In the present study we characterized in detail the expression of aromatase P450 in leiomyomas to determine the role of in situ estrogen in the growth advantage of leiomyomas. The levels of aromatase P450 transcripts were determined by quantitative RT-PCR to be significantly higher in leiomyomas than in corresponding myometrium. The overexpression of aromatase P450 in leiomyomas was also confirmed by Western blot analysis. The estimated size of immunoreactive aromatase was 58 kDa, similar to that in placenta. To identify a cell type that express aromatase P450 in leiomyomas, histological specimens were stained for aromatase P450 using a polyclonal antibody. Strong immunoreactivity was detected in the cytoplasm of leiomyoma cells, whereas surrounding normal myometrium displayed weak or negative staining. Smooth muscle-like cells in culture obtained from leiomyomas, positive for actin D fiber, possessed immunoreactive granules of aromatase in the cytoplasm. Conversion of androgen to estrogen was effectively stimulated by phorbol myristate acetate and dexamethasone plus interleukin-1beta and was completely abolished by selective inhibitors of aromatase P450 (fadrozole and TZA-2209), but not by inhibitors of 5alpha-reductase (finasteride and flutamide). The apparent Km of androstenedione was 3 nM in the presence of dexamethasone and interleukin-1beta, corresponding to the plasma concentration of androstenedione in women of reproductive age. To determine whether endogenous aromatase P450 plays a role in the growth promotion of leiomyoma cells, we evaluated the cell growth of smooth muscle-like cells treated with various concentrations of estrogen and androgen using a WST-1 assay. Treatment with testosterone (10(-8) and 10(-7) M) and androstenedione (10(-8) and 10(-7) M) stimulated the growth of smooth muscle-like cells obtained from leiomyomas to the same extent as estradiol (10(-10)-10(-7) M), whereas dihydrotestosterone (10(-11)-10(-8) M) did not. The stimulatory effect of testosterone on cell growth was again abolished by cotreatment with fadrozole. The level of estradiol in the medium of testosterone (10(-8) M)-treated smooth muscle-like cells was 10(-11) M, which was 1 order lower than the minimum concentration of estradiol necessary to promote cell growth (10(-10) M). This indicates that estradiol synthesized in leiomyomas promotes their growth via an autocrine/intracrine mechanism. We conclude that myometrial cells of leiomyomas overexpress aromatase P450 and are able to synthesize sufficient estrogen to accelerate their own cell growth. Overexpression of aromatase P450 may play a role in the growth advantage of leiomyoma tissue over surrounding myometrium via an autocrine/intracrine mechanism.
The CYP19 gene encoding aromatase P450 (estrogen synthetase) is expressed in several extragonadal sites and regulated in a tissue-specific fashion, which is achieved by alternative use of the seven different promoters (and corresponding exons 1) of the CYP19 gene. Previously, we demonstrated that aromatase P450 is overexpressed in leiomyoma tissue and that in situ estrogen synthesized in leiomyoma tissues possibly plays a role in leiomyoma growth. To elucidate the mechanism of overexpression of aromatase P450, we determined the promoter use of aromatase P450 in leiomyomas. 5'-Rapid amplification of cDNA ends analysis revealed that of six leiomyoma nodules tested, four nodules contained I.4-specific transcript of aromatase P450 alone, one nodule contained PII-specific transcript alone, and the remaining nodule contained both I.4- and PII-specific transcripts simultaneously. The levels of aromatase transcripts were then quantified by competitive RT-PCR assay. Among 21 leiomyomas, I.4-specific transcript and PII-specific transcript were predominant in 18 and 2 leiomyomas, respectively, whereas the remaining leiomyoma was negative for aromatase P450 expression. We next compared the aromatase activity of leiomyoma cells stimulated by promoter-specific regulatory factors. A combination of IL-1beta and dexamethasone, known as a potent inducer of promoter I.4-driven transcription, effectively increased aromatase activity. A combination of (Bt)(2)cAMP, 3-isobutyl-1-myethylxanthine, and PGE(2), known as inducers of promoter II-driven transcription, also increased aromatase activity, but the increases found were smaller than that induced by dexamethasone and IL-1beta. The transcriptional ability of the promoter I.4 sequence was confirmed by transient transfection assay using primary cells released from leiomyomas and established cells from normal myometrium (KW cells). Luciferase vectors containing promoter I.4 sequence (-340/+14 or longer) showed a significant increase in luciferase activity in response to dexamethasone. Deletion or mutation of a putative glucocorticoid-responsive element in the promoter I.4 sequence eliminated promoter activity. These results indicate that promoter I.4 is the major promoter responsible for overexpression of aromatase P450 in leiomyomas and that a glucocorticoid-responsive element within it plays a substantial role in the expression of aromatase P450.
