Estrogen receptor-beta potency-selective ligands: structure-activity relationship studies of diarylpropionitriles and their acetylene and polar analogues.

Through an effort to develop novel ligands that have subtype selectivity for the estrogen receptors alpha (ERalpha) and beta (ERbeta), we have found that 2,3-bis(4-hydroxyphenyl)propionitrile (DPN) acts as an agonist on both ER subtypes, but has a 70-fold higher relative binding affinity and 170-fold higher relative potency in transcription assays with ERbeta than with ERalpha. To investigate the ERbeta affinity- and potency-selective character of this DPN further, we prepared a series of DPN analogues in which both the ligand core and the aromatic rings were modified by the repositioning of phenolic hydroxy groups and by the addition of alkyl substituents and nitrile groups. We also prepared other series of DPN analogues in which the nitrile functionality was replaced with acetylene groups or polar functions, to mimic the linear geometry or polarity of the nitrile, respectively. To varying degrees, all of the analogues show preferential binding affinity for ERbeta (i.e., they are ERbeta affinity-selective), and many, but not all of them, are also more potent in activating transcription through ERbeta than through ERalpha (i.e., they are ERbeta potency-selective). meso-2,3-Bis(4-hydroxyphenyl)succinonitrile and dl-2,3-bis(4-hydroxyphenyl)succinonitrile are among the highest ERbeta affinity-selective ligands, and they have an ERbeta potency selectivity that is equivalent to that of DPN. The acetylene analogues have higher binding affinities but somewhat lower selectivities than their nitrile counterparts. The polar analogues have lower affinities, and only the fluorinated polar analogues have substantial affinity selectivities. This study suggests that, in this series of ligands, the nitrile functionality is critical to ERbeta selectivity because it provides the optimal combination of linear geometry and polarity. Furthermore, the addition of a second nitrile group beta to the nitrile in DPN or the addition of a methyl substitutent at an ortho position on the beta-aromatic ring increases the affinity and selectivity of these compounds for ERbeta. These ERbeta-selective compounds may prove to be valuable tools in understanding the differences in structure and biological function of ERalpha and ERbeta.

Salicylaldoxime moiety as a phenolic "A-Ring" substitute in estrogen receptor ligands.

The phenolic "A-ring" of natural and synthetic estrogen receptor (ER) ligands was effectively replaced by a planar six-member ring formed through an intramolecular hydrogen bond within a salicylaldoxime. Thus, oxime 1, a structural analogue of a triarylethylene estrogen, showed a significant binding affinity for the ER. The OH of the oxime function appears to mimic the phenolic OH present in more "classical" ER ligands because the binding reduced when the oxime OH is methylated (2) or absent (3).

Synthesis and biological evaluation of a novel series of furans: ligands selective for estrogen receptor alpha.

A variety of nonsteroidal systems can function as ligands for the estrogen receptor (ER), in some cases showing selectivity for one of the two ER subtypes, ER alpha or ER beta. We have prepared a series of heterocycle-based (furans, thiophenes, and pyrroles) ligands for the estrogen receptor and assessed their behavior as ER ligands. An aldehyde enone conjugate addition approach and an enolate alkylation approach were developed to prepare the 1,4-dione systems that were precursors to the trisubstituted and tetrasubstituted systems, respectively. All of the diones were easily converted into the corresponding furans, but formation of the thiophenes and pyrroles from the more highly substituted 1,4-diones was problematical. Of the systems investigated, the tetrasubstituted furans proved to be most interesting. They were ER alpha binding- and potency-selective agents, with the triphenolic 3-alkyl-2,4,5-tris(4-hydroxyphenyl)furans (15a-d) displaying generally higher subtype binding selectivity than the bisphenolic analogues (15f-i). Binding selectivity for ER alpha was as high as 50-70-fold, and transcriptional activation studies showed that several members of this series were ER alpha selective agonists, with the best compound [3-ethyl-2,4,5-tris(4-hydroxyphenyl)furan, 15b] having full transcriptional activity on ER alpha while being inactive on ER beta. Comparative binding affinity analysis and molecular modeling were used to investigate the preferred binding mode adopted by the furan ligands, which appears to have the C(2) phenol mimicking the important role of the A-ring of estradiol. These ligands should be useful in studying the biological roles of both ER alpha and ER beta, and they might form the basis for the development of novel estrogen pharmaceuticals.

