Accumulation of a non-binding form of estrogen receptor in MCF-7 cells under hydroxytamoxifen treatment

It is well known that MCF-7 cells, when incubated with hydroxytamoxifen (OH-Tam) loose their capacity to bind [³H]estradiol. By using Western blotting and [³H]tamoxifen aziridine labeling of KCl extracts from these cells we found that this loss in binding capacity was not associated with a disappearance of the estrogen receptor (ER) protein, an event known to occur after incubation with estradiol. Attempts to label under exchange conditions these ER molecules, which, on the basis of enzyme immunoassays appear to accumulate under OH-Tam treatment, were unsuccessful. Cell fractionation suggested that their origin is nuclear. Assessment of a few triphenylethylenic antiestrogens, as far as their inhibitory potency towards the in vitro MCF-7 cell growth is concerned, indicated a correlation between accumulation of these non-binding ER molecules and the antiestrogen antiproliferative action. However, we were unable to demonstrate absence of such an ER accumulation in two tamoxifen-resistant variants. Impaired folding of the ER protein or impaired phosphorylation of its hormone-binding domain are attractive hypotheses to account for these non-binding ER molecules. Whether these ER molecules have any physiological role, such as competition with the “normal” receptor molecules for the estrogen responsive elements on the DNA is unknown and deserves further study.     

Chemical and biochemical issues related to X-ray crystallography of the ligand-binding domain of estrogen receptor alpha

Careful attention to technical issues preceded successful crystallography of the ligand-binding domain of estrogen receptor alpha (ERalpha) complexed with CP-336156, a nonsteroidal estrogen agonist/antagonist. An affinity column based on immobilized estradiol was prepared according to the scheme of Greene et al. (Greene, G. L., Nolan, C., Engler, J. P., and Jensen, E. V. (1980) Proc. Natl. Acad. Sci. U.S.A. 77, 5115-5119). It was shown by X-ray crystallography that the major and less polar isomer of the affinity column precursor was 17alpha-((S)-2',3'-epoxyprop-1'-yl)estra-1,3,5(10)-triene-3,17beta-diol. This diastereomer was coupled to Thiopropyl Sepharose, with coupling monitored by observing loss of the phenolic absorption band of estradiol from the reaction supernatant, and gave an affinity matrix containing about 9 micromol of estradiol per milliliter of wet gel. Recombinant ERalpha ligand binding domain was selectively removed from E. coli cell lysate by binding to the column and was partly S-carboxymethylated by treatment with iodoacetic acid while bound to the column as described by previous workers. After being eluted from the column as a complex with drug, the receptor fragment was shown by mass spectrometry to be a mixture of differently modified forms. It was further S-carboxymethylated in solution, after which anion-exchange chromatography was used to isolate protein in which two of the four cysteine residues were S-carboxymethylated. This material, which afforded diffraction-quality crystals, was subjected to digestion with trypsin and peptide mapping analysis by HPLC coupled with mass spectrometry. For this experiment, the two previously unmodified cysteines were alkylated with 4-vinylpyridine to allow definitive identification. It was shown that Cys-417 and Cys-530 were S-carboxymethylated in the crystallized protein, while Cys-381 and Cys-447 remained unmodified. Close attention to such technical issues may be important in structural studies of other nuclear receptors, a very important class of potential drug targets.     

Mass spectrometry identification of covalent attachment sites of two related estrogenic ligands on human estrogen receptor alpha

A purified preparation of human estrogen receptor alpha (hERalpha) ligand-binding domain (LBD) involving mainly the Ser(309)Ala(569) (approximately 30%) and Ser(309)Ala(571) (approximately 63%) ER portions was used to identify the covalent attachment sites of two closely related estrogenic ER affinity labels 17alpha-bromoacetamidopropylestradiol (17BAPE(2)) and 17alpha-bromoacetamidomethylestradiol (17BAME(2)). To identify and quantify the electrophile covalent attachment sites, [(14)C]17BAPE(2)- and [(14)C]17BAME(2)-alkylated hLBD preparations were trypsinized and submitted to HPLC. In each case, two radioactive fractions were obtained. Mass spectrometry analyses of the two fractions showed signals, which closely matched the molecular masses of alkylated Cys(530)Lys(531) and Cys(417)Arg(434) hLBD tryptic peptides. The covalent attachment of the two electrophiles on hLBD was assigned to the S atoms of Cys(530) and Cys(417). However, the balance between Cys(530) and Cys(417) labeling markedly differed according to the affinity label used, with the Cys(530)/Cys(417) ratio being 2.1 for 17BAPE(2), and 20 for 17BAME(2). We attempted to interpret the covalent attachment of electrophiles by molecular modeling using the crystallographic structure of LBD bound to E(2). In agreement with the different levels of Cys(417) alkylation, the LBD model with unchanged helices could not easily account for Cys(417) labeling by 17BAME(2), whereas favorable results were obtained through 17BAPE(2) docking. Moreover, labeling at Cys(530) by the two electrophiles could not be interpreted using the LBD model. This indicates that some states of solute LBD bound to the estrogenic E(2) 17alpha-derivatives differ from the structure of crystallized LBD bound to E(2).     

