Structural features of pregna-D'-pentaranes determining their interaction with three rat proteins

Competition of a number of progesterone 16alpha,17alpha-cycloalkane derivatives with 3H-labeled ligands for the binding sites of the rat uterine progesterone receptor, uterine pentaranophilin, and blood serum pentaranophilin was studied. We found that the selective ligands for the progesterone receptor are progesterone, 16alpha,17alpha-cyclopropanoprogesterone, and 16alpha,17alpha-cyclopent-3'-enoprogesterone and the selective ligands for serum pentaranophilin are 6alpha-methyl-16alpha,17alpha-cyclohexanopregna-1,4-diene-3,20-dione and 3beta-hydroxy-16alpha,17alpha-cyclohexanopregn-5-en-20-one. No selective ligands for the uterine pentaranophilin were found. The majority of substituents in rings A, B, and D' we studied decreased the affinity of ligands for all the three proteins. The substitution of the delta5-3beta-hydroxy grouping for the delta4-3-keto grouping exerted the strongest negative effect in the case of the progesterone receptor and the uterine pentaranophilin, whereas the introduction of the 3',4'-dimethyl grouping strongly inhibited the ligand affinity for the uterine pentaranophilin. The extent and even the direction of the effect of a substituent on the affinity of ligands for the proteins substantially depended on the presence of other substituents in the steroid molecules. We hypothesized that a certain similarity exists between three proteins studied in respect to the structures of their ligand-binding pockets. The English version of the paper: Russian Journal of Bioorganic Chemistry, 2004, vol. 30, no. 3; see also http://www.maik.ru.     

Novel antiprogestins Org 31806 and 31710: interaction with mammalian progesterone receptor and DNA binding of antisteroid receptor complexes.

We have examined steroid binding parameters and transformation of calf uterine progesterone receptor (PR) liganded with progestins (progesterone and R5020) and the newly synthesized antiprogestins (Org 31806 and 31710). Species specificity analysis indicated that [3H]R5020 binding in the chicken oviduct cytosol could be eliminated in the presence of 100-fold excess radioinert progesterone and R5020 but not Org 31806 and 31710. In the calf uterine cytosol, the progestins and the antiprogestins appeared to interact with the same PR as revealed by the displacement of [3H]R5020 by all of the above steroids. When the extent of [3H]R5020 binding was examined in the presence of different concentrations of radioinert steroids, the relative affinity with which these compounds interacted with the uterine PR was found to be comparable. A 23 degrees C incubation of cytosol transformed the progestin-bound PR complexes increasing their binding to DNA-cellulose from 5 (0 degrees C, nontransformed) to 35%. Under these conditions, 20% Org 31710- and RU486-occupied PR complexes bound to DNA-cellulose whereas only 10% Org 31806-receptor complexes were retained by the resin. Transformation (23 degrees C) of cytosol receptor caused a loss of the larger 8 S form and an increase in the smaller 4 S form. In its unliganded state or when it was complexed with R5020 or the antiprogestins, incubation of PR at 23 degrees C led to dissociation of the receptor-associated 90 kDa heat-shock protein (hsp90). The PR-hsp90 association was stabilized in the presence of 10 mM iodoacetamide when the ligand binding site was occupied by Org 31806 and 31710. The R5020-receptor complexes, however, allowed release of hsp90 under the above transforming conditions. Our results indicate that although Org 31806 and 31710 show no affinity for the avian PR, these steroids interact with the mammalian PR. We propose that the reported antiprogestational effects of Org 31806 and 31710 are mediated via their interaction with PR which appears similar to one that exists between PR and RU486.     

