Effect of estrogens and antiestrogens on growth of human breast cancer cells in athymic nude mice

Endocrine therapy with estrogen deprivation or with antiestrogens results in tumor regression in a subset of patients with advanced breast cancer. To better understand the mechanisms by which estrogens and antiestrogens modulate breast cancer growth in vivo, we have studied the effects of endocrine manipulation on the development and growth of tumors derived from cultured human breast cancer cells in the athymic nude mouse. MCF-7 breast cancer cells were inoculated into 6-week-old female BALB/c athymic nude mice. Tumor growth did not occur in ovariectomized mice. Cells remained viable, however, since estrogen supplementation more than 30 days later resulted in tumor formation. Minimal tumor growth was observed in intact female nude mice which have low circulating estrogen levels. Tumor development and growth in ovariectomized or intact mice supplemented with 17 beta-estradiol in the form of a s.c. pellet were dose dependent; growth rates increased with estrogen doses ranging from 0.01 to 0.5 mg. Antiestrogen treatment with either tamoxifen or LY156758 caused transient stimulation of tumor growth, followed by a prolonged stationary phase. Growth resumed with estrogen supplementation. Treatment of mice bearing established MCF-7 tumors with estrogen withdrawal (removal of estrogen pellet) resulted in cessation of tumor growth, but not in tumor regression. Growth inhibition was also observed with antiestrogens and was dose dependent. However, tumor regression did not occur, even in mice treated with high doses of tamoxifen (serum concentration of 1.0 microM) for as long as 60 days. Tumor growth was restored in these mice with estrogen replenishment. Tumor cells also remained viable histologically despite prolonged (1 month) estrogen deprivation or antiestrogen therapy, although the mitotic index was markedly reduced. Similar observations were made with mice inoculated with the hormone-responsive ZR75-1 human breast cancer cells, but not with hormone-independent MDA-231 cells which were not influenced by estrogen or antiestrogen treatment. In summary, development and growth of MCF-7 and ZR75-1 tumors in nude mice are estrogen dependent. Endocrine therapy by estrogen deprivation or antiestrogen treatment inhibits tumor cell proliferation in nude mice, but does not cause tumor regression or loss of cell viability.     

Evidence for a direct growth-stimulating effect of estradiol on human MCF-7 cells in vivo

The MCF-7 continuous line of human breast cancer cells requires that athymic nude mice receive supplemental estrogen so that inocula can produce progressively growing tumors. Although these cells contain a typical estrogen receptor complex, the lack of consistent growth stimulation induced by estrogens added to in vitro culture systems has raised the question as to whether this class of hormones acts directly upon the cells or induces a second message produced in other tissues. The present experiments were designed to test the effect of estradiol on the growth of these cells in vivo by exposing them directly to the hormone prior to its absorption into the hepatic portal circulation and subsequent metabolic inactivation. Tumor fragments that were placed next to an estradiol-containing pellet in the spleen grew to produce grossly evident tumor masses, whereas those in the subcutis of the same animals did not, although some minute residua did remain. In the splenic tumors, the mitotic index of the MCF-7 cells immediately adjacent to the estrogen pellets was 2.4 times that of cells on the other side of the same tumor and 3.5 times that of those in the minute s.c. residua. We interpret these data as indicating that in vivo estradiol is acting directly upon the MCF-7 cells to increase their rate of proliferation rather than to initiate the production of a second message to be released into the circulation. Additionally, it was found that s.c. tumors that were decreasing in volume subsequent to withdrawal of systemic estrogen still contained dividing neoplastic cells but with a lower frequency than that seen in progressively growting tumors stimulated with estradiol. This finding indicates that MCF-7 cells can proliferate in vivo in the absence of a substantial amount of estrogen but only at a rate insufficient to sustain progressive tumor growth.     

