Oxidative and reductive pathways of estrogens in hormone responsive and non-responsive human breast cancer cells in vitro

Altered androgen metabolism eventually leads hepatocellular carcinoma to an impaired hormone responsiveness

Sex steroid hormones are thought, among several other risk factors, to play a role in liver malignancies. For example, from epidemiological studies in hepatocellular carcinoma (HCC), a clear disadvantage for male sex is evident. In addition, elevated levels of serum testosterone (T) and increased T to Estradiol (E(2)) ratio have been reported to predict an increased risk of HCC for male cirrhotic patients. On the other hand, palliative treatment of liver cancer patients with anti-hormones has been widely used in the past. However, the molecular mechanism(s) underlying sex steroid action on either normal or transformed liver cells, have not yet been fully clarified, nor endocrine discriminants have been satisfactorily assessed for an adequate characterization of liver cancer tissues. In this paper, we report studies on hormonal status of human liver tissues and cells, especially focusing on androgens, to better define endocrine end-points of interest for HCC. A consistent evidence from ex vivo or in vitro systems strongly suggests that high affinity binding sites of androgens are expressed at sufficient concentrations to induce a biological response in either normal or phenotipically transformed hepatocytes; in the latter, however, high heterogeneity and/or more scattering concentrations were encountered. Further, experimental data seem to suggest that lack of response to androgens may be due to a rapid metabolic conversion of steroids by neoplastic tissues and cells. Cancer hepatocytes privilege in fact 5beta more than 5alpha metabolic pathway of androgens. This may eventually lead biologically active androgens to be transformed into less active derivatives, as it occurs for T which is massively converted (>90% at 6 h) thus hindering the whole mechanism of action of androgens.

Effects of phytoestrogens and synthetic combinatorial libraries on aromatase, estrogen biosynthesis, and metabolism

Approximately 60% of breast cancer patients have hormone-dependent breast cancer containing estrogen receptors and requiring estrogen for tumor growth. The extent of estrogen biosynthesis and metabolism in the breast cancer tissue microenvironment influences breast-tumor development and growth, and endogenous and exogenous agents may alter the levels of hormonally active estrogens and their metabolites. Isoflavonoid phytoestrogens such as genistein exhibit numerous biochemical activities; however, their effects on estrogen biosynthesis and metabolism in breast cancer cells have not been fully examined. MCF-7 cells (hormone-dependent) and MBA-MB-231 cells (hormone-independent) were treated with genistein (100 nM) for five days and then incubated with radiolabeled estradiol (100 nM, 2.5 microCi) for 0 to 48 h. Media were extracted with ethyl acetate, and the organic residues analyzed by reverse-phase HPLC with a radioactivity flow detector. The major metabolite formed in all cases is estrone, although differences were observed between the cell lines and the various drug treatments. The formation of estrone in untreated MCF-7 cells (approximately 9.3% of radioactivity at 24 h) is relatively limited, in contrast to untreated MDA-MB-231 cells (approximately 32.0% of radioactivity at 24 h). Treatment of MCF-7 cells with 100 nM genistein increased the conversion of estradiol to estrone up to 19.5% in 24 h. The effect of genistein on estrone formation in MDA-MB-231 cells resulted in 37.7% of the radioactivity being estrone. Thus, genistein treatment of breast cancer cells resulted in increased 17-betahydroxysteroid dehydrogenase activity and elevated formation of estrone. Increased levels of oxidative 17-betahydroxysteroid dehydrogenase activity (Type II) were confirmed by Western blots. Therefore, exposure of breast cancer cells to genistein results in elevated conversion of estradiol to estrogenically weaker or inactive metabolites. The regulation of breast-tissue aromatase by exogenous agents such as drugs and environmental agents is being investigated. The benzopyranone-ring system is a molecular scaffold of considerable interest, and this scaffold is found in flavonoid natural products that have weak aromatase inhibitory activity. Medicinal chemistry efforts focus on diversifying the benzopyranone scaffold and utilizing combinatorial chemistry approaches to construct small benzopyranone libraries as potential aro- matase inhibitors. Several compounds in the initial libraries have demonstrated moderate aromatase inhibitory activity in screening assays.

