Structure of the G225P/G226P mutant of mouse 3(17)alpha-hydroxysteroid dehydrogenase (AKR1C21) ternary complex: implications for the binding of inhibitor and substrate.

3(17)alpha-Hydroxysteroid dehydrogenase (AKR1C21) is a unique member of the aldo-keto reductase (AKR) superfamily owing to its ability to reduce 17-ketosteroids to 17alpha-hydroxysteroids, as opposed to other members of the AKR family, which can only produce 17beta-hydroxysteroids. In this paper, the crystal structure of a double mutant (G225P/G226P) of AKR1C21 in complex with the coenzyme NADP(+) and the inhibitor hexoestrol refined at 2.1 A resolution is presented. Kinetic analysis and molecular-modelling studies of 17alpha- and 17beta-hydroxysteroid substrates in the active site of AKR1C21 suggested that Gly225 and Gly226 play an important role in determining the substrate stereospecificity of the enzyme. Additionally, the G225P/G226P mutation of the enzyme reduced the affinity (K(m)) for both 3alpha- and 17alpha-hydroxysteroid substrates by up to 160-fold, indicating that these residues are critical for the binding of substrates.

Large-scale synthesis of the catechol metabolites of diethylstilbestrol and hexestrol.

Diethylstilbestrol (DES) and hexestrol (HES) are carcinogenic synthetic estrogens. The major metabolites of these compounds are their catechol derivatives, 3'-OH-DES and 3'-OH-HES. Oxidation of these metabolites leads to the electrophilic quinones, which are presumably involved in the tumor-initiating process. A synthetic route based on the McMurry coupling reaction was developed for the synthesis of 3'-OH-DES. Using commercially inexpensive starting materials, this compound was synthesized in four steps, and the cis and trans isomers were separated and identified. Following the same synthetic route, 3'-OH-HES was synthesized in five steps.

Metabolic activation and formation of DNA adducts of hexestrol, a synthetic nonsteroidal carcinogenic estrogen.

Hexestrol (HES), a synthetic nonsteroidal estrogen, is carcinogenic in Syrian golden hamsters. The major metabolite of HES is its catechol, 3'-OH-HES, which can be metabolically converted to the electrophilic catechol quinone, HES-3',4'-Q, by peroxidases and cytochrome P450. Standard adducts were synthesized by reacting HES-3',4'-Q with dG and dA to produce the adducts 3'-OH-HES-6'(alpha, beta)-N7Gua and HES-3',4'-Q-6'-N6dA, respectively. When HES-3',4'-Q was reacted with calf thymus DNA, 3'-OH-HES-6'(alpha,beta)-N7Gua was identified by HPLC and tandem mass spectrometry as the depurinating adduct, with minor amounts of stable adducts. 3'-OH-HES was bound to DNA after activation by horseradish peroxidase, lactoperoxidase, or rat liver microsomes. The depurinating adduct 3'-OH-HES-6'(alpha, beta)-N7Gua was identified in these systems at levels of 65, 41, and 11 micromol/mol of DNA-P, respectively. Unidentified stable adducts were observed in much lower amounts and were quantified by the 32P-postlabeling method. Similarly to 3'-OH-HES, the catechol metabolites of the natural steroidal estrogens estrone (E1) and estradiol (E2), namely, 2-OHE1, 4-OHE1, 2-OHE2, and 4-OHE2, can be oxidized to their corresponding quinones by peroxidases and cytochrome P450. The quinones of the carcinogenic 4-OHE1 and 4-OHE2 have chemical and biochemical properties similar to those of HES-3',4'-Q. The results suggest that formation of HES-3',4'-Q may be a critical event in tumor initiation by HES and that HES is an excellent model compound to corroborate the hypothesis that estrogen-3,4-quinones are ultimate carcinogenic metabolites of the natural steroidal estrogens E1 and E2.

FLP recombinase/estrogen receptor fusion proteins require the receptor D domain for responsiveness to antagonists, but not agonists.

