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Enzyme
Compound
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Target Concepts:
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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)
Lectin cytochemistry was performed to clarify the process of glycosylation and the localization of glycocalyx in osteoclasts. Microslicer sections of decalcified rat tibiae were incubated in the presence of HRP-conjugated lectins (Con A, PNA,
MPA
, WGA, UEA-1). Lectin reactions in cell organelles revealed that glucose (Glc) and mannose (Man) are transferred to carbohydrate chains in nuclear envelopes, rough endoplasmic reticuli, and the cis and medial sides of the Golgi apparatus. N-acetylgalactosamine (GalNAc), N-acetylglucosamine (GlcNAc), and/or N-acetylneuraminic acic (NANA) residues are transferred, in turn, in the Golgi apparatus. Lectin reactions detected in lysosomal structures suggest that some sugar residues are incorporated into carbohydrate chains of hydrolytic enzymes, such as acid phosphatase and
arylsulfatase
. Others would be transported to plasma membranes as glycocalyx. PNA and
MPA
reactions were most evident on ruffled borders of osteoclasts. On the other hand, cement-line-like structures on bone surfaces displayed Con A,
MPA
, and WGA positive reactions. The following factors suggest that osteoclasts actively metabolize sugar: characteristic localization of glycocalyx in osteoclasts reflect the polarity of osteoclasts, and carbohydrate complexes in cement-line-like structures seem to play an important role in the coupling phenomenon in bone tissue.
...
PMID:Characteristic localization of carbohydrates in osteoclasts by lectin cytochemistry. 147 18
Different estrogen-3-sulfates (estrone-3-sulfate, estradiol-3-sulfate, and estriol-3-sulfate) can provoke important biologic responses in different mammary cancer cell lines; there is a significant increase in progesterone receptor. However, no significant effect was observed with estrogen-17-sulfates. The reason for the biologic response of estrogen-3-sulfates is that these sulfates are hydrolyzed, and no
sulfatase
activity for C17-sulfates is present in these cell lines. [3H]-Estrone sulfate is converted in a very high percentage to estradiol (E2) in different hormone-dependent mammary cancer cell lines (MCF-7, R-27, and T47D), but very little or no conversion was found in hormone-independent mammary cancer cell lines (MDA-MB-231 and MDA-MB-436). Different antiestrogens (tamoxifen and its derivatives) and another potent antiestrogen, ICI 164,384, significantly decrease the concentration of estradiol after incubation of estrone sulfate with the different hormone-dependent mammary cancer cell lines. No significant effect in the uptake and conversion of estrone sulfate was observed in hormone-independent mammary cancer cell lines. The data indicate that
sulfatase
activity for estrone sulfate is very low in the hormone-independent cell lines; however, comparative kinetic studies carried out after homogenization of MCF-7 and MDA-MB-436 cells show that
sulfatase
activity is similar, suggesting different mechanisms in the hydrolysis of estrone sulfate in hormone-dependent and hormone-independent cell lines.
Progesterone
also provokes a significant decrease in uptake and in estradiol levels after incubation of [3H]-estrone sulfate with the MCF-7 cell line. It is concluded that estrogen sulfates can play an important role in the biologic response of estrogens in breast cancer and that control of
sulfatase
and 17-hydroxysteroid dehydrogenase activities are key steps in the concentration and ability of estradiol in the mammary cancer cell line.
...
PMID:Metabolism and biologic response of estrogen sulfates in hormone-dependent and hormone-independent mammary cancer cell lines. Effect of antiestrogens. 237
Estrogen sulfates are quantitatively the most important form of circulating estrogens during the menstrual cycle and in the post-menopausal period. Huge quantities of estrone sulfate and estradiol sulfate are found in the breast tissues of patients with mammary carcinoma. It has been demonstrated that different estrogen-3-sulfates (estrone-3-sulfate, estradiol-3-sulfate, estriol-3-sulfate) can provoke important biological responses in different mammary cancer cell lines: there is a significant increase in progesterone receptor. On the other hand, no significant effect was observed with estrogen-17-sulfates. The reason for the biological response of estrogen-3-sulfates is that these sulfates are hydrolyzed, and no
sulfatase
activity for C17-sulfates is present in these cell lines. [3H]Estrone sulfate is converted in a very high percentage to estradiol (E2) in different hormone-dependent mammary cancer cell lines (MCF-7, R-27, T-47D), but very little or no conversion was found in the hormone-independent mammary cancer cell lines (MDA-MB-231, MDA-MB-436). Different anti-estrogens (tamoxifen and derivatives) and another potent anti-estrogen: ICI 164,384, decrease the concentration of estradiol very significantly after incubation of estrone sulfate with the different hormone-dependent mammary cancer cell lines. No significant effect was observed for the uptake and conversion of estrone sulfate in the hormone-independent mammary cancer cell lines.