Species and tissue distribution specificity of proteins binding 16alpha,17alpha-cycloalkane derivatives of progesterone

The binding of [3H]progesterone and [3H] 16 alpha,17 alpha-cycloalkanoprogesterones to proteins from rat, rabbit, and human uteri and other organs was studied. We found that 16 alpha,17 alpha-cycloalkanoprogesterone derivatives display affinities for the uterine progesterone receptors comparable with that of the natural hormone and no substantial species differences in the affinity. Rabbit uterus was found to have no proteins distinct from the progesterone receptor that specifically bind [3H] 16 alpha,17 alpha-cycloalkanoprogesterones. At the same time, in the human uterus, we found another protein that binds some of these progesterone derivatives; it turned out to be similar to the protein from rat uterus. A similar protein with the same selectivity and affinity for steroids was also found in rat and human kidneys. Blood serum, liver, lung, and a number of other tissues were found to contain a protein of the third type that binds the same 16 alpha,17 alpha-cycloalkanoprogesterones and exhibits submicromolar Kd values for these steroids and a very low affinity for progesterone. We speculated that the introduction of a bulky substituent adjacently to the 17 beta-side chain of progesterone could result in a change in the general biodynamics of the derivative including its transport, uptake, and accumulation in tissues, which may determine the selectivity of its effect.     

Synthesis of novel progestin-rhenium conjugates as potential ligands for the progesterone receptor.

To assist in the development of technetium-based radiopharmaceuticals that are useful for the diagnostic imaging of steroid receptor-positive breast tumors, we have synthesized a series of small-sized metal chelates according to 'n + 1' mixed-ligand, thioether-carbonyl and organometallic designs. In these preliminary investigations, rhenium was used as a model for the radioactive technetium. The metal chelates contain the rhenium metal in several oxidation states, being + 5, + 3, and + 1, and they were attached to 21-substituted progesterone derivatives. A competitive receptor-binding assay (rat uterine cytosol, 0 degrees C) was used to determine the binding affinity of these conjugates for the progesterone receptor. The highest affinity of 9% (RU5020 = 100%) was obtained with a '3 + 1' mixed-ligand complex, containing a NMe group as the central donor atom in the tridentate ligand part. This value reflects a relative binding affinity of 75% compared with the parent steroid progesterone.     

Affinity of corticosteroids for mineralocorticoid and glucocorticoid receptors of the rabbit kidney: effect of steroid substitution

Corticosteroid derivatives coupled in the C3, C7 or C17 position with a long aliphatic chain were synthesized in order to select a suitable ligand for the preparation of a biospecific affinity adsorbent for mineralocorticoid receptor purification. The affinity of these derivatives for mineralocorticoid receptors (MR) and glucocorticoid receptors (GR) was explored in rabbit kidney cytosol. In this model, aldosterone bound to a single class of receptors with high affinity (Kd 1 nM) and mineralocorticoid specificity. RU26988, a highly specific ligand for GR, did not compete for these sites. The C7 and C17 positions were found to be of crucial importance in the steroid's interaction with the mineralocorticoid receptors, since the linkage of a long side chain in these positions induced complete loss of affinity. Hence, deoxycorticosterone no longer bound to MR after 17 beta substitution with a 9-carbon aliphatic chain. This loss of affinity was not observed for glucocorticoids. The 17 beta nonylamide derivative of dexamethasone still competed for GR. Increasing the length of the C7 side of the spirolactone SC26304 suppressed its affinity for MR. Finally, C3 was an appropriate position for steroid substitution. The 3-nonylamide of carboxymethyloxime deoxycorticosterone bound to MR but not to GR, and therefore constitutes a suitable ligand for the preparation of a mineralocorticoid adsorbent.     

