E2-induced degradation of uterine insulin receptor substrate-2: requirement for an IGF-I-stimulated, proteasome-dependent pathway.

The insulin receptor substrates are docking proteins that bind various receptor tyrosine kinases and signaling proteins. Previous studies have shown that E2 or progesterone can regulate the relative abundance of insulin receptor substrate-1 and -2 in cells and tissues. For instance, uterine insulin receptor substrate-2 was decreased markedly at 24 h after E2 treatment of mice. In the present study we used various in vivo experimental approaches to examine the mechanism by which E2 influences uterine insulin receptor substrate-2 expression. Uterine insulin receptor substrate-2 mRNA levels were diminished after E2 treatment, but this diminution did not account for the total reduction in insulin receptor substrate-2 protein, suggesting that the E2-induced decrease in insulin receptor substrate-2 is not regulated solely at the mRNA level. Cotreatment with progesterone prevented the E2-stimulated reduction in insulin receptor substrate-2 protein at 24 h after hormone exposure. In addition, MG-132 and epoxomicin, inhibitors of proteasomal protease activity, inhibited the E2-induced decrease in uterine insulin receptor substrate-2 protein levels, and this correlated to an increase in uterine protein ubiquitination. Insulin receptor substrate-2 protein was diminished in uteri of E2-treated insulin receptor substrate-1-null mutant mice, but not in E2-treated IGF-I-null mutant mice. Furthermore, E2-induced diminution of uterine insulin receptor substrate-2 protein was only partially inhibited in the presence of wortmannin, a PI3K inhibitor. Collectively, these data suggest that the E2-induced decrease in uterine insulin receptor substrate-2 requires IGF-I signaling, is not dependent solely on insulin receptor substrate-1 and PI3K, and is blocked by progesterone as well as by pharmacological inhibition of proteasomal protease activity. We speculate that the IGF-I-activated IGF-I receptor, in response to E2, directly or indirectly modifies insulin receptor substrate-2, probably through phosphorylation, leading to ubiquitination and subsequent degradation of this docking protein by the proteasome. This degradation could be a regulatory step to inhibit insulin receptor substrate-2-dependent signaling in the uterus.

Activation of a uterine insulin-like growth factor I signaling pathway by clinical and environmental estrogens: requirement of estrogen receptor-alpha.

Recent data indicate that insulin-like growth factor I (IGF-I) may have a function in mediating the mitogenic effects of 17beta-estradiol (E2) in the uterus and in regulating the growth of uterine neoplasms. This study was designed to determine whether synthetic and plant-derived chemicals that interact with estrogen receptor-alpha (ERalpha) and elicit estrogenic responses also mimic E2 by activating the uterine IGF-I signaling pathway. Ovariectomized adult female mice were treated with both environmental and clinically relevant chemicals previously reported to display estrogenic and/or antiestrogenic properties, and their uteri were evaluated for an activated IGF-I signaling pathway. Diethylstilbestrol, 4-hydroxytamoxifen, the raloxifene analog LY353381, 2,2-bis(p-hydroxyphenyl)-1,1,1-trichloroethane (HPTE), bisphenol A, and genistein were shown to mimic E2 in the uterus by increasing the level of IGF-I messenger RNA, inducing IGF-I receptor (IGF-IR) tyrosine phosphorylation, stimulating the formation of IGF-IR signaling complexes, and increasing both proliferating cell nuclear antigen expression and the number of mitotic cells in the epithelium. The dose of chemical necessary to activate IGF-I signaling varied, with the order of potency: E2 = diethylstilbestrol > LY353381 > 4-hydroxytamoxifen > genistein > HPTE > bisphenol A. Administration of the chemicals to ERalpha knockout mice did not activate IGF-IR, indicating that ERalpha is required for activation of uterine IGF-IR by these diverse chemicals. This study demonstrates that several chemicals shown previously to display estrogenic activities also mimic E2 by activating uterine IGF-I signaling.

Differential responsiveness of MCF-7 human breast cancer cell line stocks to the pineal hormone, melatonin.