Endocrine end-points in rheumatoid arthritis

Our previous studies are reviewed and at the same time preliminary experimental observation to the topic of endocrine end-points in autoimmune disease is introduced. To this end, we have used rheumatoid arthritis (RA), including synovial fluids and primary cultures of synovial macrophages, as a model system in order to investigate (a) expression and subcellular localization of high-affinity sites of steroid binding in immune effector cells; (b) steroid metabolic profiles in both male and female RA patients, as compared to healthy subjects; and (c) activities of key steroid enzymes that govern intratissue accumulation of sex hormones. In RA tissues and cells, the concurrent evidence for (1) androgen and/or estrogen receptors, (2) high concentrations of biologically active steroids, (3) key enzymes of steroid metabolism, and (4) significant changes of estrogen to androgen ratio, all strongly suggests that individual immune cells, including synovial macrophages, may behave as steroid-sensitive cells, namely, they may represent a target for sex steroids, supporting the hypothesis of a potential endocrine regulation of the immune response also in RA disease. In this respect, definition of several endocrine end-points may have important implications for the treatment of rheumatic disease and other immunological disorders.

17Beta-hydroxysteroid dehydrogenases in human bone cells

Interconversion of estrogens by osteoblasts may play a role in regulating bone mass. As a first step toward exploring this possibility, we investigated the expression and activity of 17beta-hydroxysteroid dehydrogenases (17beta-HSDs) in cultured human osteoblasts (HOB) and osteoblast-like osteosarcoma cells (MG63, TE85, and SaOS-2). Significant 17beta-HSD activity was detected in cell-free extracts of all bone cells with oxidation of estradiol to estrone predominating over reduction. Reverse transcription-polymerase chain reaction (RT-PCR) experiments showed that the mRNA for 17beta-HSD I was detectable only in MG63 cells, albeit at low levels, while 17beta-HSD II was present in MG63, TE85, and HOB, but not SaOS-2, and 17beta-HSD III was absent from each bone cell type. 17Beta-HSD IV was the only isoform present in all bone cells analyzed. Further analysis of the expression of 17beta-HSD IV in these bone cells by immunoblotting revealed both the full-length 83 kDa protein and the proteolytic 38 kDa form. The kinetic parameters for estradiol oxidation by purified recombinant 17beta-HSD IV (Km = 49.7 microM, Vmax = 79.4 nmol/minute/mg of protein) and its HSD-domain (Km = 79.4 microM, Vmax = 476 nmol/minute/mg of protein) were significantly higher than previously reported, but consistent with the values obtained with crude cell-free extracts of SaOS-2 cells (Km = 98.8 microM, Vmax = 0.07 nmol/minute/mg of protein) which contain only 17beta-HSD IV based on RT-PCR. These studies show that bone cells have the capacity to interconvert circulating estrogens and suggest that bone cell 17beta-HSDs serve primarily to attenuate the continuing actions of estradiol through conversion to its less potent form, estrone, under certain conditions.

Alteration of oestradiol metabolism in myc oncogene-transfected mouse mammary epithelial cells

Targeted overexpression of the c-myc oncogene induces neoplastic transformation in immortalized, non-tumorigenic mouse mammary epithelial cells (MMEC). Experiments in the present study were conducted to examine whether cellular transformation induced by c-myc oncogene is associated with altered metabolism of 17beta-oestradiol (E2). The parental, MMEC and the stable c-myc transfectant (MMEC/myc3) cell lines were compared for major oestrogen metabolic pathways, namely E2 and E1 interconversion, and C2- and C16alpha-hydroxylation by both high-pressure liquid chromatography (HPLC) analysis and the 3H release assay using specifically labelled [C2-3H]E2 or [C16alpha-3H]E2. The reductive conversion of E1 to E2 was about 14-fold and 12-fold higher than the oxidative conversion of E2 to E1 in MMEC and MMEC/myc3 cells respectively. However, in MMEC/myc3 cells, both reductive and oxidative reactions were decreased by about 32% and 12% relative to those seen in the parental MMEC cells (P = 0.0028). The extent of C16alpha-hydroxylation was increased by 164.3% (P < 0.001), with a concomitant 48.4% decrease (P < 0.001) in C2-hydroxylation in MMEC/myc3 cells; this resulted in a fourfold increase in the C16alpha/C2 hydroxylation ratio in this cell line. Thus, a persistent c-myc expression, leading to aberrant hyperproliferation in vitro and tumorigenesis in vivo, is associated with an altered oestrogen metabolism. However, it remains unclear whether this represents a result of oncogene expression/activation or is rather a consequence of phenotypic transformation of the cells.