2,5-Diphenylfuran-based pure antiestrogens with selectivity for the estrogen receptor alpha

The estrogen receptor alpha (ERalpha) is understood to play an important role in the progression of breast cancer. Therefore, pure antiestrogens with a preference for this receptor form are of interest as new agents for the treatment of this malignancy. Several chemical structures with selective binding affinity for ERalpha have been identified and might be useful for the synthesis of ERalpha-selective pure antiestrogens. In this study we applied the 2,5-diphenylfuran system which is closely related to the triphenylfurans described by others. Various side chains with amino and/or sulfur functions were linked to C3 to convert the furans to estrogen antagonists without residual estrogenic activity. The degree of alpha-selectivity which ranges from 2.5- to 236-fold is strongly influenced by the alkyl group at C4. Antiestrogenic potency was determined in MCF-7/2a breast cancer cells stably transfected with a luciferase gene under the control of an ERE. The 2,5-bis(4-hydroxyphenyl)furan with an ethyl substituent and a 6-[N-methyl-N-(3-pentylthiopropyl)amino]hexyl side chain exerted the strongest antiestrogenic effect in this series with an IC(50) value of 50 nM in cells stimulated with 1 nM estradiol. The RBA values of this derivative were 18% (ERalpha) and 3.4% (ERbeta) of estradiol, respectively. It inhibited the growth of wild-type MCF-7 cells with an IC(50) value of 22 nM. The data show that the 2,5-diphenylfuran system is appropriate for the development of pure antiestrogens with preference for ERalpha.     

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)     

Differential interactions of estrogens and antiestrogens at the 17 beta-hydroxyl or counterpart hydroxyl with histidine 524 of the human estrogen receptor alpha

We investigated the role of H524 of the human estrogen receptor alpha (ERalpha) for the binding of various estrogens [estradiol (E(2)), 3-deoxyestradiol (3-dE(2)), and 17beta-deoxyestradiol (17beta-dE(2))] and antiestrogens [4-hydroxytamoxifen (OHT), RU 39 411 (RU), and raloxifene (Ral)], which possess the 17beta-hydroxyl or counterpart hydroxyl (designated: 17beta/c-OH), with the exception of 17beta-dE(2) and OHT. The work involved a comparison of the binding affinities of these ligands for wild-type and H524 mutant ERs, modified or not with diethyl pyrocarbonate (DEPC), a selective histidine reagent. Alanine substitution of H524 did not significantly change the association affinity constant (relative to OHT) of 17beta-dE(2), whereas those of RU, Ral, E(2), and 3-dE(2) were decreased 3-fold, 14-fold, 24-fold, and 49-fold, respectively. Values of the two ligands available in radiolabeled form (E(2) and OHT) were correlated with the dissociation rate constants, which were increased 250-fold and 2-fold, respectively. The action of DEPC on wild-type ER led to a homogeneous ER population which still bound antiestrogens and 17beta-dE(2) with practically unchanged affinities (less than 4-fold decreases in relative affinity constants), while E(2) and 3-dE(2) displayed markedly decreased affinities (56-fold decrease for E(2)). Conversely, DEPC treatment of H524A mutant ER did not induce marked decreases in the relative affinities of any of the checked compounds (decreases wild-type ER) and very weakly protected H524A ER. Molecular modeling was tentatively used to interpret the biochemical results.     

S-palmitoylation modulates human estrogen receptor-alpha functions

17beta-Estradiol (E2)-induced rapid functions (from seconds to minutes) can be attributed to a fraction of nuclear estrogen receptor-alpha (ERalpha) localized at the plasma membrane. As a potential mechanism, we postulated that S-palmitoylation of the Cys447 residue may explain the ability of ERalpha to associate to plasma membrane making possible E2-dependent rapid functions [e.g., extracellular regulated kinase (ERK) activation]. Here, we report direct evidence that the mutation of the Cys447 residue to Ala impairs human ERalpha palmitoylation and E2-induced rapid ERK phosphorylation when transfected in ER-devoid HeLa cells. Moreover, the Cys447Ala mutation significantly decreases the E2-induced transactivation of an estrogen responsive element construct probe. Similar effects were obtained treating HeLa cells transfected with wild type ERalpha with the palmitoyl-acyltransferase inhibitor 2-bromo-hexadecanoic acid. Moreover, the deletion of the A-D domains (containing the DNA binding region) of ERalpha had no consequences on [(3)H]palmitate incorporation, whereas no palmitoylation occurred in the ERalpha mutant devoid of the E domain (i.e., ligand binding domain). These results point to the pivotal role of the Cys447 residue in ERalpha palmitoylation and in the modulation of E2-induced non-genomic functions.     

Molecular basis for the subtype discrimination of the estrogen receptor-beta-selective ligand,diarylpropionitrile

Although the two subtypes of the human estrogen receptor (ER), ERalpha and ERbeta, share only 56% amino acid sequence identity in their ligand binding domain (LBD), the residues that surround the ligand are nearly identical; nevertheless, subtype-selective ligands are known. To understand the molecular basis by which diarylpropionitrile (DPN), an ERbeta-selective ligand, is able to discriminate between the two ERs, we examined its activity on ER mutants and chimeric constructs generated by DNA shuffling. The N-terminal region of the ERbeta LBD (through helix 6) appears to be fully responsible for the ERbeta selectivity of DPN. In fact, a single ERalpha point mutation (L384M) was largely sufficient to switch the DPN response of this ER to that of the ERbeta type, but residues in helix 3 are also important in achieving the full ERbeta selectivity of DPN. Using molecular modeling, we found an energetically favorable fit for the S-DPN enantiomer in ERbeta, in which the proximal phenol mimics the A ring of estradiol, and the nitrile engages in stabilizing interactions with residues in the ligand-binding pocket of ERbeta. Our findings highlight that a limited number of critical interactions of DPN with the ERbeta ligand-binding pocket underlie its ER subtype-selective character.