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.

Identification of covalent attachment site of antiestrogenic estradiol 11 beta-derivatives on human estrogen receptor alpha ligand-binding domain.

Affinity labeling of human estrogen receptor alpha (ERalpha) by high affinity and antiestrogenic estradiol (E(2)) 11 beta-derivatives, 11 beta-bromoacetamidoethoxyphenylE(2) (11BAEOPE(2)) and 11 beta-bromoacetamidopentoxyphenylE(2) (11BAPOPE(2)) was studied using glutathione-S-transferase (GST) fused to the ligand-binding domain (LBD) of human ERalpha. To identify and quantify the electrophile covalent attachment sites on LBD, [(14)C]11BAEOPE(2)- and [(14)C]11BAPOPE(2)-alkylated LBD were separated from GST, purified, and then trypsinized. HPLC of LBD tryptic fragments afforded one and two radioactive peaks (the ratio of the two latter peaks was 84/16) in the chromatograms related to LBD alkylated by 11BAEOPE(2) and 11BAPOPE(2), respectively.

Requirements for reliable determination of binding affinity constants by kinetic approach.

The nonspecific binding (equilibrium coefficient kn) of ligand (L) and/or the incomplete recovery (alpha < 1) of the receptor-ligand (RL) complex in binding measurements, could hamper accurate determination of the association and dissociation rate constants of the R/L system. For the simplest model of R/L interaction, characterized by a bimolecular association process (rate constant k1) and a monomolecular dissociation process (rate constant k2), the consequences of kn and/or alpha neglect on k1 and k2 determination were investigated. Various situations that are especially relevant for k1 determination, were examined in which nonspecific binding was: (i) negligible relative to specific binding, or (ii) developed progressively or very rapidly in association kinetics.

Requirements for reliable determination of binding affinity constants by saturation analysis approach.

Accurate calculation of the equilibrium association constant (K) and binding site concentration (N) related to a receptor (R)/ligand (L) interaction, via R saturation analysis, requires exact determination of the specifically bound L concentration (B(S)) and the unbound L concentration (U) at equilibrium. However, most binding determinations involve a procedure for separation of bound and unbound L. In such situations, it was previously shown that correct calculation of B(S) and U from binding data requires prior determination of alpha, i.

Identification by MALDI-TOF mass spectrometry of 17 alpha-bromoacetamidopropylestradiol covalent attachment sites on estrogen receptor alpha.

Mass spectrometry was used to identify the sites of covalent attachment of [(14)C]-17alpha-bromoacetamidopropylestradiol ([(14)C]17BAPE(2), an estradiol agonist) to the ligand-binding domain (LBD) of mouse estrogen receptor alpha (ERalpha). A glutathione S-transferase (GST)-LBD chimera protein was overexpressed in Escherichia coli, using a vector encoding GST fused with a C-terminal portion of mouse ERalpha (Ser(313)-Ile(599)), via a sequence enclosing a thrombin cleavage site (located 14 amino acids ahead of Ser313). [(14)C]17BAPE(2) covalent labeling experiments were carried out on the GST-LBD chimera immobilized on glutathione-Sepharose.

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.

Steroidal affinity labels of the estrogen receptor alpha. 4. Electrophilic 11beta-aryl derivatives of estradiol.

Ten electrophilic estradiol 11beta-aryl derivatives were synthesized, with three different types of 11beta-substituent: (i) pOO(CH(2))(2)X (compounds: 6, X = OSO(2)CH(3); 7, X = I; 13, X = NHCOCH(2)Cl; 15, X = N(CH(3))COCH(2)Br; and 16, X = N(CH(3))COCH(2)Cl); (ii) pOO(CH(2))(5)X (compounds: 17, X = I; 20, X = NHCOCH(2)Br; and 22, X = N(CH(3))COCH(2)Br); and (iii) pOC(triple bond)CCH(2)X (compounds: 27, X = NHCOCH(2)Cl; and 29, X = N(CH(3))COCH(2)Cl). The range of their apparent affinity constants for binding the lamb uterine estrogen receptor alpha (ERalpha) was 3-40% that of estradiol. Six electrophiles, chloroacetamides 13, 16, 27, and 29, iodide 17, and bromoacetamide 20 (whose arm linking the electrophilic carbon to the 11beta-phenyl group includes at least six bonds), were able to irreversibly inhibit the binding of [(3)H]estradiol to ER (25-60% decrease in binding sites), with the following compound effectiveness order: 17 < 13 < 16 approximately 20 approximately 27 approximately 29.

