Characterization of MCF 7 breast cancer cell growth inhibition by the antiestrogen nitromifene (CI 628) and selected metabolites.

Besides undergoing O-demethylation in vivo, the triarylethylene antiestrogen nitromifene [1-(4-(2-pyrrolidinylethoxy)phenyl)-1-(4-methoxy)-phenyl-2-phenyl- 2- nitroethene, 1] undergoes biotransformation via nitroreduction, ethene bond cleavage, and pyrrolidine ring oxidation affording ketone metabolites 2 and 3 and a lactam metabolite 4. Estrogen receptor (ER) affinities of 1, 2, and 4 were, in turn, 1.7, 0.1, and 3.8% that of estradiol in MCF 7 human breast cancer cells, and these compounds inhibited by 50% the proliferation of MCF 7 cells at respective concentrations of 1.1, 5.6, and 2.0 microM. The inhibitory effect of 4 was fully reversible by estradiol, but that of 2 was only partially reversible. Also 3, which did not interact with ER, inhibited proliferation by 44% at a concentration of 10 microM. These results suggested that in contrast to 4, the effects of 2 and 3 were due in part to interaction with sites distinct from ER. Antiestrogen binding sites and calmodulin have been suggested to mediate antiproliferative effects of drugs. Interaction of ligands with the former sites has been proposed to antagonize the growth promoting effect of histamine. Although 2 and 3 had high affinities for these sites, their inhibitory effects on MCF 7 cell growth were largely unaffected by the presence of histidine, the source of intracellular histamine. Thus, the relationship between antiestrogen binding site affinity and antiproliferative effects of 2 and 3 was not clarified. In contrast, MCF 7 cell growth suppression potencies paralleled calmodulin antagonist potencies of 1 and 2 suggesting that interaction of 1 and 2 with calmodulin may contribute to their anticancer effects.

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). Both ligands prevented the inactivation of the estrogen receptor by diethylpyrocarbonate, estradiol being more efficient than 4-hydroxytamoxifen. These data indicate that the action of diethylpyrocarbonate results in the formation of two populations of estrogen receptor that are quantitatively nearly equivalent: the first does not bind estrogens or antiestrogens; the second does not bind estrogens significantly but still interacts with antiestrogens at a high affinity. The simplest interpretation is that these two populations arise from mutually exclusive modifications by diethylpyrocarbonate of at least two aminoacid residues located at or close to the ligand binding site; modification of one residue totally prevents the binding of estrogens and antiestrogens; the modification of the second impairs only the binding of estrogens. Considering that (i) hydroxylamine, which specifically reverses the diethylpyrocarbonate-induced modification of histidine and tyrosine residues, restored a large part (greater than 80%) of the estradiol- and 4-hydroxytamoxifen-binding capacity of diethylpyrocarbonate-inactivated cytosol, and that (ii) similar differential inhibition of estrogen and antiestrogen binding was observed following the action of tetranitromethane, it is likely that these residues are histidine(s) and/or tyrosine(s). These results evince a marked difference in the interaction of estrogens and triphenylethylene antiestrogens with the estrogen receptor, which could account for the altered activation of the receptor by triphenylethylene antiestrogens. Consequently, the screening of ligands with modified steroid receptors could be a useful method for distinguishing between potential hormone agonists and antagonists.

Studies on the ligand specificity and potential identity of microsomal antiestrogen-binding sites.

Synthetic nonsteroidal antiestrogens are bound intracellularly by two high affinity saturable bindings sites, the estrogen receptor and the microsomal antiestrogen-binding site (AEBS). In order to further define the structural requirements for ligand binding to AEBS from rat liver and the MCF 7 human breast cancer cell line, the relative binding affinities of an extensive series of structurally related ligands were investigated using competitive binding assay techniques. The groups of compounds studied were: analogues of the triphenylethylene antiestrogens, Cl 628 and tamoxifen; analogues of cyclofenil; bibenzyl and stilbene derivatives; analogues of the cytochrome P-450 inhibitor SKF-525A; phenothiazine derivatives; and a series of structurally related compounds with a variety of pharmacological activities. High affinity binding to AEBS required the presence of both a hydrophilic basic aminoether side chain and a hydrophobic aromatic ring structure (di- or tricyclic for maximal affinity). Structural modifications to either influenced binding affinity. Aromatic substitution either raised (CF3) or lowered (OH, OCH3) affinity, apparently by electronic effects transmitted through the benzene nucleus. Side chain structure was the major determinant of binding affinity, but its influence was complex and dependent upon terminal amino group structure, side chain branching and substitution, and tissue source of AEBS. Optimal binding affinity was shown by side chains bearing basic heterocyclic amino terminal groups. Other cellular sites that are known to bind antiestrogens with relatively high affinity include calmodulin, cytochrome P-450, and histamine, dopamine, and muscarinic receptors. Binding studies using a variety of pharmacologically active and radiolabeled ligands selective for these sites, including those for dopamine D1 and D2 receptors ([3H]fluphenazine, [3H]flupenthixol, [3H]spiperone, and [3H]SCH 23390) and histamine H1 receptors ([3H]pyrilamine), demonstrated that several of these compounds interact with AEBS with high affinity. However, the ligand specificity and other binding properties of the AEBS as determined by competitive binding studies and Scatchard analysis show this site to be a molecular entity truly distinct from these other cellular binding sites.

