Estrogen-dependent and independent activation of the P1 promoter of the p53 gene in transiently transfected breast cancer cells.
(1/1497)
Loss of p53 function by mutational inactivation is the most common marker of the cancerous phenotype. Previous studies from our laboratory have demonstrated 17 beta estradiol (E2) induction of p53 protein expression in breast cancer cells. Although direct effects of E2 on the expression of p53 gene are not known, the steroid is a potent regulator of c-Myc transcription. In the present studies, we have examined the ability of E2 and antiestrogens to regulate the P1 promoter of the p53 gene which contains a c-Myc responsive element. Estrogen receptor (ER)-positive T47D and MCF-7 cells were transiently transfected with the P1CAT reporter plasmid and levels of CAT activity in response to serum, E2 and antiestrogens were monitored. Factors in serum were noted to be the dominant inducers of chloramphenicol acetyltransferase (CAT) expression in MCF-7 cells. The levels of CAT were drastically reduced when cells were maintained in serum free medium (SFM). However, a subtle ER-mediated induction of CAT expression was detectable when MCF-7 cells, cultured in SFM, were treated with E2. In serum-stimulated T47D cells, the CAT expression was minimal. The full ER antagonist, ICI 182 780 (ICI) had no effect. Treatment with E2 or 4-hydroxy tamoxifen (OHT) resulted in P1CAT induction; OHT was more effective than E2. Consistent with c-Myc regulation of the P1 promoter, E2 stimulated endogenous c-Myc in both cell lines. Two forms of c-Myc were expressed independent of E2 stimuli. The expression of a third more rapidly migrating form was E2-dependent and ER-mediated since it was blocked by the full ER antagonist, ICI, but not by the ER agonist/antagonist OHT. These data demonstrate both ER-mediated and ER-independent regulation of c-Myc and the P1 promoter of the p53 gene, and show differential effects of the two classes of antiestrogens in their ability to induce the P1 promoter of the p53 gene in breast cancer cells. (+info)
Differential regulation of specific genes in MCF-7 and the ICI 182780-resistant cell line MCF-7/182R-6.
(2/1497)
To elucidate the mechanisms involved in anti-oestrogen resistance, two human breast cancer cell lines MCF-7 and the ICI 182780-resistant cell line, MCF-7/182R-6, have been compared with regard to oestrogen receptor (ER) expression, ER function, ER regulation, growth requirements and differentially expressed gene products. MCF-7/182R-6 cells express a reduced level of ER protein. The ER protein is functional with respect to binding of oestradiol and the anti-oestrogens tamoxifen, 4-hydroxy-tamoxifen and ICI 182780, whereas expression and oestrogen induction of the progesterone receptor is lost in MCF-7/182R-6 cells. The ER protein and the ER mRNA are regulated similarly in the two cell lines when subjected to treatment with oestradiol or ICI 182780. Oestradiol down-regulates ER mRNA and ER protein expression. ICI 182780 has no initial effect on ER mRNA expression whereas the ER protein level decreases rapidly in cells treated with ICI 182780, indicating a severely decreased stability of the ER protein when bound to ICI 182780. In vitro growth experiments revealed that the ICI 182780-resistant cell line had evolved to an oestradiol-independent phenotype, able to grow with close to maximal growth rate both in the absence of oestradiol and in the presence of ICI 182780. Comparison of gene expression between the two cell lines revealed relatively few differences, indicating that a limited number of changes is involved in the development of anti-oestrogen resistance. Identification of the differentially expressed gene products are currently in progress. (+info)
Mechanism of action and clinical effects of antiprogestins on the non-pregnant uterus.
