Antagonism of glucocorticoid induction of Epstein-Barr virus early antigens by different steroids in Daudi lymphoma cells

Four antiglucocorticoids, RU38486, RU5020, RU25055 and progesterone were found to antagonize the induction of latent Epstein-Barr virus (EBV) information by dexamethasone. The dose response studies show that the antagonization was more prominent with the synthetic steroids than with the natural hormone. Specific binding characteristics of dexamethasone measured in whole cells indicate the presence of glucocorticoid receptors. Total cellular receptor contents deduced from binding data give values similar to those reported for B-lymphoblasts. Competition experiments between dexamethasone and RU38436 strongly suggest that RU38486 binds to two distinct sites in the whole cell; one is the glucocorticoid receptor but the nature of the other site is unknown. Inhibition by antiglucocorticoids differs from antagonism by 12-O-tetradecanoyl-phorbol-13-acetate (TPA) since the latter does not compete for any sites interacting with RU38486.     

Binding studies of the antiglucocorticoid RU38486 in Daudi and Raji lymphoma cells

The activity of RU38486 has been studied in Burkitt's lymphoma cells which are Epstein-Barr virus (EBV) positive. The early antigens (EA) of the virus are induced by dexamethasone (DXM) in Daudi but not in Raji cells, whereas a growth factor (transforming growth factor-beta, TGF-beta) induces the EA in both cell lines. RU38486 blocks the EA induction obtained by DXM or by TGF-beta in either cell line. In order to understand the interaction of RU38486, we considered its binding to specific receptors. We first investigated the binding of the antagonist in whole cells at 22 degrees C. A number of specific binding sites higher for RU38486 than for DXM was found, suggesting that RU38486 may bind to the glucocorticoid receptor and also to other cellular structures which we called the antiglucocorticoid binding sites ("AGBS"). To support this hypothesis, competition experiments have been conducted between RU38486 and other steroid hormones (progesterone and testosterone) since it is known that RU38486 is also able to interact with their cognate receptors. Binding studies of RU38486 in vitro at 4 degrees C in the presence of cytosolic extracts from Daudi and Raji cells led to conclusions similar to those drawn from the whole cell experiments: more complexes were formed with RU38486 than with DXM. Finally, the steroid-receptor complexes were incubated with DNA-cellulose. Since the binding measured for RU38486 was higher than for DXM, we suspect that sites different from the classical glucocorticoid receptor sites are also able to interact with DNA. The blockage exerted by RU38486 on the EA induced by glucocorticoids or by non-steroidal molecules and the lack of responsiveness to glucocorticoids in Raji cells are discussed in the light of the present findings.     

Analysis of the glucocorticoid receptor during differentiation of 3T3-F442A preadipocyte cell line in culture

A pure glucocorticoid agonist RU 28362 and the potent antagonist RU 38486 were compared with dexamethasone for the evolution and the molecular nature of the GR during insulin-dependent conversion of 3T3-F442A preadipocytes into mature cells. In the whole cell assay system, the affinity for preadipocyte GR was observed in the order RU 38486 greater than RU 28362 greater than dexamethasone. The GR complex was most stable in presence of dexamethasone followed by the antagonist RU 38486 = the agonist RU 28362. Similar results were obtained in mature adipocytes but the binding of RU 38486 was more equivocal. An insulin-dependent differentiation process did not alter any of these parameters but increased the number of GR nearly fivefold over a 2-week period. Ion-exchange analysis of the cytosolic receptor revealed that the differentiation process was not accompanied by the appearance of any novel or new forms of GR, contrary to the situation in the liver, since both RU 38486 and dexamethasone were bound to identical molecular species of GR. These data provide a defined system for further analysis of cellular receptor as a function of steroid, tissue, and species, contrary to the classical dogma where GR is generally thought to be identical as a passive vehicle for the steroid in all circumstances, and affinity for steroid is generally equated with receptor stability.     

Physiological action and receptor binding of a newly synthesized and novel antiglucocorticoid

RU 38486, a newly synthesized molecule, reversed glucocorticoid mediated enzyme induction and gluconeogenesis in the liver, and RNA synthesis in rat thymocytes. The transfer of radiolabelled dexamethasone from the cytoplasm to the nucleus was also opposed by RU 38486 in intact thymocytes. Although RU 38486 saturated the same molecular species of the receptor as the hormone in the liver, differences seemed to appear when thymus was taken into account. Along with the ongoing clinical trials, an important new tool thus appears at hand to understand and harness the molecular action of glucocorticoid hormones in mammalian systems.     