Antiestrogenic action of toremifene on hormone-dependent, -independent, and heterogeneous breast tumor growth in the athymic mouse

The antiestrogen toremifene has been used to study the growth control of hormone-dependent (MCF-7), -independent (MDA-MB-231), or mixed tumor cell populations in athymic mice. Maximal MCF-7 tumor growth was produced in ovariectomized athymic mice by circulating estradiol levels of approximately 200 pg/ml (produced by 0.5-cm silastic capsules implanted s.c.). The antiestrogen toremifene (77 +/- 4 micrograms/day from a 2-cm silastic capsule) inhibited estradiol (0.5-cm capsule)-stimulated growth by more than 70%. No tumor growth was observed in mice treated with toremifene alone, although toremifene acted as a weak partial agonist on the mouse uterus. The growth of hormone-independent MDA-MB-231 breast tumors implanted in athymic mice was not influenced by either estradiol (0.5-cm capsule) or toremifene (2-cm capsule) when administered alone or in combination. Furthermore, even very large doses of toremifene (5 mg/day p.o.) did not alter the rate of MDA-MB-231 tumor growth. Mixtures of MCF-7 and MDA-MB-231 cells in 9:1 and 99:1 ratios inoculated into athymic mice produced tumors which grew in the absence of estradiol but responded to estradiol supplementation (0.5-cm capsule) with a more rapid rate of tumor growth. Tumors grown from inoculated MCF-7:MDA-MB-231 cells (99:1 ratio) in the presence of estradiol had estrogen receptor levels of 33.2 +/- 9.2 fmol/mg of protein at Day 44 compared to 84.8 +/- 4.8 fmol/mg of protein in pure MCF-7 tumors. Toremifene (2-cm capsule) treatment inhibited the estrogen stimulation of these mixed tumors (99:1 starting ratio) to that of toremifene alone. However, toremifene-alone treatment produced a more rapid rate of tumor growth than control or tumors grown from irradiated MCF-7 cells mixed with viable MDA-MB-231 cells. Increasing the ratio of MCF-7:MDA-MB-231 cells (999:1) initially inoculated resulted in tumors which developed less rapidly than the lower ratio (99:1). Toremifene (2-cm capsule) again produced partial inhibition of 17 beta-estradiol-stimulated tumor growth while increasing tumor growth above control when the antiestrogen was administered alone. These results demonstrate that toremifene is effective in inhibiting estrogen stimulation of hormone-dependent tumors and partially successful at controlling mixed hormone-dependent/independent tumors; however, the antiestrogen cannot control the growth of a hormone-independent tumor in this model.     

125I]17-alpha-iodovinyl 11-beta-methoxyestradiol interaction in vivo with estrogen receptors in hormone-independent MCF-7 human breast cancer transfected with the v-rasH oncogene

[125I]17-alpha-Iodovinyl 11-beta-methoxyestradiol [( 125I]MIVE2) has been evaluated as a potential radiotracer for the diagnostic imaging of estrogen receptor (ER)-positive human breast cancer. In vivo distribution experiments with athymic ovariectomized nude mice bearing human breast tumors revealed an apparent correlation between uptake of 125I-labeled compound and estrogen receptor concentration in the tumors. At 4 h after i.v. injection of [125I]MIVE2, HS578T (ER negative), ZR75-B (intermediate ER), and MCF-7ras (high ER) tumors accumulated 0.320 +/- 0.186, 0.679 +/- 0.467, and 2.6163 +/- 1.0121% injected dose/g, respectively. With coinjection of unlabeled 17-beta-estradiol, levels of radioactivity in MCF-7ras tumors were decreased to 0.4859 +/- 0.1424% injected dose/g, indicating a receptor-mediated process. Peak activity of radioligand in MCF-7ras tumors and uteri was observed at 2 h and was retained for the 8-h time course. Blood and nontarget tissue, such as muscle, revealed a rapid clearance of 125I-labeled compound by 8 h. Eight hours after injection, uterus and tumor-to-blood ratios were calculated to be 225 and 21, respectively. Also, MCF-7ras tumors were shown to accumulate 6.5-fold more radioactivity than muscle. These data suggest that [125I]MIVE2 has the capability of interacting specifically and with high affinity with estrogen receptors in human breast tumors in nude mice and may possibly be used for imaging receptor-positive tumors in breast cancer patients with very low serum estrogen levels. Selective uptake of compound in MCF-7ras tumors emphasizes the usefulness of an estrogen receptor-positive tumor model which has a unique ability to grow in a host system without circulating estrogens.     

Effects of tamoxifen, medroxyprogesterone acetate and estradiol on tumor growth and oncogene expression in MCF-7 breast cancer cell line transplanted into nude mice.

