Synthesis and biological evaluation of 2,3-diaryl isoquinolinone derivatives as anti-breast cancer agents targeting ERα and VEGFR-2

The estrogen receptor α is recognized as important pharmaceutical target for breast cancer therapy, and vascular endothelial growth factor receptors (VEGFRs) play important roles in tumor angiogenesis including breast cancer. A series of 2,3-diaryl isoquinolinone derivatives were designed and synthesized targeting both estrogen receptor α (ERα) and VEGFR-2. Bioactivity evaluation showed that compounds 7c, 7d and 7f exhibited significant anti-proliferative and anti-angiogenesis activities via ERα and VEGFR-2 dependent mechanisms.     

Evaluation of synthetic isoflavones on cell proliferation, estrogen receptor binding affinity, and apoptosis in human breast cancer cells

Natural isoflavones have demonstrated numerous pharmacological activities in breast cancer cells, including antiproliferative activities and binding affinities for estrogen receptors (ERs). Chemical modifications on the isoflavone ring system have been prepared and explored for the development of new therapeutics for hormone-dependent breast cancer. The antiproliferative actions of the synthesized isoflavones on MCF-7 and MDA-MB-231 breast cancer cells were examined, as well as cytotoxicity, interaction with estrogen receptors, and proapoptotic activity. The compounds were screened in the absence and in the presence of estradiol to evaluate whether or not estradiol could rescue cell proliferation on MCF-7 cells. Several compounds were able to inhibit cell proliferation in a dose-dependent manner, and compounds containing the bulky 7-phenylmethoxy substituent resulted in cell toxicity not only in MCF-7 cells but also in MDA-MB-231 cells. Selected synthetic isoflavones were able to bind to estrogen receptor with low affinity. Apoptotic pathways were also activated by these compounds in breast cancer cells. The majority of the compounds can bind to both ERs with low affinity, and their effects on hormone-independent breast cancer cells suggest that their ability to inhibit cell growth in breast cancer cells is not exclusively mediated by ERs. Thus, the synthetic trisubstituted isoflavones act on multiple signaling pathways leading to activation of mechanisms of cell-death and ultimately affecting breast cancer cell survival.     

Analogies and differences in the modulation of progesterone receptor induction and cell proliferation by estrogens and antiestrogens in MCF-7 human breast cancer cells: study with 24 triphenylacrylonitrile derivatives

Structure-activity relationships in a homogeneous series of 24 triphenylacrylonitrile derivatives were examined with respect to the stimulation of progesterone receptor induction and cell proliferation in MCF-7 cells. In general, triphenylacrylonitrile derivatives were found to be full or partial agonists for both responses; the partial agonists were also able to antagonize the stimulatory action of estradiol. The agonistic activities of these molecules decreased as the size of the lateral side chain increased, but the side-chains correlated with partial agonism of progesterone receptor induction were bulkier than those correlated with partial agonism of cell proliferation. Agonistic and antagonistic effects on both responses were correlated with affinity for the estrogen receptor. Half maximal effects on the two responses occurred at different concentrations (4-fold) of the compounds. It can be concluded that in MCF-7 cells, triphenylacrylonitrile modulation of progesterone receptor induction and cell proliferation are mediated by the estrogen receptor; the two effects, which occur at different concentrations and with slightly different substituents of the compounds, are differentially modulated.     

Diaryl naphthyl methanes a novel class of anti-implantation agents

Diaryl naphthyl methanes and the corresponding 1, 2, 3, 4- and 5, 6, 7, 8-tetrahydro naphthyl methane derivatives have been synthesized as novel estrogen receptor binding ligands. The secondary and tertiary amino alkoxy derivatives of diaryl naphthyl and tetrahydro naphthyl methane interact with the estrogen receptor to elicit promising estrogenic, antiestrogenic and implantation inhibition activities in rats. The most active compounds in this series are 7, 9 and 20, cent percent active in preventing implantation in rats at 2.5 mgkg(-1) dose.     

