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Aromatase, estrone (E1) sulfatase and E1 sulfotransferase activities were examined in endometrium and endometrial cancer tissue preparations. Aromatase and E1 sulfatase activities in endometrial cancer tissues were found to be significantly higher than in normal endometrial tissues. However, E1 sulfotransferase activity did not differ between benign and malignant tissue. We also examined the effect of testosterone (T) on aromatase activity and tritiated thymidine uptake (DNA synthesis) in various cultured cervical or corpus endometrial cancer cell lines (OMC-4, HHUA, Ishikawa, HEC-59). The results demonstrated that only the HEC-59 cell line had high aromatase activity and increased its DNA synthesis in response to T. This increase of DNA synthesis by T was not suppressed by simultaneous addition of cyproterone acetate, but was by tamoxifen. These data suggest that in situ estrogen production in endometrial cancer tissue is biologically important and that aromatase in cancer cells may contribute partially to cell proliferation if androgen substrate is provided.
J Steroid Biochem Mol Biol 1993 Mar
PMID:Estrogen productivity of endometrium and endometrial cancer tissue; influence of aromatase on proliferation of endometrial cancer cells. 847 61

Androgen aromatase was found to also be estrogen 2-hydroxylase. The substrate specificity among androgens and estrogens and multiplicity of aromatase reactions were further studied. Through purification of human placental microsomal cytochrome P-450 by monoclonal antibody-based immunoaffinity chromatography and gradient elution on hydroxyapatite, aromatase and estradiol 2-hydroxylase activities were co-purified into a single band cytochrome P-450 with approx. 600-fold increase of both specific activities, while other cytochrome P-450 enzyme activities found in the microsomes were completely eliminated. The purified P-450 showed M(r) of 55 kDa, specific heme content of 12.9 +/- 2.6 nmol.mg-1 (+/- SD, n = 4), reconstituted aromatase activity of 111 +/- 19 nmol.min-1.mg-1 and estradiol 2-hydroxylase activity of 5.85 +/- 1.23 nmol.min-1.mg-1. We found no evidence for the existence of catechol estrogen synthetase without concomitant aromatase activity. The identity of the P-450 for the two different hormone synthetases was further confirmed by analysis of the two activities in the stable expression system in Chinese hamster ovarian cells transfected with human placental aromatase cDNA, pH beta-Aro. Kinetic analysis of estradiol 2-hydroxylation by the purified and reconstituted aromatase P-450 in 0.1 M phosphate buffer (pH 7.6) showed Km of 1.58 microM and Vmax of 8.9 nmol.min-1.mg-1. A significant shift of the optimum pH and Vmax, but not the Km, for placental estrogen 2-hydroxylase was observed between microsomal and purified preparations. Testosterone and androstenedione competitively inhibited estradiol 2-hydroxylation, and estrone and estradiol competitively inhibited aromatization of both testosterone and androstenedione. Estrone and estradiol showed Ki of 4.8 and 7.3 microM, respectively, for testosterone aromatization, and 5.0 and 8.1 microM, respectively, for androstenedione aromatization. Androstenedione and testosterone showed Ki of 0.32 and 0.61 microM, respectively, for estradiol 2-hydroxylation. Our studies showed that aromatase P-450 functions as estrogen 2-hydroxylase as well as androgen 19-, 1 beta-, and 2 beta-hydroxylase and aromatase. The results indicate that placental aromatase is responsible for the highly elevated levels of the catechol estrogen and 19-hydroxyandrogen during pregnancy. These results also indicate that the active site structure holds the steroid substrates to face their beta-side of the A-ring to the heme, tilted in such a way as to make the 2-position of estrogens and 19-, 1-, and 2-positions of androgens available for monooxygenation.
J Steroid Biochem Mol Biol 1993 Mar
PMID:Multiple functions of aromatase and the active site structure; aromatase is the placental estrogen 2-hydroxylase. 847 62