The effects of three hormonal agents with a different mechanism of action (tamoxifen [TAM], medroxyprogesterone acetate [MPA] and estradiol [E2]) on tumor growth, differentiation and oncogene expression were evaluated using the estrogen-receptor positive human breast carcinoma cell line MCF-7 transplanted into nude mice. In MCF-7 tumors treated with E2, tumor incidence, mean weight of tumors, 3H-thymidine labelling index, differentiation antigen HMFGM (human milk-fat globule membrane) and ras p21, c-myc, neu oncogene products, the level was significantly increased. On the other hand MPA suppressed all of them. TAM increased the level of c-myc expression and HMFGM antigen, but suppressed the others. This evidence indicates that E2 induces both proliferation and differentiation of MCF-7 tumor cells. MPA suppresses both proliferation and differentiation, and TAM induces differentiation and suppresses proliferation.     

Estrogen responsive proliferation of clonal human breast carcinoma cells in athymic mice

A clone of MCF-7 (MCF-7ED), a cell in continuous in vitro cultivation derived from an estrogen-responsive human breast carcinoma, requires estrogen supplementation for progressive exponential (doubling time: 50–85 h) tumor growth in the mammary fat of athymic mice. The plasma concentration of estradiol which stimulated exponential growth of MCF-7ED corresponded to physiologic premenopausal levels in women. The tumors were carcinomas with murine and MCF-7ED cells intermixed. MCF-7ED cells could be repurified in subcultures of mixed tumors. Comparative studies of breast and non-breast cell lines showed concordance between the presence of estradiol receptor, sensitivity to the anti-estrogen tamoxifen for growth in vitro, and estradiol dependence for tumorigenic growth in athymic mice. Progesterone alone did not stimulate MCF-7ED growth, but acted synergistically with estrogen. Progesterone's action was to decrease tumor latent period, not to increase final tumor incidence or growth rate. Under estrogen-deficient conditions, conditions approximating postmeno-pausal status in women, (10^?10 M in plasma), a dormant state was established between MCF-7ED cells and murine mammary stroma which could be maintained several months. The dormant state could be broken by introduction of estradiol, but not progesterone. This system should be useful for defining host and cancer cell determinants in estrogen-responsive breast cancer growth.     

Growth properties and tumorigenesis of MCF-7 cells transfected with isogenic mutants of rasH

MCF-7 human breast cancer cells are estrogen dependent for maximal in vitro growth and for tumor formation in nude mice, thus providing a useful model system to study mammary tumorigenesis. A clone of MCF-7 cells transfected with the v-rasH oncogene has been shown to form tumors in the absence of estradiol [Kasid et al., 1985, Science (Wash. DC), 228:725-728]. To extend this observation to more clones of v-rasH-expressing MCF-7 cells and to examine the effects of rasH mutation, we transfected MCF-7 cells with a construct encoding the human c-rasH protooncogene protein product and with three isogenic constructs encoding proteins containing point mutations: arg-12, thr-59, and arg-12 + thr-59 (v-rasH). We isolated several cell lines which produced levels of c-rasH and v-rasH p21 at 30- to 50-fold the levels of controls. We also isolated several cell lines producing the various mutants p21s. All of the transfected cell lines were estrogen-responsive for cell growth. Transfected cells containing high levels of rasH p21 had correspondingly high levels of growth in an anchorage-independent growth assay. Tumorigenesis studies in nude mice, however, showed that some, but not all of the cell lines expressing v-rasH, formed tumors in the absence of estradiol. Tumor formation did not correlate with the level of rasH p21 expression in these cell lines. No tumor formation in the absence of estradiol was observed for cell lines expressing single-mutated or unmutated forms of rasH.     

Secreted growth factors from estrogen receptor-negative human breast cancer do not support growth of estrogen receptor-positive breast cancer in the nude mouse model