Progesterone
provokes an important decrease in the uptake and in estradiol levels after incubation of [3H]estrone sulfate with the MCF-7 cells. It is concluded that in breast cancer: (1) Estrogen sulfates can play an important role in the biological response of estrogens; (2) Anti-estrogens and progesterone significantly decrease the uptake and estradiol levels in hormone-dependent mammary cancer cell lines; (3) The control of the
sulfatase
and 17 beta-hydroxysteroid dehydrogenase activities, which are key steps in the formation of estradiol in the breast, can open new possibilities in the treatment of hormone-dependent mammary cancer.
...
PMID:Importance of estrogen sulfates in breast cancer. 256 May 11
The adrenal production of the delta 5-androgens, dehydroepiandrosterone (DHEA) and its sulfate ester dehydroepiandrosterone sulfate (DHEAS), declines linearly with aging. The evidence that DHEA or DHEAS administration may alleviate some of the problems related to aging has opened new perspectives for clinical research. The present study aims to investigate the effects of a 6-month DHEA supplementation in early and late postmenopausal women, with normal or overweight body mass index (BMI), on the level of circulating steroids, sex hormone binding globulin (SHBG), beta-endorphin and gonadotropins, and on the adrenal gland response to dexamethasone suppression and adrenocorticotropic hormone (ACTH) stimulation. Early postmenopausal women (50-55 years) both normal weight (BMI 20-24, n = 9) and overweight (BMI 26-30, n = 9) and late postmenopausal women (60-65 years) both of normal weight and overweight, were treated with oral DHEA (50 mg/day). Circulating DHEA, DHEAS, 17-OH pregnenolone, progesterone, 17-OH progesterone, allopregnenolone, androstenedione, testosterone, dihydrotestosterone, estrone, estradiol, SHBG, cortisol, luteinizing hormone, follicle stimulating hormone and beta-endorphin levels were evaluated monthly and a Kupperman score was performed. The product/precursor ratios of adrenal steroid levels were used to assess the relative activities of the adrenal cortex enzymes. Before and after 3 and 6 months of therapy, each women underwent an ACTH stimulating test (10 micrograms i.v. in bolus) after dexamethasone administration (0.5 mg p.o.) to evaluate the response of cortisol, DHEA, DHEAS, androstenedione, 17-OH pregnenolone, allopregnanolone, progesterone and 17-OH progesterone. The between-group differences observed before treatment disappeared during DHEA administration. Levels of 17-OH pregnenolone remained constant during the 6 months. Levels of DHEA, DHEAS, androstenedione, testosterone and dihydrotestosterone increased progressively from the first month of treatment. Levels of estradiol and estrone significantly increased after the first/second month of treatment. Levels of SHBG significantly decreased from the second month of treatment only in overweight late postmenopausal women, while the other groups showed constant levels.
Progesterone
levels remained constant in all groups, while 17-OH progesterone levels showed a slight but significant increase in all groups. Allopregnanolone and plasma beta-endorphin levels increased progressively and significantly in the four groups, reaching values three times higher than baseline. Levels of cortisol and gonadotropins progressively decreased in all groups. The product/precursor ratios of adrenal steroid levels at the sixth month were used to assess the relative activities of the adrenal cortex enzymes and were compared to those found before therapy. The 17,20-desmolase,
sulfatase
and/or sulfotransferase, 17,20-lyase and 5 alpha-reductase activities significantly increased, while the 3 beta-hydroxysteroid-oxidoreductase activity did not vary. On the contrary, the 11-hydroxylase and/or 21-hydroxylase activities showed a significant decrease after 6 months of treatment. In basal conditions, dexamethasone significantly suppressed all the adrenal steroids and this suppression was greater after 3 and 6 months of treatment for DHEA, DHEAS and allopregnanolone, while it remained unchanged for other steroids. Before treatment, ACTH stimulus induced a significant response in all parameters; after the treatment, it prompted a greater response in delta 5- and delta 4-androgens, progesterone and 17-OH progesterone, while cortisol responded less in both younger and older normal-weight women. The endometrial thickness did not show significant modifications in any of the groups of postmenopausal women during the 6 months of treatment. Treatment with DHEA was associated with a progressive improvement of the Kupperman score in all groups, with major effects on the vasomotor symptoms in
...