The ligand-binding domains of steroid receptors convey ligand-dependent regulation to certain proteins to which they are fused. Here we characterize fusion proteins between a site-specific recombinase, FLP, and steroid receptor ligand-binding domains. These proteins convert ligand binding into DNA recombination. Thus, ligand binding is directly coupled to an enzyme activity that is easily measured by DNA rearrangements or heritable genetic changes in marker gene expression, as opposed to the multiple events leading to transcription. Recombination by a FLP-estrogen receptor (FLP-EBD) fusion is activated by all tested estrogens, whether agonists or antagonists, indicating that all induce EBD release from the 90-kDa heat shock protein complex. Altering the distance between FLP and the EBD domain in the fusion proteins, by reducing the included length of the estrogen receptor D domain, affects ligand efficacy. A FLP-EBD with no D domain shows reduced inducibility by agonists and, unexpectedly, complete insensitivity to induction by all antagonists tested. A FLP-EBD including some D domain shows a ligand-inducible phenotype intermediate to those displayed by FLP-EBDs containing all or none of the D domain. Thus, we observed a tethered interference between FLP and the EBD domains that differs depending on the distance between the two domains, the conformations induced by agonists or antagonists, and which presents a previously undetectable distinction between estrogen agonists and antagonists in yeast.

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)

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.

Characterization of semiquinone free radicals formed from stilbene catechol estrogens. An ESR spin stabilization and spin trapping study.

Electron spin resonance spectroscopy has been used to detect, characterize, and to infer structures of o-semiquinones derived from stilbene catechol estrogens. Radicals were generated enzymatically using tyrosinase and were detected as their Mg2+ complexes. It is suggested that initial hydroxylation of stilbene estrogen gives a catechol estrogen in situ; subsequent two-electron oxidation of the catechol to the quinone, followed by reverse disproportionation, leads to the formation of radicals. Consistent with this mechanism, o-phenylenediamine, a quinone trapping agent, inhibits formation of o-semiquinones. A competing mechanism of radical production involves autoxidation of the catechol. Hydroxyl radicals are shown to be produced in this system via a mechanism involving reduction of iron and copper complexes by stilbene catechols. Possible differences in the reactivity of stilbene ortho- and para-semiquinones are discussed.

Hexestrol-linked cytotoxic agents: synthesis and binding affinity for estrogen receptors.

With the erythro-hexestrol derivative 2 as the starting material, a variety of cytotoxic linked hexestrol (HEX) compounds were prepared including the HEX-N-lost derivative 36, the HEX-(chloroethyl)nitrosourea 38, the HEX-cyclophosphamide 44, and the HEX-epoxide 68. Relative binding affinity to estradiol receptors were in the magnitude of 1%, similar to that of comparable diethylstilbestrol compounds. HEX derivatives with long polyether spacers (64, 65, 70, 71) showed no significant decrease in binding affinity in contrast to derivatives with other bulky side chains.

Receptor binding of NBD-labeled fluorescent estrogens and progestins in whole cells and cell-free preparations.

We have studied the interactions of four fluorescent steroid conjugates with either the estrogen or progesterone receptor, both in whole cells and cell-free receptor preparations. The fluorophore, nitrobenzoxadiazole (NBD), was conjugated with a synthetic progestin, with a steroidal estrogen, a non-steroidal estrogen, and with an antiestrogen. With all compounds, receptor-specific binding could be detected by fluorescence measurements following extraction from the protein into an organic solvent. In the native state, however, the NBD-ligand-receptor complex is essentially non-emissive, although these ligands fluoresce strongly when associated with non-specific binders such as albumin. The binding site concentrations and relative affinities determined by fluorescence (after extraction) correspond well with those determined by [3H]estradiol or [3H]R5020 binding to their respective receptors. In T47D breast cancer cells, the NBD-progestin showed receptor-mediated uptake and nuclear localization. These compounds have provided valuable information about the interactions of low and medium affinity ligands with their receptors; however, the successful use of fluorescent ligands for detecting steroid receptors under native-bound conditions, by "imaging" modalities (fluorescence microscopy and flow cytometry) will require the development of fluorophores that are emissive while receptor bound or assay protocols that enable the environment of ligands associated with the receptor to be controlled.

Estrogenic affinity labels: synthesis, irreversible receptor binding, and bioactivity of aziridine-substituted hexestrol derivatives.