A progesterone receptor affinity chromatography reagent: 17α-Hexynyl nortestosterone sepharose

Several affinity chromatography reagents have been proposed for purification of progesterone receptor (PgR), and significant results have been achieved with some of these. None, however, have approached the results achieved in affinity chromatography of estrogen receptor. We have therefore synthesized a number of new 19-nortestosterone derivatives capable of chemically stable linkage with Sepharose beads, and have identified one with very high PgR affinity for further study. We first synthesized the epoxides of 17α-allyl nortestosterone, by analogy with the estradiol derivatization of Greene and Jensen. The relative affinity of these epoxides for PgR from T47D human breast cancer cells, however, was only around 5% that of R5020, and affinity beads prepared from them bound very little PgR. We then reacted appropriately protected 17α-ethynyl-nortestosterone with a series of diiodo alkanes, and found that 17α-(6'-iodohex-1'-ynyl)nortestosterone had an affinity of 22% relative to R5020, equal to the affinity of progesterone itself. Reaction with Thiopropyl-Sepharose 6B yielded hexynyl-nortestosterone-Sepharose beads with a ligand density of about 7 micromoles/ml beads. One-hundred μl of these beads adsorbed 71% of the PgR present in 1 ml ofcytosol from T47D cells. This adsorption was inhibited by 10 μM progesterone but not Cortisol, indicating the specificity of the binding. Comparisions with NADAC and Sterogel, other affinity beads used for PgR purification, show that the former takes up much less receptor, while the latter takes up and releases similar amounts of receptor but more extraneous protein, and is less stable. We therefore believe that hexynyl-nortestosterone-Sepharose, having a high density of a high affinity ligand, and having chemically and biochemically stable covalent bonds, should be a good reagent for affinity purification of PgR.     

Characterization of progesterone binding to nuclear receptors in rat placenta

Exchange assays have been validated to study several forms of the progesterone receptor found to occur in nuclei of rat placenta after extraction with high salt. One form was solubilized by the extraction procedure (KCl extractable Rpn) and another form remained attached to nuclear structures (KCl resistant Rpn). Specific binding of progesterone was optimized in both forms using buffered media containing 0.01 M Tris, 30%-glycerol (v/v), 0.2 mM leupeptin, and 1 mM dithiothreitol (TDGL), pH 7.8, at 0-4 degrees C for 18-24 h. At 0-4 degrees C the nuclear receptors were stable and degradation was negligible even after 44 h of in vitro incubation. The binding reaction between progesterone and receptor demonstrated mass action principles of ligand exchange throughout this interval. Saturation analysis indicated the presence of a single binding moiety of high affinity (app Kd = 2.9-3.2 nM) for both forms of the receptor. However, the nuclear progesterone receptor was thermolabile and after a 10 min exposure to 30 degrees C no longer complexed ligand. At an intermediate incubation temperature of 22 degrees C the binding reaction was stable for about 30 min. The KCl resistant binding sites were markedly more thermolabile. Addition of 10 mM Na molybdate protected all forms of the nuclear progesterone receptor from thermal denaturation and extended the life of the complex 3-4-fold. The dissociation rate constant of progesterone-nuclear receptor complex in each preparation was 6-8 X 10(5) s-1 resulting in a half-life of about 3 h. The KCl resistant and extractable binding sites were sensitive to blockade by 1 mM N-ethylmaleimide which was reversed by co-incubation with a 2-fold molar excess of dithiothreitol. This suggested that reduced sulfhydryl groups located on or near the surface of the ligand binding domain of the receptor were necessary to bind hormone. These studies showed that the interactions between ligand and the KCl resistant and extractable receptor sites found in rat placenta were of high affinity, saturable, and heat sensitive. Thus, these binding moieties exhibited physicochemical behavior very similar to each other and to the placental receptor which has previously been partially purified from the cytosol. The conclusion is made that all of the nuclear receptor binding sites for progesterone are structurally identical. Thus, the distinctive physicochemical properties responsible for KCl resistant and extractable forms of the nuclear progesterone receptor must reside in other domains of the receptor molecule.     