Comparison of animal models for the evaluation of radiolabeled androgens.

Biodistribution of two 18F-labeled androgens and an 124I/125I-labeled androgen were studied in five androgen receptor (prostate) animal models with or lacking sex hormone binding globulin (SHBG). As models for androgen-receptor positive ovarian cancer, xenografts of three human ovarian cancer cell lines were tested in SCID mice. SHBG in the prostate model systems significantly affects the metabolism, clearance, and distribution of the radiolabeled androgens in several tissues, but ovarian cancer animal models were disappointing.

Estrogenic effects of extracts from cabbage, fermented cabbage, and acidified brussels sprouts on growth and gene expression of estrogen-dependent human breast cancer (MCF-7) cells.

Cruciferous vegetable extracts from freeze-dried cabbage (FDC), freeze-dried fermented cabbage (FDS), and acidified Brussels sprouts (ABS) were prepared by exhaustive extraction with ethyl acetate. Estrogenic and antiestrogenic effects of these extracts were analyzed. To identify whether the extracts are potential estrogen receptor (ER) ligands that can act as agonists or antagonists, the binding affinity of extracts for the ER was measured using a competitive radiometric binding assay. The extracts bound with low affinity to the ER, and the relative binding affinity is estradiol > FDS > FDC > ABS. These extracts were evaluated for their estrogenic and antiestrogenic activities in estrogen-dependent human breast cancer (MCF-7) cells using as endpoints proliferation and induction of estrogen-responsive pS2 gene expression, which was analyzed using Northern blot assay. At low concentrations (5-25 ng/mL) all of the extracts reduced 1 nM estradiol-induced MCF-7 cell proliferation. Extracts at 25 ng/mL also inhibited estradiol-induced pS2 mRNA expression. At higher extract concentrations (50 ng/mL-25 microg/mL), however, increased proliferation in MCF-7 cells was observed. Similarly, expression of the pS2 gene was induced by higher extract concentrations (0.25-25 microg/mL). The pure estrogen antagonist, ICI 182,780, suppressed the cell proliferation induced by the extracts as well as by estradiol and also the induction of pS2 expression by the extracts. The ER subtype-selective activities of FDC and FDS were analyzed using a transfection assay in human endometrial adenocarcinoma (HEC-1) cells. FDS acted as an ERalpha-selective agonist while FDC fully activated both ER-alpha and ER-beta. Growth of the ER-negative MDA-231 cells was not affected by the extracts or by estradiol. This study demonstrates that cruciferous vegetable extracts act bifunctionally, like an antiestrogen at low concentrations and an estrogen agonist at high concentrations.

Coactivator peptides have a differential stabilizing effect on the binding of estrogens and antiestrogens with the estrogen receptor.

The effectiveness of estrogens in stimulating gene transcription mediated by the estrogen receptor (ER) appears to depend on ER interactions with coactivator proteins. These coactivators bind to ER when it is liganded with an estrogen agonist, but not when it is liganded with an estrogen antagonist. Because estrogen agonists are known to induce a conformation in ER that stabilizes coactivator binding, we asked whether coactivator binding to ER causes a reciprocal stabilization of agonist ligand binding. We used a fluorescent ligand for ER, tetrahydrochrysene-ketone, to monitor the rates of ligand dissociation from ERalpha and ERbeta, and to see how this process is affected by the p160-class coactivator, steroid receptor coactivator-1 (SRC-1). We used a 15-amino acid peptide corresponding to the second nuclear receptor box LXXLL motif in SRC-1 (NR-2 peptide), which is known to interact with the ER ligand-binding domain, a mutant peptide with an LXXAL sequence (NR-2A peptide), and a 203-amino acid fragment of SRC-1, termed the nuclear receptor domain (SRC1-NRD), embodying all three of the internal NR boxes of this protein. Both the NR-2 peptide and the SRC1-NRD fragment markedly slow the rate of dissociation of the agonist ligands tetrahydrochrysene-ketone, estradiol, and diethylstilbestrol, increasing the half-life of the ER-agonist complex by up to 50- to 60-fold. The SRC1-NRD has much higher potency in retarding ligand dissociation than does the NR-2 peptide; it is maximally effective at 30 nM, and it appears to bind with the stoichiometry of one SRC1-NRD per ER dimer. The peptides had little effect on the dissociation rate of antagonist ligands. Consistent with these results, we find that increasing the concentration of SRC-1 in cells by transfection of an expression plasmid encoding SRC-1 causes a 17-fold increase in the potency of estradiol in an estrogen-responsive reporter gene transcription assay. Thus, there is multifactorial control over receptor-coactivator interaction, its strength being determined by the agonist vs. antagonist nature of the ligand and the particular structure of the agonist ligand, and by the receptor subtype and the NR box sequence. The stabilizing effect of coactivator on ER-agonist ligand complexes may be important in determining the potency of estrogen agonists in a cell and may also underlie the tissue-selective pharmacology of certain synthetic estrogens.

