BG-1 ovarian cell line: An alternative model for examining estrogen-dependent growth in vitro

Summary Examination of estrogen-responsive processes in cell culture is used to investigate hormonal influence on cancer cell growth and gene expression. Most experimental studies have used breast cancer cell lines, in particular MCF7 cells, to investigate estrogen responsiveness. In this study we examined an ovarian cancer cell line, BG-1, which is highly estrogen-responsive in vitro. This observation, plus the fact that the cells are of ovarian rather than mammary gland origin, makes it an attractive alternative model. 17β-Estradiol, epidermal growth factor, and insulin-like growth factor induced proliferation of BG-1 and MCF7 cells. Viability was dependent on these growth factors in BG-1 cells, but not in MCF7 cells. Therefore, we examined the differences between these two cell lines with respect to estrogen and growth factor receptors. BG-1 cells have twice as many estrogen receptors as MCF7 cells, and BG-1 cells have higher insulin-like growth factor-1 and epidermal growth factor receptor levels than MCF7 cells. This may also explain why BG-1 cells proliferate 56% more robustly in serum and show more serum dependence in culture. In both BG-1 and MCF7 cells, epidermal growth factor receptor number is low (<20 000/cell), while insulin-like growth factor-1 receptor level was highest in estrogen receptor positive cell lines. For example, insulin-like growth factor-1 receptor was higher in BG-1 and MCF7 cells than in estrogen receptor negative cells (HeLa>MDA-MB-435>HBL100). In conclusion, BG-1 cells are an excellent model for understanding hormone responsiveness in ovarian tissue and an alternative for examining estrogen receptor-mediated and insulin-like growth factor-1/epidermal growth factor/estrogen cross-talk processes because of their sensitivity to these factors.     

The potential role of estrogen in aromatase regulation in the breast

Aromatase is expressed in both normal and malignant breast tissues. Aromatase activity in the breast varies over a wide range. Our previous studies have demonstrated that in situ aromatization contributes to the estrogen content of breast tumors to a major extent. Consequently, alterations of aromatase activity could serve as a major determinant of tissue estradiol content. However, the mechanisms and extent of aromatase regulation in breast tissues have not been fully established. We have observed an inverse correlation between tumor aromatase activity and estrogen content in nude mice bearing xenografts of MCF-7 cells transfected with the aromatase gene. To investigate the potential role of estrogen in aromatase regulation in the breast, studies were carried out in an in vitro model. In this model, MCF-7 cells were cultured long term in estrogen-deprived medium and called by the acronym, LTED cells. We found that long-term estrogen deprivation enhanced aromatase activity by 3–4-fold when compared to the wild-type MCF-7 cells. Re-exposure of LTED cells to estrogen reduced aromatase activity to the levels of the wild-type MCF-7 cells. We also measured aromatase activity in 101 frozen breast carcinoma specimens and compared tumor aromatase activities in pre-menopausal patients versus post-menopausal patients and in post-menopausal patients with or without hormone replacement therapy (HRT). Although statistically not significant, there was a trend paralleling that observed in the in vitro studies. Aromatase activity was higher in breast cancer tissues from the patients with lower circulating estrogen levels. Our data suggest that estrogen may be involved in the regulation of aromatase activity in breast tissues.     

An antibody to the receptor for insulin-like growth factor I inhibits the growth of MCF-7 cells in tissue culture

Alpha IR-3, a monoclonal antibody to the insulin-like growth factor I receptor which blocks insulin-like growth factor I binding and inhibits its activity, inhibits the binding of 125I-insulin-like growth factor I to MCF-7 cells (an estrogen dependent human breast carcinoma cell line) with an IC-50 of approximately 100 ng/ml. It also inhibits the growth of MCF-7 cells cultured in 5% calf serum with approximately the same IC-50. Inhibition of growth occurs both when cells are cultured in the presence and absence of estrogen and is more pronounced when cells are grown at a low density. These findings demonstrate a requirement for insulin-like growth factor I for optimal growth of MCF-7 cells and suggest that it is an autocrine growth factor in these cells.     