To develop an affinity label for the estrogen receptor that would be an estrogen agonist, rather than antagonist, we prepared several aziridine derivatives of the potent nonsteroidal estrogen hexestrol [3R,4S)-3,4-bis(4-hydroxyphenyl)hexane) bearing an aziridine function on the side chain. Three functional groups link the hexestrol ligand and the aziridine: a carbonyl group (ketone or ester), a thioether, or a methylene chain. The apparent competitive binding affinity of these derivatives for the estrogen receptor ranges from 1.8% to 25% that of estradiol, and most of them bind in a time-dependent, irreversible manner with the receptor, although the rate and efficiency of this binding vary widely, often with relatively small changes in structure. This is consistent with the irreversible attachment requiring a precise alignment of activating and reacting residues in the binding site of the receptor. The estrogenic and antiestrogenic activity of these aziridine derivatives was investigated in MCF-7 human breast cancer cells. Most of the compounds are agonists, with one being an antagonist. The derivative (6R,7S)-1-N-aziridinyl-6,7-bis(4-hydroxyphenyl)-5-nonanone (keto-nonestrol aziridine 3) appears to have the most ideal behavior of the estrogenic affinity labeling agents prepared: It is an agonist, and it binds to receptor irreversibly, efficiently, and quite rapidly.

Preparation, receptor binding, and fluorescence properties of hexestrol-fluorophore conjugates: evaluation of site of attachment, fluorophore structure, and fluorophore-ligand spacing.

We have undertaken a staged development of certain estrogen-fluorophore conjugates, in order to prepare a fluorescent estrogen suitable for determination of the estrogen receptor content of individual cells. Since non-steroidal estrogens with bulky substituents are often more readily bound by receptor than their steroidal counterparts, we have investigated fluorophore conjugates with derivatives of the non-steroidal estrogen hexestrol [3R*, 4S*)-3,4-bis(4-hydroxyphenyl)hexane). On the basis of the receptor-binding affinity of model compounds, we prepared a prototypical set of three ring- and side-chain-substituted fluorescent hexestrol derivatives, whose binding and fluorescence properties ultimately led to the preparation of a series of side-chain-substituted nitrobenzoxadiazole derivatives. The compounds prepared have binding affinities for the estrogen receptors that range from ca. 1% to 5% that of estradiol, and they have very favorable fluorescence characteristics, similar to those of fluorescein.

Influence of alkyl chain ramification on estradiol receptor binding affinity and intrinsic activity of 1,2-dialkylated 1,2-bis(4- or 3-hydroxyphenyl)ethane estrogens and antiestrogens.

The influence of a symmetrical introduction of CH3 substituents in the alpha or beta positions of the 1,2-dialkyl-1,2-bis(4-hydroxyphenyl)ethane estrogens hexestrol (ethyl, HES) and octestrol (n-propyl, OCES) [isopropyl (1), tert-butyl (2), sec-butyl (3), isobutyl (4)] and the 1,2-dialkyl-1,2-bis(3-hydroxyphenyl)ethane antiestrogens metahexestrol (ethyl, MetaHES) and metaoctestrol (n-propyl, MetaOCES) [isopropyl (5), tert-butyl (6), sec-butyl (7), isobutyl (8)] on estradiol receptor (E2R) binding affinity and intrinsic activity is described. The synthesis of compounds 1-8 was accomplished by reductive coupling of (a) the corresponding alpha-alkylbenzyl alcohols with TiCl3/LiAlH4 and separation of the meso diastereoisomers (compounds 2-4, 7, and 8), (b) alpha-tert-butyl-3-methoxybenzyl chloride with CoCl2/EtMgCl and isolation of the meso configurated isomer (6), and (c) the isopropyl phenyl ketones with TiCl4/Zn and subsequent hydrogenation of the corresponding cis-hex-3-enes (compounds 1 and 5). The binding affinity of 1-8 to the calf uterine E2R was measured relative to that of [3H]E2 by a competitive binding assay. Compounds 1 and 5 showed relative binding affinity (RBA) values exceeding those of HES and MetaHES, respectively. All other derivatives showed RBA values smaller than the corresponding parent compounds. The intrinsic activity was monitored in terms of uterotrophic and antiuterotrophic activity. It is striking that the introduction of a CH3 group in the alpha positions of MetaHES and MetaOCES led to compounds with full intrinsic activity (5-7), i.e., estrogens without antiestrogenic properties. No correlation between E2R binding affinity and intrinsic activity was found.