Estrogen receptor (ER)-negative MDA-231 human breast cancer cells have been shown to secrete high concentrations of several growth factors including transforming growth factor-alpha and insulin-like growth factor I, which could have important autocrine or paracrine growth regulatory functions and, additionally, could explain the rapid autonomous growth of these cells. In contrast, the hormone-responsive, ER-positive MCF-7 cells secrete low levels of these factors constitutively. Since estrogen treatment increases secretion of these growth factors in MCF-7 cells, it has been postulated that these growth factors mediate estrogen's growth effects through an autocrine mechanism. To test this hypothesis we reasoned that growth factors supplied by MDA-231 cells should support growth of MCF-7 cells in an estrogen-depleted environment. Inoculation of castrated female athymic nude mice with MDA-231 cells resulted in rapid tumor growth. However, MDA-231 tumors did not support growth of MCF-7 cells inoculated on the opposite flank by an endocrine mechanism; MCF-7 tumors required estrogen supplementation for growth. To determine if MDA-231 cells could support MCF-7 growth by a paracrine mechanism, various mixtures of the two cell lines were coinoculated at the same site in castrated or in estrogen-supplemented mice. ER was not detectable in tumors derived from a mixed inoculum, indicating the absence of MCF-7 cell growth. Furthermore, DNA flow cytometry of these tumors revealed only a single G₁ peak representative of MDA-231 cells in estrogen-deprived mice. On the other hand, two distinct G₁ peaks representing both MDA-231 and MCF-7 cells were detected in tumors grown in estrogen-supplemented mice. These data demonstrate that growth factors from estrogen-independent MDA-231 cells are not capable of replacing estrogen for growth stimulation of MCF-7 cells. Either estrogen-stimulated growth of MCF-7 cells requires other secreted factors not supplied by MDA-231 cells, or it involves a different mechanism.     

Overexpression of vascular endothelial growth factor by MCF-7 breast cancer cells promotes estrogen-independent tumor growth in vivo

Alteration of the phenotype of breast cancers from estrogen-dependent to estrogen-independent growth often leads to the failure of antiestrogenic tumor therapies. We report that overexpression of vascular endothelial growth factor (VEGF) by estrogen-dependent MCF-7 breast cancer cells could abolish estrogen-dependent tumor growth in ovariectomized mice. In the absence of estrogen, MCF-7 VEGF-expressing tumors with increased vessel density showed growth kinetics similar to, or even greater than, that of parental MCF-7 tumors with estrogen supplementation. Overexpression of VEGF by MCF-7 cells or treatment on parental MCF-7 cells with recombinant VEGF also stimulated cell proliferation in culture. Our data suggest that VEGF stimulation of MCF-7 tumor angiogenesis and growth is mediated by both autocrine and paracrine mechanisms.     

Biological differences among MCF-7 human breast cancer cell lines from different laboratories

Summary MCF-7 human breast cancer cells are used widely for studies of tumor biology and hormone mechanism of action. Conflicting results have often been obtained in studies reported from different laboratories. In this report several biological properties were studied in four MCF-7 cell lines obtained from different laboratories. MCF-7 (ATCC), MCF-7, MCF-7 (KO), and MCF-7 (S) demonstrated similar morphology in monolayer culture. Chromosome analysis revealed that three of the lines shared several structural chromosome alterations and marker chromsomes; however, MCF-7 (ATCC) was distinctly different with virtually no chromosomal alterations shared in common with the other lines. All four lines contained variable amounts of estrogen receptor (ER) and progesterone receptor (PgR). The growth rate of MCF-7 (ATCC) was 50% slower than that of the other lines, and, unlike the other three lines, cell proliferation was unaffected by estrogen or antiestrogen treatment despite the presence of receptors. Cloning efficiency of the four lines varied over a 10-fold range. Tumorigenicity in athymic nude mice also varied considerably among these lines. MCF-7 (ATCC) grew well in ovariectomized nude mice, while the other lines required estrogen supplementation. MCF-7 (S) and MCF-7 grew rapidly with estrogen supplementation; MCF-7 (KO) grew very slowly. Antiestrogen therapy inhibited growth of MCF-7, MCF-7 (S), and MCF-7 (KO) tumors, but it had no effect on MCF-7 (ATCC). These data demonstrate that MCF-7 lines from different laboratories may have unique biological properties, despite having a similar karyotype (MCF-7, MCF-7 (S), MCF-7 (KO)). The fundamental differences in karyotype and biological properties of the MCF-7 (ATCC), and the previously reported differences in DNA restriction fragment polymorphism analyses, demonstrate that this line is derived from an entirely different patient. Investigators should carefully document the source and identity of MCF-7 cells used in published experiments.     