Insulin receptor substrate-1 expression is regulated by estrogen in the MCF-7 human breast cancer cell line

Estrogens can stimulate the proliferation of estrogen-responsive breast cancer cells by increasing their proliferative response to insulin-like growth factors. The mechanism underlying the increased proliferation could involve the induction of components of the insulin-like growth factor signal transduction pathway by estrogen. In this study we have examined the regulation of the expression of insulin receptor substrate-1, a major intracellular substrate of the type I insulin-like growth factor receptor tyrosine kinase. Estradiol increased insulin receptor substrate-1 mRNA and protein levels at concentrations consistent with a mechanism involving the estrogen receptor. Insulin receptor substrate-1 was not induced significantly by the antiestrogens tamoxifen and ICI 182,780, but they inhibited the induction of insulin receptor substrate-1 by estradiol. Analysis of tyrosine-phosphorylated insulin receptor substrate-1 showed that the highest levels were found in cells stimulated by estradiol and insulin-like growth factor-I, whereas low levels were found in the absence of estradiol irrespective of whether type I insulin-like growth factor ligands were present. Insulin receptor substrate-2, -3, and -4 were not induced by estradiol. These results suggest that estrogens and antiestrogens may regulate cell proliferation by controlling insulin receptor substrate-1 expression, thereby amplifying or attenuating signaling through the insulin-like growth factor signal transduction pathway.     

Enhancement of insulin-like growth factor signaling in human breast cancer: estrogen regulation of insulin receptor substrate-1 expression in vitro and in vivo.

Cross-talk between insulin-like growth factor (IGF)- and estrogen receptor (ER)-signaling pathways results in synergistic growth. We show here that estrogen enhances IGF signaling by inducing expression of three key IGF-regulatory molecules, the type 1 IGF receptor (IGFR1) and its downstream signaling molecules, insulin receptor substrate (IRS)-1 and IRS-2. Estrogen induction of IGFR1 and IRS expression resulted in enhanced tyrosine phosphorylation of IRS-1 after IGF-I stimulation, followed by enhanced mitogen-activated protein kinase activation. To examine whether these pathways were similarly activated in vivo, we examined MCF-7 cells grown as xenografts in athymic mice. IRS-1 was expressed at high levels in estrogen-dependent growth of MCF-7 xenografts, but withdrawal of estrogen, which decreased tumor growth, resulted in a dramatic decrease in IRS-1 expression. Finally, we have shown that high IRS-1 expression is an indicator of early disease recurrence in ER-positive human primary breast tumors. Taken together, these data not only reinforce the concept of cross-talk between IGF- and ER-signaling pathways, but indicate that IGF molecules may be critical regulators of estrogen-mediated growth and breast cancer pathogenesis.     

Estradiol down-regulates the mannose-6-phosphate/insulin-like growth factor-II receptor gene and induces cathepsin-D in breast cancer cells: a receptor saturation mechanism to increase the secretion of lysosomal proenzymes.

We have studied the regulation by estradiol of the mannose-6-phosphate (Man-6-P)/insulin-like growth factor-II (IGF-II) receptor concentration in different breast cancer cell lines. The mRNA level was assayed by Northern blot using the H5.1 cDNA probe. The protein level was assayed by Western ligand blot, by binding saturation with [125I]procathepsin-D on total membrane preparations, and by immunoprecipitation of 35S-labeled proteins. In three estrogen receptor-positive cell lines (MCF7, T47D, and ZR75-1), estradiol specifically decreased the steady state level of the Man-6-P/IGF-II receptor protein and mRNA. Moreover, in different cell lines and in primary culture of normal mammary cells, the secretion of procathepsin-D was inversely correlated with the level of Man-6-P/IGF-II receptor protein and mRNA. We conclude that estradiol down-regulates the Man-6-P/IGF-II receptor in breast cancer cells. Since two of its ligands, procathepsin-D and IGF-II, are induced by estrogen, we propose that the Man-6-P/IGF-II receptor becomes saturated after estrogen treatment. This model might explain the previously described estrogen-induced secretion of procathepsin-D and other lysosomal proenzymes routed by the same transport system.     

Estrogen-induced lysosomal proteases secreted by breast cancer cells: A role in carcinogenesis?

In an attempt to understand the mechanism by which estrogens stimulate cell proliferation and mammary carcinogenesis, metastatic human breast cancer cell lines (MCF7, ZR75-1) were found to secrete a 52,000 dalton (52K) protein under estrogen stimulation. Following its purification to homogeneity, the 52K protein was identified as a secreted procathepsin-D-like aspartyl protease bearing mannose-6-phosphate signals. This precursor displays an in vitro autocrine mitogenic activity on estrogen-deprived MCF7 cells and is able to degrade basement membrane and proteoglycans following its autoactivation. The total protease (52K + 48K and 34K) was detected and assayed by monoclonal antibodies and was found to be highly concentrated in proliferative and cystic mastopathies. In breast cancer, its cytosolic concentration appears to be correlated more to tumor invasiveness than to hormone responsiveness. The mRNA of the 52K protease accumulates rapidly following estradiol treatment, as was shown by Northern blot analysis with cloned cDNA. The 52K cathepsin-D-like protease is the first example of a lysosomal protease induced by estrogens in cancer cells. Results obtained using different approaches suggest that two cysteinyl cathepsins are also related to cell transformation and invasiveness. It has been proposed that cathepsin-B is involved in breast cancer and metastatic melanoma, and its regulation by estrogen has been shown in the rat uterus. Cathepsin-L corresponds to the major excreted protein (MEP) whose synthesis and secretion are markedly increased by transformation of NIH 3T3 cells with Ki ras and are regulated by several growth factors. In addition to secreted autocrine growth factors and to other proteases (plasminogen activator, collagenase), lysosomal cathepsins may therefore play an important role in the process of tumor growth and invasion as long as their precursor is secreted abundantly.     