Involvement of a non-hormone-binding 90-kilodalton protein in the nontransformed 8S form of the rabbit uterus progesterone receptor

Nontransformed 8S progesterone receptor (8S-PR) was purified by hormone-specific affinity chromatography from rabbit uterine low-salt cytosol containing 20 mM molybdate. In the eluate obtained with radioactive progestin, sodium dodecyl sulfate-polyacrylamide electrophoresis (SDS-PAGE) showed the presence of several bands, including three that corresponded to approximately 90-, approximately 120-, and approximately 85-kDa proteins. None of these three proteins was found in the eluate of the affinity column when the molybdate-containing cytosol was chromatographed in the presence of nonradioactive progesterone ("mock purification"). Subsequent purification of the affinity eluate by DEAE-Sephacel chromatography gave a single radioactive receptor peak at 0.15 M KCl (approximately 20% yield, 19% purity on the basis of one binding site per approximately 100 kDa) with a sedimentation coefficient of 8.5 S. Silver staining after SDS-PAGE revealed that this purified 8S-PR fraction contained mainly the 120-, 90-, and 85-kDa proteins. [3H]R5020-labeled 8S-PR purified by DEAE-Sephacel column chromatography was UV irradiated, and after SDS-PAGE the 120- and 85-kDa proteins were revealed, but the 90-kDa protein was not.(ABSTRACT TRUNCATED AT 250 WORDS)     

Progesterone receptor in the rat anterior pituitary: Effect of estrogen priming and adrenalectomy

The present study was done to determine if a progesterone receptor is present in rat pituitary. Cytosol was labeled with ³H-progesterone (3HP) or ³H-RS020 (³HR) and subjected to sucrose-glycerol density-gradient centrifugation. Serum progesterone was measured for correlation with progesterone receptor levels. Two ³HP-binding peaks (4S + 6S) were evident in uterine and pituitary cytosols. The 4S peak was eliminated by competition with unlabeled cortisol leaving a single 6S peak (progesterone receptor). Estradiol (E) priming of the male or female rat increased progesterone receptor levels in pituitary cytosol as demonstrated using ³HP and ³HR, and pituitary progesterone receptor bound ³HR with a higher affinity than ³HP. Following adrenalectomy of gonadectomized rats, progesterone receptor levels were increased in pituitary and uterine cytosol of both E-primed and unprimed groups. An inverse relationship was established between serum progesterone and progesterone receptor levels in the uterus and pituitary suggesting that stressinduced adrenal progesterone secretion significantly influences progesterone receptor levels in the rat. These results demonstrate an estrogen-inducible progesterone receptor in the rat pituitary with properties similar to those of the uterine progesterone receptor.     

Differential DNA binding by calf uterine estrogen and progesterone receptors results from differences in oligomeric states

The studies presented here provided evidence that the calf uterine estrogen and progesterone receptors exhibit different DNA-binding properties in vitro as a result of having different dimerization constants. The affinity of the estrogen and progesterone receptors for DNA was measured by using isocratic elution from DNA-Sepharose. The hormone-free estrogen receptor had a 10-fold higher affinity for DNA than did the hormone-free progesterone receptor when measured at receptor concentrations of 6-12 nM and 180 mM KCl. No effect on DNA binding by binding progesterone to its receptor was detected. This contrasts with the increased affinity for DNA and increased number of ions released upon DNA binding exhibited by the hormone-bound estrogen receptor. Between 2 and 3 ions were released when the progesterone receptor and the diluted estrogen receptor bound DNA. These observations suggested the progesterone receptor was in the monomeric state, whereas the estrogen receptor was in the dimeric state at receptor concentrations of 6-12 nM. When the dimerization constant of the progesterone receptor was measured, the value of approximately 7 nM obtained was 20-fold higher than the value of 0.3 nM reported for the estrogen receptor. This makes it likely the two receptors exist in different forms at the same concentration in vitro. It is also suggested the predominant form of the estrogen and progesterone receptors in vivo could differ.     