The process of malignant progression in human breast cancer

Malignant progression in breast cancer represents the processes through which localized, hormone-dependent tumor cells become resistant to endocrine manipulations and metastasize to sites distant from the primary tumor. By selection in ovariectomized athymic nude mice, we have isolated a variant (MIII) of the hormone-dependent, poorly invasive, human breast cancer cell line MCF-7. MIII cells have lost their absolute requirement for estrogen to form proliferating tumors in nude mice. Furthermore, these tumors are significantly more invasive than the parental MCF-7 cell line. MIII cells retain some responsivity to estrogens and antiestrogens, indicating that they have progressed to a hormone-independent but hormone-esponsive phenotype. In an attempt to determine the nature of this process, we have compared the phenotype of MIII cells with that of other MCF-7 variants. These comparisons strongly suggest that the factors contributing to perturbations in antiestrogen sensitivity, hormone-dependent growth, metastatic potential and tumorigenicity are essentially independent of each other and acquired in a random manner. Loss of estrogen receptor expression and overexpression of EGF receptors tend to occur later in the process of malignant progression.     

Melatonin does not inhibit estradiol-stimulated proliferation in MCF-7 and BG-1 cells

Melatonin, an indolic pineal hormone, is produced primarily at night in mammals and is important in controlling biological rhythms. Previous research suggested that melatonin can attenuate proliferation in the estrogen-responsive MCF-7 breast cancer cell line. We tested whether these anti-proliferative effects may have physiological consequences upon two estrogen-responsive cell lines, MCF-7 (a breast cancer cell line) and BG-1 (an ovarian adenocarcinoma cell line). Melatonin (10(-9)- 10(-5) M) attenuated proliferation of MCF-7 and BG-1 cells by >20% in the absence of estrogen. However, 17beta-estradiol exposure negated the ability of melatonin to inhibit proliferation. To substantiate this finding, cells were estrogen starved followed by multiple treatments with estradiol and melatonin. Melatonin did not inhibit estradiol- stimulated proliferation under this protocol. Estradiol increased MCF-7 and BG-1 cell cycle transition from G1 to S phase, however, melatonin did not inhibit this transition nor did it down-regulate estradiol- induced pS2 mRNA levels measured by northern blotting, further indicating that melatonin was unable to attenuate estradiol-induced proliferation and gene expression. We also examined the effects of melatonin on estradiol-induced proliferation in MCF-7 cell xenografts in athymic nude mice. Melatonin at a dose 28 times greater than 17beta- estradiol did not inhibit estradiol-induced proliferation in vivo. Furthermore, pinealectomy did not increase proliferation. Therefore, we conclude that melatonin does not directly inhibit estradiol-induced proliferation.      

Estrogen induced growth of human breast cancer cells (MCF-7) in athymic nude mice is enhanced by secretions from a transplantable pituitary tumor

MCF-7, a human breast carcinoma cell line, was maintained s.c. in female athymic nude mice for a period of 5–6 weeks. Administration of estrogen (s.c. pellet of 17β-estradiol and estrone in drinking water, 0.5 mg/l) to these mice resulted in sustained (P < 0.001) growth of MCF-7 tumors. Grafting of a prolactin and growth hormone secreting rat pituitary tumor to the estrogen-treated mice resulted in an increased (P < 0.05) rate of MCF-7 tumor growth. MCF-7 did not grow in athymic nude mice grafted with rat pituitary tumor alone or in mice without hormone treatment (controls). Thus, secretions of pituitary hormones alone are not capable of promoting in vivo growth of MCF-7 although such secretions significantly enhance estrogen-induced growth of this cell line. A synergism between pituitary hormones and estrogen for in vivo growth of a human breast carcinoma has been demonstrated in this study.     

Regulation of human estrogen receptor gene, epidermal growth factor receptor gene, and oncogenes by estrogen and antiestrogen in MCF-7 breast cancer cells

It is generally believed that estrogen may act either as an initiator or as a promoter in carcinogenesis of human breast cancer. This estrogenic action is generally dependent on the estrogen receptor. In the human estrogen receptor, cDNA has a homology to V-erb-A oncogene. Experiments using MCF-7 human breast cancer cells were carried out to study the regulatory effect of estrogen and antiestrogen on RNA activities of oncogenes, estrogen receptor gene, and epidermal growth factor (EGF) receptor gene. The effect of estradiol on activation of estrogen and EGF receptor genes and myc, ras, and fos oncogenes was positive in relation to the concentrations of supplemented estradiol. In addition, the effects of antiestrogen (tamoxifen) were investigated. Tamoxifen suppressed MCF-7 cell growth, and spot hybridization of the RNA of MCF-7 cells revealed that RNA activities of estrogen and EGF receptor genes and myc, ras, and fos oncogenes were suppressed by tamoxifen. These results suggest that the three oncogenes and two receptor genes are partly regulated by estrogen and antiestrogen (tamoxifen) in MCF-7 human breast cancer cells. This regulatory system may have a role in carcinogenesis and in the treatment of human breast cancer.     