(3/1497)
Considerable progress has been made in elucidating the mechanism of action of antiprogestins. The biological response to a progesterone antagonist depends on many factors. The usual effect is that of an antagonist, but progesterone agnostic or even antioestrogenic or oestrogenic effects have also been observed. The present review focuses on the clinical applications of antiprogestins in the non-pregnant uterus. Whereas high doses of antiprogestins block ovulation, low doses impair endometrial development without affecting ovulation, hormonal levels or bleeding patterns Indeed, the endometrium is the tissue which is the most sensitive to antiprogestins. The effect of antiprogestins is to produce a delay in endometrial maturation and to postpone the appearance of the implantation window. This concept of 'endometrial contraception' requires further testing in humans, although the principle has been proven in monkeys. In contrast to the low doses of mifepristone which delay endometrial maturation, a minimum dose of 50 mg is required to produce endometrial bleeding. Late luteal phase antiprogestin administration does not disturb ovulation, hormonal levels or bleeding patterns. This has clinical application, and mifepristone has been used together with prostaglandins in women with delayed menses to successfully prevent implantation. Mifepristone has also been shown to be an effective post-coital agent. However, when used on a regular basis once monthly at the end of the cycle as a potential contraceptive, the results are disappointing. Because of their antiproliferative and anti-oestrogenic effects on the endometrium, antiprogestins are also used in the treatment of oestrogen-dependent conditions such as endometriosis and fibromyomas. In humans, chronic administration of high doses of antiprogestins has on rare occasions been associated with endometrial hyperplasia, presumably a consequence of unopposed oestrogen activity. This does not occur with low doses (1 mg daily for 5 months). (+info)
Uterine peristalsis during the follicular phase of the menstrual cycle: effects of oestrogen, antioestrogen and oxytocin.
(4/1497)
Uterine peristalsis, directing sustained and rapid sperm transport from the external cervical os or the cervical crypts to the isthmic part of the tube ipsilateral to the dominant follicle, changes in direction and frequency during the menstrual cycle, with lowest activity during menstruation and highest activity at mid cycle. It was therefore suggested that uterine peristalsis is under the control of the dominant follicle with the additional involvement of oxytocin. To test this hypothesis, vaginal sonography of uterine peristalsis was performed in the early, mid and late proliferative phases, respectively, of cycles of women treated with oestradiol valerate and with human menopausal gonadotrophin following pituitary downregulation, with clomiphene citrate and with intravenous oxytocin, respectively. Administration of oestradiol valerate resulted in oestradiol serum concentrations comparable with the normal cycle with a simulation of the normal frequency of peristaltic contractions. Elevated oestradiol concentrations and bolus injections of oxytocin resulted in a significant increase in the frequency of peristaltic contractions in the early and mid follicular phases, respectively. Chlomiphene tended, though insignificantly so, to suppress the frequency of peristaltic waves in the presence of elevated oestradiol concentrations. In the late follicular phase of the cycle extremely elevated oestradiol concentrations as well as the injection of oxytocin resulted only in an insignificant further increase of peristaltic frequency. In the normal cycles, as well as during extremely elevated oestradiol concentrations and following oxytocin administration, the peristaltic contractions were always confined to the subendometrial layer of the muscular wall. The results and the review of literature indicate that uterine peristalsis during the follicular phase of the menstrual cycle is controlled by oestradiol released from the dominant follicle with the probable involvement of oxytocin, which is presumably stimulated together with its receptor within the endometrial-subendometrial unit and therefore acting in an autocrine/paracrine fashion. Since unphysiological stimulation with oestradiol and oxytocin did not significantly increase the frequency of uterine peristalsis in the late follicular phase of the cycle it is assumed that normal preovulatory frequency of uterine peristalsis is at a level which cannot be significantly surpassed due to phenomena of refractoriness of the system. (+info)
Idoxifene derivatives are less reactive to DNA than tamoxifen derivatives, both chemically and in human and rat liver cells.
(5/1497)
The drug tamoxifen shows evidence of genotoxicity, and induces liver tumours in rats. Covalent DNA adducts have been detected in the liver of rats treated with tamoxifen, and these arise through metabolism at the alpha-position to give an ester which reacts with DNA. (E)-1-(4-iodophenyl)-2-phenyl-1-[4-(2-pyrrolidinoethoxy)phenyl]-but-1-en e (idoxifene) is an analogue of tamoxifen in which formation of DNA adducts is greatly reduced; we could not detect any adducts in the DNA of cultured rat hepatocytes treated with 10 microM idoxifene, after analysis by the 32P-post-labelling method. The metabolite (Z)-4-(4-iodophenyl)-4-[4-(2-pyrrolidinoethoxy)phenyl]-3-phenyl-3-but en-2-ol (alpha-hydroxyidoxifene) gave adducts in rat hepatocytes, but far fewer than the corresponding tamoxifen metabolite. In human hepatocytes, neither idoxifene nor tamoxifen induced detectable levels of DNA adducts. We prepared the alpha-acetoxy ester of idoxifene as a model for the ultimate reactive metabolite formed in rat liver. It was less reactive than alpha-acetoxytamoxifen, as might be expected on mechanistic grounds. It reacted with DNA in the same way, to give adducts which were probably N2-alkyldeoxyguanosines, but to a lower extent. All these results indicate that idoxifene is much less genotoxic than tamoxifen, and should therefore be a safer drug. (+info)
Statistical analysis of array expression data as applied to the problem of tamoxifen resistance.