Diethylstilbestrol metabolites and analogs. Biochemical probes for differential stimulation of uterine estrogen responses

Diethylstilbestrol (DES) and certain chemically structural derivatives and analogs, indenestrol A (IA), indenestrol B (IB), indanestrol (IN), and pseudo-DES (PD), have been used as probes to examine various estrogenic responses previously considered interrelated and obligatory to the stimulation of uterine growth. All the analogs had poor uterotropic activity in vivo which ranged from 10-200 times less than that of estradiol or DES. The poor uterotropic activity was not due to poor binding affinity for the receptor. All compounds except IN interacted with the mouse uterine estrogen receptor with high affinity (approximately Ka 1.5-2.2 X 10(10) M-1). In addition, the compounds were able to translocate similar levels of receptor to the nucleus in vivo. Nuclear retention and occupancy of the estrogen receptor by the compounds was comparable to the patterns produced by DES or estradiol. The activity of uterine tissue responses was investigated during treatment with the compounds. Only IA stimulated uterine glucose-6-phosphate dehydrogenase to significant levels similar to DES or estradiol. Uterine progesterone receptor was induced to varying degrees by all compounds; the indenestrol isomers (IA and IB) were the most active. Uterine DNA synthesis was marginally stimulated by the derivatives and analogs except for IB which showed a response increase comparable to DES or estradiol. Because of the differential stimulation, these data suggest that in uterine tissue estrogen receptor stimulates certain biochemical responses independently and not in concert. The ability of a particular response to be increased may depend on the chemical nature of the ligand receptor complex and its interaction at genomic sites.     

Synthesis of a disulfide affinity adsorbent for purification of estrogen receptor

Synthesis of an estrogen affinity adsorbent containing a disulfide linkage between the steroid and stationary matrix permitted facile purification of high affinity estrogen binding proteins. Following affinity chromatography of either antibody directed against estrone 17-carboxymethyloxime — bovine serum albumin or immature calf uterine cytoplasmic estrogen receptor proteins, the specifically bound protein was recovered by incubating the adsorbent with 2-mercaptoethanol. Crude antibody and uterine cytosol was prepared for affinity chromatography in buffer containing 10^?3 to 10^?2M cystamine (S-S) to block SH-containing proteins, in order to protect the adsorbent against protein-mediated S-S ag SH exchange. Cystamine was found to markedly stabilize crude cytosol receptor protein by 200–300% compared with preparations obtained under ordinary conditions. Disulfide affinity adsorbents are versatile in that they can be used either under conventional conditions of specific protein recovery, or with 2-mercaptoethanol which removes the ligand and bound protein from the stationary matrix quantitatively.     

Synthesis and structure-activity relationships of selective ligands for P3 purinoceptor-like protein (P3LP).

We examined the structure-activity relationship of various 5'-N-substituted-carboxamidoadenosine derivatives toward P3 purinoceptor-like protein (P3LP), which has affinity for both adenine nucleosides and nucleotides. We discovered a hydrophobic binding region near the 5'-N-substituted-carboxamide group. From the linear alkyl N-substituted derivatives, 1-(adenin-9-yl)-1-deoxy-N-n-pentyl-beta-D-ribofuranuronamide (6) was found to be the most potent ligand. In the series of the N-cycloalkyl derivatives, 1-(adenin-9-yl)-1-deoxy-N-cyclohexyl-beta-D-ribofuranuronamide (8) was the strongest ligand. We also examined the receptor selectivity for the selected nucleosides 6 and 8 with 1 (HAK2701) and N-ethylcarboxamidoadenosine (NECA) versus P1 purinoceptor subtypes, such as adenosine A1, A2A, A2B, and A3 receptors and found 8 is the most selective ligand for P3LP.     