A possible role for endogenous glucocorticoids in orchiectomy-induced atrophy of the rat levator ani muscle: studies with RU 38486, a potent and selective antiglucocorticoid

We employed RU 38486, a potent and selective antiglucocorticoid, to study a possible role for endogenous glucocorticoids in atrophy of the levator ani muscle secondary to castration of male rats. RU 38486 was shown to block [3H]triamcinolone acetonide binding to cytosol from levator ani muscle. Daily oral administration of RU 38486 to castrated rats partially prevented atrophy of the levator ani muscle, as well as a decrease in RNA concentration. In a control group receiving RU 38486 alone, the levator ani underwent significant (20%) hypertrophy. Administration of exogenous dexamethasone also caused pronounced atrophy of the levator ani muscle. This atrophy was prevented, to a significant degree, by simultaneous oral administration of RU 38486. It is concluded that endogenous glucocorticoids, the actions of which are blocked by RU 38486, may be involved in regulation of the mass of the levator ani muscle in intact rats.     

Effect of the antiglucocorticoid agent RU 38486 on the dexamethasone inhibition of Friend cell differentiation

Glucocorticoid hormones are known to inhibit the erythroid differentiation of Friend cells. The mechanism of action of these hormones has been questioned, and results suggesting an action not involving the nuclear binding of the receptors have been published. We have used the antiglucocorticoid RU 38486 to block the inhibitory effect of dexamethasone on the induced differentiation of Friend cells. Our results strongly suggest a glucocorticoid action involving the binding of classical receptors to the cell nucleus.     

Steroid metabolism in normal and transformed liver cells. Relation with glucocorticoid antagonism

The metabolism of the potent antagonist RU38486 has been studied in cultured liver cells and in two hepatoma cell lines. In the liver cells, this steroid undergoes a rapid degradation, whereas in hepatoma cells grown in similar conditions only a minor degradation occurs. Moreover the rate of degradation is much higher for the antagonist steroid than for the agonist steroid tested, dexamethasone. The high antiglucocorticoid potency and the relative instability of the RU38486 molecule are very important to define its different effects and its mechanism of action in liver and in liver derived tumor cells. RU38486 may represent a useful drug in cancerotherapy.     

Effect of antiglucocorticoids on dexamethasone-induced inhibition of uridine incorporation and cell lysis in isolated mouse thymocytes

We have compared in isolated mouse thymocytes the action of progesterone, cortexolone, DXH (a 17-beta carboxamide derivative of dexamethasone) and RU 38486 (a new antiglucocorticoid molecule), on dexamethasone-induced inhibition of uridine incorporation and cell lysis, with the affinities of these drugs for glucocorticoid receptors. Our results show that progesterone, cortexolone and DXH which possess similar affinities for glucocorticoid receptors may exhibit variable, weak agonist and antagonist activities according to the parameter studied. RU 38486 was a potent competitor of dexamethasone and was able, when present in a 10-fold excess, to counteract almost completely the inhibitory action as well as the lytic action of 5 X 10(-8) M dexamethasone. This compound which exerts almost no agonist activity may therefore represent a useful tool to investigate the mode of action of antiglucocorticoids.     

RU 38486: Potent antiglucocorticoid activity correlated with strong binding to the cytosolic glucocorticoid receptor followed by an impaired activation

In order to explain the potent antiglucocorticoid activity of RU 38486 and the absence of agonist effect in spite of its very strong interaction with the cytoplasmic glucocorticoid receptor (GR), we investigated the compound's ability to promote GR “activation” and nuclear translocation. We have compared the dissociation-rates of the “non-activated” (molybdate stabilized) and of the “activated” (25°C pre-heated) GR complexes formed either with [³H]RU 38486 or with different tritiated glucocorticoid agonists. While agonists dissociated more slowly from the “activated” than from the “non-activated” complex, RU 38486 dissociated much faster from the “activated” than from the “native” receptor. This difference of activation was confirmed in a DNA-cellulose binding assay. The affinity of the “activated” RU 38486-GR complex for DNA was much lower than that of the dexamethasone-GR complex. Finally, the in vitro nuclear uptake of [³H]RU 38486 was compared with that of [³H]dexamethasone after incubation with thymus minces at 25 or 37°C. A very weak or nearly undetectable level of specific uptake of [³H]RU 38486 was observed in purified nuclei, whatever the concentration or the time of incubation used. These observations suggest that while glucocorticoid agonists form with the non-activated receptor a complex able to be activated into a more stable form (lower k⁻¹), RU 38486 interacts strongly with the non-activated receptor (impeding the binding of DM) but the complex is “transformed” by heat to a less stable form (higher k⁻¹), unable to translocate properly into the nucleus in order to trigger a glucocorticoid response.     