The aromatase (estrogen synthetase) enzyme catalyzes the conversion of androgens to estrogens in peripheral tissues, as well as in the brain. Our study aimed at comparing the brain distribution of aromatase-immunoreactive neurons in male and female, normal and gonadectomized rats. Light microscopic immunostaining was employed using a purified polyclonal antiserum raised against human placental aromatase. Two anatomically separate aromatase-immunoreactive neuronal systems were detected in the rat brain: A "limbic telencephalic" aromatase system was composed by a large population of labeled neurons in the lateral septal area, and by a continuous "ring" of neurons of the laterodorsal division of the bed nucleus of stria terminalis, central amygdaloid nucleus, stria terminalis, and the substantia inominata-ventral pallidum-fundus striati region. The other, "hypothalamic" aromatase system consisted of neurons scattered in a dorsolateral hypothalamic area including the paraventricular, lateral and dorsomedial hypothalamic nuclei, the subincertal nucleus as well as the zona incerta. In addition, a few axon-like processes (unresponsive to gonadectomy) were present in the preoptic-anterior hypothalamic complex, the ventral striatum, and midline thalamic regions. No sexual dimorphism was observed in the distribution or intensity of aromatase-immunostaining. However, 3 days, 2, 3, 8, 16, or 32 weeks after gonadectomy, aromatase-immunoreactive neurons disappeared from the hypothalamus, whereas they were still present in the limbic areas of both sexes. The results indicate the existence of two distinct estrogen-producing neuron systems in the rat brain: (1) a "limbic ring" of aromatase-labeled neurons of the lateral septum-bed nucleus-amygdala complex unresponsive to gonadectomy; and (2) a sex hormone-sensitive "hypothalamic" aromatase neuron system.
J Steroid Biochem Mol Biol 1993 Mar
PMID:Aromatase immunoreactivity in the rat brain: gonadectomy-sensitive hypothalamic neurons and an unresponsive "limbic ring" of the lateral septum-bed nucleus-amygdala complex. 847 63

Estrogens are required for both the organization of the brain in early development and adult behavior. Two approaches have been used in our laboratory to study the behavioral role of brain aromatase. First, brain metabolism of testosterone (T) has been related to behavior in the same individual using a well established neuroendocrine model, the ring dove, in which estradiol-17 beta (E2) has specific effects on brain mechanisms of male behavior. Aromatase in preoptic area (POA) (a) has a high activity (Vmax) and strong substrate binding affinity (Km < 5 nM), (b) is regulated by both androgens and estrogens, and the type of regulation differs according to brain area, (c) is influenced by products of an endogenous inactivating pathway, 5 beta-reduction; 5 beta-dihydrotestosterone and other 5 beta-reduced metabolites appear to be non-genomic regulators of the brain aromatase. Preoptic aromatase activity is also influenced by photoperiod and socio-sexual stimuli. The codistribution of regulated aromatase activity and estrogen receptor cells is found to be T-dependent. Our second approach has been to relate the aromatase system to developmental sex differences in brain structure and behavior of the Mongolian gerbil. Neonatal gerbil aromatase is relatively active in the POA, but has a weaker T substrate-binding affinity (Km = 30 nM) than the dove. T acting via its metabolite, E2, masculinizes the sexually dimorphic area of the hypothalamus; the differentiating effect is asymmetric. We suggest that the regulation of the brain aromatase system may be lateralized during steroid-sensitive periods of development.
J Steroid Biochem Mol Biol 1993 Mar
PMID:Aromatase: neuromodulator in the control of behavior. 847 65

The activational effects of testosterone (T) on male copulatory behavior are mediated by its aromatization into estradiol. In quail, we have shown by stereotaxic implantation of steroids and metabolism inhibitors and by electrolytic lesions that the action of T and its aromatization take place in the sexually dimorphic medial preoptic nucleus (POM). The distribution and regulation of brain aromatase was studied in this species by product-formation assays measuring aromatase activity (AA) in microdissected brain regions and by immunocytochemistry (ICC). Aromatase-immunoreactive (ARO-ir) neurons were found in four brain regions: the POM, the septal region, the bed nucleus of the stria terminals (BNST) and the tuberal hypothalamus. ARO-ir cells actually outline the POM boundaries. ARO-ir material is found not only in the perikarya of neurons but also in the full extension of their cellular processes including the axons and the presynaptic boutons. This is confirmed at the light level by the demonstration of immunoreactive fibers and punctate structures in brain regions that are sometimes fairly distant from the closest ARO-ir cells. A lot of ARO-ir cells in the POM and BNST do not contain immunoreactive estrogen receptors (ER-ir) as demonstrated by double label ICC. These morphological data suggest an unorthodox role for the enzyme or the locally formed estrogens. In parallel with copulatory behavior, the preoptic AA decreases after castration and is restored by T to levels seen in sexually mature males. This probably reflects a change in enzyme concentration rather than a modulation of the activity in a constant number of molecules since the maximum enzymatic velocity (Vmax) only is affected while the affinity (Km) remains unchanged. In addition, T increases the number of ARO-ir neurons in POM and other brain areas suggesting that the concentration of the antigen is actually increased. This probably involves the direct activation of aromatase transcription as demonstrated by RT-PCR studies showing that aromatase mRNA is increased following T treatment of castrates. These activating effects of T seem to result from a synergistic action of androgenic and estrogenic metabolites of the steroid. The anatomical substrate for these regulations remains unclear at present especially in POM where ARO-ir cells do not in general contain ER-ir while androgen receptors appear to be rare based on both [3H] dihydrotestosterone autoradiography and ICC. Transynaptic mechanisms of control may be considered. A modulation of brain aromatase by catecholamines is also suggested by a few pharmacological studies.(ABSTRACT TRUNCATED AT 400 WORDS)
J Steroid Biochem Mol Biol 1993 Mar
PMID:Brain aromatase and the control of male sexual behavior. 847 66