Effect of ligand and DNA binding on the interaction between human transcription intermediary factor 1alpha and estrogen receptors.

Hormonal regulation of gene activity is mediated by nuclear receptors acting as ligand-activated transcription factors. To achieve efficient regulation of gene expression, these receptors must interact with different type of molecules: 1) the steroid hormone, 2) the DNA response element, and 3) various proteins acting as transcriptional cofactors. In the present study, we have investigated how ligand and DNA binding influence the in vitro interaction between estrogen receptors (ERs) and the transcription intermediary factor hTIF1alpha (human transcriptional intermediary factor 1alpha).

Cysteine 530 of the human estrogen receptor alpha is the main covalent attachment site of 11beta-(aziridinylalkoxyphenyl)estradiols.

The efficiency of 11beta-[p(aziridinylethoxy)phenyl]estradiol 1 and 11beta-[p(aziridinylpentoxy)phenyl]estradiol 2 affinity labeling of the estrogen receptor alpha (ERalpha) was evaluated on the basis of their capacity to inhibit [(3)H]estradiol binding to lamb and human ERalphas. Relative to RU 39 411 (11beta-[p(dimethylaminoethoxy)phenyl]estradiol), the most closely related and chemically inert analogue of 1, the two electrophiles irreversibly inhibited [(3)H]estradiol binding to the lamb ERalpha. The fact that the compound effects were prevented (i) when the ERalpha hormone-binding site was occupied by estradiol and (ii) when the ERalpha-containing extracts were pretreated with methyl methanethiosulfonate (an SH-specific reagent) suggested that the compounds specifically alkylated ERalpha at cysteine residues.

Steroidal affinity labels of the estrogen receptor. 3. Estradiol 11 beta-n-alkyl derivatives bearing a terminal electrophilic group: antiestrogenic and cytotoxic properties.

With the aim of developing a new series of steroidal affinity labels of the estrogen receptor, six electrophilic 11 beta-ethyl (C2), 11 beta-butyl (C4), or 11 beta-decyl (C10) derivatives of estradiol bearing an 11 beta-terminal electrophilic functionality, i.e. bromine (C4), (methylsulfonyl)oxy (C2 and C4), bromoacetamido (C2 and C4), and (p-tolylsulfonyl)oxy (C10), were synthesized.

17 alpha (haloacetamidoalkyl) estradiols alkylate the human estrogen receptor at cysteine residues 417 and 530.

Results obtained in a previous study suggested that cysteine residues in the estrogen receptor were covalent attachment sites for four 17 alpha-(haloacetamidoalkyl) estradiols (halo, bromo or iodo; alkyl, methyl, ethyl, or propyl). To identify the putative concerned cysteines, we expressed wild-type and various cysteine --> alanine mutants of the human estrogen receptor in COS cells and determined their ability to be alkylated by the four electrophiles. The quadruple mutant, in which all the cysteines (residues 381, 417, 447, and 530) of the hormone-binding site were changed to alanines, showed very little electrophile labeling, whereas the four single mutants (C381A, C417A, C447A, and C530A) were alkylated as efficiently as the wild-type receptor.

The effect of free DNA on the interactions of the estrogen receptor bound to hormone, partial antagonist or pure antagonist with target DNA.