Effect of estrogen and antiestrogen on the human breast cancer cell line MCF-7 adapted to growth at low serum concentration

The human breast cancer cell line MCF-7 has been adapted to long-term growth at 0.5 and 0.05% fetal bovine serum. Free cytoplasmic and filled nuclear estrogen receptors were found in cells grown at 5, 0.5, and 0.05% fetal bovine serum. Cells grown in medium with 0.05% dextran-charcoal-treated serum contained cytoplasmic receptors but no filled nuclear receptors, indicating that this medium did not contain biologically active concentrations of estrogen. Addition of estradiol to the medium translocated the cytoplasmic receptor to the nucleus and stimulated progesterone receptor synthesis but did not increase the growth rate. The antiestrogen tamoxifen (TAM) inhibited cell growth at all serum concentrations investigated, at least in part by a reduction of the growth fraction. The sensitivity to TAM was highest at low serum concentrations. The effect of TAM could be reversed by estradiol at TAM concentrations of 10(-6) M or lower. It is concluded that estradiol does not have a direct growth-stimulatory effect on our MCF-7 cells in monolayer cultures although the cells contain functional estrogen receptors and growth of the cells in athymic mice requires estrogens. TAM has an estrogen-competitive, inhibitory effect on the growth of MCF-7 cells at concentrations lower than 10(-6) M. At higher concentrations, the growth inhibition is unspecific and noncompetitive by estradiol.     

Proliferation, hormonal responsiveness, and estrogen receptor content of MCF-7 human breast cancer cells grown in the short-term and long-term absence of estrogens

We have examined the effect of short-term and long-term growth in the absence of estrogens on the proliferation rate and estrogen and antiestrogen responsiveness of MCF-7 human breast cancer cells. The removal of phenol red, the pH indicator in tissue culture medium that is weakly estrogenic (Y. Berthois et al., Proc. Natl. Acad. Sci. USA, 83:2496-2500, 1986), immediately slows the cell proliferation rate, and MCF-7 cells grown in phenol red-free medium with charcoal dextran-treated serum for periods up to 1 mo maintain this reduced rate of cell proliferation. In these short-term phenol red-withdrawn cells, estradiol stimulates proliferation markedly and reproducibly, and antiestrogens inhibit estrogen-stimulated proliferation. Antiestrogens by themselves appear as partial agonists/antagonists; at low concentrations they stimulate proliferation weakly, but they show no stimulation at the high concentrations where they fully inhibit estrogen-stimulated proliferation. In contrast to the short-term phenol red-withdrawn cells, cells maintained for several months (5 to 6 mo) in the apparently complete absence of estrogens (no phenol red, with charcoal dextran-treated calf serum) show a markedly increased basal rate of cell proliferation; estradiol is unable to increase this rate of proliferation further, but antiestrogens are able to decrease proliferation. This change in growth pattern is associated with a 3-fold increase in cellular estrogen receptor levels. Despite their differing basal growth rates, cells grown in either the short-term (less than 1 mo) or long-term (greater than 6 mo) absence of estrogens both have progesterone receptor levels that are very low and, in both cases, estradiol increases progesterone receptor levels markedly. Thus, under long-term estrogen-free conditions, there is a dissociation between the stimulation of cell proliferation and of specific protein synthesis (progesterone receptor) by estrogen. The increase in the cell proliferation rate observed in cells grown in the long-term absence of estrogen may reflect altered regulation of growth factor production or altered sensitivity to growth factors in the medium or produced by the cells themselves. Hence, these breast cancer cells adapt significantly to long-term growth in estrogen-free conditions, an observation that may be relevant to understanding the growth of hormone-responsive human breast cancers in vivo.     

Long-term cultivation of a human breast cancer cell line, MCF-7, in a chemically defined medium. Effect of estradiol

The human breast cancer cell line, MCF-7, has been adapted to long-term growth in chemically defined medium without loss of estrogen and progesterone receptors or tumorigenicity in athymic mice. An estrogen reversible inhibition of cell proliferation is exerted by newborn calf serum (NCS) 10%, athymic mouse serum (AMS) 2% or tamoxifen 0.1 to 1.0 microM. The mamma-related hormones, hydrocortisone, progesterone, prolactin, and insulin could not mimic this growth inhibitory effect, and estradiol alone or combined with these hormones did not stimulate cell proliferation in chemically defined medium.     