Dose-dependent changes of the ratio of apoptosis to proliferation by norethisterone and medroxyprogesterone acetate in human breast epithelial cells.

OBJECTIVE: There is increasing evidence that adding progestogens to estrogen replacement therapy may do more harm than good; however, whether all progestogens act equally on breast cells is debatable. Apart from estrogens, mitogenic growth factors from stromal breast tissue are important in growth-regulation of breast cells, and may modify the response to progestogens. We investigated the effects of medroxyprogesterone acetate (MPA) as well as norethisterone (NET) in the presence of a growth factor mixture and/or estradiol in normal and cancerous human epithelial breast cells. METHODS: MCF10A cells (human epithelial, estrogen- and progesterone-receptor negative, normal breast cells), HCC1500 (human estrogen and progesterone receptor-positive primary breast cancer cells) and MCF-7 cells (human estrogen and progesterone receptor-positive metastatic breast cancer cell line) were used in the experiments. The cells were incubated with progestogens at concentrations of 10(-10) to 10(-6) M for 7 days and growth factors (GFs), estradiol (E2) alone and a combination of GFs + E2. Cell proliferation rate was measured by ATP assay. Apoptosis was measured by cell death assay. Ratios of cell death : proliferation were calculated from these results. RESULTS: In MCF10A cells growth factors elicited a decrease in the ratio of apoptosis to proliferation. This effect was further stimulated by the addition of MPA, whereas NET had no effect. In HCC cells growth factors and estradiol alone and in combination led to a reduction in the ratio. This effect could be partly reversed dose-dependently by the addition of MPA and NET, being more pronounced for MPA. Similar results were found for MCF-7 cells stimulated by estradiol. CONCLUSION: The results of our investigations demonstrate that there are differences between the two progestogens NET and MPA investigated with respect to their effects on normal and cancerous cells. By increasing the mitotic rate of normal epithelial cells, MPA may increase breast cancer risk in women when used in long-term treatment. In this respect NET reacts neutral. The mitosis of pre-existing cancerous cells may be partly inhibited by the addition of both progestogens. Thus, our results indicate that it is necessary to differentiate between normal and malignant breast cells concerning the assessment of progestogens as a risk factor for breast carcinogenesis.     

Antiestrogens inhibit the mitogenic effect of growth factors on breast cancer cells in the total absence of estrogens

The antiproliferative effect of antiestrogens in breast cancer is believed to be entirely due to the inhibition of estrogen induced growth. We show here that non-steroidal antiestrogens inhibit the growth of the human breast cancer MCF7 cells in the complete absence of estrogens (phenol-red-free medium) when cell proliferation is stimulated by insulin or epidermal growth factor. This non-antiestrogenic effect of antiestrogens is, however, mediated by accessible estrogen receptor sites, as it is not observed in receptor negative hormone-independent breast cancers, and is rescued by estradiol but not by insulin. We conclude that antiestrogens inhibit cell proliferation by inhibiting growth factor action as well as estrogen action and that in both cases, accessible estrogen receptors are required.     

Identification and characterization of estrogen-regulated RNAs in human breast cancer cells

Two cDNA libraries have been constructed with RNA prepared from the estrogen-responsive breast cancer cell lines, MCF7 and ZR 75. They were screened by differential hybridization for estrogen-regulated sequences. A total of 11 different RNAs were isolated from the MCF7 cell cDNA library and four from the ZR 75 cell cDNA library. Only two sequences were isolated from both libraries. The levels of the 13 different RNAs are induced between 2.5- and 100-fold by estrogen in MCF7 cells. The expression and regulation by estrogen of the RNAs was examined in eight different human tumor cell lines. The relative abundance of each RNA varied in the different cell lines. The expression of three RNAs (pNR-1, pNR-2, and pNR-25) was detected only in estrogen-responsive breast cancer cells. The sequences that were expressed in all eight cell lines were regulated by estrogen only in the three estrogen-responsive breast cancer cell lines. The response of the RNAs to other classes of steroids and to different concentrations of estrogen was characterized in more detail. The extent to which different concentrations of estradiol induced each RNA varied, but half-maximal induction of most of the RNAs occurred between 2 and 5 X 10(-11) M. The time at which increased RNA levels were first detected following exposure to estradiol also varied. Estrogen increased the levels of some RNAs within 15 min, while for others there was a lag of 4 h.     

