Effects of acetylation, polymerase phosphorylation, and DNA unwinding in glucocorticoid receptor transactivation

Varying the concentration of selected factors alters the induction properties of steroid receptors by changing the position of the dose-response curve (or the value for half-maximal induction=EC(50)) and the amount of partial agonist activity of antisteroids. We now describe a rudimentary mathematical model that predicts a simple Michaelis-Menten curve for the multi-step process of steroid-regulated gene induction. This model suggests that steps far downstream from receptor binding to steroid can influence the EC(50) of agonist-complexes and partial agonist activity of antagonist-complexes. We therefore asked whether inhibitors of three possible downstream steps can reverse the effects of increased concentrations of two factors: glucocorticoid receptors (GRs) and Ubc9. The downstream steps (with inhibitors in parentheses) are protein deacetylation (TSA and VPA), DNA unwinding (CPT), and CTD phosphorylation of RNA polymerase II (DRB and H8). None of the inhibitors mimic or prevent the effects of added GRs. However, inhibitors of DNA unwinding and CTD phosphorylation do reverse the effects of Ubc9 with high GR concentrations. These results support our earlier conclusion that different rate-limiting steps operate at low and high GR concentrations versus high GR with Ubc9. The present data also suggest that downstream steps can modulate the EC(50) of GR-mediated induction, thus both supporting the utility of our mathematical model and widening the field of biochemical processes that can modify the EC(50).     

Discovery and SAR study of novel dihydroquinoline-containing glucocorticoid receptor agonists

We have recently reported the discovery of a novel class of glucocorticoid receptor (GR) antagonists, exemplified by 3, containing a 1,2-dihydroquinoline molecular scaffold. Further SAR studies of these antagonists uncovered chemical modifications conveying agonist functional activity to this series. These agonists exhibit good GR binding affinity and are selective against other nuclear hormone receptors.     

The glucocorticoid agonist activities of mifepristone (RU486) and progesterone are dependent on glucocorticoid receptor levels but not on EC50 values

Mifepristone is an antagonist of the glucocorticoid receptor (GR) that also has significant agonist activity in some cell types. We examined the partial agonist activity of mifepristone in COS-7 cells transfected with increasing amounts of a glucocorticoid receptor expression vector pmGR. As pmGR levels increased, the response of the reporter, pMTVCAT to dexamethasone increased, consistent with increasing levels of receptor expression; the response to mifepristone also increased but at a higher rate, resulting in increasing mifepristone agonist and decreasing antagonist activity. In contrast, increasing pMTVCAT levels increased CAT activity induced by both dexamethasone and mifepristone, but did not change the relative agonist activity of mifepristone. We also examined the relationship between agonist activity and receptor level in a series of clones of the E8.2.A3 cell line expressing various levels of GR. Again, the relative agonist activity of mifepristone increased as GR increased. This increase was not due to changes in the dose response curves to these two ligands since their EC50 values were independent of receptor levels. These results indicate that the degree of glucocorticoid agonist activity exhibited by mifepristone is dependent on the concentration of GR in the cell. Similar results were obtained with another partial agonist of the GR, progesterone, whereas the complete antagonist ZK98.299 had no agonist activity under any condition. Taken together, these results suggest that the phenomenon of receptor concentration-dependence is a property of partial GR agonists in general.     

Trifluoromethyl group as a pharmacophore: effect of replacing a CF3 group on binding and agonist activity of a glucocorticoid receptor ligand

Compound 1, a potent glucocorticoid receptor ligand, contains a quaternary carbon bearing trifluoromethyl and hydroxyl groups. This paper describes the effect of replacing the trifluoromethyl group on binding and agonist activity of the GR ligand 1. The results illustrate that replacing the CF3 group with a cyclohexylmethyl or benzyl group maintains the GR binding potency. These substitutions alter the functional behavior of the GR ligands from agonists to antagonists. Docking studies suggest that the benzyl analog 19 binds in a similar fashion as the GR antagonist, RU486. The central benzyl group of 19 and the C-11 dimethylaniline moiety of RU486 overlay. Binding of compound 19 is believed to force helix 12 to adopt an open conformation and this leads to the antagonist properties of the non-CF3 ligands carrying a large group at the center of the molecule.