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: UNIPROT:P00750 (PLA)
16,800 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In a study of human breast carcinomas in short-term organ culture, in which plasminogen activator modulation by estrogen was used as a test of estrogen sensitivity (R. Mira-y-Lopez and L. Ossowski, Cancer Res., 47: 3558-3564, 1987), we found that the number of estrogen and progesterone receptor-positive cancers showing estrogen sensitivity was less than anticipated from reported rates of antiestrogen-induced clinical remission. Since in these experiments the estrogen receptor (ER) content of the tumor cultures was only inferred from determinations carried out before culture, we postulated that the apparent estrogen insensitivity of some tumors resulted from poor ER preservation. We have now measured ER levels directly in cultured tissue and found that (a) ER levels in slices of human breast cancers decreased 78% (median) after 1-4 days; 4 of 16 (25%) ER-positive breast cancers had no detectable estradiol binding activity after culture; (b) the drop in ER level was a result of net receptor loss rather than inactivation of binding activity; (c) loss of cell viability could be definitively ruled out as a cause of decreased receptor level; (d) cortisol receptor levels in human breast cancers and ER levels in other hormone-responsive cancers also decreased in culture, and to a similar extent. Higher ER levels (sometimes equal to preculture levels) were preserved by culture at subphysiological temperature or in slices of controlled thickness, not exceeding 0.6 mm. These findings should be considered when organ culture is used to predict tumor hormone responsiveness.
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PMID:Preservation of steroid hormone receptors in organ cultures of human breast carcinomas. 229 60

Breast growth and development is influenced by oestrogens and the growth of many breast cancers is driven by oestrogens, an effect which is utilised in the endocrine treatment of breast cancer. Oestrogens act by binding to the oestrogen receptor, a specific protein which in turn binds to specific regulatory regions of DNA, thereby altering gene expression. The effects of oestrogens may be mediated by growth factors and other substances under oestrogen regulation. Oestrogen receptor status in breast tumours can be determined by cytosolic radioligand binding assays, enzyme linked immunoassay, immunohistochemistry and measurement of messenger RNA levels. Tumour oestrogen receptor content is an established but not absolute predictor of both response to endocrine therapy and prognosis in breast cancer. Paradoxically, a small proportion of apparently oestrogen receptor negative tumours do respond to endocrine therapy, perhaps reflecting expression of low and unmeasurable levels of receptor or tumour heterogeneity with respect to receptor expression. A larger proportion of oestrogen receptor positive tumours unexpectedly fail to respond to endocrine therapy; in these cases it is possible that oestrogen receptor has become dissociated from the transcriptional and translational events which it normally regulates. Determination of levels of expression of substances regulated by oestrogens can provide information regarding the functional integrity of the oestrogen response pathway and such substances include the progesterone receptor, plasminogen activator, cathepsin D and a variety of messenger RNA sequences.
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PMID:Oestrogen receptor and oestrogen regulated proteins in human breast cancer: a review. 268 40

The tumorigenic properties of human rheumatoid arthritis synovial cells in culture were investigated. The synovial cells developed good colonies and secreted plasminogen activator (PA) and collagenase in the cell cultures, as do Hela cells. Since PA and progesterone receptor (PgR) are considered to be end products of estradiol action in breast cancer cells, the estrogen receptor (ER) and PgR content in these cells was also assayed. Large amounts of ER and PgR were detected in the synovial cells in culture, even though these cells are not targets for sex steroids. Study of the cytomorphologic changes in the synovial cells in culture revealed many characteristics generally observed in neoplastic cells. Whether any or all of these observations have any implication in prognosis or therapy in this disease remains to be studied.
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PMID:Expression of tumor cell properties in synovial cells in culture. 302 23

To examine whether plasminogen activator reflects the functional state of estrogen receptors in human breast cancer, the enzyme activities were determined in extracts prepared from 160 breast cancer specimens and compared on qualitative and quantitative bases with the levels of steroid receptors, such as cytoplasmic estrogen receptor (ERC), progesterone receptor (PgR) and nuclear estrogen receptor (ERN). With any receptor, plasminogen activator activity was significantly higher in receptor-positive tumors than in receptor-negative tumors. When these breast tumors were categorized into 8 groups in terms of combinations of receptor status, breast cancers which were positive for all these receptors were found to contain the highest plasminogen activator activity. Furthermore, quantitative analyses demonstrated positive correlations of the enzyme activity with either ERC content (correlation coefficient +0.37, P less than 0.001) or PgR content (correlation coefficient +0.45, P less than 0.001). These results strongly suggest that plasminogen activator can be used as an effective functional marker for hormone dependence in human breast cancer.
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PMID:Plasminogen activator as a functional marker for estrogen dependence in human breast cancer cells. 308 29