Estrogen receptor subtype-selective ligands: asymmetric synthesis and biological evaluation of cis- and trans-5,11-dialkyl- 5,6,11, 12-tetrahydrochrysenes.

We have recently reported that racemic 5,11-cis-diethyl-5,6,11, 12-tetrahydrochrysene-2,8-diol (THC, rac-2b) acts as an agonist on estrogen receptor alpha (ERalpha) and as a complete antagonist on estrogen receptor beta (ERbeta) (Sun et al. Endocrinology 1999, 140, 800-804). To further investigate this novel ER subtype-selective estrogenic activity, we have synthesized a series of cis- and trans-dialkyl THCs. cis-Dimethyl, -diethyl, and -dipropyl THCs 2a-c were prepared in a highly enantio- and diastereoselective manner by the acyloin condensation of enantiomerically pure alpha-alkyl-beta-arylpropionic esters, followed by a Lewis acid-mediated double cyclization under conditions of minimal epimerization. ERalpha and ERbeta binding affinity of both cis and trans isomers of dimethyl, diethyl, and dipropyl THCs was determined in competitive binding assays, and their transcriptional activity was determined in reporter gene assays in mammalian cells. Nearly all THCs examined were found to be affinity-selective for ERbeta. All these THCs are agonists on ERalpha, and THCs with small substituents are agonists on both ERalpha and ERbeta. As substituent size was increased, ERbeta-selective antagonism developed first in the (R,R)-cis enantiomer series and finally in the trans diastereomer and (S,S)-cis enantiomer series. The most potent and selective ligand was identified as (R,R)-cis-diethyl THC 2b, which mimicked the ERbeta-selective antagonist character of racemic cis-diethyl THC 2b. This study illustrates that the antagonist character in THC ligands for ERbeta depends in a progressive way on the size and geometric disposition of substituent groups and suggests that the induction of an antagonist conformation in ERbeta can be achieved with these ligands with less steric perturbation than in ERalpha. Furthermore, antagonists that are selectively effective on ERbeta can have structures that are very different from the typical antiestrogens tamoxifen and raloxifene, which are antagonists on both ERalpha and ERbeta.

Synthesis and binding affinities of new 17 alpha-substituted estradiol-rhenium "n + 1" mixed-ligand and thioether-carbonyl complexes.

The development of technetium and rhenium-based radiotracers for the steroid receptor system requires the use of suitable donor groups on the steroid to provide stable binding sites for the metal. Previous approaches have mainly exploited methods involving various N- and S-coordinating chelate systems or organometallic complexes. In this work, we have prepared several novel chelate systems attached to a series of 17 alpha-substituted estradiol derivatives and examined their binding to the estrogen receptor (ER). The neutral "n + 1" mixed-ligand and dithioether-carbonyl complexes that we prepared contain the metal in three oxidation states, +5, +3 or +1, attached to a 17 alpha-substituted estradiol derivative through a thiol group, an isocyanide group, or a dithioether unit, respectively. In our preliminary investigations, we used rhenium as a nonradioactive analog of the radionuclide technetium. All complexes synthesized were evaluated in a competitive radiometric receptor binding assay at 0 degree C and 25 degrees C to determine their relative binding affinities (RBA) to the ER (relative to 3,17 beta-estradiol, RBA = 100%). The complexes show binding affinities up to 23.4% at 0 degree C and 14.1% at 25 degrees C.