Interactions between the lamb uterine estrogen receptor occupied by estradiol, 4-hydroxytamoxifen (a non-steroidal partial estrogen antagonist) or ICI 164,384 (a steroidal pure estrogen antagonist), and the vitellogenin A2 estrogen-response element (vit ERE) were compared using a biotinylated 25-base all-palindromic double-stranded oligonucleotide, containing vit ERE (b-ERE), which allowed isolation of the b-ERE.receptor.[3H]ligand assembly on streptavidin-Sepharose.

Steroidal affinity labels of the estrogen receptor. 2. 17 alpha-[(Haloacetamido)alkyl]estradiols.

In a previous study, we described affinity labeling of the lamb uterine estrogen receptor by 17 alpha-[(bromoacetoxy)alkyl/alkynyl]estradiols. However, the intrinsic receptor-alkylating activities of these compounds were probably very hampered by their poor hydrolytic stability in estrogen receptor-containing tissue extracts. Therefore, (i) to develop affinity labels of the receptor not susceptible to hydrolysis and (ii) to specify the structural requirements for 17 alpha-electrophilic estradiol derivatives to be potent affinity labels of the receptor, we prepared four 17 alpha-[(haloacetamido)alkyl]estradiols.

[The elucidation of the antiestrogen and antitumoral mechanisms of tamoxifen].

Our contribution to elucidation of the mechanism of action of tamoxifen can be summarized as follows: (i) hydroxylated metabolites of tamoxifen (especially 4-hydroxytamoxifen), with high affinity for the oestrogen receptor are more potent antioestrogen and antitumoral agents than tamoxifen; they might play an important role in the in vivo antioestrogenic and antitumoral activities of tamoxifen; (ii) the activity of tamoxifen and derivatives in vitro is closely related to their affinity for the receptor; (iii) certain oestrogen receptor properties (dissociation kinetics, immunoreactivity, sensitivity to specific reagents) vary according to whether oestrogen or antioestrogen is bound to the receptor. These variations probably result from different "positioning" of oestrogen and antioestrogen at the receptor hormone-binding site. They indicate that antioestrogens may induce altered conformation and probably defective activation of the oestrogen receptor.

Steroidal affinity labels of the estrogen receptor. 1. 17 alpha-(Bromoacetoxy)alkyl/alkynylestradiols.

To develop steroidal affinity labels for the estrogen receptor, we prepared five electrophilic estradiol derivatives bearing the 17 alpha-propyl, 17 alpha-(1'-butynyl), or 17 alpha-(1'octynyl) chain, with either a terminal epoxy function (for the 17 alpha-propyl substituent) or a terminal bromoacetoxy function (for all three 17 alpha-substituent types). These compounds displayed low affinity for the lamb uterine estrogen receptor; with apparent relative affinity constants ranging from 0.02% to 0.

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).

Mapping on the calf estrogen receptor of the binding domain for an antibody interfering with receptor activation.

The localization on the calf estrogen receptor of the binding domain for B36 (an IgM antibody which prevents and reverses the effects of receptor activation) has been studied by means of controlled proteolysis of the receptor-estradiol complex using trypsin, chymotrypsin, and papain. We successively determined for intact and proteolyzed receptor-estradiol complex (i) the abilities of estradiol-binding species to aggregate in low salt medium, to bind to nonspecific DNA absorbed onto cellulose, and to interact with B36 antibody in sucrose gradients; (ii) the hydrodynamic properties of estradiol-binding species, by gel permeation chromatography and sucrose gradient centrifugation in high salt media and (iii) the molecular weights of B36-reactive species, by immunoblot analysis. Three tryptic receptor fragments of Mr 36,000, 34,000, and 33,000 and two chymotryptic fragments of Mr 36,000 and 33,000 included both the hormone- and B36-binding domains but did not interact with DNA, whereas at least two receptor fragments resulting from the action of chymotrypsin and papain bound estradiol with high affinity but interacted neither with DNA nor with B36.

Differential inhibition of estrogen and antiestrogen binding to the estrogen receptor by diethylpyrocarbonate.

