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Query: UMLS:C0276241 (MCF)
 28,353 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The aromatase cytochrome P450 complex is responsible for the in vivo conversion of androgens to estrogens. Although breast cancer epithelial cells have been reported to have appreciable aromatase activity, its biologic significance remains uncertain. To address this, the effect of androgens on the expression of the estrogen-regulated gene pS2 in hormone-dependent human breast carcinoma cells in vitro was examined. Steroid-deprived MCF-7 cells were exposed to varying concentrations (1 nM, 10 nM, and 100 nM of androstenedione or testosterone for 2,4, and 6 days. Baseline aromatase activity was 4.9 (+/-3.1) fmol 3H2O/hour/microgram DNA [34.3 (+/-21.3) fmol/hr/10(6) cells] and was not influenced by the androgens. As an indication of estrogen biosynthesis, northern analysis was performed to quantitate pS2 mRNA expression. Although no significant pS2 induction was observed at 2 days, both 4 and 6 day exposure to 100 nM testosterone resulted in a 3-fold increase in pS2 mRNA expression. 5 alpha-dihydrotestosterone (5 alpha-DHT) failed to elicit a similar pS2 response. This testosterone-induced response was inhibited with the aromatase inhibitor 7 alpha (4'-amino) phenylthio-1,4-androstadiene-3,17-dione (7 alpha-APTADD) and with 10 microM tamoxifen. MCF-7 breast cancer cells possess endogenous aromatase activity at high enough levels to convert androgens to estrogens and elicit an estrogen-induced response. The expression of aromatase may offer a potential advantage to hormone-responsive cells, providing an additional autocrine growth pathway which may be exploited.
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PMID:Androgens influence estrogen-induced responses in human breast carcinoma cells through cytochrome P450 aromatase. 916 78

The expression of aromatase is tissue-specifically regulated through the alternative use of multiple exons 1 and promoters. We analysed expression levels of aromatase mRNA, preferential utilization of multiple exon 1 of the human aromatase gene, and transcriptional regulation of their multiple promoters in breast cancer tissues by newly developed fluorometric methods. The expression levels of aromatase mRNA in breast cancer tissues were significantly higher than those in regions distal to tumours or in non-malignant breast tissues. Aromatase mRNA in these non-malignant tissues was transcribed from skin fibroblast/fetal liver-specific exon 1 (exon 1b) of the aromatase gene. However, in half the cases of breast cancer patients, the utilization of multiple exons 1 in the aromatase mRNA changed from exon 1b to ovary-specific exon 1 (exon 1c) in their breast tissues. Aromatase mRNA in HepG2 cells as well as in non-malignant breast tissues was also transcribed from exon 1b. Then, the promoter region responsible for the exon 1b-specific utilization in HepG2 cells was examined by fluorometric promoter assay using a new reporter containing four major alternative exons 1 and promoters. The results suggested that transcriptional elements determining preferential utilization of exon 1b in the cells was located on the promoter region of exon 1b from -255 to -1145. To investigate further the cause of the elevation of aromatase mRNA and the switching from exon 1b to exon 1c in the transcription of the aromatase gene, the effects of various factors on the expression levels and preference of alternative exons 1 were examined in cultured adipose stromal cells from breast tissues. Aromatase mRNA was transcribed from exon 1b in the stromal cells, cultured in the presence of calf serum. However, removal of the serum or the addition of forskolin or phorbol ester (TPA) induced a rapid elevation of aromatase mRNA and the switching of aromatase transcripts to exon 1c in the cells, whereas TGFbeta almost abolished the expression of aromatase mRNA. Because co-culture of cancer cells such as MCF-7 increased aromatase mRNA of the cells cultured in the serum-containing medium, it is possible that cancer cells secret stimulatory factors acting like forskolin or TPA, or consume serum inhibitory factors acting like TGFbeta, consequently causing levels of aromatase mRNA to increase.
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PMID:Aberrant expression of aromatase in breast cancer tissues. 936 88

