Linker histones in hormonal gene regulation.

In the present review, we summarize advances in our knowledge on the role of the histone H1 family of proteins in breast cancer cells, focusing on their response to progestins. Histone H1 plays a dual role in gene regulation by hormones, both as a structural component of chromatin and as a dynamic modulator of transcription. It contributes to hormonal regulation of the MMTV promoter by stabilizing a homogeneous nucleosome positioning, which reduces basal transcription whereas at the same time promoting progesterone receptor binding and nucleosome remodeling. These combined effects enhance hormone dependent gene transcription, which eventually requires H1 phosphorylation and displacement. Various isoforms of histone H1 have specific functions in differentiated breast cancer cells and compact nucleosomal arrays to different extents in vitro. Genome-wide studies show that histone H1 has a key role in chromatin dynamics of hormone regulated genes. A complex sequence of enzymatic events, including phosphorylation by CDK2, PARylation by PARP1 and the ATP-dependent activity of NURF, are required for H1 displacement and gene de-repression, as a prerequisite for further nucleosome remodeling. Similarly, during hormone-dependent gene repression a dedicated enzymatic mechanism controls H1 deposition at promoters by a complex containing HP1γ, LSD1 and BRG1, the ATPase of the BAF complex. Thus, a broader vision of the histone code should include histone H1, as the linker histone variants actively participate in the regulation of the chromatin structure. How modifications of the core histones tails affect H1 modifications and vice versa is one of the many questions that remains to be addressed to provide a more comprehensive view of the histone cross-talk mechanisms.

Mechanism of action of the potent sodium-retaining steroid 11, 19-oxidoprogesterone.

We have demonstrated previously that a planar conformation of the molecular frame is required for steroids to acquire optimal sodium-retaining activity and binding properties to the mineralocorticoid receptor (MR). One of the most active sodium-retaining compounds tested in those studies was 11, 19-oxidoprogesterone. Despite its biological potency, the relative affinity of 11,19-oxidoprogesterone for the MR is 5-fold lower than that of 21-deoxycorticosterone and 10-fold lower than aldosterone. Such a discrepancy may be assigned to uncommon biopharmacological properties of this synthetic steroid or an unusual molecular mechanism of action. In this work, we studied the biopharmacological and mechanistic features of 11,19-oxidoprogesterone. We show that both the pharmacokinetic properties of 11,19-oxidoprogesterone and its ability to transform and translocate the MR into the nucleus are undistinguishable from aldosterone. However, the capability of the serine/threonine phosphatase inhibitor tautomycin to impair nuclear translocation of the aldosterone-MR complex is not observed for the 11,19-oxidoprogesterone-MR complex. In addition, the binding properties of both steroids are differentially affected by modification of crucial lysyl residues of the MR. Kinetic studies performed on the aldosterone-MR complex in the presence of low concentrations of oxidopregnane suggest that 11,19-oxidoprogesterone may bind to the MR in a different binding site from the aldosterone binding pocket. Consistent with this postulate, a biologically inactive dose of 0.6 ng of oxidopregnane is able to potentiate the mineralocorticoid effect of a suboptimal dose of aldosterone.

The promoter of the rat 3-hydroxy-3-methylglutaryl coenzyme A reductase gene contains a tissue-specific estrogen-responsive region.

The isoprenoid metabolic pathway is mainly regulated at the level of conversion of 3-hydroxy-3-methylglutaryl coenzyme A (HMG CoA) to mevalonate, catalyzed by HMG CoA reductase. As estrogens are known to influence cholesterol metabolism, we have explored the potential regulation of the HMG CoA reductase gene promoter by estrogens. The promoter contains an estrogen-responsive element-like sequence at position -93 (termed Red-ERE), which differs from the ERE consensus by one mismatch in each half of the palindrome. A Red-ERE oligonucleotide specifically bound estrogen receptor in vitro and conferred receptor-dependent estrogen responsiveness to a heterologous promoter in all cell lines tested. However, expression of a reporter driven by the rat HMG CoA reductase promoter was induced by estrogen treatment after transient transfection into the breast cancer cell line MCF-7 cells but not in hepatic cell lines expressing estrogen receptor. Estrogen induction in MCF-7 cells was dependent on the Red-ERE and was strongly inhibited by the antiestrogen ICI 164,384. A functional cAMP-responsive element is located immediately upstream of the Red-ERE, but cAMP and estrogens inhibit each other in terms of transactivation of the promoter. Similarly, induction by estrogens was inhibited by micromolar concentrations of cholesterol, likely acting via changes in occupancy of the sterol-responsive element located 70 bp upstream of the Red-ERE. Thus, within its natural context, Red-ERE is able to mediate hormonal regulation of the HMG CoA reductase gene in tissues that respond to estrogens with enhanced cell proliferation, while it is not operative in liver cells. We postulate that this tissue-specific regulation of HMG CoA reductase by estrogens could partially explain the protective effect of estrogens against heart disease.

The glucocorticoid properties of the synthetic steroid pregna-1,4-diene-11beta-ol-3,20-dione (deltaHOP) are not entirely correlated with the steroid binding to the glucocorticoid receptor.