We have determined that the primary reason for the frequently encountered poor survival of human scirrhous breast carcinomas in short-term (4 days) organ culture is mechanical injury to the tumor tissue during explant preparation. It was possible to minimize this injury by preparing 0.5-mm-thick slices using very sharp blades. This resulted in much improved preservation of tissue structure and function, as assessed by histology, DNA content, and enzyme synthesis and secretion. With the exception of insulin, which was always present in the culture medium, exogenous hormones, including estrogen, or serum did not further improve explant preservation. In rodent mammary tumors, growth in vivo and production of the serine protease plasminogen activator (PA) in organ culture are coordinately regulated by hormones, suggesting that PA may be a valuable indicator of tumor hormone responsiveness. We have now tested the effect of estrogen and other hormones on PA secretion in organ cultures of primary human breast carcinomas. We found that: modulation of PA by 17-beta-estradiol (10-8) M) occurred only in carcinomas which were positive for both estrogen and progesterone receptors; of 21 such tumors, 11 (52%) were responsive. Plasminogen activator was not modulated by estradiol in any of the 22 tumors which were negative for one or both receptors; hydrocortisone (10(-7) M) effectively inhibited, and 3,5,3'-L-triiodothyronine (10(-8) M) and adenylate cyclase activators effectively stimulated PA in most breast tumors, regardless of their estrogen and progesterone receptor status. Prolactin (5 micrograms/ml) had no effect when tested alone; urokinase-type PA was found to be the principal PA produced by human breast tumors. Changes in its rate of synthesis and secretion and not in the content of PA inhibitors appeared to be the prevailing mechanism of enzyme regulation by hormones. In summary, short-term organ culture coupled with the use of PA as an index of response appears to be a promising approach to the study of hormone sensitivity of primary human breast carcinomas.
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PMID:Hormonal modulation of plasminogen activator: an approach to prediction of human breast tumor responsiveness. 310 11

Antiestrogens have proven to be effective in controlling the growth of hormone-responsive breast cancers. At the concentrations of antiestrogens achieved in the blood of breast cancer patients taking antiestrogens (up to 2 X 10(-6) M), antiestrogens selectively inhibit the proliferation of estrogen receptor-containing breast cancer cells, and this inhibition is reversible by estradiol. Antiestrogens also inhibit estrogen-stimulation of several specific protein synthetic activities in breast cancer cells, including increases in plasminogen activator activity, progesterone receptor levels and production of several secreted glycoproteins and intracellular proteins. Antiestrogens bind with high affinity to the estrogen receptor and to additional microsomal binding sites to which estrogens do not bind. These latter sites, called antiestrogen binding sites (AEBS), are present in equal concentrations in estrogen receptor-positive and -negative breast cancer cells and are present in a wide variety of tissues, with highest concentrations being found in the liver. The antiestrogenic and growth suppressive potencies of a variety of antiestrogens correlate best with their affinity for estrogen receptor and not with affinity for AEBS. Antiestrogens undergo bioactivation and metabolism in vivo and hydroxylated forms of the antiestrogen have markedly enhanced affinities for the estrogen receptor. Detailed studies with high affinity radiolabelled antiestrogens indicate that antiestrogens induce important conformational changes in receptor that are reflected in the enhanced maintenance of a 5 S form of the estrogen receptor complex; reduced interaction with DNA; and altered activation and dissociation kinetics of the antiestrogen-estrogen receptor complex. These conformational changes effected by antiestrogens likely result in different interactions with chromatin, causing altered cell proliferation and protein synthesis. Analyses of the rates of synthesis and turnover of the estrogen receptor through pulse-chase experiments utilizing the covalently attaching antiestrogen, tamoxifen aziridine, and studies employing dense amino acid labeling of estrogen receptor reveal that the antiestrogen-occupied receptor is degraded at a rate (t 1/2 = 4 h) similar to that of the control unoccupied receptor. Hence, antiestrogens do not prevent estrogen receptor synthesis and they do not either accelerate or block estrogen receptor degradation.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Antiestrogen action in breast cancer cells: modulation of proliferation and protein synthesis, and interaction with estrogen receptors and additional antiestrogen binding sites. 402 93