Cytokines such as interleukin-6 (IL-6) and tumour necrosis factor alpha (TNF alpha), have been identified as important regulators of aromatase activity in fibroblasts derived from normal and malignant breast tissues, and may play an important role in controlling aromatase activity in breast tumours. The major source of such cytokines within breast tumours remains to be established but macrophages and lymphocytes, which can infiltrate tumours, have been identified as a potential source of aromatase stimulatory cytokines. To obtain further insight into the possible role played by the immune system in cancer development, and in particular its ability to regulate aromatase activity via cytokine production, we have obtained peripheral blood monocytes and lymphocytes from an immunosuppressed kidney transplant recipient, receiving cyclosporin A therapy, and a woman with breast cancer. Monocytes and lymphocytes were stimulated with lipopolysaccharide (LPS), and the conditioned medium (CM) collected from these cells was tested for its ability to stimulate aromatase activity in fibroblasts derived from normal breast tissue from a woman undergoing lumpectomy for the removal of a breast tumour. The white blood cell count was lower for the immunosuppressed patient, mainly because of the reduction in the number of monocytes and lymphocytes. The ability of CM from the monocytes and lymphocytes of the immunosuppressed patient to stimulate aromatase activity was significantly reduced (68% and 82% for monocytes and lymphocytes, respectively) compared with that of CM from the cells of the woman with breast cancer. It is possible, therefore, that immunosuppression, which has been found to be associated with a reduction in the incidence of de novo breast cancer in kidney transplant recipients, may exert its effect by inhibiting cytokine production by the cells of the immune system and thus oestrogen synthesis. In contrast to the stimulatory effects that TNF alpha has on aromatase activity in breast fibroblasts, in MCF-7 breast cancer cells, which possess low aromatase activity, it reduced activity. However, the extent of inhibition of aromatase activity in these epithelial cells was much lower than the marked stimulation which it can induce in breast fibroblasts.
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PMID:Control of aromatase activity in breast tumours: the role of the immune system. 936 89

The inhibition of aromatase, the enzyme responsible for converting androgens to estrogens, is therapeutically useful for the endocrine treatment of hormone-dependent breast cancer. Research by our laboratory has focused on developing competitive and irreversible steroidal aromatase inhibitors, with an emphasis on synthesis and biochemistry of 7alpha-substituted androstenediones. Numerous 7alpha-thiosubstituted androst-4-ene-3,17-diones are potent competitive inhibitors, and several 1,4-diene analogs, such as 7alpha-(4'-aminophenylthio)-androsta-1,4-diene-3,17-di one (7alpha-APTADD), have demonstrated effective enzyme-activated irreversible inhibition of aromatase in microsomal enzyme assays. One focus of current research is to examine the effectiveness and biochemical pharmacology of 7alpha-APTADD in vivo. In the hormone-dependent 7,12-dimethylbenz(a)anthracene (DMBA)-induced rat mammary carcinoma model system, 7alpha-APTADD at a 50 mg/kg/day dose caused an initial decrease in mean tumor volume during the first week, and tumor volume remained unchanged throughout the remaining 5-week treatment period. This agent lowers serum estradiol levels and inhibits ovarian aromatase activity. A second research area has focused on the synthesis of more metabolically stable inhibitors by replacing the thioether linkage at the 7alpha position with a carbon-carbon linkage. Several 7alpha-arylaliphatic androst-4-ene-3,17-diones were synthesized by 1,6-conjugate additions of appropriate organocuprates to a protected androst-4,6-diene or by 1,4-conjugate additions to a seco-A-ring steroid intermediate. These compounds were all potent inhibitors of aromatase with apparent Kis ranging between 13 and 19 nM. Extension of the research on these 7alpha-arylaliphatic androgens includes the introduction of a C1-C2 double bond in the A-ring to provide enzyme-activated irreversible inhibitors. The desired 7alpha-arylaliphatic androsta-1,4-diene-3,17-diones were obtained from their corresponding 7alpha-arylaliphatic androst-4-ene-3,17-diones by oxidation with 2,3-dichloro-5,6-dicyano-1,4-benzoquinone (DDQ). These inhibitors demonstrated enzyme-mediated inactivation of aromatase with apparent k(inact)s ranging from 4.4 x 10(-4) to 1.90 x 10(-3) s(-1). The best inactivator of the series was 7alpha-phenpropylandrosta-1,4-diene-3,17-dione, which exhibited a T(1/2) of 6.08 min. Aromatase inhibition was also observed in MCF-7 human mammary carcinoma cell cultures and in JAr human choriocarcinoma cell cultures, exhibiting IC50 values of 64-328 nM. The 7alpha-arylaliphatic androgens thus demonstrate potent inhibition of aromatase in both microsomal incubations and in choriocarcinoma cell lines expressing aromatase enzymatic activity. Additionally, the results from these studies provide further evidence for the presence of a hydrophobic binding pocket existing near the 7alpha-position of the steroid in the active site of aromatase. The size of the 7alpha-substituent influences optimal binding of steroidal inhibitors to the active site and affects the extent of enzyme-mediated inactivation observed with androsta-1,4-diene-3,17-dione analogs.
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PMID:Biochemistry and pharmacology of 7alpha-substituted androstenediones as aromatase inhibitors. 936 97

