Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:3.1.6.1 (sulfatase)
3,205 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Estradiol (E2) is one of the main factors which control the growth and evolution of breast cancer. Consequently, to block the formation of E2 inside cancer cells has been an important target in recent years. Breast cancer cells possess all the enzymatic systems (e.g. sulfatase, aromatase, 17beta-hydroxysteroid dehydrogenase [17beta-HSD]) involved in the conversion of estrogen precursors into E2. Sulfotransferase, which converts estrogen to its sulfate, is also present in this tumoral tissue. Duphaston is a synthetic progestogen with properties similar to the natural progesterone. In the present study we examined the effect of Duphaston and its 20-dihydro-metabolite on the sulfatase and 17beta-HSD activities in MCF-7 and T-47D breast cancer cells. The cells were incubated with estrone sulfate (E1S) (5x10(-9)M) in the absence or presence of Duphaston or its 20-dihydro-metabolite (5x10(-5) to 5x10(-9)M) for 24h at 37 degrees C. In another series of experiments, estrone (E1) (5x10(-9)M) was incubated with T-47D cells in the absence or presence of the two progestogens (5x10(-5) to 5x10(-9)M) for 24h at 37 degrees C. E1S, E1 and E2 were characterized by thin layer chromatography and quantified using the corresponding standard. Duphaston and its 20-dihydro-metabolite, at concentrations of 5x10(-7) and 5x10(-5)M, inhibited the conversion of E1S to E2 by 14% and 63%, 65% and 74%, respectively, in MCF-7 cells; the values were 15% and 48% and 31% and 51%, respectively, in T-47D cells. In another series of experiments it was observed that, after 24-h incubation, E1 (5x10(-9)M) was converted in a great proportion to E2 in the T-47D cells and that this transformation was significantly inhibited by Duphaston and its 20-dihydro-metabolite. The IC50 value, corresponding to 50% of the inhibition in the conversion of 1 to E2, was 9x10(-6)M for 20-dihydro-metabolite in this cell line. It was concluded that the progestogen Duphaston and its 20-dihydro-metabolite are potent inhibitory agents on sulfatase and 17beta-HSD activities in breast cancer cells. Duphaston is a progestogen with properties similar to the endogenous progesterone. The data open interesting perspectives to study the biological responses of these progestogens in clinical trials of patients with breast cancer.
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PMID:Dydrogesterone (Duphaston) and its 20-dihydro-derivative as selective estrogen enzyme modulators in human breast cancer cell lines. Effect on sulfatase and on 17beta-hydroxysteroid dehydrogenase (17beta-HSD) activity. 1527 6

The origin of oestrogens at the level of the breast itself is discussed. In particular in postmenopausal women an accumulation of oestradiol at the site of breast tumours has been documented by a number of independent studies. The mechanism behind the high local oestrogens concentrations is thought to be the in situ production of these steroids by local processes with androstenedione as the main precursor. The presence of all enzymes required for this production has been demonstrated in a large proportion of breast tumours, with probably aromatase, hydroxysteroid dehydrogenase type 1 and sulfatase as the most important enzymes leading to the biologically highly active oestradiol. The individual enzymes that are relevant for the biosynthesis and the metabolism of oestrogens are discussed. The conclusion is reached that a number of these local processes may be involved in the promotion of premalignant lesions and in stimulation of growth of malignant tumours in the human breast.
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PMID:Local biosynthesis and metabolism of oestrogens in the human breast. 1535 Oct 93