Facile synthesis of high affinity styrylpyridine systems as inherently fluorescent ligands for the estrogen receptor.

A series of styrylpyridine derivatives containing two phenols was prepared via an efficient two-step synthesis. These compounds were designed to maximize the estrogen receptor binding affinity of a known series of inherently fluorescent styrylpyridines. While significant improvements were achieved in receptor affinity, the fluorescence intensity of this series of compounds is poor.

Altered ligand binding properties and enhanced stability of a constitutively active estrogen receptor: evidence that an open pocket conformation is required for ligand interaction.

To elucidate the ligand binding properties of the estrogen receptor (ER) and how ligand access to and release from the ligand binding pocket is affected by the conformational state of the receptor, we have measured the rates of estradiol association and dissociation, the equilibrium binding, and the stability of estradiol binding to denaturants, comparing wild-type human ER and a point mutant (Y537S ER) that shows full constitutive activity, i.e., the same full transcriptional activity in the absence or presence of estrogen. Ligand binding kinetics and affinity were measured with the full-length (1-595) ERs and with truncated forms of both receptors containing domains C through F (including the DNA binding, hinge, and ligand binding domains, amino acids 175-595) or domains E and F (the ligand binding domain; amino acids 304-595). With all ERs, the rates of ligand association and dissociation were considerably slower with the Y537S mutant ER than with wild-type ER (6-fold and 3-4-fold, respectively). These marked differences in ligand on and off rates for the wild-type and Y537S receptors result in a predicted (k-1/k+1) and measured Kd that is 2-fold lower for Y537S ER compared to wild-type ER. The binding of estradiol by wild-type ER was disrupted by high concentrations of urea (above 2 M), whereas the Y537S ER was distinctly more resistant to this disruption. These results are consistent with a model in which wild-type ER in the absence of ligand adopts a transcriptionally inactive collapsed pocket conformation, stabilized by specific interactions of Y537 with nearby regions of ER. When estradiol is bound, the wild-type ER adopts a transcriptionally active, closed pocket (ligand occupied) conformation. By contrast, the Y537S mutant ER favors the transcriptionally active closed pocket conformation, whether occupied by ligand or not, the latter state (closed pocket but unoccupied) accounting for its constitutive activity. Our findings suggest that the entry or exit of ligand from the binding pocket requires that ER adopt an open pocket conformation. The reduced rates of ligand association and dissociation in the constitutively active form of the ER, as well as its greater resistance to disruption of ligand binding by urea, support the supposition that the rate at which this open pocket conformation can be accessed from the unoccupied or ligand-occupied Y537S ER is slower than from the unoccupied or occupied forms of wild-type ER. Thus, the binding and release of ligand by ER require that the receptor access an open pocket state, and the ease with which this state can be accessed is affected by mutations that alter receptor conformation.

The estradiol pharmacophore: ligand structure-estrogen receptor binding affinity relationships and a model for the receptor binding site.