(6/1497)
BACKGROUND: Although the emerging complementary DNA (cDNA) array technology holds great promise to discern complex patterns of gene expression, its novelty means that there are no well-established standards to guide analysis and interpretation of the data that it produces. We have used preliminary data generated with the CLONTECH Atlas human cDNA array to develop a practical approach to the statistical analysis of these data by studying changes in gene expression during the development of acquired tamoxifen resistance in breast cancer. METHODS: For hybridization to the array, we prepared RNA from MCF-7 human breast cell tumors, isolated from our athymic nude mouse xenograft model of acquired tamoxifen resistance during estrogen-stimulated, tamoxifen-sensitive, and tamoxifen-resistant growth. Principal components analysis was used to identify genes with altered expression. RESULTS AND CONCLUSIONS: Principal components analysis yielded three principal components that are interpreted as 1) the average level of gene expression, 2) the difference between estrogen-stimulated gene expression and the average of tamoxifen-sensitive and tamoxifen-resistant gene expression, and 3) the difference between tamoxifen-sensitive and tamoxifen-resistant gene expression. A bivariate (second and third principal components) 99% prediction region was used to identify outlier genes that exhibit altered expression. Two representative outlier genes, erk-2 and HSF-1 (heat shock transcription factor-1), were chosen for confirmatory study, and their predicted relative expression levels were confirmed in western blot analysis, suggesting that semiquantitative estimates are possible with array technology. IMPLICATIONS: Principal components analysis provides a useful and practical method to analyze gene expression data from a cDNA array. The method can identify broad patterns of expression alteration and, based on a small simulation study, will likely provide reasonable power to detect moderate-sized alterations in clinically relevant genes. (+info)
Estrogens induce apoptosis in mouse peritoneal macrophages.
(7/1497)
AIM: To study whether estrogen might induce apoptosis in mouse peritoneal macrophages (MPM). METHOD: The MPM were isolated and incubated in culture medium containing 17-beta-estradiol, estrone, or equal volume of 100% ethanol as control. DNA fragmentation was visualized by agarose gel electrophoresis. RESULTS: 17-beta-Estradiol 0.01-1 mumol.L-1 or estrone 10-20 mumol.L-1 elicited typical morphological apoptosis and DNA fragmentation in a concentration-dependent manner in MPM. Staurosporine (Sta) 0.01 mumol.L-1, cycloheximide (Cyc) 1 mg.L-1, and tamoxifen (Tam) 10 mumol.L-1 inhibited the DNA fragmentation induced by 17-beta-estradiol 1 mumol.L-1 or estrone 20 mumol.L-1. CONCLUSION: Estradiol and estrone induced apoptosis in MPM. (+info)
Developing hypothalamic dopaminergic neurones as potential targets for environmental estrogens.
(8/1497)
Environmental chemicals which mimic the actions of estrogen have the potential to affect any estrogen responsive tissue. The aim of the present study was to investigate their potential to mimic the effects of 17beta-estradiol (E2) on developing primary rat hypothalamic dopaminergic (DA) neurones maintained in a chemically defined medium. We now show that both E2 and octylphenol (OP), but not the non-aromatizable androgen, dihydrotestosterone, enhanced the uptake of [3H]DA by the cultured cells, whereas they had no effect on the uptake of [14C]GABA. Although the sensitivity of responses may change with the age of the developing cultures, the dose response curves for E2 and OP were typically 'bell-shaped', with a rise in response followed by a decline to control levels with increasing concentrations. Effects were seen as low as 10(-14) M for E2 and 10(-11) M for OP. Responses to E2 (10(-12) M) and OP (10(-9) M) were reversed in the presence of the antiestrogen, ZM 182780 (10(-5) M). This study thus provides direct evidence, using a mechanistic rather than toxicological end-point, in support of the hypothesis that inappropriate exposure to environmental estrogens at critically sensitive stages of development, could potentially perturb the organisational activities of estrogen on selected neuronal populations in the CNS. (+info)