Development of a stable dual cell-line GFP expression system to study estrogenic endocrine disruptors

Environmental estrogenic endocrine disruptors are a health concern. Here we constructed a dual cell-line green fluorescence protein (GFP) expression system to identify and study endocrine disrupting compounds with activities of estrogen receptor agonists or antagonists. Human breast cancer MCF-7 cells and endometrial carcinoma Ishikawa cells were infected with a two tandem estrogen response elements--E4 promoter-GFP reporter gene construct. The use of GFP reporter enabled direct and simple evaluations of cell responses. GFP intensity in stably transfected MCF7-GFP and Ishikawa-GFP cells was dose-responsive to 17-beta-estradiol, diethylstilbestrol, 2-hydroxyestradiol, and environmental toxins bisphenol A, genistein and o-p'-DDT. Raloxifene and tamoxifen were effective antiestrogens in MCF7-GFP cells, but acted as partial estrogen receptor agonists in Ishikawa-GFP cells at concentrations of 0.1 nM and above. No synergistic effect was observed in chemical combinations between organochlorine pesticides methoxychlor, o-p'-DDT, p-p'-DDT, nor between estradiol and estrone. In summary, for the first time the effects of estrogen receptor agonists or antagonists were compared between mammary and endometrial cancer cells both stably expressing identical plasmids with GFP reporter genes under the control of tandem estrogen response elements. This dual cell-line system provides a rapid method and sensitive assay to identify environmental estrogens, antiestrogens, selective estrogen receptor modulators and to study their tissue specific effects and chemical interactions. Such a system is especially useful for direct and parallel toxicity assessments with a microfluidic cell culture device.     

Cytotoxic small molecule dimers and their inhibitory activity against human breast cancer cells

Small molecules based upon natural product dimers that exhibit cytotoxic activity were synthesized and evaluated for their anti-proliferative activity in human breast cancer cell lines. A central isophthalic core structure linking aromatic amines containing 3,5-disubstitutions produced the most active compounds. This series of compounds was found to be more active against the estrogen receptor positive cell line MCF-7 than the estrogen receptor negative cell line, SKBr3.     

Differential activation of wild-type and variant forms of estrogen receptor alpha by synthetic and natural estrogenic compounds using a promoter containing three estrogen-responsive elements

Structure-dependent estrogen receptor alpha (ER alpha) agonist and antagonist activities of synthetic and natural estrogenic compounds were investigated in human HepG2, MDA-MB-231 and U2 cancer cell lines. Compounds used in this study include 4'-hydroxytamoxifen, ICI 182,780, bisphenol-A (BPA), 2',4',6'-trichloro-4-biphenylol (3Cl-PCB-OH), 2',3',4',5'-tetrachloro-4-biphenylol (4Cl-PCB-OH), p-t-octylphenol, p-nonylphenol, naringenin, kepone, resveratrol, and 2,2-bis(p-hydroxyphenyl)-1,1,1-trichloroethane (HPTE). Cells were transfected with a construct (pERE(3)) containing three tandem estrogen responsive elements (EREs) and either wild-type estrogen receptor alpha (ER-wt) or variants expressing activation function-1 (ER-AF1) or AF-2 (ER-AF2). The ER agonist activities of the synthetic mono and dihydroxy aromatic compounds are comparable in all three-cell lines, whereas the activities of naringenin, kepone and resveratrol are dependent on cell context and expression of wild-type or variant forms of ER alpha. In contrast, the ER antagonist activities for these compounds were highly complex and, with the exception of 3Cl-PCB-OH, all compounds inhibited E2-induced wild-type or variant ER action. Results of this in vitro study suggest that the estrogenic and antiestrogenic activity of structurally diverse synthetic and natural estrogenic compounds is complex, and this is consistent with published data that often give contradictory results for these compounds.     