Mammalian lignans enterolactone and enterodiol, alone and in combination with the isoflavone genistein, do not promote the growth of MCF-7 xenografts in ovariectomized athymic nude mice

This study determined the effect of the mammalian lignans enterolactone (ENL) and enterodiol (END) alone and in combination with the isoflavone genistein (GEN) on the growth of MCF-7 tumors in ovariectomized nude mice. Ovariectomized athymic nude mice with established MCF-7 tumors were fed a basal diet (AIN-93G) and divided into 5 groups that received daily subcutaneous injections (10 mg/kg body weight (BW)) of ENL, END, GEN, a mixture of these compounds (MIX), or vehicle as a negative control for 22 weeks. A positive control group was implanted with an estradiol pellet in order to establish an estrogenic tumor growth response. In the ENL- and END-treated mice, palpable tumors regressed significantly by 91 and 83%, respectively, resulting in final tumors that were similar to the negative control tumors. However, tumor cell apoptosis was significantly enhanced by the lignans. In the GEN-treated mice, tumors initially regressed significantly by 64% but regression ceased following prolonged treatment, resulting in final tumors that were significantly larger compared to negative control, ENL-, and END-treated mice, in part by increasing tumor cell proliferation. The MIX treatment significantly regressed palpable tumors by 87% similar to negative control group, with no effects on tumor cell apoptosis or proliferation. The isoflavone GEN alone promoted the growth of established MCF-7 human breast cancer xenografts after prolonged treatment while the mammalian lignans ENL and END did not. When these phytoestrogens were given in combination, no tumor growth-promoting effects were observed. (c) 2005 Wiley-Liss, Inc.     

Characterization of estrogen and progesterone receptors and the dissociated regulation of growth and progesterone receptor stimulation by estrogen in MDA-MB-134 human breast cancer cells

We have examined the properties of the estrogen receptor and progesterone receptor in MDA-MB-134 human breast cells and have evaluated the effects of estrogen on cell proliferation and progesterone receptor levels in these cells as indices of hormonal sensitivity. These cells contain high levels of estrogen receptor (approximately 1.5 pmol/mg DNA) and low levels of progesterone receptor (0.15 pmol/mg DNA). More than 80% of the estrogen receptor is found in the nuclear fraction in the absence of estrogen, and the Kd of the receptor for estradiol is approximately 1.5 X 10(-10) M. Upon exposure to estradiol, the receptors become occupied, but there is no processing or apparent decrease in either nuclear or total cellular estrogen receptor content, as can be seen in MCF-7 human breast cancer cells. The nuclear estrogen receptor sediments as a 4.6 S species on high salt sucrose gradients, and it can be detected on sodium dodecyl sulfate-polyacrylamide gel immunoblot analysis as a species of molecular weight 65,000, identical to that of the MCF-7 estrogen receptor, using the monoclonal antibodies D75P3 gamma and H222Sp gamma prepared against the MCF-7 estrogen receptor. The estrogen receptor shows binding selectivity for estrogens and antiestrogens, and its affinity for ligands follows the order diethylstilbestrol (190%) greater than estradiol (100%) greater than estriol (13%) greater than tamoxifen (3%), as expected for estrogen receptor. Hence the receptor appears normal in many of its physicochemical properties and in terms of its binding affinity and specificity for estrogens and antiestrogens. Control cells contain low levels of progesterone receptor that display high affinity (Kd = 6 X 10(-9) M) for the synthetic progestin R5020, but exposure to estradiol (10(-11)-10(-7)M) fails to increase cellular progesterone receptor levels. In contrast, estradiol markedly stimulates the rate of cell proliferation, while tamoxifen suppresses the growth of control and of estradiol treated cells. Hence, our data show that these cells, which contain substantial levels of estrogen receptor, respond to estrogen with enhanced cell proliferation but fail to have their progesterone receptor level modulated by estradiol. These cells represent an interesting and unusual situation in which estrogenic regulation of proliferation and the stimulation of progesterone receptor are dissociated. These cells should prove useful in further evaluation of estrogenic regulation of cell proliferation and specific protein synthesis in human breast cancer.