Metabolism and antiproliferative effect of the glucocorticoid antagonist RU38486 in cultured liver and hepatoma cells

In an attempt to elucidate the relationship between the antiglucocorticoid effect and the state of differentiation of the target cells, we studied the metabolism of the potent antagonist in cultured liver and hepatoma cells (HTC, FAZA). After incubation of [3H]RU38486 with the cells for different periods of time, the native steroid and its metabolites were extracted and analyzed by thin layer chromatography. We observed that RU38486 was not metabolized in the transformed cell lines after a 3 h incubation. In contrast RU38486 was extensively metabolized in cultured liver cells. The observed degration could help explain why RU38486 inhibited tyrosine aminotransferase induction in hepatoma cells at a concentration 100 times lower than that needed in liver cells. Moreover this catabolism concerned specifically the antagonist RU38486 since other steroids tested (dexamethasone, promegestone) underwent a much slower degradation. Indirect experiments suggest that the alterations of the RU38486 molecule might be at least partially related to the cytochrome P-450 which is very active in the hepatocytes. This study was paralleled by testing the effect of the antagonist on the growth of hepatoma cells. RU38486 exerted an antiproliferative effect in absence of serum. On the basis of the low metabolism of RU38486 and of its antiproliferative effect in hepatoma cells. one can emphasize that RU38486 might represent a potential drug for use in cancer therapy.     

RU 38486: a potent antiglucocorticoid in vitro and in vivo

The antiglucocorticoid activity of RU 38486, was studied both in vitro and in vivo. In vitro studies, RU 38486 was characterized by a high affinity (3 times higher than that of dexamethasone) for the cytosolic glucocorticoid receptor in rat hepatoma tissue culture (HTC) cells. This high affinity was due to a very low dissociation rate of the complexes formed with the receptor. In whole cells it was a potent full antagonist of dexamethasone-induced tyrosine aminotransferase (TAT) activity: the IC50 was 6-7 times lower than the concentration of the dexamethasone used. It was devoid of any glucocorticoid activity up to a concentration of 10 microM. In in vivo studies using adrenalectomized rats, RU 38486 totally inhibited dexamethasone-induced hepatic tryptophan oxygenase (TO) activity. It is also the first pure antagonist of dexamethasone-induced hepatic TAT. However, doses as high as 5 mg/kg of body weight were required for a 50% inhibition of the effect of dexamethasone at 0.01 mg/kg. RU 38486 did not display any glucocorticoid effect on these two responses up to 50 mg/kg.     

Characteristics of a Membrane-Associated Steroid Binding Site in Rat Liver

Abstract

The glucocorticoid dexamethasone binds a site in microsomes in a saturable manner which by competition studies also binds other classes of steroids. The characteristics of dexamethasone binding to microsomes is distinct from the cytosolic glucocorticoid receptor by virtue of a slower rate of association; a differential competition by the glucocorticoid receptor agonist triamcinolone acetonide and antagonist RU38486; and a lack of sensitivity to the reversible thiol reactive agent arsenite. However, both binding sites have a similar rate constant for complex dissociation; are sensitive to covalent thiol modification by N ethylmaleimide and iodoacetamide; and have a similar concentration-dependent sensitivity to the reversible thiol reactive agent methyl methanethiosulfonate. The binding of dexamethasone by microsomes therefore exhibits distinct properties from the soluble glucocorticoid receptor.     

In vitro activation of rat cardiac glucocorticoid antagonist- versus agonist-receptor complexes

The synthetic antiglucocorticoid RU 38486 interacts with cardiac cytoplasmic glucocorticoid receptors and competes for in vitro binding with the potent agonist triamcinolone acetonide. In addition to binding to receptors with high affinity, RU 38486 also facilitates the in vitro conformational change in the receptor which is a consequence of the physiologically relevant activation step during which the receptor is converted from a non DNA- to a DNA-binding form. This ability of RU 38486 to promote receptor activation is reflected by both the appropriate shift in the elution profile of [3H]RU 38486-receptor complexes from DEAE-cellulose as well as by an increased binding of these complexes to DNA-cellulose. Although less effective than triamcinolone acetonide, RU 38486 promotes in vitro receptor activation under a variety of experimental conditions, including incubation of labeled cardiac cytosols at 25 degrees C for 30 min or at 15 degrees C for 30 min in the presence of 5 mM pyridoxal 5'-phosphate. Once thermally activated, the cardiac [3H]triamcinolone acetonide and [3H]RU 38486-receptor complexes bind to nonspecific DNA-cellulose with the same relative affinities, as evidenced by the fact that 50% of both activated complexes are eluted at approx. 215-250 mM NaCl. Thus, this pure antiglucocorticoid does promote, at least to some extent, many of the crucial in vitro events including high-affinity binding, activation, and DNA binding which have been shown to be required to elicit a physiological response in vivo.     