Differential interactions of estrogens and antiestrogens at the 17 beta-hydroxy or counterpart function with the estrogen receptor

The action of diethylpyrocarbonate on lamb uterine estrogen receptor produced an homogeneous population of the receptor (approximately 55%) which still bound triarylethylene antiestrogens such as 4-hydroxytamoxifen with a high affinity but bound classical potent estrogens such as estradiol or diethylstilbestrol with a very low affinity. To specify the structural features of the ligands involved in the decrease of ligand affinity upon modification of the estrogen receptor, we determined the relative affinity constants of 17 steroidal estrogens or antiestrogens (deriving from estradiol by a 7 alpha- or 11 beta-substitution) and 14 nonsteroidal estrogens or antiestrogens (all including the 1,2-trans-diphenylethylene structure of diethylstilbestrol) for native and diethylpyrocarbonate-modified estrogen receptors. Then the ratio of the relative affinity constant for the native receptor to that for the modified receptor (rho) was calculated for each ligand, to compare the variation in the affinity of the ligand upon modification of the receptor to that of 4-hydroxytamoxifen (rho = 1). The results showed that the strong decrease of ligand affinity upon modification of the receptor displayed by classical estrogens (rho greater than or equal to 200) is strictly dependent on the presence of the 17 beta-hydroxyl group in steroidal compounds or its alpha-4- and beta-4-counterparts in diethylstilbestrol-related compounds. However, for the 7 alpha- or 11 beta-derivatives of estradiol displaying potent antiestrogenic properties, the relative decrease in affinity was much more limited (rho less than or equal to 19). For 11 beta-derivatives displaying a relative estrogenic activity weaker than that of estradiol itself, an average decrease in affinity was observed (23 less than or equal to rho less than or equal to 62). With the diethylstilbestrol-related compounds, bearing or not the alpha-4-hydroxyl and/or the beta-4-hydroxy functions and showing either weak relative estrogenic or antiestrogenic properties, the relative variation in affinity was weak (0.6 less than or equal to rho less than or equal to 24). These results indicate that the interaction of 7 alpha- or 11 beta-substituted steroidal antiestrogens and of 1,2-trans-diphenylethylene or triphenylethylene derivatives, displaying either weak relative estrogenic or antiestrogenic properties with the receptor, differs at the 17 beta-hydroxy or at the alpha-4-/beta-4-hydroxy functions from that of potent estrogens. They suggest that the strong decrease in the relative affinity of ligands upon receptor modification may reflect the high efficiency of the ligands to activate the receptor properly.(ABSTRACT TRUNCATED AT 400 WORDS)     

Biotinylated human beta-endorphins as probes for the opioid receptor

The reaction of human beta-endorphin and biotinyl N-hydroxysuccinimide with or without spacer arm, afforded a series of products that were separated by high performance liquid chromatography (HPLC). Liquid secondary ion mass spectrometry of the biotinylated products and their tryptic digests produced abundant protonated molecular ions (MH+), which specified the number and location of biotinylation. Between 1 and 4 biotinyl residues were incorporated per human beta-endorphin molecule, at Lys-9, -19, -24, -28, and -29, but not at the amino-terminal Tyr-1. Three HPLC fractions were isolated for receptor binding studies with monobiotinylation of Lys-9 (B1 beta and B1X beta; X = C6 spacer arm), Lys-19 (B1 gamma), and a mixture of Lys-24, Lys-28, and Lys-29 derivatives (B1 alpha, BX1 alpha). All derivatives displayed tight binding to avidin, and no dissociation from avidin was detectable over several hours at 0 degrees C for the derivatives (BX1 alpha) tested. IC50 values for binding to mu and delta opioid receptor sites were 3-8 times higher for monobiotinylated derivatives than for the parent human beta-endorphin (IC50,mu = 1.5 nM, IC50,delta = 1.3 nM). Association with avidin decreased opioid receptor affinities for the C6 spacer derivative biotinylated at position Lys-9, which is close to the (1-5) enkephalin receptor region. In contrast, avidin did not affect or even increased apparent affinities to mu and delta sites for derivatives biotinylated at the alpha-helical part of the molecule (Lys-19, -24, -28, and -29). Thus, when bound to avidin, the biotinylated human beta-endorphin derivatives with spacer arm (BX1 alpha), substituted near the carboxyl terminal (Lys-24, -28, and -29), displayed mu binding affinities equal to and delta binding affinities only four times lower than underivatized human beta-endorphin. Biotinylated human beta-endorphins also bound to low affinity nonopioid binding sites on NG-108-15 cells; however, affinities to these sites were considerably reduced when derivatives were bound to avidin. The ability of biotinylated human beta-endorphin to cross-link the mu and delta opioid receptors to avidin allows application of the biotin-avidin system as a molecular probe of the opioid receptor.     