An evaluation of the interactions of antiestrogens with pituitary and striatal dopamine receptors.

We have examined the ability of various antiestrogens (AE's) to compete with 3H-spiroperidol for binding to membrane preparations from striatal tissue and anterior pituitary glands of immature female rats in order to determine the affinity of binding of AE's to D-2 dopamine receptors. Scatchard analyses revealed the presence of a single class of high affinity receptor sites in both the striatum and pituitary with a dissociation constant (Kd) of 0.33 nM and 0.40 nM, respectively, for the dopamine antagonist spiroperidol. The AE's tamoxifen, 4-hydroxy-tamoxifen (TAM-OH), CI-628, LY 117018, and a structurally related compound t-butyl-phenoxyethyl diethylamine (BPEA) were all able to compete with spiroperidol for binding to D-2 receptors and demonstrated relative binding affinities of 0.4-0.06%, with spiroperidol set at 100%. Dopamine displayed a lower affinity, 0.01%. Estradiol failed to compete with spiroperidol for D-2 receptor binding while the non-steroidal estrogen diethylstilbestrol (DES) showed very weak competition. For the lipophilic AE's, alteration of the level of their non-specific binding greatly affected their relative affinities in these competitive binding assays. The amine side chain on an aromatic ring appears to be a critical structural requirement in allowing the AE's to bind to the dopamine receptor. The relatively low affinity of AE's for the dopamine receptor and the high degree of interaction of AE's with other proteins suggest that only limited occupancy of D-2 receptors by AE's is likely in vivo.

Metabolism of nitromiphene (CI 628) in the immature female rat: role of gastrointestinal microflora in the biotransformation of a triarylethylene antiestrogen.

Nitromiphene (NIT; CI 628) is a triarylethylene antiestrogen shown to be effective in treatment of experimental breast cancer. We have studied the fate of NIT in the immature female rat, the animal model in which most of the biochemical studies of NIT have been carried out. NIT was eliminated mainly via the feces after i.p. administration, primarily as metabolites. One of these, a diphenylmethane derivative, p-[2-(N-pyrrolidinyl)ethoxy]-p'-methoxybenzophenone (PMB), was also eliminated in urine as such and as its O-demethyl and keto-reduced metabolites. In uterine and liver tissue, unchanged NIT was accompanied by demethyl NIT (CI 628M), PMB, and a diarylacetophenone derivative, p-[2-(N-pyrrolidinyl)ethoxy-p'-hydroxybenzhydryl phenyl ketone (demethyl KET). In vitro studies showed that O-demethyl NIT was produced in the presence of liver enzymes and that PMB and demethyl KET were produced in the presence of intestinal bacteria. These results suggested that PMB and demethyl KET accumulate in uterine and liver tissue due to reabsorption from the intestine after having been produced there from NIT and demethyl NIT, respectively. The effects of antiestrogens and their metabolites may be due in part to interaction with antiestrogen binding sites. Both demethyl KET and PMB had good affinity for such sites. Thus, these enteric bacterial metabolites not only have the ability to accumulate in vivo, but could, together with demethyl NIT, contribute to the antiestrogenic effects observed with NIT.

Estrogen receptor binding and estrogenic/antiestrogenic effects of two new metabolites of nitromiphene, 2-[p-[2-nitro-1-(4-methoxyphenyl)-2-phenylvinyl]phenoxy]-N-ethylpyrrolidine.