Influence of alkyl-chain fluorination on the action of mammary tumor inhibiting 2,3-bis(hydroxyphenyl)butanes and 2,3-bis(hydroxyphenyl)but-2-enes.

trans-1,2-Bis(trifluoromethyl)-1,2-bis(4- and 3-hydroxyphenyl)ethenes 2 and 4 were prepared by reductive coupling (TiCl4/Zn/pyridine) of the methoxy-substituted alpha, alpha, alpha-trifluoroacetophenones, separation of the resulting cis- and trans-stilbene derivatives, and ether cleavage with BBr3. The cis-stilbenes were catalytically hydrogenated to give meso-1,1,1,4,4,4-hexafluoro-2,3-bis(4- and 3-hydroxyphenyl)butanes 6 and 8. Compounds 2, 4, 6, and 8 showed 2- to 10-fold increased binding affinities for the estradiol receptor (E2R) and enhanced estrogenicity in the uterine weight test of the immature mouse compared to their unfluorinated analogues. Compound 8 exhibited a 46% inhibition of the estrone-stimulated uterine growth. Antitumor activity was evaluated with use of the transplantable, hormone-dependent MXT mammary tumor of the BD2F1 mouse. All compounds showed tumor growth inhibitory activity corresponding to their RBA values. The most interesting compound 8 led to a significant inhibition of the tumor growth on the DMBA-induced hormone-dependent mammary carcinoma of the Sprague-Dawley rat.

Carcinogenicity and metabolic activation of hexestrol.

The carcinogenic activity of the synthetic estrogen hexestrol was measured in male Syrian hamsters. Between 90% and 100% of the animals treated with hexestrol or with 3',3",5',5"-tetradeuteriohexestrol, implanted subcutaneously as 25-mg pellets, were found with renal carcinoma after 6-7 months. In vitro hexestrol metabolism, mediated by phenobarbital-induced rat liver microsomes, led to the formation of 3'-hydroxyhexestrol. This metabolite was identified by comparison with authentic reference material synthesized by oxidation of hexestrol with Fremy's salt. Diethylstilbestrol could not be detected as a metabolite. In urine of male Syrian hamsters, 3'-hydroxyhexestrol, 3'-methoxyhexestrol, 1-hydroxyhexestrol, and other hydroxylated and/or methoxylated hexestrol metabolites were identified. Again, diethylstilbestrol was not detectable as a hexestrol metabolite in vivo. The reactivity of 3'-hydroxyhexestrol was then studied to determine if this catechol estrogen played a role in hexestrol carcinogenicity. Horseradish peroxidase catalyzed the oxidation of 3'-hydroxyhexestrol to 3',4'-hexestrol quinone. This oxidation reaction could also be carried out non-enzymatically using silver oxide or silver carbonate on celite as oxidants. The quinone was unstable (t1/2 in methylene chloride: 53 min). It reacted with sulfur-containing compounds such as mercaptoethanol by Michael addition to form 3'-(2-hydroxyethylthio)-5'-hydroxyhexestrol. 3',4'-Hexestrol quinone reacted with simple amines such as ethylamine to form N-ethyl-aminohexestrol. The chemical reactions described above were carried out to test the reactivity of identified or suspected metabolic intermediates of hexestrol. It was concluded that carcinogenicity of hexestrol was not based on its conversion to diethylstilbestrol. Rather, catechol estrogen formation may be necessary for the carcinogenic action of hexestrol in analogy to events observed earlier with estradiol.

Synthesis and receptor-binding affinity of fluorotamoxifen, a possible estrogen-receptor imaging agent.

Aminotamoxifen was totally synthesized from p-nitrobenzoyl chloride via a Friedel-Crafts acylation. Then, by means of a Balz-Schiemann reaction, aminotamoxifen was converted into fluorotamoxifen. The triazene variation of this conversion, with a 25% yield, enables a rapid, one-step diazotization, incorporating a fluorine atom into the phenyl ring of the tamoxifen. This reaction may be useful for the preparation of low specific activity 18F-labeled tamoxifen, for distribution, and for estrogen-receptor studies. For these in vivo and in vitro studies, fluorotamoxifen was also synthesized from p-fluorobenzoyl chloride, and its chemical intermediates were compared with estradiol and hexestrol, for their receptor binding and competition, as well as for their uterotropic activity. It is demonstrated that tamoxifen and fluorotamoxifen are strong estradiol agonists and partial hexestrol agonists, while aminotamoxifen is a weak estradiol and hexestrol agonist.

Ring-substituted 1,1,2,2-tetraalkylated 1,2-bis(hydroxyphenyl)ethanes. 4. Synthesis, estrogen receptor binding affinity, and evaluation of antiestrogenic and mammary tumor inhibiting activity of symmetrically disubstituted 1,1,2,2-tetramethyl-1,2-bis(hydroxyphenyl)ethanes.

