Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
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Target Concepts:
Gene/Protein
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Query: UNIPROT:P04155 (
pS2
)
1,234
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The level of oestrogen-responsive gene expression in breast tumours has been proposed as a predictor of the response of the tumour to endocrine (anti-oestrogen) therapy. We demonstrate that different oestrogen-responsive genes may differ in their responses to other hormones. pLIV-1 and
pS2
are two oestrogen-regulated genes that are expressed in the MCF-7 human breast cancer cell line. We show that pLIV-1 mRNA, but not
pS2
mRNA, is also induced, to a lesser extent, by progesterone, 5 alpha-dihydrotestosterone and dexamethasone. For pLIV-1, combinations of these hormones with oestradiol and with the pure anti-oestrogen,
ICI 164384
, indicate that the mechanism of its response to these other steroid hormones is clearly separable from its response to oestrogen. Such behaviour in breast tumours in vivo could explain the lack of absolute correlation between marker gene expression and anti-oestrogen sensitivity and between the expression of individual marker genes.
...
PMID:Oestrogen-induced genes, pLIV-1 and pS2, respond divergently to other steroid hormones in MCF-7 cells. 764 56
Estradiol levels in breast tumors from post-menopausal women are similar to those in pre-menopausal women even though plasma estrogens are much lower after the menopause. In situ estrogen production by the tumor provides a potential means of maintaining high estradiol levels in post-menopausal breast cancer tissue. The estrone sulfatase pathway has been proposed as the mediator of in situ estrogen production. A number of studies suggest that estrone sulfate may be converted into estradiol in breast tumors via the catalytic activity of estrone sulfatase and 17 beta-hydroxysteroid dehydrogenase. However, these studies used pharmacologic levels of estrogen sulfates and have not shown that physiologic levels can support biologic effects. Accordingly, the present study examined the dose relationship of estrone sulfate to a variety of biologic endpoints in MCF-7 breast cancer cells in culture. These cells converted physiologic concentrations of estrone sulfate to quantities of free estradiol capable of stimulating cell growth. Under these conditions, the nuclear steroids observed were free estrone and estradiol. Increase in cell number after 6 days of exposure to steroid required 100 nM estrone sulfate. However, S-phase, a more sensitive measure of cell proliferation, was stimulated by 0.1 nM estrone sulfate, a clearly physiologic concentration. Stimulation of estrogen-dependent protein markers such as
pS2
and progesterone receptor required much higher concentrations of estrone sulfate. These effects were mediated through the estrogen receptor since the pure anti-estrogen,
ICI 164384
, blocked all effects produced by estrone sulfate. While it has been suggested that anti-estrogens may partly exert their effects by inhibition of sulfatase and 17 beta-hydroxysteroid dehydrogenase, this did not occur under our experimental conditions. These data provide evidence of the relevance of the estrone sulfatase pathway since biologic effects can be demonstrated in response to physiologic concentrations of estrone sulfate.
...
PMID:Estrone sulfate promotes human breast cancer cell replication and nuclear uptake of estradiol in MCF-7 cell cultures. 847 38
Estrogen responses of human breast cancer cell lines have frequently been shown to be promoted by insulin. We have examined the action of insulin, and its interaction with estradiol, in regulating the expression of the estrogen-induced genes, LIV-1 and
pS2
. Both hormones cause increases in mRNA levels of the two genes but do so by distinct mechanisms. The concentration of insulin required to produce this effect suggests that it is acting via its ability to bind to the IGF-1 receptor. Both insulin and estradiol exert their effects at the level of transcription. Induction by insulin is dependent upon continued protein synthesis whereas induction by estradiol is not. Induction by both insulin and estradiol is prevented by the pure antiestrogen.
ICI 164384
, indicating the requirement for an activatable estrogen receptor. Insulin does not stimulate LIV-1 expression via the androgen receptor. These results demonstrate that both estradiol and insulin can stimulate the transcription of these estrogen-inducible genes, by separate mechanisms both of which involve the estrogen receptor.
...
PMID:Insulin/IGF-1 modulation of the expression of two estrogen-induced genes in MCF-7 cells. 886 63
The response of two endogenous, estrogen-induced genes, LIV-1 and
pS2
, to growth factor stimulation of MCF-7 cells was examined. Epidermal growth factor (EGF), transforming growth factor alpha (TGF alpha) and insulin-like growth factor-1 (IGF-1) were each able to induce an increase in the two mRNAs in the absence of estradiol, and their effects were additive to that of an optimally inducing concentration (10(-8) M) of the hormone. Induction by EGF and TGF alpha, but not by IGF-1, were also additive to induction by a saturating concentration (2 microg/ml) of insulin. TGFbeta, an antimitogenic growth factor for MCF-7 cells, did not induce LIV-1 or
pS2
mRNA but inhibited induction by estradiol. Increases in mRNA were shown to reflect increases in specific gene transcription. Induction by growth factors, but not by estradiol, was dependent upon protein synthesis. Induction by both growth factors and estradiol was inhibited by the pure antiestrogen,
ICI 164384
(
ICI
), and by the mixed agonist/antagonist, tamoxifen. Despite differences in patterns of expression in vivo and in vitro, both LIV-1 and
pS2
appeared to be responsive to growth factors via a mechanism distinct from that of estradiol but requiring the estrogen receptor.