PMID:Six-month oral dehydroepiandrosterone supplementation in early and late postmenopause. 1110 74
Progestins exert their progestational activity by binding to the progesterone receptor (form A, the most active and form B, the less active) and may also interact with other steroid receptors (androgen, glucocorticoid, mineralocorticoid, estrogen). They can have important effects in other tissues besides the endometrium, including the breast, liver, bone and brain. The biological responses of progestins cover a very large domain: lipids, carbohydrates, proteins, water and electrolyte regulation, hemostasis, fibrinolysis, and cardiovascular and immunological systems. At present, more than 200 progestin compounds have been synthesized, but the biological response could be different from one to another depending on their structure, metabolism, receptor affinity, experimental conditions, target tissue or cell line, as well as the biological response considered. There is substantial evidence that mammary cancer tissue contains all the enzymes responsible for the local biosynthesis of estradiol (E(2)) from circulating precursors. Two principal pathways are implicated in the final steps of E(2) formation in breast cancer tissue: the 'aromatase pathway', which transforms androgens into estrogens, and the '
sulfatase
pathway', which converts estrone sulfate (E(1)S) into estrone (E(1)) via estrone sulfatase. The final step is the conversion of weak E(1) to the potent biologically active E(2) via reductive 17beta-hydroxysteroid dehydrogenase type 1 activity. It is also well established that steroid sulfotransferases, which convert estrogens into their sulfates, are present in breast cancer tissues. It has been demonstrated that various progestins (e.g. nomegestrol acetate, medrogestone, promegestone) as well as tibolone and their metabolites can block the enzymes involved in E(2) bioformation (
sulfatase
, 17beta-hydroxysteroid dehydrogenase) in breast cancer cells. These substances can also stimulate the sulfotransferase activity which converts estrogens into the biologically inactive sulfates. The action of progestins in breast cancer is very controversial; some studies indicate an increase in breast cancer incidence, others show no difference and still others a significant decrease.
Progestin
action can also be a function of combination with other molecules (e.g. estrogens). In order to clarify and better understand the response of progestins in breast cancer (incidence, mortality), as well as in hormone replacement therapy or endocrine dysfunction, new clinical trials are needed studying other progestins as a function of the dose and period of treatment.
...
PMID:Progestins and breast cancer. 1794 37
At present, more than 200 progestin compounds are synthetized, but their biological effects are different: this is function of their structure, receptor affinity, metabolic transformations, the target tissues considered, dose. The action of progestins in breast cancer is controversial; some studies indicate an increase in breast cancer incidence, others show no differences, and yet others indicate a decrease. Many studies agree that treatment with progestins plus estrogens at a low dose and during a limited period (less than 5 years) can have beneficial effects in peri- and post-menopausal women. It was demonstrated that various progestins (e.g. nomegestrol acetate, medrogestone, promegestone), as well as tibolone and its metabolites, can block the enzymes involved in estradiol bioformation (
sulfatase
, 17beta-hydroxysteroid dehydrogenase) in breast cancer.
Progesterone
is converted into various metabolic products: in normal breast tissue the transformation is mainly to 4-ene derivatives, whereas in the tumor tissue 5alpha-pregane derivatives are predominant. Aromatase activity is the last step in the formation of estrogens by the conversion of androgens. In recent studies it was shown that 20alpha-dihydroprogesterone, a metabolite found mainly in normal breast tissue and having anti-proliferative properties, can act as an anti-aromatase agent. The data suggest the possible utilization of this compound in breast cancer prevention. In conclusion, in order to clarify and better understand the response of progestins in breast cancer (incidence and mortality), as well as in hormone replacement therapy or in endocrine dysfunction, new clinical trials are necessary using other progestins in function of the dose and period of treatment.
...