Due to exceptionally high brain aromatase activity, teleost fish are advantageous for studying neural aromatase regulation, localization, and physiology. To determine the molecular mechanism of enhanced expression, we have isolated, cloned and sequenced a 3 kb full-length aromatase cDNA from a goldfish (Carassius auratus) brain library using a human placental aromatase cDNA as probe. The deduced sequence of goldfish aromatase is 510 amino acids (predicted Mw, 58 kDa) with 69% overall sequence similarity, when compared to human placental aromatase, and higher homologies in presumptive functional domains. A major 3 kb mRNA species was abundant in brain and low or non-detectable in non-neural tissues, reflecting the order of enzyme activities. To determine the cellular basis of high enzyme activity in goldfish brain, a human placental aromatase antibody was used to immunolocalize labeled cells. This antibody immunoprecipitated a single 56 kDa in vitro translation product of goldfish brain poly(A+)RNA and revealed discrete clusters of intensely stained neurons, processes, and terminals concentrated in, but not limited to, reproductive brain centers. Close proximity of aromatase- and androgen receptor-positive neurons in certain regions provides anatomic evidence of a functional relationship between direct and indirect pathways of neural androgen action. Aromatase-positive neurons and fibers formed interconnected networks in novel loci (e.g. retina-->optic tract-->optic tectum), and catalytic activity was confirmed biochemically in these tissues, indicating that neuroestrogen may have a role in visual input and integration. Availability of goldfish-specific nucleotide and antibody probes will facilitate further studies using this model.
J Steroid Biochem Mol Biol 1993 Mar
PMID:Molecular and cellular physiology of aromatase in the brain and retina. 847 67

Low levels of testicular estrogen synthesis have been reported in a number of species, but the cellular localization has not been unequivocally established. To study aromatase in the human testis, we have combined immunocytochemistry with direct measurement of enzyme activity in the testicular 6 microns cryosections. Thus, the functionality of the immunoreaction and its sensitivity can be assessed in quantitative terms. Testes were obtained from immediate autopsy from men aged 18-53 years, from surgery from two patients with prostatic cancer (67 and 74 years) and from two normal children aged 8 months and 3 years at autopsy. Benign testicular sex cord tumors were also examined from two unrelated patients aged 5 and 8 years with gynecomastia and diagnosed with Peutz-Jeghers syndrome. Our results consistently showed low to moderate staining intensity of immunoreactive aromatase in comparison to that of normal human placental cryosections. Immunoreactive aromatase was only present in the interstitial Leydig cells and absent from the Sertoli cells of all normal adult testes showing spermatogenesis. Aromatase activity correlated well with the intensity of the immunostain. However, there was no obvious relationship between the level of aromatase activity and increasing age. Generally higher levels were present in testes of young men (18-22 years). No immunostain in any cell type was detected in one 33-year-old patient with testicular cancer. In the testes of the two normal prepubertal boys, no immunostaining was observed. However, intensely stained Sertoli cells as well as high aromatase activity were observed in the testicular tumors of the patients with Peutz-Jeghers syndrome. Our results suggest that Leydig cells are the source of aromatase in normal men but that Sertoli cells may express this enzyme under abnormal conditions. The combined methods for measuring enzyme activity and immunoreactive aromatase are suitable for application to tissues expressing low levels of aromatase.
J Steroid Biochem Mol Biol 1993 Mar
PMID:Aromatase in the human testis. 847 68