Hormone treatment with an estrogen plus a progestagen (EPT) increases the risk of breast cancer. Both hormone activities are also induced by tibolone. In order to assess the breast safety of tibolone, it was evaluated in several pre-clinical models. The effects were inconclusive in breast cancer cell lines but, in various in vivo models, it did not stimulate the breast. In the 17,12-dimethylbenz(a)anthracene (DMBA) model, tibolone clearly inhibited the growth of breast tumors and, when given prophylactally, far less tumors developed. Ovariectomized monkeys showed no increase in the expression of the proliferation marker Ki67. The effects of tibolone and its metabolites on the steroid metabolizing enzymes in breast tissues were investigated in order to unravel its mode of action in the breast. Tibolone and its metabolites did not inhibit aromatase, but sulfatase was profoundly inhibited. The sulfated 3alpha-OH tibolone metabolite even showed irreversible inhibition of sulfatase. In addition, 17ss-hydroxysteroid dehydrogenase activities were slightly inhibited and sulfotransferase activity was stimulated at low concentrations. The consequence of these effects is that, for both endogenous estrogens and estrogenic-metabolites of tibolone, the equilibrium is preferential for the sulfated forms. The intracellular hormonal milieu tibolone and its metabolites also influence cellular homeostasis. It inhibits cell proliferation of normal breast epithelial cells and stimulates apoptosis. In this respect, tibolone behaves differently from estrogens. Clinical studies have shown that tibolone users experience less breast tenderness and do not show an increase in mammographic density as found with continuous combined EPT. The data concerning tibolone and breast cancer risk are inconclusive and require further investigation.
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PMID:Tissue-selective effects of tibolone on the breast. 1535 Nov 2

Although ovaries serve as the primary source of estrogen for pre-menopausal women, after menopause estrogen biosynthesis from circulating precursors occurs in peripheral tissues by the action of several enzymes, 17beta-hydroxysteroid dehydrogenase 1 (17beta-HSD1), aromatase and estrogen sulfatase. In the breast, both normal and tumoral tissues have been shown to be capable of synthesizing estrogens, and this local estrogen production can be implicated in the development of breast tumors. In these tissues, estradiol (E(2)) can be synthesized by three pathways: (1) estrone sulfatase transforms estrogen sulfates into bioactive estrogens, (2) 17beta-HSD1 converts estrone (E(1)) into E(2), (3) aromatase which converts androgens into estrogens is also present and contributes to the in situ synthesis of active estrogens but to a far lesser extent than estrone sulfatase. Quantitative assessment of E(2) formation in human breast tumors indicates that metabolism of estrone sulfate (E(1)S) via the sulfatase pathway produces 100-500 times more E(2) than androgen aromatization. Breast tissue also possesses the estrogen sulfotransferase involved in the conversion of estrogens into their sulfates that are biologically inactive. In the present review, we summarized the action of the 19-nor-progestin nomegestrol acetate (NOMAC) on the sulfatase, 17beta-HSD1 and sulfotransferase activities in the hormone-dependent MCF-7 and T47-D human breast cancer cell lines. Using physiological doses of substrates NOMAC blocks very significantly the conversion of E(1)S to E(2). It inhibits the transformation of E(1) to E(2). NOMAC has a stimulatory effect on sulfotransferase activity in both cell lines, with a strong stimulating effect at low doses but only a weak effect at high concentrations. The effects on the three enzymes are always stronger in the progesterone-receptor rich T47-D cell line as compared with the MCF-7 cell line. Besides, no effect is found for NOMAC on the transformation of androstenedione to E(1) in the aromatase-rich choriocarcinoma cell line JEG-3. In conclusion, the inhibitory effect provoked by NOMAC on the enzymes involved in the biosynthesis of E(2) (sulfatase and 17HSD pathways) in estrogen-dependent breast cancer, as well as the stimulatory effect on the formation of the inactive E(1)S, can open attractive perspectives for future clinical trials.
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PMID:Effect of nomegestrol acetate on estrogen biosynthesis and transformation in MCF-7 and T47-D breast cancer cells. 1574 27

Between one-third to one-half of all breast cancers are steroid sensitive. Steroid-pathway enzymes (sulfatase, 17beta-hydroxysteroid dehydrogenases, aromatase and sulfotransferases) are thus prime candidates for therapeutic approaches based on the control of intacrine activity. Some phytoestrogens, ubiquitous in our diet, are inhibitors of these enzymes. Such a therapeutic potential has stimulated research and progress has been achieved during the last years. Complementary to previous reviews on phytoestrogens, this contribution covers the estrogen pathway inhibition effects of these compounds and special attention will be given to isoflavonoids, flavonoids and lignans. Furthermore, the research on structurally-related compounds as therapeutic agents will be discussed briefly.
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PMID:Dietary phytoestrogens: potential selective estrogen enzyme modulators? 1585 2