Relationship between steroid levels in peripheral serum and uterine tissue during pseudopregnancy in rabbit

Determination of the main C21, C19 and C18 steroids in peripheral serum and uterine tissue was made to study the relationships of the steroids during pseudopregnancy in the rabbit. Tissue and serum progesterone levels rose significantly (P < 0.01) from estrus to Day 9 and then decreased by 81% (tissue) and 57% (serum) at Day 15, while pregnenolone levels in uterine tissue and serum remained unaffected. Estradiol serum levels remained fairly stable, whereas its concentration in uterine tissue decreased after estrus by 85%, followed by a significant (P < 0.05) increase from Day 9. Most of the C19 steroid values in the uterine tissue and in the serum were generally at levels below or near the limit of detection and did not vary significantly. Since progesterone and estradiol levels were high and/or varied significantly in tissue throughout pseudopregnancy, and since androgens were produced in small amounts, it is suggested that androgens might not play a significant role in uterine tissue during pseudopregnancy.     

Progestin and antiprogestin effects on progesterone receptor transformation

Transformation of the rabbit uterine progesterone receptor following binding to several synthetic steroids was studied. Cytosolic receptors were prepared with and without 10 mM sodium molybdate. Following incubation with the 3H-ligands the cytosols were chromatographed on phosphocellulose minicolumns. The rank order of the compounds to promote transformation in the absence of molybdate was: medroxyprogesterone acetate (MPA) greater than 17 alpha, 21-dimethyl-19-nor-4,9-pregnadiene-3,20-dione (R5020) greater than progesterone much greater than deoxycorticosterone (DOC) much greater than 20 alpha-hydroxyprogesterone (20 alpha OH-P). The rank order was the same in the presence of molybdate, but the amount of transformation was reduced by 35-90%. Molybdate inhibited transformation to a greater extent when the receptor was bound to progesterone, DOC and 20 alpha OH-P than when bound to MPA or R5020. The antiprogestin, 11 beta-[4-(dimethylamino)phenyl]-17 beta-hydroxy-17-(1-propynyl)-4,9-estradiene-3-one (RU38486, synthesized by The Upjohn Company and designated U-66990), promoted approximately twice as much receptor transformation as did progesterone. MPA, R5020 and U-66990 all dissociated from the progesterone receptor much more slowly than did progesterone. In all cases dissociation was faster in the presence of molybdate than in its absence. These data demonstrate that potent progestins (MPA and R5020) promote a greater amount of receptor transformation than does progesterone, and that steroids with little progestin bioactivity (DOC and 20 alpha OH-P) promote very little transformation. In addition, the antiprogestin activity of U-66990 cannot be attributed to a lack of progesterone receptor transformation nor to a rapid rate of dissociation from the receptor.     