Studies of breast tumor homogenates from women with breast cancer have demonstrated the synthesis of estrogens in situ through the enzyme aromatase. The present series of investigations sought to determine which cell type within the tumor is responsible for local estrogen biosynthesis, and whether or not the amount produced is biologically important. Accordingly, we utilized an indirect immunohistochemical scoring method (H-score) to determine the relative amount of enzyme present in tumor epithelial and stromal cells. This revealed a value of 13 for tumor stromal cells and 4.8 for the epithelial component. Contributing to this difference is the fact that a greater percentage of cells in the tumor were stromal (45%) than epithelial (37%). To obtain direct evidence that tumor stromal cells could synthesize estrogens, we isolated and grew these cells in tissue culture. Stromal cells originating from within the tumor could be stimulated by known enhancers of transcription to produce nearly as much aromatase as is found in placental microsomes. Stromal cells isolated from benign tissue distal to the tumor exhibited properties similar to those of the tumor stroma. Epithelial cells, in contrast, did not respond to these enhancers and had low levels of aromatase basally. To obtain proof of the principle that local estrogen synthesis can be biologically meaningful, we measured tumor tissue estradiol levels and growth rates in aromatase-transfected MCF-7 cells implanted into nude mice. Local synthesis resulted in tumor levels ranging from 300 to 800 pg/g and growth rates substantially higher than in non-aromatase-containing tumors. These data suggest that tumor stromal cells contribute the major portion of estrogen synthesized in tumors, and that this local synthesis can increase tumor estradiol levels and growth rates.
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PMID:Estrogen production via the aromatase enzyme in breast carcinoma: which cell type is responsible? 936

