Internuclear migration of chicken progesterone receptor, but not simian virus-40 large tumor antigen, in transient heterokaryons.

The chicken progesterone receptor (PR) is a transcriptional regulatory protein that localizes predominantly within the nucleus of hormone-treated and untreated cells. Transient heterokaryons were generated between PR-expressing Cos-1 cells and PR-negative NIH3T3 cells to examine whether PRs are confined to the nucleus or are capable of bidirectionally traversing the nuclear envelope. Migration of PR from Cos-1 to NIH3T3 nuclei was observed in both the presence and absence of hormone. Since de novo PR synthesis was inhibited in heterokaryons with cycloheximide treatment, PRs that localize within NIH3T3 nuclei of heterokaryons must derive from preexisting receptors that were exported from Cos-1 nuclei. Thus, PR, like some nucleolar and heat shock proteins, appears to be capable of shuttling between the nuclear and cytoplasmic compartments. Not all proteins that enter the nucleus exhibit this trait, since simian virus-40 large tumor antigen, endogenously expressed in Cos-1 cells, does not efficiently translocate to NIH3T3 nuclei of heterokaryons, which support internuclear migration of PR. Thus, proteins that may use analogous or identical mechanisms for nuclear import may differentially interact with the nuclear export machinery. Furthermore, the fact that PR and simian virus-40 large tumor antigen localization within nuclei is not identical, as revealed by laser scanning confocal microscopy, supports the notion that nuclear export may be influenced by subnuclear compartmentalization.

Glucocorticoid receptor-mediated repression of gonadotropin-releasing hormone promoter activity in GT1 hypothalamic cell lines.

The synthesis and release of GnRH within a specific subset of neurons in the hypothalamus, which serves as the primary drive to the hypothalamic-pituitary-gonadal (HPG) axis, is subject to various levels of control. Although a number of direct synaptic connections to GnRH-containing neurons have been identified, which presumably provide some regulatory inputs, the mechanisms responsible for hormonal regulation of GnRH synthesis and release mediated by either cell surface or intracellular receptors remain controversial. The recent demonstration that a subset of GnRH-containing neurons in the rat hypothalamus possesses immunoreactive glucocorticoid receptors (GR) implies that this class of steroid hormones could exert a direct effect to regulate the functioning of these neurons and perhaps the HPG axis. We used the GT1-3 and GT1-7 cell lines of immortalized GnRH-secreting hypothalamic neurons as a model to study the direct effects of glucocorticoids on GnRH gene expression. We demonstrated that these cell lines possess GR that bind the synthetic glucocorticoid, dexamethasone, in vitro with high affinity (Kd = 2-3 nM). These receptors are functional, as indicated by their ability to activate transcription from exogenously introduced heterologous glucocorticoid-responsive promoters. Furthermore, dexamethasone represses both the endogenous mouse GnRH gene, decreasing steady state levels of GnRH mRNA, and the transcriptional activity of transfected rat GnRH promoter-reporter gene vectors. Glucocorticoid repression of rat GnRH promoter activity appears to be mediated by sequences contained within the promoter proximal 459 basepairs and not be influenced by the relative basal activity of the GnRH promoter. Thus, our results provide the first direct demonstration of glucocorticoid repression of transcription in a hypothalamic cell line and suggest that GR acting directly within GnRH neurons could be at least partly responsible for negative regulation of the HPG axis by glucocorticoids.

Glucocorticoid repression of gonadotropin-releasing hormone gene expression and secretion in morphologically distinct subpopulations of GT1-7 cells.

Two morphologically distinct subpopulations of GT1-7 cells have been characterized and examined for their responsiveness to glucocorticoids. Type I cells have a neuronal phenotype, extending many lengthy processes, and express neuronal, but not glial, markers. Type II cells show weaker or negative immunostaining for neuronal markers and exhibit fewer processes. The effect of glucocorticoids on gonadotropin-releasing hormone (GnRH) secretion and gene expression was compared in type I and type II GT1-7 cells. For secretion studies, cells were attached to Cytodex beads and perifused with control medium or medium containing dexamethasone (dex). The high level of GnRH secreted by type I cells was slightly enhanced in the presence of dex, whereas dex rapidly and profoundly decreased the already low level of GnRH secreted by type II cells. Immunocytochemistry for GnRH showed dark reaction product in the cell bodies and processes of type I cells and little or no immunoreactivity in type II cells. Both the endogenous mouse GnRH mRNA and the transcriptional activity of a mouse GnRH promoter luciferase reporter gene plasmid were suppressed to a greater extent in type II cells than in type I. In electrophoretic mobility shift assays, there was no difference between type I and type II nuclear extracts in the pattern of protein-DNA complexes formed on two previously identified negative glucocorticoid response elements located at -237 to -201 and -184 to -150 bp of the mouse promoter. Both cell types contained glucocorticoid receptors (GR) by Western blot analysis. Cytosols from type I or type II cells were incubated with [3H]dex to obtain GR binding parameters. Binding data were consistent with a one-site model for dex binding in each case. Small differences in Kd (1.7 nM, type I; 3.1 nM, type II) or Bmax (approximately 3600 sites/cell, type I; approximately 1800 sites/cell, type II) were not likely to account for the differential sensitivity to dex treatment. In conclusion, nuclear alterations in type II cells leading to greater transcriptional susceptibility to dex, coupled with low GnRH storage levels, may be reflected in exquisite sensitivity of GnRH secretion to glucocorticoid repression. This represents the first example of a steroid hormone acting directly on GnRH-producing cells to alter GnRH secretion.