Rapid synthesis of 4-benzylidene and 4-[bis-(4-methoxyphenyl)-methylene-2-substituted phenyl-benzopyrans as potential selective estrogen receptor modulators (SERMs) using McMurry coupling reaction

7-Methoxy-4-(4-methoxybenzylidene)-2-substituted phenyl-benzopyrans I and 4-[bis-(4-methoxyphenyl)-methylene-2-substituted phenyl-benzopyrans II carrying different alkylamino residues, designed as estrogen receptor (ER) binding ligands, were successfully synthesized through the McMurry coupling reaction of substituted benzaldehyde/substituted benzophenones and 2-hydroxyphenyl-7-methoxy-chroman-4-one in presence of lithium aluminum hydride and titanium (IV) chloride (LAH-TiCl(4)). Self-coupling of carbonyl reactants led to the formation of several side products. The prototypes were evaluated for their relative binding affinity (RBA), as well as their estrogenic and antiestrogenic activities. High order of estrogenic activity (>50% gain) observed with compounds 3, 7a, 7b, 7c, 8, and 10a and also their partial estrogen antagonistic activity (> or =15%) at the uterine level points toward successful designing of the compounds. Compounds 4, 7a, 7b, 7c, and 10a also possessed significant anticancer activity against human adenocarcinoma cell line (MCF-7 cell line) that may be related to their estrogen-dependent action.     

Structure-activity relationships of estrogens. Effects of 14-dehydrogenation and axial methyl groups at C-7, C-9 and C-11

Thirty compounds were evaluated in the rat for uterotropic effects, inhibition of gonadotropin release, and competitive displacement of (3H) estradiol-17 beta from uterine cytosolic preparations. 7 alpha-Methylestradiol-17 beta was 150% as active as estradiol-17 beta as an uterotropic agent. Estradiol-17 beta was the most active inhibitor of gonadotropin release. 11 beta-Methylestradiol-17 beta had 124% of the activity of estradiol-17 beta in displacing (3H) estradiol-17 beta from the "estrogen receptor." The 9 alpha-methyl group considerably decreased the potency of estrogens in any of the three assays. The 14-dehydro modification was advantageous only in the estradiol-17 beta 3-methyl ether series. Uterotropic activities and inhibition of gonadotropin release did not parallel. The best compound for inhibiting gonadotropin release, as compared to uterotropic activity, was estrone. The "estrogen receptor" assay data correlated fairly well with uterotropic assay data, but only for compounds having free 3-hydroxyl groups; even so, some exceptions were noted.     

Promising core structure for nuclear receptor ligands: design and synthesis of novel estrogen receptor ligands based on diphenylamine skeleton

Novel diphenylamine-type estrogen receptor ligands were designed and synthesized, and their biological activities were evaluated by means of binding assays for estrogen receptor-alpha and -beta and cell proliferation assay using MCF-7 cells. Compounds 4f, 11b, 12c, and 8 showed moderate estrogenic activities. We propose that the diphenylamine skeleton may be a privileged structure for various nuclear receptor ligands, including RAR, RXR, and AR ligands.     

Estrogenic properties of isoflavones derived from Millettia griffoniana.