The great majority of breast cancers are in their early stage hormone-dependent and it is well accepted that estradiol (E2) plays an important role in the genesis and evolution of this tumor. Human breast cancer tissues contain all the enzymes: estrone sulfatase, 17beta-hydroxysteroid dehydrogenase, aromatase involved in the last steps of E2 bioformation. Sulfotransferases which convert estrogens into the biologically inactive estrogen sulfates are also present in this tissue. Quantitative data show that the 'sulfatase pathway', which transforms estrogen sulfates into the bioactive unconjugated E2, is 100-500 times higher than the 'aromatase pathway', which converts androgens into estrogens. The treatment of breast cancer patients with anti-aromatases is largely developed with very positive results. However, the formation of E2 via the 'sulfatase pathway' is very important in the breast cancer tissue. In recent years it was found that antiestrogens (e.g. tamoxifen, 4-hydroxytamoxifen), various progestins (e.g. promegestone, nomegestrol acetate, medrogestone, dydrogesterone, norelgestromin), tibolone and its metabolites, as well as other steroidal (e.g. sulfamates) and non-steroidal compounds, are potent sulfatase inhibitors. In another series of studies, it was found that E2 itself has a strong anti-sulfatase action. This paradoxical effect of E2 adds a new biological response of this hormone and could be related to estrogen replacement therapy in which it was observed to have either no effect or to decrease breast cancer mortality in postmenopausal women. Interesting information is that high expression of steroid sulfatase mRNA predicts a poor prognosis in patients with +ER. These progestins, as well as tibolone, can also block the conversion of estrone to estradiol by the inhibition of the 17beta-hydroxysteroid dehydrogenase type I (17beta-HSD-1). High expressison of 17beta-HSD-1 can be an indicator of adverse prognosis in ER-positive patients. It was shown that nomegestrol acetate, medrogestone, promegestone or tibolone, could stimulate the sulfotransferase activity for the local production of estrogen sulfates. This is an important point in the physiopathology of this disease, as it is well known that estrogen sulfates are biologically inactive. A possible correlation between this stimulatory effect on sulfotransferase activity and breast cancer cell proliferation is presented. In agreement with all this information, we have proposed the concept of selective estrogen enzyme modulators (SEEM). In conclusion, the blockage in the formation of estradiol via sulfatase, or the stimulatory effect on sulfotransferase activity in combination with anti-aromatases can open interesting and new possibilities in clinical applications in breast cancer.
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PMID:Recent insight on the control of enzymes involved in estrogen formation and transformation in human breast cancer. 1586 Feb 65

Thirty years after the introduction of tamoxifen, which was expanded from palliation of metastatic cancer to recent application for chemoprevention, the primacy of this drug as the mainline pharmacological intervention is currently being challenged by the third generation aromatase inhibitors and inactivators. In contrast to the oestrogen receptor blockade provided by tamoxifen, aromatase inhibitors result in deprivation of oestrogens in postmenopausal women both through paracrine/intracrine and endocrine modulation. Experimental evidence has shown a significant (97-99%) reduction of in vivo aromatase activity and an equal or sometimes better antitumour activity compared with megestrol acetate when these drugs are used as second-line treatment for metastatic breast cancer. Recent pivotal studies in first-line settings comparing tamoxifen for metastatic breast cancer and preliminary results from the neoadjuvant trials demonstrate that third generation aromatase inhibitors are superior to tamoxifen. With a better understanding of local tissue production of oestrogen through oestrone sulfatase, which hydrolyses oestrone sulfate to oestrone, and 17-beta-hydroxysteroid dehydrogenase Type 1, which in turn catalyses the reduction of oestrone to oestradiol, more powerful tactics for oestrogen starvation of cancer may be realised in future.
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PMID:Aromatase inhibitors and other novel agents in breast cancer treatment. 1598 53