Expression of different 17beta-hydroxysteroid dehydrogenase types and their activities in human prostate cancer cells

The 17beta-hydroxysteroid dehydrogenase (17betaHSD) enzyme system governs important redox reactions at the C17 position of steroid hormones. Different 17betaHSD types (no. 1-4) have been identified to date in peripheral human tissues, such as placenta, testis, and breast. However, there is little information on their expression and activity in either normal or malignant prostate. In the present work, we have inspected pathways of 17beta-oxidation of either androgen or estrogen in human prostate cancer cells (LNCaP, DU145, and PC3) in relation to the expression of messenger RNAs (mRNAs) for 17betaHSD types 1-4. These cell systems feature distinct steroid receptor status and response to hormones. We report here that high expression levels of 17betaHSD4 were consistently observed in all three cell lines, whereas even greater amounts of 17betaHSD2 mRNA were detected solely in PC3 cells. Neither 17betaHSD1 nor 17betaHSD3 mRNAs could be detected in any cell line. From a metabolic standpoint, intact cell analysis showed a much lower extent of 17beta-oxidation of both androgen [testosterone (T)] and estrogen [estradiol (E2)] in LNCaP and DU145 cells compared to PC3 cells, where a greater precursor degradation and higher formation rates of oxidized derivatives (respectively, androstenedione and estrone) were observed. Using subcellular fractionation, we have been able to differentiate among 17betaHSD types 1-4 on the basis of their distinct substrate specificities and subcellular localization. This latter approach gave rise to equivalent results. PC3 cells, in fact, displayed a high level of microsomal activity with a low E2/T activity ratio and approximately equal apparent Km values for E2 and T, suggesting the presence of 17betaHSD2. Dehydrogenase specific activity with both E2 and T was also detected, although at lower levels, in LNCaP and DU145 cells. No evidence for reductase activity could be obtained in either the soluble or microsomal fraction of any cell line. As comparable expression levels of 17betaHSD4 were seen in the three cell lines, 17betaHSD2 is a likely candidate to account for the predominant oxidative activity in PC3 cells, whereas 17betaHSD4 may account for the lower extent of E2 oxidation seen in both LNCaP and DU145 cells. This is the first report on the expression of four different 17betaHSD types in human prostate cancer cells. It ought to be emphasized that for the first time, analysis of different 17betaHSD activities in either intact or fractionated cells harmonizes with the expression of relevant mRNAs species.

17 beta-Hydroxysteroid dehydrogenase activity in endometrial cancer cells: different metabolic pathways of estradiol in hormone-responsive and non-responsive intact cells

In this paper we report that two human long-term endometrial cancer cell lines, Ishikawa and HEC-1A, exhibit quite different abilities in metabolizing estrogens. As a matter of fact, incubation of Ishikawa cells with close-to-physiological concentrations of estradiol (E2) as precursor resulted in: (1) elevated formation (up to 90%) of E2-sulphate (E2-S), using lower precursor concentrations; (2) very limited conversion to estrone (E1) (< 10% at 24 h incubation), as either free or sulphate; and (3) low but consistent production of other estrogen derivatives, such as 2-hydroxy-estrogens and estriol. Conversely, scant amounts (if any) of E2-S were found in HEC-1A cells, while no detectable formation of other estrogen metabolites could be observed after 24 h. On the other hand, E1 production was significantly greater (nearly 60% at 24 h) than in Ishikawa cells, a large proportion of E1 (over 50% of the total) being formed after only 6 h incubation using time-course experiments. The hypothesis that E2 metabolism could be minor in Ishikawa cells as a consequence of the high rate of E2-S formation encountered is contradicted by the evidence that conversion to E1 also remains limited in the presence of much lower E2-S amounts, seen using higher molar concentrations of precursor. Overall, we observe that 17 beta-hydroxysteroid dehydrogenase (17 beta-HSD) activity diverges significantly in intact Ishikawa and HEC-1A endometrial cancer cells. This difference could not merely be accounted for by the diverse amounts of substrate (E2) available to the cells, nor may it be imputed to different levels of endogenous estrogens. It should rather be sought in different mechanisms controlling 17 beta-HSD activity or, alternatively, in the presence of distinct isoenzymes in the two different cell types.