Aromatase is present in human breast tumors and in breast cancer cell lines suggesting the possibility of in-situ estrogen production via the androstenedione to estrone and estradiol pathway. However, proof of the biologic relevance of aromatase in breast cancer tissue requires the demonstration that this enzyme mediates biologic effects on cell proliferation. Accordingly, we studied the effects of the aromatase substrate, androstenedione, on the rate of proliferation of wild-type and aromatase-transfected MCF-7 breast cancer cells. Androstenedione did not increase cell growth in wild-type MCF-7 cells which contained relatively low aromatase activity and produced 4-fold more estrone than estradiol. In contrast, aromatase-transfected cells contained higher amounts of aromatase, produced predominantly estradiol, and responded to androstenedione with enhanced growth. An aromatase inhibitor fadrozole hydrochloride, blocked the proliferative effects of androstenedione providing evidence for the role of aromatase in this process. As further evidence of the requirement for aromatase, cells transfected with the neomycin resistance expression plasmid but lacking the aromatase cDNA did not respond to androstenedione. These studies provide evidence that aromatase may have a biologic role for in-situ synthesis of estrogens in breast cancer tissue.
J Steroid Biochem Mol Biol 1993 Mar
PMID:Effect of androstenedione on growth of untransfected and aromatase-transfected MCF-7 cells in culture. 847 72

Aromatase plays a crucial role in the mechanism of action of testosterone in the central nervous system. Nevertheless, the exact cellular localization of this enzymatic complex within the different cell populations of the brain is still uncertain. In the experiments described here the presence of aromatase (assayed by the tritiated water method) has been evaluated in the two main cellular components of the brain: neurons and glia. Neurons, mixed glial cells, type 1 astrocytes, were obtained in cultures; oligodendrocytes were prepared by gradient ultracentrifugation. The results indicate that, among the different cells tested, only neurons possess a significant degree of aromatase activity, while the enzymatic activity is extremely low in mixed glial cell and in astrocyte preparations. Oligodendrocytes seem to be completely inactive in this respect.
J Steroid Biochem Mol Biol 1993 Mar
PMID:Distribution of aromatase activity in cultured neurons and glia cells. 847 75

In order to better understand the function of aromatase, we carried out kinetic analyses to assess the ability of natural estrogens, estrone (E1), estradiol (E2), 16 alpha-OHE1, and estriol (E3), to inhibit aromatization. Human placental microsomes (50 micrograms protein) were incubated for 5 min at 37 degrees C with [1 beta-3H]testosterone (1.24 x 10(3) dpm 3H/ng, 35-150 nM) or [1 beta-3H,4-14C]androstenedione (3.05 x 10(3) dpm 3H/ng, 3H/14C = 19.3, 7-65 nM) as substrate in the presence of NADPH, with and without natural estrogens as putative inhibitors. Aromatase activity was assessed by tritium released to water from the 1 beta-position of the substrates. Natural estrogens showed competitive product inhibition against androgen aromatization. The Ki of E1, E2, 16 alpha-OHE1, and E3 for testosterone aromatization was 1.5, 2.2, 95, and 162 microM, respectively, where the Km of aromatase was 61.8 +/- 2.0 nM (n = 5) for testosterone. The Ki of E1, E2, 16 alpha-OHE1, and E3 for androstenedione aromatization was 10.6, 5.5, 252, and 1182 microM, respectively, where the Km of aromatase was 35.4 +/- 4.1 nM (n = 4) for androstenedione. These results show that estrogen inhibit the process of androgen aromatization and indicate that natural estrogens regulate their own synthesis by the product inhibition mechanism in vivo. Since natural estrogen binds to the active site of human placental aromatase P-450 complex as competitive inhibitors, natural estrogens might be further metabolized by aromatase. This suggests that human placental estrogen 2-hydroxylase activity is catalyzed by the active site of aromatase cytochrome P-450 and also agrees with the fact that the level of catecholestrogens in maternal plasma increases during pregnancy. The relative affinities and concentration of androgens and estrogens would control estrogen and catecholestrogen biosynthesis by aromatase.
J Steroid Biochem Mol Biol 1993 Mar
PMID:Competitive product inhibition of aromatase by natural estrogens. 847 77

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