The antiestrogenic character and potency of 4-(N,N-diethylaminoethoxy)-4'-methoxy-alpha-(p-hydroxyphenyl)-alpha' -ethylstilbene (H1285) and its binding to estrogen receptor and to estrogen-noncompetible antiestrogen binding sites have been studied in MCF-7 human breast cancer cells. H1285 has an affinity for the estrogen receptor (Kd 0.23 nM) which is comparable to that of estradiol (Kd 0.25 nM), and the binding of these two compounds to estrogen receptor is mutually competitive. On high salt sucrose gradients, the sedimentation profiles of nuclear receptor complexes with H1285 and estradiol are different. While the sedimentation profile of the complex with estradiol varies with the buffer composition, being 4.1S in phosphate:thioglycerol: glycerol and predominantly 5.5S in Tris:EDTA buffered gradients, the H1285 receptor complex shows the same sedimentation (5.5S) regardless of the buffer composition. H1285 also binds to estrogen-noncompetable antiestrogen binding sites that are distinct from the estrogen receptor with a low affinity, only 15% that of the antiestrogen tamoxifen. The biological character and potency of H1285 were examined by determining its effects on cell proliferation, cellular progesterone receptor levels, and plasminogen activator activity. In MCF-7 cells, H1285 was a 30- to 100-fold more potent inhibitor of cell proliferation than was the antiestrogen tamoxifen, and it was approximately equipotent with the higher affinity antiestrogen trans-hydroxytamoxifen. H1285 evoked very minimal increases in cellular progesterone receptor levels, and no increase in plasminogen activator activity over a broad range of concentrations (10(-10)-10(-6)M), and it suppressed plasminogen activator activity stimulated by estradiol. Therefore, by the criteria we have used, we conclude that H1285 is a potent and very effective antiestrogen in MCF-7 cells. The ability of estradiol to reverse the suppression of cell proliferation by H1285, and the high affinity of H1285 for estrogen receptor and its low affinity for estrogen-noncompetible antiestrogen binding sites suggest that H1285 exerts its antiestrogenic effects via interaction with the estrogen receptor of these breast cancer cells.
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PMID:Antiestrogenic potency and binding characteristics of the triphenylethylene H1285 in MCF-7 human breast cancer cells. 404 Aug 7

Tamoxifen is used widely in the treatment of endocrine-responsive breast cancers in humans. Studies were undertaken to examine the biological character (estrogenic-antiestrogenic properties) and estrogen receptor (ER) interaction of the cis- and trans-isomers of tamoxifen and hydroxytamoxifen in MCF-7 human breast cancer cells. For each compound, the following parameters were monitored: affinity for ER and effects on cellular ER levels; stimulation-inhibition of cell growth, plasminogen activator activity, and cellular progesterone receptor levels; and isomer interconversion and metabolism in vitro. The relative binding affinities of the compounds cis-tamoxifen, trans-tamoxifen, cis-hydroxytamoxifen, and trans-hydroxytamoxifen for cytosol ER were 0.3, 2.5, 1.8, and 310%, respectively, in which the affinity of estradiol is considered 100%. cis-Tamoxifen behaved as a weak estrogen agonist in all assays, while trans-tamoxifen was an effective estrogen antagonist. cis-Tamoxifen behaved like estradiol in stimulating MCF-7 cell growth and increasing plasminogen activator activity and cellular progesterone receptor content, although very much higher concentrations of cis-tamoxifen (10(-6) M) were needed to achieve the levels of stimulation observed with 10(-10) M estradiol. trans-Tamoxifen and trans-hydroxytamoxifen suppressed cell growth, inhibited plasminogen activator activity of control cells, and suppressed estradiol-stimulation of plasminogen activator activity, and they evoked minimal increases in cellular progesterone receptor levels. trans-Hydroxytamoxifen had a 100-fold increased affinity for ER and was approximately 100-times more potent than was trans-tamoxifen in suppressing cell growth and plasminogen activator activity. cis-Hydroxytamoxifen behaved as an estrogen antagonist, suppressing cell growth and plasminogen activator activity, and it elicited submaximal increases in progesterone receptor levels. This apparently paradoxical behavior of cis-hydroxytamoxifen was shown to be due to the fact that the cis- and trans-hydroxytamoxifens readily undergo isomeric interconversion upon exposure to our cell culture conditions, resulting in substantial accumulation of the higher-affinity trans-hydroxytamoxifen in the nuclear ER fraction of cells. In contrast to the facile interconversion of the hydroxytamoxifen isomers, there is no metabolism or interconversion of the parent compounds cis- and trans-tamoxifen in vitro. Hence, by the criteria we have used, the biological characters of trans-tamoxifen and trans-hydroxytamoxifen are similar, the major difference being the approximately 100-fold enhanced potency of the hydroxylated form. In contrast, cis-t
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PMID:Bioactivities, estrogen receptor interactions, and plasminogen activator-inducing activities of tamoxifen and hydroxy-tamoxifen isomers in MCF-7 human breast cancer cells. 653 99