In most developing countries, 70-80% of the population still resort to traditional medicine for their primary health care. This medicine utilises medicinal plants which are traditionally taken as concoction and infusion. The root and stem bark of Millettia griffoniana (Leguminosae), has been reported to contain isoflavonoids, alkaloids, and diterpenoids. The possible benefit of some bioactive isoflavones derived from M. griffoniana prompted us to screen them for estrogenic activity. Six isoflavones and coumarin derived from M. griffoniana (bail) namely, compound nos. 1-6 (Fig. 1) were tested for their potential estrogenic activities in three different estrogen receptor alpha (ERalpha)-dependent assays. In a yeast-based ERalpha assay, all test substances and 17beta-estradiol as endogenous agonist, showed a significant induction of beta-galactosidase activity. The test compounds at the concentration of 5 x 10(-6) M could achieve 59-121% of the beta-galactosidase induction obtained with 10(-8) M 17beta-estradiol (100%). In the reporter gene assay based on stably transfected MCF-7 cells (MVLN cells), the estrogen responsive induction of luciferase was also stimulated by the M. griffoniana isoflavones. In Ishikawa cells, all substances exhibited estrogenic activity revealed by the induction of alkaline phosphatase (AlkP) activity. The estrogenic activities of isoflavones from M. griffoniana could be completely suppressed by the pure estrogen antagonist, ICI 182,780, suggesting that the compounds exert their activities through ERalpha. Although all substances showed estrogenic effects, 4'-methoxy-7-O-[(E)-3-methyl-7-hydroxymethyl-2,6-octadienyl]isoflavone (7-O-DHF), Griffonianone C (GRIF-C), and 3',4'-dihydroxy-7-O-[(E)-3,7-dimethyl-2,6-octadienyl]isoflavone (7-O-GISO) were found to be the most potent of tested substances. In summary, estrogenic activities of the isoflavones derived from M. griffoniana were described for the first time using reporter gene assays and the estrogen-inducible AlkP Ishikawa model.     

Benzothiepin-derived molecular scaffolds for estrogen receptor modulators: synthesis and antagonistic effects in breast cancer cells

A series of novel benzothiepin-derived compounds are described as potent selective modulators of the human estrogen receptor (SERMs). The objective of the study is to evaluate the antiproliferative effects of the compounds on human MCF-7 breast tumor cells. These heterocyclic compounds contain the traditional triarylethylene arrangement exemplified by tamoxifen, conformationally restrained through the incorporation of the benzothiepin ring system. The compounds demonstrated potency at nanomolar concentrations in antiproliferative assays against an MCF-7 human breast cancer cell line with low cytotoxicity. The compounds exhibited low nanomolar binding affinity for the estrogen receptor (ER) with some specificity for ERβ, and also demonstrate potent antiestrogenic properties in the human uterine Ishikawa cell line. The effect of a number of functional group substitutions on the ER binding properties of the benzothiepin molecular scaffold is explored through a brief computational structure-activity relationship investigation with molecular simulation.     

Benzothiepin-derived molecular scaffolds for estrogen receptor modulators: synthesis and antagonistic effects in breast cancer cells

A series of novel benzothiepin-derived compounds are described as potent selective modulators of the human estrogen receptor (SERMs). The objective of the study is to evaluate the antiproliferative effects of the compounds on human MCF-7 breast tumor cells. These heterocyclic compounds contain the traditional triarylethylene arrangement exemplified by tamoxifen, conformationally restrained through the incorporation of the benzothiepin ring system. The compounds demonstrated potency at nanomolar concentrations in antiproliferative assays against an MCF-7 human breast cancer cell line with low cytotoxicity. The compounds exhibited low nanomolar binding affinity for the estrogen receptor (ER) with some specificity for ERbeta, and also demonstrate potent antiestrogenic properties in the human uterine Ishikawa cell line. The effect of a number of functional group substitutions on the ER binding properties of the benzothiepin molecular scaffold is explored through a brief computational structure-activity relationship investigation with molecular simulation.     

Topographic recognition of cyclic hydrocarbons and related compounds by receptors for androgens, estrogens, and glucocorticoids