Insulin/insulin-like growth factor-I and estrogen cooperate to stimulate cyclin E-Cdk2 activation and cell Cycle progression in MCF-7 breast cancer cells through differential regulation of cyclin E and p21(WAF1/Cip1)

Estrogens and insulin/insulin-like growth factor-I (IGF-I) are potent mitogens for breast epithelial cells and, when co-administered, induce synergistic stimulation of cell proliferation. To investigate the molecular basis of this effect, a MCF-7 breast cancer cell model was established where serum deprivation and concurrent treatment with the pure estrogen antagonist, ICI 182780, inhibited growth factor and estrogen action and arrested cells in G(0)/G(1) phase. Subsequent stimulation with insulin or IGF-I alone failed to induce significant S-phase entry. However, these treatments increased cyclin D1, cyclin E, and p21 gene expression and induced the formation of active Cdk4 complexes but resulted in only minor increases in cyclin E-Cdk2 activity, likely due to recruitment of the cyclin-dependent kinase (CDK) inhibitor p21(WAF1/Cip1) into these complexes. Treatment with estradiol alone resulted in a greater increase in cyclin D1 gene expression but markedly decreased p21 expression, with a concurrent increase in Cdk4 and Cdk2 activity and subsequent synchronous entry of cells into S phase. Co-administration of insulin/IGF-I and estrogen induced synergistic stimulation of S-phase entry coincident with synergistic activation of high molecular mass (approximately 350 kDa) cyclin E-Cdk2 complexes lacking p21. To determine if the ability of estrogen to deplete p21 was central to these effects, cells stimulated with insulin and estradiol were infected with an adenovirus expressing p21. Induction of p21 to levels equivalent to those following treatment with insulin alone markedly inhibited the synergism between estradiol and insulin on S-phase entry. Thus the ability of estradiol to antagonize the insulin-induced increase in p21 gene expression, with consequent activation of cyclin E-Cdk2, is a central component of the synergistic stimulation of breast epithelial cell proliferation induced by simultaneous activation of the estrogen and insulin/IGF-I signaling pathways.     

Melatonin blocks the activation of estrogen receptor for DNA binding.

The present study shows that melatonin prevents, within the first cell cycle, the estradiol-induced growth of synchronized MCF7 breast cancer cells. By using nuclear extracts of these cells, we first examined the binding of estradiol-estrogen receptor complexes to estrogen-responsive elements and found that the addition of estradiol to whole cells activates the binding of the estrogen receptor to DNA whereas melatonin blocks this interaction. By contrast, melatonin neither affects the binding of estradiol to its receptor nor the receptor nuclear localization. Moreover, we also show that addition of estradiol to nuclear extracts stimulates the binding of estrogen receptor to DNA, but this activation is also prevented by melatonin. The inhibitory effect caused by melatonin is saturable at nanomolar concentrations and does not appear to be mediated by RZR nuclear receptors. The effect is also specific, since indol derivatives do not cause significant inhibition. Furthermore, we provide evidence that melatonin does not interact with the estrogen receptor in the absence of estradiol. Together, these results demonstrate that melatonin interferes with the activation of estrogen receptor by estradiol. The effect of melatonin suggests the presence of a receptor that, upon melatonin addition, destabilizes the binding of the estradiol-estrogen receptor complex to the estrogen responsive element.     

Role of insulin-like growth factors and the type I insulin-like growth factor receptor in the estrogen-stimulated proliferation of human breast cancer cells

Estrogen sensitizes the MCF-7 estrogen-responsive breast cancer cell line to the mitogenic effect of insulin and the insulin-like growth factors (IGFs). This sensitization is specific for estrogen and occurs at physiological concentrations of estradiol. Dose-response experiments with insulin, IGF-I, and IGF-II suggested that the sensitization is mediated through the type I IGF receptor. Binding experiments with 125I-IGF-I and hybridization of a type I IGF receptor probe to RNA showed that the levels of the type I IGF receptor and its mRNA are increased 7- and 6.5-fold, respectively, by estradiol. IGF-I and estradiol had similar synergistic effects on other estrogen-responsive breast cancer cell lines, but IGF-I alone increased the proliferation of the MDA MB-231 cell line which is not responsive to estrogens. These experiments suggest that an important mechanism by which estrogens stimulate the proliferation of hormone-dependent breast cancer cells involves sensitization to the proliferative effects of IGFs and that this may involve regulation of the type I IGF receptor.     