The estrogen receptor (ER)-positive MCF-7 human breast cancer cell line has been used extensively for the study of estrogen-responsive human breast cancer. However, various levels of estrogen responsiveness have been described in different stocks of MCF-7 cells. Because we have previously shown that the pineal hormone, melatonin, inhibits proliferation of MCF-7 cells and can modulate ER expression and transactivation, we investigated if various stocks of MCF-7 cells exhibit a differential responsiveness to the anti-proliferative effects of melatonin and the possible mechanisms involved. The MCF-7 stocks (M, O, H) were examined for: (1) mitogenic response to estradiol; (2) steady-state ER mRNA levels; (3) expression of the mt1 melatonin membrane receptor; (4) growth inhibition by melatonin; and (5) melatonin's modulation of expression of the ER and the estrogen-regulated genes, PgR, TGFbeta and pS2. For all of these parameters, there was a stock-specific response which showed: MCF-7M > MCF-7O > MCF-7H. These results demonstrate that there are significant differences in the responsiveness of various stocks of MCF-7 breast cancer cells to the growth-inhibitory effects of melatonin which can be correlated with both the level of ER mRNA expression and the degree of estrogen-responsiveness. These findings suggest that not only may these differences have some impact on the cells' estrogen-response pathway, but also that the primary growth-inhibitory effects of melatonin are transduced through the membrane-associated G-protein coupled mt1 melatonin receptor.

In vitro synergistic interaction of alligator and human estrogen receptors with combinations of environmental chemicals.

The effect of mixtures of environmental chemicals with hormonal activity has not been well studied. To investigate this phenomenon, the estrogen receptor (ER) from the American alligator (aER) or human (hER) was incubated with [3H]17beta-estradiol in the presence of selected environmental chemicals individually or in combination. The environmental chemicals included the insecticide chlordane, which has no estrogenic activity, and the pesticides dieldrin and toxaphene, which have very weak estrogenic activity. Chlordane, dieldrin, and toxaphene individually demonstrated no appreciable displacement of [3H]17beta-estradiol from aER and hER at the concentration tested. A combination of these chemicals inhibited the binding of [3H]17beta-estradiol by 20 to 40%. Alachlor, a chemical recently discovered to have weak estrogenic activity, also displaced [3H]17beta-estradiol more effectively in combination with dieldrin than alone. These results indicate that combinations of some environmental chemicals inhibit [3H]17beta-estradiol binding in a synergistic manner. This suggests that the ER may contain more than one site for binding environmental chemicals. The possibility that the ER binds multiple environmental chemicals adds another level of complexity to the interaction between the environment and the endocrine system.

o,p'-DDT and its metabolites inhibit progesterone-dependent responses in yeast and human cells.

Using a combination of in vitro assays we have evaluated whether DDT metabolites can interact with the progesterone receptor pathway in yeast expressing human progesterone receptor (hPR) and in T47D human breast cancer cells which express endogenous hPR. In transactivation assays using both yeast and T47D cells, o,p'-DDT and the metabolites p,p'-DDT, o,p'-DDD, p,p'-DDD, o,p'-DDE, p,p'-DDE, p,p'-DDA, and DDOH inhibited progesterone-induced reporter gene activity in a dose-dependent manner. None of the DDT metabolites functioned as hPR agonists. Whole cell competition binding assays using T47D cells indicated that the inhibitory effects of DDT metabolites on progesterone-dependent activites may occur through both hPR-dependent and hPR-independent pathways. Our results and previous reports of DDT metabolites interacting with estrogen and androgen receptors suggests that this class of environmental chemicals may interact with numerous hormone receptor signaling pathways.

Inhibition of 17 beta-estradiol and progesterone activity in human breast and endometrial cancer cells by carbamate insecticides.

Using a combination of in vitro assays we have examined the capacities of contemporary-exposure chemicals to modulate human estrogen and human progesterone receptor (hER and hPR) activity in human breast and endometrial cancer cells. The carbamate insecticides aldicarb, Baygon (propoxur), bendiocarb, carbaryl, methomyl, and oxamyl were used in this study. The carbamates alone weakly activated estrogen- or progesterone-responsive reporter genes in breast and endometrial cancer cells. All of the carbamates decreased estradiol- or progesterone-induced reporter gene activity in the breast and endometrial cancer cells. In whole cell competition binding assays, the carbamates demonstrated a limited capacity to displace radiolabeled estrogen or progesterone from ER or PR. Based on the results presented here, the carbamate insecticides may represent a class of chemicals which function through a mechanism separate from ligand-binding and, therefore, may act as general endocrine modulators in mammalian cells.

Inhibition of progesterone receptor activity in yeast by synthetic chemicals.