The structural requirements for the interaction of about 80 cyclic hydrocarbons and related compounds with the androgen receptor of rat ventral prostate, the estrogen receptor of human breast tumor MCF-7 cells, and the glucocorticoid receptor of rat liver were examined by comparing their abilities to compete with radioactive hormones for binding to the respective receptors. The results indicate that the receptor-binding affinity of a compound is dependent on its electronic configuration and geometrical similarity to a portion of a natural steroid hormone which can be recognized by local ligand-binding sites in the receptor. For the estrogen receptor, beta-phenols are more active than the corresponding alpha-phenols, whereas nonphenolic compounds are totally inactive. For androgen and glucocorticoid receptors, alpha-phenols are more active than beta-phenols. The androgen receptor can interact stereospecifically with nonoxygenated and nonalkylated cyclic hydrocarbons, such as 10,11-dihydro-5H-dibenzo[a,d] cycloheptene or 9,10-dihydrophenanthrene, which can, in vivo, inhibit the androgen-dependent growth of the male accessory reproductive organs. The affinities of naphthalene, anthracene, phenanthrene, biphenyl, and adamantane toward glucocorticoid and androgen receptors can be enhanced by acetylation or ethanolization of these ligands. Our results also indicate that, while the hormonal action of a steroid may be dependent on the interaction of a functional group on the hormone with a specific group on the receptor, the presence of such a group may not be required for the antagonistic activity of a compound that can physically block hormone binding to the receptor. Thus, many small molecules that were hitherto considered to be biologically inert may interact with steroid receptors specifically and affect hormonal activities in vivo.     

m-Carborane bisphenol structure as a pharmacophore for selective estrogen receptor modulators

A series of m-carborane derivatives was prepared based upon the structures of antiestrogenic drugs and their activities were evaluated by estrogen receptor alpha (ERalpha) binding assay and transactivation assay using human breast cancer cell line, MCF-7 cells. The m-carborane bisphenol 5 exhibited about a thousand times more potent ER agonistic activity than the o-carborane bisphenol 11. The m-carborane bisphenol structure appears to be a favorable hydrophobic pharmacophore for the development of novel selective estrogen receptor modulators (SERMs).     

A bacterial biosensor of endocrine modulators

The nuclear hormone receptors comprise one of the largest classes of protein targets for drug discovery, as their function has been linked to a variety of serious diseases, including several forms of cancer. Identifying novel compounds with the ability to modulate the function of these targets could lead to the development of effective therapeutics. In vivo sensors of ligand binding have emerged as tools that can greatly accelerate the lead identification process, allowing new drugs to be discovered more rapidly and cheaply. In this work, a novel sensor of nuclear hormone binding has been developed in Escherichia coli by constructing a fusion of the ligand-binding domain of the human estrogen receptor with a thymidylate synthase enzyme (TS). Expression of this fusion protein in TS-deficient bacterial cells resulted in growth phenotypes that were dependent on the presence of estrogen. Subsequent replacement of the estrogen receptor with the ligand-binding domain of the human thyroid hormone receptor led to specific thyroid hormone-enhanced growth that was insensitive to estrogen. This biosensor was then challenged with a small library of estrogen and thyroid hormone analogues, and it was observed that levels of cell growth correlate well with ligand-binding affinity. Remarkably, this simple biosensor was able to discriminate between agonistic and antagonistic activities, as combinations of estrogen agonists had an additive impact on cell growth, whereas known estrogen antagonists were found to neutralize agonist effects. This system constitutes a technique for facile selection of lead compounds with potential medical applications.     

SERMs and SARMs: Detection of their activities with yeast based bioassays

Selective estrogen receptor modulators (SERMs) and selective androgen receptor modulators (SARMs) are compounds that activate their cognate receptor in particular target tissues without affecting other organs. Many of these compounds will find their use in therapeutic treatments. However, they also will have a high potential for misuse in veterinary practice and the sporting world. Here we demonstrate that yeast estrogen and androgen bioassays can be used to detect SERMs and SARMs, and are also useful screening tools to investigate their mode of action. Six steroidal 11β-substituents of E2 (SERMs) and some arylpropionamide- and quinoline-based SARMs were tested. In addition, 7 compounds previously tested on AR agonism and determined as inactive in the yeast androgen bioassay, while QSAR modelling revealed strong binding to the human androgen receptor, are now shown to act as AR antagonists.