Immunologically distinct binding molecules for progesterone and RU38486 in the chick oviduct cytosol

[3H]Progesterone and [3H]RU38486 binding in the chick oviduct cytosol is associated with macromolecules which sediment as 8 S and 4 S moieties, respectively, in molybdate-containing 5-20% sucrose gradients. The [3H]progesterone binding could be displaced by excess progesterone, but not by RU38486. Conversely, the [3H]RU38486 binding was able to compete with RU38486 but not by excess progesterone. A preparation containing antibodies against chick oviduct progesterone receptor recognized only the [3H]progesterone-receptor complex but not the 4 S, [3H]RU38486 binding component of the chick cytosol. In the calf uterus cytosol, [3H]R5020 (a synthetic progestin) and [3H]RU38486 were associated with 8 S molecules and the peaks of radioactivity were displaceable upon preincubation with radionert steroids. In addition, the complexes were recognized by antibodies to chick oviduct progesterone receptor. Our data suggest that in the chick oviduct cytosol, RU38486 does not bind to progesterone receptor, but interacts with an immunologically distinct macromolecule.     

In vitro activation of rat cardiac glucocorticoid antagonist-versus agonist-receptor complexes

The synthetic antiglucocorticoid RU 38486 interacts with cardiac cytoplasmic glucocorticoid receptors and competes for in vitro binding with the potent agonist triamcinolone acetonide. In addition to binding to receptors with high affinity, RU 38486 also facilitates the in vitro conformational change in the receptor which is a consequence of the physiologically relevant activation step during which the receptor is converted from a non DNA- to a DNA-binding form. This ability of RU 38486 to promote receptor activation is reflected by both the appropriate shift in the elution profile of [³H]RU 38486-receptor complexes from DEAE-cellulose as well as by an increased binding of these complexes to DNA-cellulose. Although less effective than triamcinolone acetonide, RU 38486 promotes in vitro receptor activation under a variety of experimental conditions, including incubation of labeled cardiac cytosols at 25°C for 30 min or at 15°C for 30 min in the presence of 5 mM pyridoxal 5′-phosphate. Once thermally activated, the cardiac [³H]triamcinolone acetonide and [³H]RU 38486-receptor complexes bind to nonspecific DNA-cellulose with the same relative affinities, as evidenced by the fact that 50% of both activated complexes are eluted at approx. 215–250 mM NaCl. Thus, this pure antiglucocorticoid does promote, at least to some extent, many of the crucial in vitro events including high-affinity binding, activation, and DNA binding which have been shown to be required to elicit a physiological response in vivo.     

Physicochemical characteristics of the interaction of the glucocorticoid antagonist RU38486 with glucocorticoid receptors in vitro, and the role of molybdate

The physicochemical properties of complexes formed between the glucocorticoid antagonist, RU38486, and the glucocorticoid receptor in rat thymus cytosol were investigated and compared with those of complexes formed with the potent agonist, triamcinolone acetonide. The equilibrium dissociation constant for the interaction of [3H]RU38486 with the molybdate-stabilized glucocorticoid receptor was lower than that for [1,2,4-3H]triamcinolone acetonide at 0 degree C but higher at 25 degrees C, suggesting that hydrophobic interactions play a major role in the binding of RU38486. Differences in equilibrium constants were reflected in corresponding differences in dissociation rate constants; association rate constants for the two steroids were similar. The rate of dissociation of [3H]RU38486 from the glucocorticoid receptor was higher in the absence of molybdate than in its presence both at 0 degree C and at 25 degrees C, suggesting that molybdate modifies the physical state of the antagonist-receptor complex, but other physical properties were similar both in the presence and in the absence of molybdate. The rate of inactivation of the unoccupied glucocorticoid receptor at 25 degrees C in the absence of molybdate was lower in phosphate buffer than in Tris-HCl buffer but the rate of dissociation of [3H]RU38486 was the same in both buffers. The binding of RU38486 afforded little, if any, protection against inactivation in either buffer; [3H]RU38486 dissociated irreversibly from the inactivated receptor at the same rate as from the non-inactivated complex but molybdate had no effect on the dissociation kinetics of the inactivated complex. It is concluded that RU38486 interacts with the ground state of the glucocorticoid receptor in a manner which neither promotes receptor transformation nor prevents receptor inactivation.     