Steroid sulfatase (STS) is the only well characterized enzyme in human cells that is capable to desulfate estrone 3-sulfate (E1S) and dehydroepiandrosterone sulfate (DHEAS) as a first step in the conversion of these precursors to active hormones. STS has been found to be highly expressed in estrogen-dependent breast tumors in post-menopausal women and is regarded as a crucial component of the local estrogen production that is required for tumor growth and survival. Inhibitors of STS are expected to block the intra-tumoral estrogen synthesis and, therefore, are considered as potential new therapeutic agents for the treatment of estrogen-dependent cancers of the breast and the endometrium. In this review, we give an overview on the current status in the field of medicinal chemistry of STS inhibitors. Newer developments comprise potent aryl sulfamate-based irreversible inhibitors, and several types of reversible inhibitors. Other directions include compounds with dual mode of action, such as compounds that block both STS and aromatase, or act as STS inhibitors and antiproliferative or antiangiogenic agents at the same time. In particular, these agents featuring an extended mode of action hold promise to be included in the armamentarium to fight endocrine-dependent cancer.
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PMID:Steroid sulfatase inhibitors: their potential in the therapy of breast cancer. 1617 76

It is well known that sex steroids are involved in the growth of breast cancers, and the great majority of breast carcinomas express estrogen (ER), progesterone (PR), and androgen (AR) receptors. In particular, recent studies have demonstrated that estrogens and androgens are locally produced in breast carcinoma tissues, and total blockade of in situ estrogen production potentially leads to an improvement in prognosis of breast cancer patients. Therefore, it is important to obtain a better understanding of sex steroid-producing enzymes in breast carcinoma tissues. In this review, we summarize recent studies on the expression and regulation of enzymes related to intratumoral production of estrogens (aromatase, 17beta-hydroxysteroid dehydrogenase type 1 (17betaHSD1), and steroid sulfatase (STS) etc) and androgens (17betaHSD5 and 5alpha-reductase) in human breast carcinoma tissues, and discuss the biological and/or clinical significance of these enzymes. The cellular localization of aromatase in breast carcinoma tissues still remains controversial. Therefore, we examined localization of aromatase mRNA in breast carcinoma tissues by laser capture microdissection/real time-polymerase chain reaction. Aromatase mRNA expression was detected in both carcinoma and intratumoral stromal cells, and the expression level of aromatase mRNA was higher in intratumoral stromal cells than in carcinoma cells in the cases examined. We also examined an association among the immunoreactivity of enzymes related to intratumoral estrogen production and ERs in breast carcinoma tissues, but no significant association was detected. Therefore, the enzymes responsible for the intratumoral production of estrogen may not always be the same among breast cancer patients, and not only aromatase but also other enzymes such as STS and 17betaHSD1 may have important therapeutic potential as targets for endocrine therapy in breast cancer patients.
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PMID:Sex steroid-producing enzymes in human breast cancer. 1632 18

Estrogen-dependent endometrial cancer is related to unopposed and prolonged estrogen stimulation. We examined the expression of estrogen-metabolizing enzymes in correlation with the ERalpha and ERbeta estrogen receptors in human endometrial Ishikawa adenocarcinoma cells and in endometrial cancer specimens and adjacent normal endometrium from the same patients. Real-time PCR analysis revealed that both estrogen receptors and selected estrogen-metabolizing enzymes were expressed in the Ishikawa cells and in endometrial tissue. We detected higher expression of ERalpha than ERbeta, higher expression of sulfatase than sulfotransferase and low expression of aromatase in the Ishikawa cells and the tissue, as well as higher levels of type 2 17beta-hydroxysteroid dehydrogenase (17beta-HSD) in normal and diseased tissue than in the Ishikawa cells. When we compared the expression in endometrial cancer samples and in the adjacent normal endometrium, ERalpha and ERbeta, sulfatase and sulfotransferase were seen to be downregulated in the majority of the cancerous tissue specimens.
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PMID:Expression analysis of estrogen-metabolizing enzymes in human endometrial cancer. 1633 31


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