Diethylpyrocarbonate differentially inhibited the specific binding, in lamb uterine cytosol, of estradiol (inhibition approximately 90% with 4 mM reagent) and 4-hydroxytamoxifen (inhibition approximately less than 50% with 4-16 mM reagent), a potent triphenylethylene antiestrogen. Saturation analysis experiments indicated that the effects of diethylpyrocarbonate were due to progressive but differing decreases in the concentration of binding sites for the two ligands, with no apparent change in the affinity constants. However, competitive binding and dissociation experiments evidenced that steroidal and nonsteroidal estrogens still bound, but with very low affinities, to diethylpyrocarbonate-modified receptor (greater than 1000-fold decrease in affinity) whereas the affinities of triphenylethylene antiestrogens were much less affected (less than 10-fold decrease).

A monoclonal antibody to the estrogen receptor inhibits in vitro criteria of receptor activation by an estrogen and an anti-estrogen.

The effect of an IgM class monoclonal antibody (B36) (Greene, G. L., Fitch, F.

Ellipticine derivatives with an affinity to the estrogen receptor, an approach to develop intercalating drugs with a specific effect on the hormone-dependent breast cancer.

In order to obtain breast tumor directed agents, we have prepared mixed compounds using estradiol or (E)-clomiphene as specific vectors of the breast tissue and a DNA intercalator from the ellipticine series as the cytotoxic agent. Among the newly synthesized ellipticine derivatives, only the 2-[3-aza-5-(3,17 beta-dihydroxy-1,3,5-estratrien-17 alpha-yl)-4-oxopentamethylene]ellipticinium bromide shows the desired properties, DNA intercalation and affinity for estrogen receptor. Competition experiments with estradiol on the hormone-dependent human MCF-7 breast cancer cell line demonstrate that a transport by the estrogen receptor system is not involved in the antitumor activity of derivative 24.

A monoclonal antibody to the estrogen receptor discriminates between the nonactivated and activated estrogen- and anti-estrogen-receptor complexes.

An IgM-class monoclonal antibody ( B36 ) [Greene, G. L., Fitch, F.

[Effects and mechanism of action of antiestrogens in breast cancer].

Tamoxifen, a non-steroidal antiestrogen, is currently used to treat post-menopausal breast cancer. In estrogen-sensitive breast cancer cell lines, tamoxifen and some of its metabolites display, for the induction of estrogen-regulated proteins, a partial agonist/antagonist activity. They also inhibit totally the proliferation of these cells.

[Effects and mechanism of action of antiestrogens in breast cancer].

Tamoxifen, a non-steroidal antioestrogen, is currently used to treat post-menopausal breast cancer. In oestrogen-sensitive breast cancer cell lines, tamoxifen and some of its metabolites display, for the induction of oestrogen-regulated proteins, a partial agonist/antagonist activity. They also inhibit totally the proliferation of these cells.

Cellular and molecular mechanism of action of antiestrogens.

The mechanism of action of tamoxifen and of 4-hydroxytamoxifen is reviewed at the cellular and molecular level, through the current view of the authors. Synthetic antiestrogens are mainly acting directly on breast cancer cells by interacting with the estrogen receptor (RE). They prevent estrogen action by competing with estrogens on the cytosol RE.

Mode of action of LN 1643 (a triphenylbromoethylene antiestrogen): probable mediation by the estrogen receptor and high affinity metabolite.

After in vivo administration of [3H]LN 1643, a triphenylbromoethylene antiestrogen, to immature female rats, polar metabolites were selectively accumulated in uterine nuclear fractions which contained most of the estrogen receptor. One metabolite comigrated with the 4-hydroxylated derivative (LN 2839) of LN 1643. LN 1643 and LN 2839 inhibited competitively and reversibly the binding of estradiol to the estrogen receptor, and the affinity of LN 2839 for the estrogen receptor was about 150-fold higher than that of LN 1643.