The expression of aromatase in human breast tumors was studied using the reverse transcription-polymerase chain reaction (RT-PCR) method on 70 breast tissue specimens. An RT-PCR analysis using two oligonucleotide primers derived from exon II of the human aromatase gene revealed that aromatase mRNA was detected in all but three tissue specimens. Furthermore, primer-directed RT-PCR was performed to determine the exon I usage in aromatase mRNA in these breast tumor specimens. The analysis revealed that exons I.3 and PII are the two major exons I present in aromatase mRNA isolated from breast tumors, suggesting that promoters I.3 and II are the major promoters driving aromatase expression in breast cancer and surrounding adipose stromal cells (ASCs). Recently, the regulatory properties of a 696-base pair region that contains promoter II, and is situated immediately upstream of exon II of the human aromatase gene, were investigated. Detailed DNase 1 footprinting analysis, DNA mobility shift assays, and chloramphenicol acetyltransferase (CAT) functional studies of this genomic region were performed and led to the identification of a segment (B1) that could act as a promoter (probably promoter I.3) in adipose stromal and breast cancer cells. The study further revealed that the B1 region could be divided into two domains which were designated RE1 and RE2. RE1 was found to have the promoter activity, and RE2 was found to regulate the promoter activity of RE1, but in different manners in MCF-7 cells (as an example of breast cancer cells) and in ASCs. RE2 was found to function as a positive regulatory element in MCF-7 cells and as a negative regulatory element in ASCs, respectively. It was also found that in several breast cancer cell lines, including MCF-7, the promoter activities of both promoter II and promoter I.3 were found to be suppressed by a negative regulatory element, a silencer, present in the 162 bp fragment which is located upstream from promoter II and downstream from promoter I.3. The precise position of the silencer element (termed S1) was localized by deletion mutation and DNase 1 footprinting analysis, and the silencing activity of S1 on promoter I.3 (in B1 fragment) was confirmed by CAT plasmid transfection experiments. UV crosslinking experiments are being performed to examine the regulatory proteins interacting with the silencer element. These studies serve as the basis for the further characterization of the regulatory mechanism of aromatase expression in human breast cancer and ASCs.
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PMID:Gene regulation studies of aromatase expression in breast cancer and adipose stromal cells. 936 1

We investigated conversion rates of androgens to estrogens in cultured, hormone-responsive prostate (LNCaP) and breast (MCF-7) human cancer cells. For this purpose, we adopted an intact cell analysis, whereby cells were incubated for different incubation times in the presence of close-to-physiological (1 nM) or supraphysiological (1 microM) concentrations of labelled androgen precursors, i.e. testosterone (T) and androstenedione (delta4Ad). The aromatase activity, as measured by estrogen formation, was detected in LNCaP cells (0.5 pmol/ml), even though to a significantly lower extent than in MCF-7 cells (5.4 pmol/ml), using 1 microM T after 72 h incubation. Surprisingly, LNCaP cells displayed a much higher aromatase activity when T was used as a substrate with respect to delta4Ad. In either cell line, T transformation to delta4Ad was relatively low, attaining only 2.8% in LNCaP and 7.5% MCF-7 cells. However, T was mostly converted to conjugates (over 95%), glucuronides and some sulphates, in LNCaP cells, whereas it was only partly converted to sulphates (<10%) in MCF-7 cells. Aromatase activity seems to be inconsistent in LNCaP cells, being strongly affected by culture conditions, especially by fetal calf serum (FCS). Further studies should assess the regulation of aromatase expression by serum or growth factors in different human cancer cells, also using anti-aromatase and/or anti-estrogen compounds, in different culture conditions.
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PMID:Product of aromatase activity in intact LNCaP and MCF-7 human cancer cells. 936 3

Aromatization or in situ estrogen production by aromatase has been considered to play an important role in the development of human breast carcinoma. In the human breast, aromatase overexpression is observed in the stromal or interstitial cells of the carcinoma, especially at the sites of frank invasion and/or adipose tissue. Transplantation experiments in the nude mouse employing MCF-7 and/or SF-TY human fibroblast cell lines revealed that aromatase activity and expression were much higher in the tumour with MCF-7 and SF-TY than that with MCF-7 alone. Aromatase overexpression in human breast carcinoma tissue is considered to occur as a result of carcinoma-stromal cell interactions, i.e. paracrine communication between stromal and carcinoma cells. Aromatase overexpression is correlated with the malignant phenotype in the human breast, but not with stage, age, clinical stages, clinical course, or proliferative activity of breast carcinoma. Aromatase overexpression may be correlated with development, rather than the biological behaviour of breast malignancy. Aromatase overexpression is not necessarily correlated with expression of 17beta-hydroxysteroid dehydrogenase type 1, which converts estrone to estradiol and estrogen receptor. Different mechanisms may be involved in the regulation of expression of these two important estrogen-metabolizing enzymes and estrogen receptor in human breast cancer. Aromatase overexpression in intratumoral stromal cells was much more frequently detected in male breast cancer than in female counterparts, which confers a growth advantage on cancer cells in a male hormonal environment with low serum estrogen levels.
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PMID:Aromatase expression and its localization in human breast cancer. 936 4