Numerous synthetic chemicals have estrogenic activity by interacting with the estrogen receptor. In this report, we test the hypothesis that some estrogenic chemicals may also modulate the human progesterone receptor (hPR) signaling pathway. This was evaluated by examining synthetic chemicals for their ability to modulate the activity of hPR expressed in yeast. The transcriptional activity of hPR was not increased in the presence of several synthetic chemicals. However, the estrogenic chemicals p-nonylphenol and 4-tert-octyphenol, and pentachlorophenol, effectively inhibited the activity of the hPR in yeast. Competition binding studies indicated these chemicals effectively competed with radiolabeled R5020, a synthetic progestin, for binding to the hPR in yeast. These results indicate that some synthetic chemicals directly inhibit the activity of hPR in yeast. The observations that some estrogenic chemicals can also inhibit hPR activity suggest a potential mechanism for the reported potent estrogenic activities of these chemicals.

Identification of environmental chemicals with estrogenic activity using a combination of in vitro assays.

Environmental chemicals that function as estrogens have been suggested to be associated with an increase in disease and dysfunctions in animals and humans. To characterize chemicals that may act as estrogens in humans, we have compared three in vitro assays which measure aspects of human estrogen receptor (hER)-mediated estrogenicity. Chemicals were first tested for estrogen-associated transcriptional activity in the yeast estrogen screen (YES). This was created by expressing hER and two estrogen response elements linked to the lacZ gene in yeast. Second, chemicals that were tested in YES were then assayed for direct interaction with hER in a competition binding assay. Third, chemicals were tested in the estrogen-responsive MCF-7 human breast cancer cell line transiently transfected with a plasmid containing two estrogen response elements linked to the luciferase gene. Together, these assays have identified two metabolites of DDT, o,p'-DDD and p,p'-DDD, that have estrogenic activity. Interestingly, previous studies had reported that the DDD metabolites were nonestrogenic in whole animal models. Alachlor, the most frequently used herbicide in the United States, cis-nonachlor, and trans-nonachlor displayed weak estrogenic activity in the combined assays. The antifungal agent benomyl had no estrogenic activity. We propose that a combination of in vitro assays can be used in conjunction with whole animal models for a more complete characterization of chemicals with estrogenic activity.

Synergistic activation of estrogen receptor with combinations of environmental chemicals.

Certain chemicals in the environment are estrogenic. The low potencies of these compounds, when studied singly, suggest that they may have little effect on biological systems. The estrogenic potencies of combinations of such chemicals were screened in a simple yeast estrogen system (YES) containing human estrogen receptor (hER). Combinations of two weak environmental estrogens, such as dieldrin, endosulfan, or toxaphene, were 1000 times as potent in hER-mediated transactivation as any chemical alone. Hydroxylated polychlorinated biphenyls shown previously to synergistically alter sexual development in turtles also synergized in the YES. The synergistic interaction of chemical mixtures with the estrogen receptor may have profound environmental implications. These results may represent a previously uncharacterized level of regulation of estrogen-associated responses.

Dexniguldipine hydrochloride, a protein-kinase-C-specific inhibitor, affects the cell cycle, differentiation, P-glycoprotein levels, and nuclear protein phosphorylation in Friend erythroleukemia cells.

Dexniguldipine hydrochloride (DNIG) is a potent antineoplastic agent with well-documented anti-(protein kinase C) activity and an ability to reverse multidrug resistance. Given the importance of protein kinase C (PKC) activity in proliferation and differentiation, we examined the effect of DNIG on several parameters of Friend erythroleukemia cell (FELC) activity. Particular attention was paid to proliferation, hexamethylene-bisacetamide-(HMBA)-induced differentiation, nuclear localization of protein kinase C, and nuclear protein phosphorylation. P-glycoprotein expression was also followed as an indicator of changes in multidrug resistance. At 2.5 microM, DNIG caused a significant decrease in the rate of FELC proliferation, while maintaining a cellular viability of greater than 80%, whether exposure to the drug was continuous over 96 h or took the form of a 6-h pulse/chase. DNA synthesis was decreased in cells exposed to DNIG for 20 h. Flow cytometry showed a marked increase in the percentage of cells in S phase of the cell cycle. Phosphorylation studies revealed decreased phosphorylation of two nuclear proteins (80 kDa and 47 kDa) following a 4-h exposure to the drug. HMBA-induced differentiation was significantly inhibited with continuous exposure to DNIG, and this effect appears to be a pre-commitment one, as 6-h pulse/chase exposures also resulted in inhibition of differentiation. Cells induced to differentiate with HMBA also demonstrated a decrease in the quantity of the 80-kDa phosphoprotein. Western blotting revealed that, even in the face of decreased phosphorylation, exposure to this PKC inhibitor resulted in an increase in the amount of nuclear PKC alpha. Finally, levels of P-glycoprotein were decreased in the presence of this drug. Our work identifies several effects of the PKC inhibitor DNIG on FELC and suggests several roles for PKC in regulating FELC proliferation and differentiation. Additionally, these results suggest that this PKC inhibitor may increase the effect of other chemotherapeutic drugs, particularly S-phase-specific ones, by increasing the length of S phase and decreasing multidrug resistance. The possibility of combination therapy with DNIG and other antineoplastic agents should be investigated further in light of these findings.