...
PMID:Interaction between estradiol and growth factors in the regulation of specific gene expression in MCF-7 human breast cancer cells. 921 17
Estrogen (E) inhibits the growth of both non-tumorigenic, immortal human mammary epithelial cells (HMEC) and breast cancer cells which stably express exogenous estrogen receptors (ER). The anti-estrogenic compounds 4-hydroxy-tamoxifen (HT) and
ICI 164384
(
ICI
) have different effects on the growth of the ER-transfectants. HT is a potent growth inhibitor, while
ICI
has no effect by itself but is able to block the anti-proliferative effects of E and HT. In order to elucidate the mechanism by which E or HT-bound ER inhibit cell growth, we have evaluated the effects of these compounds on the growth of HMEC stably expressing ER with mutations or deletions in the N-terminal A/B domain, the DNA-binding domain (DBD), and the C-terminal ligand-binding domain. These studies revealed that E and HT require different structural domains of the ER for their anti-proliferative activities. The N-terminal A/B domain is required for HT-, but not E-dependent growth inhibition. The DNA-binding domain of the ER is not essential for HT-mediated anti-proliferative effects, but is important for E-dependent activity. The effect of ER mutations on the ligand-inducible expression of the endogenous progesterone receptor (PR) and
pS2
genes was also evaluated. Neither gene was induced in the cells containing the ER mutated in the DBD, even though cell growth was inhibited. These results suggest that E and HT use different pathways to elicit their anti-proliferative effects and that this occurs via modulation of genes that are controlled by mechanisms different from those important for activation of the PR and
pS2
genes.
...
PMID:Different estrogen receptor structural domains are required for estrogen- and tamoxifen-dependent anti-proliferative activity in human mammary epithelial cells expressing an exogenous estrogen receptor. 944 40
Estrogen receptor (ER)-negative breast carcinomas are often difficult to treat as they do not respond to hormone therapy. In an attempt to determine if expressing the human estrogen receptor in an ectopic manner could restore the hormone responsiveness of these cells, we have expressed the human ER in ER-negative MDA-MB 231 breast cancer cells using a recombinant adenovirus gene delivery system that allows high level expression of ER in essentially all cells. In these cells, the ER was correctly translated, had a wild type hormone binding affinity (Kd = 0.6 nM), bound well to estrogen response element-containing DNA, and showed an activation pattern of estrogen response element-reporter gene activity by estrogen and antiestrogens very similar to that observed in MCF-7 breast cancer cells containing endogenous ER (stimulation by estrogen, no stimulation by the antiestrogens trans-hydroxytamoxifen or
ICI 164384
, and blockade of estradiol stimulation by trans-hydroxytamoxifen or
ICI 164384
). Intriguingly, estradiol stimulation of these cells was also able to induce expression of
pS2
, an estrogen regulated gene considered to be a favorable prognostic marker for endocrine therapy in ER-positive breast cancer cells. Expression of the ER had no effect by itself on the proliferation rate of MDA-MB 231 cells. However, treatment of the ER-containing cells with estradiol or with the pure antiestrogen ICI 164 384 suppressed proliferation of the cells while the antiestrogen trans-hydroxytamoxifen had little effect on proliferation; and cotreatment with trans-hydroxytamoxifen reversed the estradiol- or ICI 164 384-evoked suppression of proliferation. To understand the mechanism underlying the inhibition of proliferation by estradiol, we examined the expression of several growth related endogenous genes. c-Myc protooncogene expression was strongly inhibited by treatment with estradiol as was expression of BRCA1 and BRCA2 genes, which is in agreement with their mitogenic-dependent expression, while expression of beta-actin, a housekeeping gene, was not affected by hormone treatment. Together, these data suggest that reexpressing the human ER in breast cancer cells that no longer express this protein renders them sensitive to hormone treatment. The ability of the antiestrogen ICI 164 384 to suppress the proliferation of ER-negative breast cancer cells that reexpress ER might be useful ultimately as an endocrine gene therapy approach for controlling the growth of ER-negative breast cancer cells. The application of recombinant adenoviruses expressing the human ER presents interesting features which might be used as a basis for designing more powerful and effective treatments for ER-negative breast cancers.
...
PMID:Expression of human estrogen receptor using an efficient adenoviral gene delivery system is able to restore hormone-dependent features to estrogen receptor-negative breast carcinoma cells. 1037 22