Tamoxifen is the endocrine therapy of choice for all stages of breast cancer. However, the drug cannot be considered to be a cure as drug resistance will eventually develop. The resistance can take two forms: either the loss of estrogen receptor or the selection of estrogen receptor positive disease that is tamoxifen stimulated for growth. Laboratory studies have demonstrated that tamoxifen-stimulated MCF-7 breast tumors can develop in athymic mice. A number of pure (nonestrogenic) antiestrogens have been discovered that can either be administered by injection (e.g., ICI 182,780) or orally (e.g., EM-800). In preliminary clinical studies, the compound ICI 182,780 (Faslodex) has been shown to be an effective second-line therapy after tamoxifen failure. The goal of future clinical studies is to evaluate the therapeutic efficacy and patient acceptability of aromatase inhibitors (postmenopausal estrogen withdrawal), and injectable or oral pure antiestrogens after the failure of long-term tamoxifen therapy. Clearly, the primary purpose for the treatment of advanced breast cancer is to control disease growth; nevertheless, an evaluation of the effect of new agents on bones and lipids is required before pure antiestrogens could be considered for adjuvant therapy.
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PMID:Pure antiestrogens as a new therapy for breast cancer. 943 92

Stable aromatase-expressing MCF-7 and T-47D cell lines (i.e. MCF-7aro and T-47Daro) have been prepared by aromatase cDNA transfection and G418 (neomycin) selection. MCF-7aro was further subjected to a clonal purification. Aromatase activity in the transfected MCF-7 and T-47D cell lines was determined to be 73 +/- 6 pmol/mg/h and 48 +/- 4 pmol/mg/h, respectively. It is thought that these cell lines express aromatase in a stable manner, as demonstrated by a steady expression of the enzyme during culture in the absence of G418. The growth of these cells could be stimulated by androgens (1-10 nM) as demonstrated through a spheroid culture method. The androgen-stimulated growth could be suppressed by 4-hydroxyandrostenedione (4-OHA) (0.01-0.1 mM) or tamoxifen (50 nM-1 microM). In order to test the hypothesis that tumor aromatase can affect breast tumor growth in a paracrine manner, we have carried out cell culture experiments by co-culturing MCF-7 cells with either MCF-7aro or T-47Daro cells. Testosterone (1 nM) increased cell growth to a similar degree for MCF-7/MCF-7aro co-culture (0.75 x 10(6) cells each type) as with MCF-7aro only (2- to 3-fold). In addition, the enzyme activities remained unchanged for MCF-7/MCF-7aro co-culture samples with and without androgen treatment, indicating that estrogen produced by transfected cells can also stimulate the growth of untransfected cells. The androgen response could be inhibited by an addition of 4-OHA (0.01-0.1 mM). For MCF-7/T-47Daro co-culture experiments, a clear induction of cell growth by androgen was observed, and the level of the increase was similar to that on T-47Daro only. However, for either culture with T-47D only or with MCF-7/T-47Daro co-culture, the aromatase activity was found to increase significantly after testosterone treatment. T-47Daro cells were not subjected to a clonal purification, and it is therefore thought that the androgen treatment may selectively stimulate the growth of high aromatase-expressing T-47Daro cells. These results indicate that estrogen synthesized by tumor aromatase can stimulate breast tumor growth in both an autocrine and a paracrine manner.
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PMID:Autocrine and paracrine actions of breast tumor aromatase. A three-dimensional cell culture study involving aromatase transfected MCF-7 and T-47D cells. 944 3


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