Differential expression of wild-type and variant ER mRNAs by stocks of MCF-7 breast cancer cells may account for differences in estrogen responsiveness.

The MCF-7 human breast cancer cell line is routinely used as a model system for the study of ER+, estrogen-responsive human breast cancer. Although most investigators have found these cells to be estrogen-responsive, there are reports that some stocks of MCF-7 cells may be either insensitive or may display decreased sensitivity to the mitogenic effects of estrogen. We report here that differences in estrogen responsiveness appear to be related to varying ratios of wild type to variant ER mRNAs. MCF-7 stocks which express a high ratio of wild type to variant ER transcripts are more responsive to the mitogenic effects of physiological concentrations of estradiol than stocks which express an elevated ratio of exon 5 deletion variant to wild type ER transcripts.

Coexpression of wild-type and variant oestrogen receptor mRNAs in a panel of human breast cancer cell lines.

Wild-type as well as variant oestrogen receptor (ER) mRNAs with exon 5 and 7 deleted were identified in a panel of human breast tumour cell lines by reverse transcriptase-polymerase chain reaction followed by dideoxynucleotide sequence analysis, and then quantitated by ribonuclease protection analysis. All cell lines categorised as ER+ by ligand-binding analysis expressed both wild-type and variant ER transcripts. Most cell lines classified as ER- did not express any ER transcript. However, three ER- cell lines (BT-20, MDA-MB-330 and T47Dco) expressed both wild-type and variant transcripts. A differential pattern of expression of wild type to variant was seen in both ER+ and ER- cell lines, however this pattern was not paralleled by differences in ligand-binding activity. Breast tumour cell lines previously classified as ER- expressed significantly lower levels of ER transcripts than did their ER+ counterparts. In view of these findings, as well as earlier reports that the exon 5 deletion ER variant encodes a dominant-positive receptor, it seems clear that some cell lines are misclassified as ER-, and express both wild-type and variant ER mRNAs, and that the overexpression of this variant may account, in part, for their oestrogen-independent phenotype.

Expression of a constitutively active estrogen receptor variant in the estrogen receptor-negative BT-20 human breast cancer cell line.

Estrogen receptor (ER) expression by breast tumors is an important predictor of disease-free survival in breast cancer patients and, more importantly, is a strong predictor of response to endocrine therapy. Variant forms of the ER may play an important role in the loss of hormone responsiveness and the progression to hormone independence. We have examined a panel of human breast tumor cell lines, both ER-positive and ER-negative, and have identified an ER mRNA variant containing a deletion of exon 5 in the ER-negative BT-20 and ER-positive MCF-7 cell lines. This exon 5 deletion variant has been previously reported to be overexpressed in ER-negative/progesterone receptor-positive breast tumors. Using RNase protection analysis, we have found that the predominant ER transcript in the BT-20 cells is the exon 5 deletion variant, while the principal transcript in MCF-7 cells is the wild-type ER mRNA. The variant ER transcript is translated into a truncated receptor protein of approximately M(r) 42,000 when expressed in yeast and, more important, in breast tumor cells. This is the first demonstration of an exon 5 deletion variant ER protein. Functional analysis has shown that this variant ER possesses constitutive transcriptional regulatory activity with respect to an estrogen-regulated reporter gene construct in a yeast expression system. The presence of this ER variant in breast tumor cell lines, as well as breast tumor biopsies and uterine tissue, suggests that it is a naturally occurring variant that may arise by alternative splicing, and whose overexpression may be involved in the progression of breast tumors to a hormone-independent state.