The accumulated knowledge on the binding of estradiol (E2) and its analogs and the results of affinity-labeling studies have been reviewed and are used herein to derive a binding site model for the estrogen receptor (ER). Estradiol is nonpolar and hydrophobic, except at its molecular termini. Most of its skeletal flexibility resides in the B-ring, and it probably binds in a low-energy conformation. The phenolic OH group in the A-ring contributes about 1.9 kcal/mol to the binding free energy and probably acts primarily as a hydrogen bond donor. The 17 beta-hydroxyl group in the D-ring contributes approximately 0.6 kcal/mol to the binding and probably acts as a hydrogen bond acceptor, either directly or via a water molecule. There also seems to be a degree of flexibility in the region of the receptor that encompasses the D-ring. The aromatic ring contributes about 1.5 kcal/mol, probably through weak polar interactions with receptor residues that contact the beta-face of the steroid. The receptor seems to surround the ligand, so that all four rings contribute significantly to binding. Small hydrophobic substituents enhance binding affinity at positions 4, 12 beta, 14, and 16 alpha; whereas, larger hydrophobic substituents are tolerated at positions 7 alpha, 11 beta, and 17 alpha. In general, the ER is intolerant of polar substituents. Based on E2 analogs bearing affinity-labeling groups, cysteine residues might be present in the binding site in the area of C-4, C-17 alpha, and C-17 beta, and a lysine residue might be located near C-16. Models that represent the limits of deformability of the ligand binding site, the position of preformed pockets, and space occupied by the receptor are presented. The various elements in this model for the binding of steroidal estrogens by the estrogen receptor are consistent with evidence emerging from the crystal structures of related nuclear hormone receptor ligand complexes.

Analysis of the structural core of the human estrogen receptor ligand binding domain by selective proteolysis/mass spectrometric analysis.

The structure of the ca. 250 amino acid hormone binding domain of the human estrogen receptor (hER-LBD), expressed in E. coli and purified as a complex with estradiol, has been probed by selective proteolysis, with analysis of the protein fragments both by classical methods (SDS-PAGE and Edman N-terminal sequencing) and by mass spectrometry (HPLC-coupled electrospray ionization mass spectrometry (LC/ESI-MS)). Rapid cleavage by several proteases (trypsin, chymotrypsin, thermolysin, and Asp-N endoproteinase) is observed within a localized region (residues 297-303) at the N-terminus. In contrast, proteolytic scission at the C-terminus is less localized and more progressive; initial cuts by trypsin, chymotrypsin, thermolysin, V8, and Asp-N proteinases are observed to occur in the region 553-571, followed by further cleavage with thermolysin (548) and trypsin (548, 531, and 529). Thus, N304 and K529 define the protease-resistant N- and C-termini of a core structure for this domain that appears to contain the elements sufficient for ligand binding. The remaining segment of this domain (530-553), which is known to embody elements essential for ligand-modulated transcription activation (AF-2), is likely a surface-exposed region that, through these studies, is shown to be accessible to proteases. Only a single region within the 26 kDa ligand-binding core (N304-K529) has been identified as being readily accessible to proteases; rapid proteolysis using the proteases trypsin, chymotrypsin, and thermolysin, is localized to residues 465-468, with cleavage occurring at residues K467, L466, and both T465 and S468, respectively. The flexibility implied by the cuts in this internal 465-468 region suggest that the hER-LBD may actually consist of two subdomains. These proteolysis studies provide a substantially refined view of the conformational nature of the human estrogen receptor ligand binding domain.

Role of the TATA box in transcription of the mouse mammary tumor virus long terminal repeat.

An in vitro transcription system from mammary cells was established to study transcription of the long terminal repeat (LTR) of the mouse mammary tumor virus (MMTV). Experiments with progressive 5'-deletion constructs of the MMTV LTR revealed that a 19-base pair (bp) region from -41 to -23 bp, encompassing the TATA box and flanking DNA sequence, was as transcriptionally active as larger promoter constructs, both in nuclear extracts from human mammary cell lines (T47D and MCF7) and a nonmammary cell line (HeLa). The cell-free system was capable of supporting transcriptional induction by factors binding upstream of the TATA box, however, since purified glucocorticoid receptor-induced transcription in larger promoter constructs encompassing the MMTV hormone-responsive elements. Transcription from two other promoters, the adenovirus major late promoter and the human immunodeficiency virus LTR, also revealed a significant transcriptional contribution of upstream elements. The 19-bp TATA region from the MMTV LTR was shown to have considerably more activity in this transcription system than comparable TATA regions from other promoters. Sequences critical to the MMTV TATA region were evaluated by single base pair mutagenesis and found to comprise a consensus TATA box sequence, TATAAAA, as well as a single A just upstream of the TATAAAA sequence. Thus, the high level of basal transcription observed with the TATA region from MMTV is due to a perfect consensus TATA box sequence and a single base immediately 5' adjacent. It is likely that the high basal rate of transcription observed with this TATA box region on histone-free templates represents an inappropriate level of basal expression and that a complete evaluation of transactivation mechanisms in this system will require the recapitulation in vitro of the chromatin-mediated repressive state that exists in vivo.