Characterization of R5020 and RU486 binding to progesterone receptor from calf uterus

We have examined and compared the binding characteristics of the progesterone agonist R5020 [promegestone, 17,21-dimethylpregna-4,9(10)-diene-3,20-dione] and the progesterone antagonist RU486 [mifepristone, 17 beta-hydroxy-11 beta-[4-(dimethylamino) phenyl]-17 alpha-(prop-1-ynyl)-estra-4,9-dien-3-one] in calf uterine cytosol. Both steroids bound cytosol macromolecule(s) with high affinity, exhibiting Kd values of 5.6 and 3.6 nM for R5020 and RU486 binding, respectively. The binding of the steroids to the macromolecule(s) was rapid at 4 degrees C, showing saturation of binding sites at 1-2 h for [3H]progesterone and 2-4 h for both [3H]R5020 and [3H]RU486. Addition of molybdate and glycerol to cytosol increased the extent of [3H]R5020 binding. The extent of [3H]RU486 binding remained unchanged in the presence of molybdate, whereas glycerol had an inhibitory effect. Molybdate alone or in combination with glycerol stabilized the [3H]R5020- and [3H]RU486-receptor complexes at 37 degrees C. Although the rate of association of [3H]RU486 with the cytosolic macromolecule was slower than that of [3H]R5020, its dissociation from the ligand-macromolecule complex was significantly slower than [3H]R5020. Competitive steroid binding analysis revealed that [3H]progesterone, [3H]R5020, and [3H]RU486 compete for the same site(s) in the uterine cytosol, suggesting that all three bind to the progesterone receptor (PR). Sedimentation rate analysis showed that both steroids were bound to a molecule that sediments in the 8S region. The 8S [3H]R5020 and [3H]RU486 peaks were abolished by excess radioinert progesterone, RU486, or R5020.(ABSTRACT TRUNCATED AT 250 WORDS)     

Approaches to the design of selective ligands for membrane progesterone receptor alpha

A number of progesterone derivatives were assayed in terms of their affinity for recombinant human membrane progesterone receptor alpha (mPRα) in comparison with nuclear progesterone receptor (nPR). The 16α,17α-cycloalkane group diminished an affinity of steroids for mPRα without significant influence on affinity for nPR, thus rendering a prominent selectivity of ligands for nPR. On the contrary, substitution of methyl at C10 for ethyl or methoxy group moderately increased the affinity for mPRα and significantly lowered the affinity for nPR. A similar but even more prominent effect was observed upon substitution of the 3-oxo group for the 3-O-methoxyimino group. A significant preference towards mPRα was also rendered by the 17α-hydroxy group and additional C6–C7-double bond. The data suggest that the modes of lig- and interaction with mPRα and nPR in the C3 region of the steroid molecule are different. One can speculate that combination of the above substitutions at C17, C10, C6, and C3 may give ligand(s) with high specificity towards mPRα over nPR.     

Effect of epostane, ZK 98299, and ZK 98734 on the interruption of pregnancy in the rat

The objective of these studies was to determine whether treatment of 10-day pregnant rats with a combination of epostane (a progesterone biosynthesis inhibitor) and either ZK 98299 or ZK 98734 (progesterone receptor antagonists) would result in additive or synergistic effects on the interruption of pregnancy. When these compounds were tested individually, the order of potency in interrupting pregnancy was ZK 98734 greater than ZK 98299 greater than epostane (50% effective doses 1.3, 4.0, and 35 mg/kg, respectively). Epostane and ZK 98299 were then tested in combination. When epostane was given either 4 h prior to or concurrently with ZK 98299, the combined drug treatment resulted in a significant additive increase in interceptive activity compared to when ZK 98299 was administered alone. In vitro binding studies showed that ZK 98299 and ZK 98734 bound to the rat uterine progesterone receptor in vitro with approximately equal affinity. ZK 98734 bound to the rat thymus glucocorticoid receptor and to the rat ventral prostate androgen receptor with a greater affinity than ZK 98299. The affinity of ZK 98299 for the rat uterine estrogen receptor was weak while the binding of ZK 98734 was not detectable. Thus, the in vitro receptor binding profiles observed were consistent with the known progesterone and glucocorticoid antagonist activities of ZK 98299 and ZK 98734. Overall these findings show that the interceptive activity of epostane and ZK 98299, agents that exert their interceptive activity via different molecular mechanisms, is additive in the 10-day pregnant rat.