Regulation of gonadotropin-releasing hormone gene transcription.

The GT1-7 cell line, derived from gonadotropin-releasing hormone (GnRH) neurons of the mouse hypothalamus, has provided a useful system for the analysis of GnRH gene regulation. We have used these cells to examine the mechanism of glucocorticoid repression of GnRH gene transcription. One GnRH negative glucocorticoid response element (nGRE) that contributes to glucocorticoid repression is not bound directly by the glucocorticoid receptor (GR). Rather, GR is tethered to this nGRE by virtue of its interaction with a DNA-bound POU domain transcription factor (i.e. Oct-1). DNA-dependent conformational changes in Oct-1 play a major role in recruiting GR to the distal nGRE and impacts transcriptional repression brought about by either glucocorticoids or tumor-promoting phorbol esters. GT1-7 cell-specific transcription of the mouse GnRH gene is controlled by an enhancer element that shares a high degree of sequence homology with the rat GnRH gene enhancer. As in the rat gene, Oct-1 is important for mGnRH enhancer activity. Furthermore, enhancer activity appears to be influenced by the DNA-dependent conformation adopted by bound Oct-1. Thus, the precise sequence recognized by Oct-1 appears to play a important role in both cell-specific and hormonal regulation of GnRH gene transcription.

The glucocorticoid receptor is tethered to DNA-bound Oct-1 at the mouse gonadotropin-releasing hormone distal negative glucocorticoid response element.

An element required for glucocorticoid repression of mouse gonadotropin-releasing hormone (GnRH) gene transcription, the distal negative glucocorticoid response element (nGRE), is not bound directly by glucocorticoid receptors (GRs) but is recognized by Oct-1 present in GT1-7 cell nuclear extracts or by Oct-1 purified from HeLa cells. Furthermore, purified full-length GRs interact directly with purified Oct-1 bound to the distal nGRE. Increasing the extent of distal nGRE match to an Oct-1 consensus site not only increases the affinity of Oct-1 binding, but also alters the conformation of DNA-bound Oct-1 and the pattern of protein DNA complexes formed in vitro with GT1-7 cell nuclear extracts. In addition, the interaction of purified GR with DNA-bound Oct-1 is altered when Oct-1 is bound to the consensus Oct-1 site. Mutation of the distal nGRE to a consensus Oct-1 site is also associated with reduced glucocorticoid repression in transfected GT1-7 cells. Furthermore, repression of GnRH gene transcription by 12-O-tetradecanoylphorbol-13-acetate, which utilizes sequences that overlap with the nGRE, is reversed by this distal nGRE mutation leading to activation of GnRH gene transcription. Thus, changes in the assembly of multi-protein complexes at the distal nGRE can influence the regulation of GnRH gene transcription.

Glucocorticoid repression of the mouse gonadotropin-releasing hormone gene is mediated by promoter elements that are recognized by heteromeric complexes containing glucocorticoid receptor.

We have identified two regions of the mouse gonadotropin-releasing hormone (GnRH) promoter, one between -237 and -201 (distal element) and the other between -184 and -150 (proximal element), which are required for glucocorticoid repression in transiently transfected GT1-7 cells. These sequences show no similarity to known positive or negative glucocorticoid response elements (nGREs) and do not function when placed upstream of heterologous viral promoters. The glucocorticoid receptor (GR) does not bind directly to the distal or proximal promoter elements but may participate in glucocorticoid repression of GnRH gene transcription by virtue of its association within multiprotein complexes at these nGREs. Electrophoretic mobility shift assays with GT1-7 nuclear extract demonstrate the presence of GR-containing protein complexes on GnRH nGREs. One protein that co-occupies the distal nGRE in vitro along with GR is the POU domain transcription factor Oct-1. Thus, the tethering of GR to the GnRH distal nGRE, by virtue of a direct or indirect association with DNA-bound Oct-1, could play a role in hormone-dependent transcriptional repression of the GnRH gene. In contrast, Oct-1 does not appear to be a component of the GR-containing protein complex that is bound to the proximal nGRE.