11 beta-substituted estradiol derivatives. 2. Potential carbon-11- and iodine-labeled probes for the estrogen receptor.

Four new classes of 11 beta-substituted estradiol and estriol derivatives (cyanoalkyl, ethynyl, propynyl, and iodovinyl) have been synthesized, and their binding affinity for the estrogen receptor has been evaluated. The binding affinity values indicate that the estrogen receptor has tolerance for estradiol derivatives bearing 11 beta-groups whose size, rigidity, and polarity are limited. The estradiol derivatives have higher affinity than the estriol derivatives. The potential of these agents as imaging agent for estrogen receptor-positive breast tumors is discussed. On the basis of the results of this and a previously reported study (Napolitano, E.; Fiaschi, R.; Carlson, K. E.; Katzenellenbogen, J. A. 11 beta-Substituted Estradiol Derivatives, Potential High-Affinity Carbon-11-Labeled Probes for the Estrogen Receptor: A Structure-Affinity Relationship Study. J. Med. Chem. 1995, 38, 429-434), a general strategy for designing high-affinity probes for the estrogen receptor is proposed.

Molecular characterization by mass spectrometry of the human estrogen receptor ligand-binding domain expressed in Escherichia coli.

The ligand binding domain of the human estrogen receptor (hER-LBD), encompassing the sequence MDPS282AG...V595, has been expressed at high levels in Escherichia coli from a pET-23d vector, and a purified preparation has been characterized both by mass spectrometry and biochemical methods. Inclusion bodies from the bacterial expression were solubilized by sonication and the hER-LBD was purified to near homogeneity by affinity chromatography over an estradiol-Sepharose column in urea-containing buffer. This material ran as a single peak on reversed-phase HPLC, and sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis showed a band with apparent molecular mass of 31-32 kilodaltons (kDa), somewhat smaller than that expected from the construct (35.6 kDa). Edman degradation revealed a single sequence of MDPSAGDMRA, consistent with an intact N terminus. Further characterization of this material using low resolution matrix-assisted laser desorption ionization mass spectrometry indicated an apparent single protein species of average mass 33,143 daltons (Da). Detailed molecular analysis by electrospray ionization mass spectrometry, however, revealed that this purified hER-LBD preparation was actually composed of a number of both modified and unmodified LBD protein fragments between 32,900-33,400 Da. The bulk of this 33-kDa protein mixture consisted of three LBD protein fragments with C termini at Ala571 (70%), Ala569 (23%), and Ser575 (4%), with only a trace amount (3%) of the full length expressed LBD (MDPS282...V595; 35, 602 Da). These four protein species also appear to be partially chemically modified by carbamylation. The functional integrity of this hER-LBD preparation was investigated by a ligand-exchange assay, which showed that the hER-LBD retained full estradiol-binding capacity; specific, covalent labeling was also observed using either the electrophilic affinity-labeling ligand tamoxifen aziridine (TAZ) or the photoaffinity-labeling ligand hexestrol diazirine. Thus, this expressed hER-LBD preparation, while appearing nominally pure by conventional biochemical techniques and having the expected ligand-binding capacity, was shown by sensitive high resolution electrospray ionization mass spectrometry techniques to be largely truncated 20-26 amino acids from the expected C terminus and to have a substantial level of covalent modification arising from the urea.(ABSTRACT TRUNCATED AT 400 WORDS)

Studies using fluorescent tetrahydrochrysene estrogens for in situ visualization of the estrogen receptor in living cells.