Interrelationship between RU38486 and the P450 activities in rat liver

Microsomal P450 monooxygenases contribute actively to the biotransformation of the antiglucocorticoid RU38486, an 11 beta-substituted nor-steroid. Pretreatment of adult rats by inducers of specific forms, belonging to different P450 subfamilies, affects the ability of liver microsomes to metabolize RU38486. Phenobarbital and pregnenolone 16 alpha-carbonitrile increase the metabolic activity of liver microsomes whereas methylcholanthrene decreases their capacity to oxidize the steroid. Thus P450 forms IIIA, IIB1,2 and IIC7 are good candidates to be involved in the degradation of this peculiar molecule. Our study has been completed by investigating whether RU38486 would influence the P450 spectrum. Whereas the treatment of rats with either a glucocorticoid (cortisol, dexamethasone) or an antiglucocorticoid (pregnenolone 16 alpha-carbonitrile) has been shown to induce the P450 activity by increasing the hepatic concentration of form IIIA, we observed a slight decrease of the P450 activity by treating the animals with RU38486. Moreover RU38486 was able to antagonize the P450 induction by the other steroids as well as it inhibits the synthesis of various liver enzymes induced by glucocorticoids (for instance tyrosine aminotransferase). These findings may be important for the therapeutic use of RU38486 since its inhibitory effect on P450 activity may be at the origin of drug interactions by modifying the endogenous hormonal status.     

Inhibition by dexamethasone of beta 3-adrenergic receptor responsiveness in 3T3-F442A adipocytes. Evidence for a transcriptional mechanism.

Modulation of beta 3-adrenergic receptor (beta 3AR) expression by dexamethasone was investigated in the murine 3T3-F442A adipocytic cell line. In untreated cells, a major population of binding sites (62,000-114,000 sites/cell) of low affinity for (-)-[3H] CGP12177 and (-)-[125I]iodocyanopindolol (corresponding to the beta 3AR subtype) was present along with a minor population (6,500-8,000 sites/cell) of sites of high affinity for the radioligands (corresponding to a mixture of the beta 1 and beta 2AR subtypes). Long-term exposure of the cells to 250 nM dexamethasone led to a sharp decrease in beta 3AR density (less than 5,000 sites/cell) which paralleled a diminished potency of the beta 3AR-selective agonists BRL37344 and CGP12177 to stimulate the production of intracellular cAMP. Analysis of RNA by polymerase chain reaction and nuclear run-on assays indicated that dexamethasone inhibited the synthesis of beta 3AR mRNA, resulting in 4-8-fold decrease in the steady-state levels of this mRNA. The down-regulation of beta 3AR protein and cellular mRNA appeared to be mediated by the receptor for glucocorticoids as assessed by the antagonistic action of the anti-glucocorticoid RU38486.     

The effects of the anti-glucocorticoid RU 38486 on steroid-mediated suppression of experimental allergic encephalomyelitis (EAE) in the Lewis rat

Lewis rats, sensitised for the autoimmune condition EAE received a range of doses of the steroid dexamethasone at various times post-inoculation in an attempt to modify the clinical course of the disease. Depending upon the dosing regime employed microgram quantities of the steroid were sufficient to significantly inhibit the clinical development of EAE and milligram doses of the drug completely suppressed the emergence of disease. Administration of the potent anti-glucocorticoid RU38486 to sensitised animals intensified the clinical course of EAE and reversed the steroid-induced inhibition of the disease. Furthermore, after the characteristic loss of neurological symptoms in rats receiving dexamethasone and RU38486, readministration of the anti-glucocorticoid resulted in clinical relapses in the majority of animals. The study emphasises the potent effects of exogenous, physiologically relevant doses of steroid on the course of EAE and, as a result of the observations made using RU38486, considers the role of endogenous steroids in the control of the disease in the rat.     

Paradoxical involvement of glucocorticoid receptors in the aldosterone-induced impairment of ACTH secretion from perifused pituitary glands

The present investigation was aimed at examining whether interaction of aldosterone with specific mineralocorticoid receptors at the level of the pituitary gland may account for the inhibitory effect of that steroid on ACTH secretion. By using pituitaries from neonatal rats, which we show to completely lack specific mineralocorticoid receptors but to contain a functional glucocorticoid receptor system, we demonstrated the persistence of aldosterone-induced inhibition of ACTH release from perifused glands. Conversely, when the glucocorticoid receptors sites were blocked in pituitaries from mature rats by means of a potent antiglucocorticoid (RU 38486), thus leaving unaltered mineralocorticoid binder, aldosterone no longer dampened hormonal output. We conclude that the latter steroid affected corticotropic activity by interacting not with its proper and specific receptor, but rather with the glucocorticoid binding sites.