Reduction of the triarylethylene antiestrogen 2-[p-[2-nitro-1-(4-methoxphenyl)-2-phenylvinyl]phenoxy]-N-ethylpyrrolidine (1) with sodium borohydride-stannous chloride afforded 2-(p-methoxyphenyl)-p'-(2-pyrrolidin-1-ylethoxy)deoxybenzoin (2). Incubation of 1 with rat cecal content suspension under aerobic or anaerobic conditions also resulted in the generation of 2. The lactam analogue of 1 (6) was prepared by condensation of 4-(2-bromoethoxy)-4'-methoxybenzophenone (3) with benzylmagnesium chloride, followed by dehydration, amidation with 2-pyrrolidinone, and nitration. A metabolite with chromatographic and spectral properties identical with those of 6 was found in extracts from incubation mixtures of 1 with phenobarbital-induced rat liver 9000g supernatant. Compound 2 did not exhibit appreciable binding to the rat uterine cytosol estrogen receptor at concentrations of up to 1 X 10(-6) M and had no estrogenic or antiestrogenic activity in the 3-day rat uterotropic assay. By contrast, 6 had estrogen receptor affinity somewhat greater than that of 1 and slightly greater estrogenic activity accompanied by reduced antiestrogenic activity in comparison with those of 1.

Formation of benzophenone and alpha, alpha-diarylacetophenone metabolites of the antiestrogen nitromiphene (CI628) in the presence of rat cecal contents.

Incubation of the nonsteroidal antiestrogen nitromiphene (CI628) with rat cecal content suspension under aerobic or anaerobic conditions resulted in extensive biotransformation, yielding three metabolites, as determined by thin-layer chromatography. These metabolites were not recovered from incubation mixtures containing previously frozen suspension, and recoveries were decreased (that of nitromiphene was increased) when incubations were carried out in the presence of 2mM EDTA. Spectral and chromatographic comparison of two of the purified metabolites resulted in their structural characterization, as p-[beta(N-pyrrolidinyl)ethoxy]p'-methoxybenzophenone, and a similarly substituted alpha, alpha-diphenyl-acetophenone. These metabolites are, in turn, due formally to ethylenic bond cleavage and nitro group reduction/hydrolysis of nitromiphene.

A high-affinity binding site for the antioestrogens, tamoxifen and CI 628, in immature rat uterine cytosol which is distinct from the oestrogen receptor.

A high-affinity, saturable antioestrogen binding site, which does not bind oestradiol, has been reported to exist in a number of oestrogen target tissues but not in the immature rat uterus. This study reports the results of a more thorough search for this site in immature rat uterine cytosol. When concentrations of uterine cytoplasmic receptor were selectively depleted by translocation of 90-95% of the cytoplasmic oestrogen receptor to the nucleus, saturation analysis studies revealed that the antioestrogens, tamoxifen and CI 628, were bound to high-affinity, saturable binding sites which were present at about 2.5 times the concentration of the residual oestrogen receptor sites. Oestradiol could only partially inhibit the binding of tritiated antioestrogens to their saturable binding sites in this material indicating that a significant proportion of these sites were distinct from the oestrogen receptor sites. This was confirmed in experiments where oestrogen receptor sites were saturated in vitro with oestradiol and high-affinity, saturable sites for CI 628 and tamoxifen were still present. The CI 628 and tamoxifen had high affinity for these sites with dissociation constants of 1.0-1.6 nmol/l. These specific antioestrogen binding sites were present at about 5% of the concentration of oestrogen receptors in normal immature rat uterine cytosol which probably explains their previous lack of detections in this material.

Anti-oestrogen action: uterine nuclear retention of the CI-628 anti-oestrogen receptor complex in vitro.

Experiments were performed in vitro which compared the nuclear retention of the anti-oestrogen receptor complex formed by CI-628 and the nuclear retention of the oestrogen receptor complex formed by oestradiol-17beta. Uterine nuclei retained the CI-628 receptor complex regardless of whether uterine incubations were carried out in the continued in fresh medium. However, for oestradiol-17beta there was a rapid decrease in the amount of receptor complex retained in the nucleus with time. When extractions using KCI were performed on nuclei after maximal accumulation of receptor complex by oestradiol-17beta or CI-628 the oestrogen receptor complex was found to have a higher relative nuclear affinity than did the CI-628 receptor complex. These studies suggest different nuclear binding sites for these complexes.