We have analyzed four fluorescent nonsteroidal estrogens for their potential to serve as vital cytological stains to visualize the estrogen receptor (ER) in a model receptor expression system. The novel estrogen fluorophores are based on the rigidified stilbene-like structure of 5,6,11,12-tetrahydrochrysene (THC), and they embody electron-donor (hydroxyl) and electron-acceptor groups (nitrile, amide, ester, or ketone) that afford efficient, long wavelength, and environment-sensitive fluorescence. These probes bind with high affinity to human ER (relative binding affinity, 22-85 vs. estradiol, 100), and they stimulate the transcriptional activity of this receptor. The strong fluorescence of the estrogenic THCs permits visualization, using conventional epifluorescence microscopy, of ER in transfected Cos-7 cells that express elevated levels of receptor. Cell staining by the donor-acceptor THCs characteristically displays a nonuniform pattern of nuclear fluorescence that can be fully inhibited by nonfluorescent estrogens such as estradiol or diethylstilbestrol. Additionally, this staining appears to be specific for ER, since it coincides with the distribution of receptor as determined by indirect immunofluorescence analysis using an ER-specific monoclonal antibody. Using these probes, we have analyzed the intracellular distribution of ER mutants containing a variety of deletions. Evidence is presented to show that removal of amino-terminal sequences within the ER polypeptide results in an altered pattern of intranuclear distribution with preferential accumulation of receptor protein within the nucleolus. These THC fluorophores therefore represent excellent probes for cytological studies involving ER expressed in cultured cells and represent an important advance toward the goal of exploiting fluorescence technology to analyze the expression and distribution of ER within tissue samples.

11 beta-Substituted estradiol derivatives, potential high-affinity carbon-11-labeled probes for the estrogen receptor: a structure-affinity relationship study.

In view of their possible development as carbon-11-labeled receptor-based radiotracers for imaging estrogen-responsive breast tumors, we have synthesized a series of estradiols (1), estriols (2), 11 beta-ethylestradiols (3), 11 beta-ethylestriols (4), 11 beta-methoxyestradiols (5), and 11 beta-methoxyestriols (6), differing in the type of substituent R present at the 17 alpha-position (a, -H; b, -CH3; c, -C identical to CH; d, -C identical to CCH3; e, -Ph; f, -CH = CHMe cis), and measured their binding affinity for the estrogen receptor relative to estradiol (RBA). As expected, all the derivatives having an 11 beta-ethyl substituent have good binding properties (3a-d, 4a-d, RBA (25 degrees C): 109-3000%), and among them there are several promising candidates for carbon-11 labeling. Moxestrol (RBA (25 degrees C) = 185%) and its corresponding estriol derivative (4c, RBA (25 degrees C) = 20%) were the analogs having the highest affinity in the 11 beta-methoxyestradiol (5a-f) and 11 beta-methoxyestriol (6a-e) series, respectively; other analogs (R = Me, C identical to CMe, Ph, or cis-CH = CHMe) had uniformly lower RBA values.

Evaluation of a highly efficient aryl azide photoaffinity labeling reagent for the progesterone receptor.

16 alpha,17 alpha-[(R)-1'-(4-Azidophenyl)ethylidenedioxy]pregn-4-ene- 3,20-dione (7) was prepared in high specific activity tritium-labeled form (20 Ci/mmol) and shown to bind to the progesterone receptor with an affinity (Kd = 0.80 nM) that is 47% of that of [3H]-R 5020 (Kd = 0.38 nM). [3H]Progestin aryl azide 7 exhibits high photoattachment efficiency (60% at 1 h) compared to the commonly used progesterone receptor photoaffinity labeling reagent [3H]-R 5020 (2.2% at 1 h) and is the most efficient progesterone receptor photoaffinity labeling reagent prepared to date. The photoattachment observed with 7 proceeds in a time-dependent fashion, with most of the attachment occurring within the first 10 min of photolysis. Characterization of the photolabeled proteins by SDS-polyacrylamide gel electrophoresis shows specific labeling of two adducts of molecular weight 108,500 +/- 800 and 87,000 +/- 1,500 (n = 3), the same species as labeled by [3H]-R 5020. The ratio of progesterone receptor subunits A:B was determined to be 3.3:1 with both [3H]progestin azide 7 and [3H]-R 5020. Information on the specific amino acid(s) that attach to the ligand during photolysis awaits further analysis of the covalently bound ligand-protein adduct.

Bivalent ligands as probes of estrogen receptor action.