Amino acid transport in a human neuroblastoma cell line is regulated by the type I insulin-like growth factor receptor

Insulin-like growth factor I (IGF-I) and IGF-II stimulate cancer cell proliferation via interaction with the type I IGF receptor (IGF-IR). We put forward the hypothesis that IGF-IR mediates cancer cell growth by regulating amino acid transport, both when sufficient nutrients are present and when key nutrients such as glutamine are in limited supply. We examined the effects of alphaIR3, the monoclonal antibody recognizing IGF-IR, on cell growth and amino acid transport across the cell membrane in a human neuroblastoma cell line, SK-N-SH. In the presence of alphaIR3 (2 micro/ml), cell proliferation was significantly attenuated in both control (2 mM glutamine) and glutamine-deprived (0 mM glutamine) groups. Glutamine deprivation resulted in significantly increased glutamate (system X(AG)(-)), MeAIB (system A), and leucine (system L) transport, which was blocked by alphaIR3. Glutamine (system ASC) and MeAIB transport was significantly decreased by alphaIR3 in the control group. Addition of alphaIR3 significantly decreased DNA and protein biosynthesis in both groups. Glutamine deprivation increased the IGF-IR protein on the cell surface. Our results suggest that activation of IGF-IR promotes neuroblastoma cell proliferation by regulating trans-membrane amino acid transport.     

Endogenous human prolactin and not exogenous human prolactin induces estrogen receptor alpha and prolactin receptor expression and increases estrogen responsiveness in breast cancer cells

Prolactin (PRL) and estrogen act synergistically to increase mammary gland growth, development, and differentiation. Based on their roles in the normal gland, these hormones have been studied to determine their interactions in the development and progression of breast cancer. However, most studies have evaluated only endocrine PRL and did not take into account the recent discovery that PRL is synthesized by human mammary cells, permitting autocrine/paracrine activity. To examine the effects of this endogenous PRL, we engineered MCF7 cells to inducibly overexpress human prolactin (hPRL). Using this Tet-On MCF7hPRL cell line, we studied effects on cell growth, PRLR, ER alpha, and PgR levels, and estrogen target genes. Induced endogenous hPRL, but not exogenous hPRL, increased ER alpha levels as well as estrogen responsiveness in these cells, suggesting that effects on breast cancer development and progression by estrogen may be amplified by cross-regulation of ER alpha levels by endogenous hPRL. The long PRLR isoform was also upregulated by endogenous, but not exogenous PRL. This model will allow investigation of endogenous hPRL in mammary epithelial cells and will enable further dissection of PRL effects on other hormone signaling pathways to determine the role of PRL in breast cancer.     

Oxidative and reductive pathways of estrogens in hormone responsive and non-responsive human breast cancer cells in vitro

In order to measure the formation and degradation rates of estradiol by human breast cancer cells, after assessing the biochemical basis of hormone responsiveness and growth response to estrogens, we considered both responsive, estrogen receptor (ER) positive, and non-responsive, ER-negative, breast cancer cell lines, i.e. MCF7, ZR75-1 and MDA-MB231. To this end, we employed a novel “intact cell” approach which allows us, after 24 h incubation, to analyze several enzyme activities in sequence, concurrently with the monitoring of labeled precursor degradation. Our investigations led to the following evidence: (a) the reductive activity of the 17β-hydroxysteroid oxoreductase (17β-HSOR) appears to be higher than the oxidative only in responsive, ER-rich MCF7 and ZR75-1 cells, as also previously observed by others; (b) this activity is, on the contrary, much lower in MDA-MB231 cells and other unresponsive, ER-poor breast cancer cell lines; (c) conversely, the oxidative activity shows an opposite pattern, being limited in MCF7 and ZR75-1 cells and much higher in MDA-MB231 cells. Overall, a 17β-HSOR reductive pathway prevails in both MCF7 and ZR75-1 cells, whilst the oxidative pathway is prevalent in MDA-MB231 cells, leading to a large formation of estrone that is no further metabolized, at least in the experimental conditions used. Our results may provide a likely explanation of previous data on the different estrogen content of breast tumor tissues.