The natural steroid 11beta-hydroxyprogesterone is not only a modulator of 11beta-hydroxy-steroid dehydrogenase activity, but also an efficient inducer of tyrosine aminotransferase activity in hepatocytes. In contrast with the low affinity for the mineralocorticoid receptor. 11beta-hydroxyprogesterone binds well to both the glucocorticoid receptor and the carrier protein transcortin. It is accepted that the introduction of a 1:ene double bond into 3-keto 4:ene steroids increases the glucocorticoid potency, so that 3-keto-1,4:diene steroids show improved chemical stability and are more potent glucocorticoids than their respective 4:ene analogs. The steroid pregna-1,4-diene-11beta-ol-3,20-dione (deltaHOP) had previously been described as an anti-inflamatory compound and an inhibitor of macromolecular biosynthesis in thymocytes and lymphocytes. In such studies, deltaHOP also exhibited some particular glucocorticoid properties which made it attractive as a tool for the study of the mechanism of action of glucocorticoids. In the present paper we show that deltaHOP possesses some classical biological actions of glucocorticoids such as deposition of glycogen in rat liver, induction of TAT activity in hepatocytes, and inhibition of the uptake of leucine and thymidine by thymocytes. It also exhibits minimal sodium-retaining properties. Consistent with these biological effects, deltaHOP shows a 70 times lower relative binding affinity for the mineralocortioid receptor than aldosterone, but a reasonable affinity for the glucocorticoid receptor, and is as efficient as dexamethasone in dissociating the 90 kDa heat shock protein from the glucocorticoid receptor heterocomplex. However, the inhibition of the uptake of amino acids and nucleotides observed in the presence of deltaHOP is not efficiently blocked when thymocytes are coincubated in the presence of steroids with known antiglucocorticoid activity. deltaHOP is similarly inefficient in inducing chloramphenicol-acetyl transferase activity in cells transfected with a plasmid that possesses two canonical glucocorticoid-responsive elements. Unlike most glucocorticoids, deltaHOP does not induce the fragmentation of DNA in a regular pattern characteristic of apoptosis and it does not reduce thymus weight. This unusual dissociation of glucocorticoid parameters makes deltaHOP a useful tool to discriminate between mechanisms of action by which steroids can exert their biological effects.

Influence of calf serum on glucocorticoid-responses of certain progesterone derivatives.

UNLABELLED: The following in vitro glucocorticoid (GC) parameters of progesterone (P), 1-ene progesterone (deltaP), 11beta-hydroxyprogesterone (HOP), 11beta-1-ene progesterone (deltaHOP) and dexamethasone (Dexa) were assayed in the presence or absence of bovine calf serum (BCS): binding to thymus cytosol, dissociation of the glucocorticoid receptor (GR)-heat shock protein 90 (hsp90) complex (diss.), tyrosine aminotransferase (TAT) induction in hepatocytes and the inhibition of 3H-uridine and 35S-methionine uptake by thymocytes. Without BCS, steroids were in most cases active in this general order: Dex > deltaHOP > HOP > deltaP > P. BCS abolished all activities in P and deltaP, but left them unaltered in all other steroids, except diss. in HOP, which diminished intermediately. Binding of P, deltaP, HOP and deltaHOP to GR and CBG paralleled their in vivo activating effects on glycogen deposition. CONCLUSIONS: in this steroid series, BCS, but not CBG, inhibits GC responses of P and deltaP. 11-Beta hydroxylation frees those molecules from the inhibitory effects of BCS.

21-Hydroxy-6,19-oxidoprogesterone: a novel synthetic steroid with specific antiglucocorticoid properties in the rat.

In the rat, the conformationally highly bent steroid 21-hydroxy-6, 19-oxidoprogesterone efficiently displaces [3H]corticosterone from thymus-glucocorticoid receptors and blocks type II receptors in kidney cytosols but competes with neither [3H]aldosterone for kidney-mineralocorticoid receptors nor [3H]progesterone for uterus-progesterone receptors. It evokes Na+ retention only at very high doses (approximately 100 microg/100 g of rat weight) and is unable to induce tyrosine aminotransferase or to increase glycogen deposits in rat liver. When coincubated with corticosterone or dexamethasone, 2.5 microM 21OH-6OP inhibits 80% of tyrosine aminotransferase induction. It may therefore be used experimentally as an antiglucocorticoid virtually lacking mineralocorticoid or glucocorticoid properties as well as affinity for mineralocorticoid or progesterone receptors.

Features of the shuttle pair 11 beta-hydroxyprogesterone-11-ketoprogesterone.

11 beta-hydroxyprogesterone (HOP) and 11-ketoprogesterone (KP) are reversible components of a shuttle pair whose interconversion in rat liver is catalyzed by isoform-1 of 11 beta-hydroxysteroid dehydrogenase. Kidneys also produce this interconversion. The present study was carried out to investigate the shuttle pair and its components in the rat. As in corticosterone/11-dehydrocorticosterone, oxidation is more effective at an alkaline pH, while reduction prevails at a neutral pH. Moreover, both reactions are inhibited by the detergent 3-[(3-cholamido propyl)-dimethylammonio]-1-propane-sulphonate (CHAPS). However, at variance with the 11-ketosteroids cortisone (E) and 11-dehydrocorticosterone (A) thought to be "inactive," KP has slight direct Na(+)-retaining properties, and it, as well as HOP, induces glucocorticoids (11 beta-hydroxycorticoids) to retain sodium. 11-ketoprogesterone exhibits 17 times better affinity for native type 1 mineralocorticoid receptor than HOP and a 3-fold affinity for partially purified (transcortin free) mineralocorticoid receptor. However, KP, in contrast to HOP, binds only weakly to transcortin, not at all to glucocorticoid receptor, and requires reduction at C11 for tyrosine aminotransferase (TAT) induction.