stages of gestation, from embryonic day 7.5 to 13.5, in transgenic mice carrying specific RARE mutations. We demonstrate that the DR(5) RARE is required for the regulation of Hoxb-1 transgene region-specific expression in the gut and extraembryonic tissues, as well as for the RA-induced anteriorization of Hoxb-1 transgene expression in the gut. In contrast, expression of the Hoxb1 transgene in the neural epithelium requires only the DR(2) RARE. By in situ hybridization, we have identified a new site of Hoxb1 expression in the developing forelimbs at approximately day 12.5, and we show that, in transgenic embryos, expression in the forelimb buds requires that either the DR(2) or the DR(5) RARE is functional. Attainment of a high level of Hoxb1 transgene expression in other regions, such as in rhombomere 4 (r4) and in the somites, requires that both the DR(2) and DR(5) RAREs are functional. In addition, our transgenic data indicate that the Hoxb1 gene is expressed in other tissues such as the hernia gut, genital eminence, and lung. Our analysis shows that endogenous retinoids act through individual DR(2) and DR(5) RAREs to regulate Hoxb1 expression in different regions of the embryo and that functional redundancy between these DR(2) and DR(5) RAREs does not exist with respect to neural epithelium and the gut Hoxb1 expression.

Mouse Mix gene is activated early during differentiation of ES and F9 stem cells and induces endoderm in frog embryos.

In frog and zebrafish, the Mix/Bix family of paired type homeodomain proteins play key roles in specification and differentiation of mesendoderm. However, in mouse, only a single Mix gene (mMix) has been identified to date and its function is unknown. We have analyzed the expression of mouse Mix RNA and protein in embryos, embryoid bodies formed from embryonic stem cells and F9 teratocarcinoma cells, as well as several differentiated cell types. Expression in embryoid bodies in culture mirrors that in embryos, where Mix is transcribed transiently in primitive (visceral) endoderm (VE) and in nascent mesoderm. In F9 cells induced by retinoic acid to differentiate to VE, mMix is coordinately expressed with three other endodermal transcription factors, well before AFP, and its protein product is localized to the nucleus. In a subpopulation of nascent mesodermal cells from embryonic stem cell embryoid bodies, mMix is coexpressed with Brachyury. Intriguingly, mMix mRNA is detected in a population (T+Flk1+) of cells which may contain hemangioblasts, before the onset of hematopoiesis and activation of hematopoietic markers. In vitro and in vivo, mMix expression in nascent mesoderm is rapidly down-regulated and becomes undetectable in differentiated cell types. In the region of the developing gut, mMix expression is confined to the mesoderm of mid- and hindgut but is absent from definitive endoderm. Injection of mouse mMix RNA into early frog embryos results in axial truncation of developing tadpoles and, in animal cap assays, mMix alone is sufficient to activate expression of several endodermal (but not mesodermal) markers. Although these observations do not exclude a possible cell-autonomous function for mMix in mesendodermal progenitor cells, they do suggest an additional, non-cell autonomous role in nascent mesoderm in the formation and/or patterning of adjacent definitive endoderm.