Impact of glucocorticoid receptor density on ligand-independent dimerization, cooperative ligand-binding and basal priming of transactivation: a cell culture model

Glucocorticoid receptor (GR) levels vary between tissues and individuals and are altered by physiological and pharmacological effectors. However, the effects and implications of differences in GR concentration have not been fully elucidated. Using three statistically different GR concentrations in transiently transfected COS-1 cells, we demonstrate, using co-immunoprecipitation (CoIP) and fluorescent resonance energy transfer (FRET), that high levels of wild type GR (wtGR), but not of dimerization deficient GR (GRdim), display ligand-independent dimerization. Whole-cell saturation ligand-binding experiments furthermore establish that positive cooperative ligand-binding, with a concomitant increased ligand-binding affinity, is facilitated by ligand-independent dimerization at high concentrations of wtGR, but not GRdim. The down-stream consequences of ligand-independent dimerization at high concentrations of wtGR, but not GRdim, are shown to include basal priming of the system as witnessed by ligand-independent transactivation of both a GRE-containing promoter-reporter and the endogenous glucocorticoid (GC)-responsive gene, GILZ, as well as ligand-independent loading of GR onto the GILZ promoter. Pursuant to the basal priming of the system, addition of ligand results in a significantly greater modulation of transactivation potency than would be expected solely from the increase in ligand-binding affinity. Thus ligand-independent dimerization of the GR at high concentrations primes the system, through ligand-independent DNA loading and transactivation, which together with positive cooperative ligand-binding increases the potency of GR agonists and shifts the bio-character of partial GR agonists. Clearly GR-levels are a major factor in determining the sensitivity to GCs and a critical factor regulating transcriptional programs

Identification of an estrogen-responsive element from the 5'-flanking region of the rat prolactin gene.

The DNA sequences which interact with the estrogen receptor and which mediate the estrogenic regulation of prolactin gene transcription have been investigated by the use of receptor-DNA-binding experiments and gene transfer studies. Nitrocellulose filter binding assays using highly purified estrogen receptor and cloned fragments of the 5'-flanking region of the rat prolactin gene demonstrate that the receptor selectively binds to DNA sequences located between nucleotides -1713 and -1532 with respect to the transcription initiation site. The binding of the estrogen receptor to this region of the prolactin gene was strongly dependent on receptor concentration, suggesting that receptor dimers may be important in DNA binding. These data demonstrate that the selective binding of purified estrogen receptor to specific sequences of the rat prolactin gene is an intrinsic property of the receptor and is not due to the interaction of receptor with other proteins. The role of specific prolactin gene sequences in mediating the estrogenic regulation of prolactin gene transcription was confirmed by the use of prolactin-chloramphenicol acetyltransferase fusion genes. These studies demonstrated that sequences upstream of position -1532 are required for estrogen responsiveness. Furthermore, the region of the prolactin gene at -1713 to -1495 was able to confer estrogen responsiveness on the thymidine kinase promoter. Exonuclease III protection experiments further localized the receptor-binding sequences to positions -1587 to -1563. Comparison of the nucleotide sequence of the region of the prolactin gene which binds the estrogen receptor with the sequence of other estrogen-responsive genes suggested the presence of the conserved sequence [sequence in text], which shows similarity to sequences thought to mediate glucocorticoid receptor effects on transcription