The estrogen receptor (ER) is a hormone-regulated transcription factor which is thought to bind to specific DNA sequences as a homodimer. In order to better understand structural requirements for dimerization and its functional role in ER action, we synthesized a series of bivalent ligands based on the non-steroidal estrogen hexestrol. These molecular probes join two hexestrol molecules of the erythro (E, active) configuration with either 4 or 8 carbon linkers (designated E-4-E and E-8-E series, respectively), or with longer linkers comprised of ethylene glycol units (E-eg-E series). Several other bi- and monovalent control compounds were prepared. The bivalent ligands bind to ER with a relative affinity 1-7% that of estradiol. While most of the ligands demonstrated normal monophasic displacement curves in competitive binding assays with [3H]estradiol, uncharacteristic biphasic competitive binding curves were seen for some of the ligands, indicating possible structure-specific, negative site-site interaction. In ER-deficient Chinese hamster ovary (CHO) cells transfected with an expression vector encoding ER, one series of bivalent ligands (E-4-E) had little stimulatory activity and inhibited transcription stimulated by hexestrol, as determined by a transient transfection assay using an estrogen-responsive reporter gene construct [(ERE)2-TATA-CAT, containing two estrogen response elements linked to a TATA promoter and the chloramphenicol acetyl transferase reporter gene]. Monovalent or control bivalent ligands failed to antagonize hexestrol-stimulated activity and were as fully active as hexestrol itself. Studies performed in MCF-7 human breast cancer cells, which contain endogenous ER, yielded similar bioactivity profiles for the E-4-E bivalent inhibitory ligands, showing them to be effective estrogen antagonists, when using either induction of progesterone receptor or (ERE)2-TATA-CAT transcriptional activation as the endpoint. The E-8-E ligand, however, acted as a partial agonist/antagonist of ERE-reporter gene transactivation and a full agonist of progesterone receptor induction in MCF-7 cells, thus showing cell- and response-specific differences in the effects of this bivalent ligand. These bivalent ligands for ER do not show enhanced potency or receptor binding affinity; however, some of them display binding properties that suggest the possibility of structure-specific negative site-site interaction, and some of them function as quite effective estrogen antagonists.

Progestin radiopharmaceuticals labeled with technetium and rhenium: synthesis, binding affinity, and in vivo distribution of a new progestin N2S2-metal conjugate.

We have prepared and evaluated three metal conjugates of a progestin-monoamine-monoamide (MAMA') bisthiol chelate system. These conjugates of rhenium and technetium-99 and -99m, are structural analogs of the bisamino-bisthiol (BAT) conjugates we have described recently, but the MAMA' chelate, being more polar than the BAT system, gives a conjugate that is much less lipophilic, having an octanol-water partition coefficient that is nearly 80-fold lower. In competitive binding assays, the Re- and 99Tc-MAMA'-progestin conjugates bind to the progesterone receptor with affinities greater than that of progesterone itself, and in a direct binding assay, the equilibrium dissociation constant (Kd) of the 99mTc-MAMA' conjugate was 0.97 nM. As is typical for 11 beta-substituted progestins, these conjugates also have substantial binding affinity for glucocorticoid receptors. In tissue distribution studies in immature female rats, the progestin-99mTc-MAMA' conjugates show selective uptake for principal target tissue (such as uterus) over that of blood and nontarget tissue (such as muscle); these uptake ratios reach maximum levels of 5 and 4, respectively. Uptake by fat, liver, and kidney is quite high; however, only the uptake in uterus is displaceable upon coinjection of the selective progestin ORG2058. Metabolism studies show that the radioactivity in the uterus is essentially unmetabolized out to 4 h, while liver activity is completely due to metabolites. Other tissues show an intermediate fraction of unmetabolized conjugates that decreases with time. The in vivo behavior of the progestin-99mTc-MAMA' conjugate is similar to that of the labeled BAT conjugate: its uptake selectivity is somewhat greater than that of the BAT conjugate, but its target tissue uptake is lower. Factors that may be responsible for limiting the target tissue uptake properties of these conjugates are their moderate affinity for progesterone receptor, their substantial binding to glucorticoid receptors, and their large overall molecular size.