PMID:Progestins in the menopause in healthy women and breast cancer patients. 1917 24
Progesterone
and estradiol are the foremost steroid hormones in human pregnancy. However, the origin of maternal progesterone has still not been satisfactorily explained, despite the generally accepted opinion that maternal LDL-cholesterol is a single substrate for placental synthesis of maternal progesterone. The question remains why the levels of progesterone are substantially higher in fetal as opposed to maternal blood. Hence, the role of the fetal zone of fetal adrenal (FZFA) in the synthesis of progesterone precursors was addressed. The FZFA may be directly regulated by placental CRH inducing an excessive production of sulfated 3beta-hydroxy-5-ene steroids such as sulfates of dehydroepiandrosterone (DHEAS) and pregnenolone (PregS). Due to their excellent solubility in plasma these conjugates are easily transported in excessive amounts to the placenta for further conversion to the sex hormones. While the significance of C19 3beta-hydroxy-5-ene steroid sulfates originating in FZFA for placental estrogen formation is mostly recognized, the question "Which maternal and/or fetal functions may be served by excessive production of PregS in the FZFA?" - still remains open. Our hypothesis is that, besides the necessity to synthesize de novo all the maternal progesterone from cholesterol, it may be more convenient to utilize the fetal PregS. The activities of
sulfatase
and 3beta-hydroxysteroid dehydrogenase (3beta-HSD) are substantially higher than the activity of cytochrome P450scc, which is rate-limiting for the placental progesterone synthesis from LDL-cholesterol. However, as in the case of progesterone synthesis from maternal LDL-cholesterol, the relative independence of progesterone levels on FZFA activity may be a consequence of substrate saturation of enzymes converting PregS to progesterone. Some of the literature along with our current data (showing no correlation between fetal and maternal progesterone but significant partial correlations between fetal and maternal 20alpha-dihydroprogesterone (Prog20alpha) and between Prog20alpha and progesterone within the maternal blood) indicate that the localization of individual types of 17beta-hydroxysteroid dehydrogenase is responsible for a higher proportion of estrone and progesterone in the fetus, but also a higher proportion of estradiol and Prog20alpha in maternal blood. Type 2 17beta-hydroxysteroid dehydrogenase (17HSD2), which oxidizes estradiol to estrone and Prog20alpha to progesterone, is highly expressed in placental endothelial cells lining the fetal compartment. Alternatively, syncytium, which is directly in contact with maternal blood, produces high amounts of estradiol and Prog20alpha due to the effects of type 1, 5 and 7 17?-hydroxysteroid dehydrogenases (17HSD1, 17HSD5, and 17HSD7, respectively). The proposed mechanisms may serve the following functions: 1) providing substances which may influence the placental production of progesterone and synthesis of neuroprotective steroids in the fetus; and 2) creating hormonal milieu enabling control of the onset of labor.
...
PMID:Is maternal progesterone actually independent of the fetal steroids? 1953 20
It is well documented that breast tissue, both normal and cancerous, contains all the enzymatic systems necessary for the bioformation and metabolic transformation of estrogens, androgens and progesterone. These include sulfatases, aromatase, hydroxysteroid-dehydrogenases, sulfotransferases, hydroxylases and glucuronidases. The control of these enzymes plays an important role in the development and pathogenesis of hormone-dependent breast cancer. As discussed in this review, various progestogens including dydrogesterone and its 20alpha-dihydro-derivative, medrogestone, promegestone, nomegestrol acetate and norelgestromin can reduce intratissular levels of estradiol in breast cancer by blocking
sulfatase
and 17beta-hydroxysteroid-dehydrogenase type 1 activities. A possible correlation has been postulated between breast cell proliferation and estrogen sulfotransferase activity.
Progesterone
is largely transformed in the breast; normal breast produces mainly 4-ene derivatives, whereas 5alpha-derivatives are most common in breast cancer tissue. It has been suggested that this specific conversion of progesterone may be involved in breast carcinogenesis. In conclusion, treatment with anti-aromatases combined with anti-
sulfatase
or 17beta-hydroxysteroid-dehydrogenase type 1 could provide new therapeutic possibilities in the treatment of patients with hormone-dependent breast cancer.
...
PMID:Breast cancer and steroid metabolizing enzymes: the role of progestogens. 1996 54