A substantial proportion of human breast cancers contain estrogen receptors, and it is believed that the growth of some of these tumors and their synthesis of specific proteins are stimulated by estrogens. Since natural estrogens, such as estradiol, react reversibly with estrogen receptors, it was of interest to determine the biological consequences that would result from very strong, possibly irreversible interaction of an estradiol-based ligand with the estrogen receptor of breast cancer cells. For these studies, we have examined the receptor interactions and biological character of 11 beta- chloromethylestradiol (CME) and 11 beta- bromomethylestradiol (BME) as potential estradiol-based affinity labeling ligands in MCF-7 human breast cancer cells which contain high levels of estrogen receptors. The apparent relative binding affinities of CME and BME for MCF-7 estrogen receptor measured by competitive binding assay are 230 and 15%, respectively, whereas the affinity of estradiol is considered 100%. Incubation of receptor preparations from MCF-7 cells or rat uteri with CME at 21 degrees results in a concentration- and time-dependent decrease in receptor content measured by exchange assays with [3H]estradiol. This may be due to covalent attachment of CME to receptor and is termed "inactivation." Inactivation of 80 to 85% of the receptors occurs within 30 min at 21 degrees by exposure to 5 or 20 nM CME, with 2 nM giving 20 to 40% inactivation. This receptor inactivation is prevented by preincubation with 2000 nM estradiol, indicating that the interaction of CME is occurring at the estradiol binding site on the receptor. MCF-7 cells incubated with 20 nM CME show a rapid loss of cytosol receptor sites and no accumulation of receptors detectable by exchange assay in the nucleus, while 20 nM estradiol shows nuclear localization of receptor. BME, in contrast, inactivates only a portion (approximately 40%) of estrogen receptors. CME and BME both behave as estrogen agonists. They stimulate the proliferation of MCF-7 cells and increase cellular progesterone receptor content and plasminogen activator activity. CME is at least as potent as estradiol on a molar basis in increasing all of these activities, while BME shows a biopotency of only 1% of that of estradiol or CME. Hence, although CME reacts very strongly and apparently irreversibly with estrogen receptors in MCF-7 cells, it still behaves as a potent estrogen agonist.
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PMID:Biological activity and receptor binding of a strongly interacting estrogen in human breast cancer cells. 654 74

The production of plasminogen activator by the human breast cancer cell line MCF-7 was stimulated by physiological concentrations of estradiol under conditions where the growth of the cells was neither dependent on nor stimulated by estradiol. Stimulation was measurable within 8 hr after the addition of estradiol and was evident in both the level of plasminogen activator released into the culture medium and the level within the cells. The level of production varied with cell density, but production was stimulated by estradiol at all densities tested. The antiestrogen tamoxifen inhibited estrogen stimulation, and this inhibition could be overcome by increased concentrations of estradiol. Production was also stimulated by progesterone and could be stimulated by lower levels of progesterone in cells pretreated with estradiol or tamoxifen, both of which have been reported to increase the level of progesterone receptor in these cells. It has been reported that estrogen is essential and that progesterone is stimulatory for the formation of tumors by MCF-7 cells in athymic mice. The ability of these same two hormones to stimulate the production of plasminogen activator by these cells, under conditions where they have no effect on cell growth, raises the possibility that estrogen may not play a mitogenic role in the growth of these tumors. Rather, it may support tumor growth by inducing the cells to produce products, such as plasminogen activator, and possibly take on other characteristics essential to the malignant state.
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PMID:Steroid stimulation of plasminogen activator production in a human breast cancer cell line (MCF-7). 668 6


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