The syntheses of symmetrically 2,2'-disubstituted derivatives of 1,1,2,2-tetramethyl-1,2-bis(4-hydroxyphenyl)ethane (1) and of 5,5'-, and 6,6'-disubstituted derivatives of 1,1,2,2-tetramethyl-1,2-bis(3-hydroxyphenyl)ethane (6) are described (1 and 6 are strong antiestrogens with mammary tumor inhibiting activity exhibiting only slight estrogenic properties): (2,2'-substituents) F (2), Cl (3), OCH3 (4), CH3 (5); (5,5'-substituents) Cl (7); (6,6'-substituents) F (8), Cl (9), OCH3 (10), CH3 (11). The synthesis of 1-11 was accomplished by reductive coupling of the corresponding 2-phenyl-2-propanols with TiCl3 and LiAlH4. The binding affinity of the compounds to the calf uterine estrogen receptor was measured relative to that of [3H]estradiol by a competitive binding assay. With the exception of 7 and 10 all other compounds showed relative binding affinity (RBA) values between 0.5 and 6.4% that of estradiol, 2 (RBA value 6.4), and 8 and 9 (4.0 and 3.5), exceeding those of the corresponding unsubstituted 1 and 6 (3.6 and 3.0). Compounds exhibiting RBA values of greater than 2.5% were evaluated in the mouse uterine weight test. The substituted derivatives showed an increase in uterotrophic and a decrease in antiuterotrophic activity compared to 1 and 6. Compound 2 showed a strong, dose-dependent inhibition on the DMBA-induced hormone-dependent mammary tumor of the SD-rat, exceeding that of the parent compound 1. At a dose of 5 mg/kg per day, 2 reduced total tumor area by 47% and caused a complete remission in 74% of the tumors.

Hexestrol residues and metabolites in the tissues of wethers injected with hexestrol dicaprylate or hexestrol.

Four young (23 kg body weight) and two mature wethers (52 and 92 kg body weight) were subcutaneously injected with hexestrol (HX) or HX dicaprylate (HX-D) and killed 41 d later. The HX residues, comprising free, glucuronide and KOH hydrolyzable forms plus metabolites were determined by gas chromatography after liquid-liquid extraction and silica gel chromatographic purification of tissue sample. The HX residues were observed to be at concentrations of .1 to 1.0 ppb in most of the tissues examined. Maturity of the animals and the two hormonal formulations resulted in little difference in residues. The KOH hydrolyzable fraction was hardly detected in the tissues examined. Free HX was a major residue in muscle, representing about 70% of HX residues. Glucuronide HX represented 70 to 80% of HX residues in liver and kidney. In lung, glucuronide and free HX were present in similar amounts. This study showed that the gross metabolic patterns of HX and its esters are similar to other estrogens and steroids.

Molecular studies of the induction of cellular phospholipidosis by cationic amphiphilic drugs.

More than 30 cationic amphiphilic drugs have been shown to cause phospholipidosis in humans, animals, and cultured cells. Evidence obtained with drug-treated rats and cultured Madin-Darby canine kidney cells grown in the presence of these agents suggests a three-step mechanism: 1) the agents enter the target cell readily: 2) they concentrate in cell lysosomes; and 3) they inhibit lysosomal phospholipases A and C. The inhibition may be direct, or it may be indirect resulting from effects on lysosomal pH. This mechanism may also be relevant to other cells and tissues, although the evidence to date has been obtained in only liver and MDCK cells.

Synthesis, receptor binding, and target-tissue uptake of carbon-11 labeled carbamate derivatives of estradiol and hexestrol.

The reaction of ethyl chloroformate with amino compounds has been evaluated as a simple route to carbon-11 labeling of steroid hormone-receptor-based imaging agents. Both a 17 beta-amino analogue of estradiol and an aminoethyl derivative of the nonsteroidal estrogen hexestrol with potential affinity for the estrogen receptor were studied. The unlabeled carbamate derivatives of the amino estrogens were prepared by standard methods, and the 11C-labeled analogues were synthesized from [11C]ethyl chloroformate, generated by purging ethanol with [11C]phosgene. Both carbamates showed weak in vitro binding affinity for the estrogen receptor, and only the 11C-labeled hexestrol exhibited a small but significant estrogen-responsive uterus uptake in immature rats.