In the present study we characterized in detail the expression of aromatase P450 in leiomyomas to determine the role of in situ estrogen in the growth advantage of leiomyomas. The levels of aromatase P450 transcripts were determined by quantitative RT-PCR to be significantly higher in leiomyomas than in corresponding myometrium. The overexpression of aromatase P450 in leiomyomas was also confirmed by Western blot analysis. The estimated size of immunoreactive aromatase was 58 kDa, similar to that in placenta. To identify a cell type that express aromatase P450 in leiomyomas, histological specimens were stained for aromatase P450 using a polyclonal antibody. Strong immunoreactivity was detected in the cytoplasm of leiomyoma cells, whereas surrounding normal myometrium displayed weak or negative staining. Smooth muscle-like cells in culture obtained from leiomyomas, positive for actin D fiber, possessed immunoreactive granules of aromatase in the cytoplasm. Conversion of androgen to estrogen was effectively stimulated by phorbol myristate acetate and dexamethasone plus interleukin-1beta and was completely abolished by selective inhibitors of aromatase P450 (fadrozole and TZA-2209), but not by inhibitors of 5alpha-reductase (finasteride and flutamide). The apparent Km of androstenedione was 3 nM in the presence of dexamethasone and interleukin-1beta, corresponding to the plasma concentration of androstenedione in women of reproductive age. To determine whether endogenous aromatase P450 plays a role in the growth promotion of leiomyoma cells, we evaluated the cell growth of smooth muscle-like cells treated with various concentrations of estrogen and androgen using a WST-1 assay. Treatment with testosterone (10(-8) and 10(-7) M) and androstenedione (10(-8) and 10(-7) M) stimulated the growth of smooth muscle-like cells obtained from leiomyomas to the same extent as estradiol (10(-10)-10(-7) M), whereas dihydrotestosterone (10(-11)-10(-8) M) did not. The stimulatory effect of testosterone on cell growth was again abolished by cotreatment with fadrozole. The level of estradiol in the medium of testosterone (10(-8) M)-treated smooth muscle-like cells was 10(-11) M, which was 1 order lower than the minimum concentration of estradiol necessary to promote cell growth (10(-10) M). This indicates that estradiol synthesized in leiomyomas promotes their growth via an autocrine/intracrine mechanism. We conclude that myometrial cells of leiomyomas overexpress aromatase P450 and are able to synthesize sufficient estrogen to accelerate their own cell growth. Overexpression of aromatase P450 may play a role in the growth advantage of leiomyoma tissue over surrounding myometrium via an autocrine/intracrine mechanism.
We have shown that in situ estrogen synthesized in leiomyoma of the uterus plays a possible role in the promotion of leiomyoma cell growth via an autocrine/paracrine mechanism. In the present study, we demonstrated that leuprorelin acetate, a GnRH agonist widely used for treatment of uterine leiomyoma by down-regulation of pituitary-ovarian function, suppressed the expression of aromatase P450 (an estrogen synthetase) in leiomyoma cells. Given the role of in situ estrogen in leiomyoma cell growth, the inhibition of in situ estrogen synthesis may play a role in GnRH agonist-induced rapid regression of leiomyomas. Quantitative RT-PCR revealed that in women receiving no medication uterine leiomyomas express aromatase P450 mRNA at levels 20 times higher than that in the surrounding myometrium. Leuprorelin acetate treatment (1.88 mg every 4 wk, sc injection) for 12-24 wk reduced the expression of aromatase P450 mRNA in leiomyoma tissue as well as in the myometrium, to approximately one tenth of that in the myometrium of untreated women. Suppression of aromatase P450 expression was also demonstrated by Western blot analysis and aromatase activity assay of microsomal fractions prepared from leiomyomas. On the other hand, no differences in the levels of activity and mRNA of aromatase P450 were observed between leiomyoma cells obtained from women treated with and without leuprorelin acetate injections when cells were cultured ex vivo and stimulated by various combinations of stimulants such as dexamethasone + IL-1beta. The addition of various concentrations of E2 did not affect the aromatase activity of leiomyoma cells, suggesting that deprivation of circulating (ovarian) estrogen is not a cause of decreased expression of aromatase during leuprorelin acetate therapy. On the other hand, 8-d treatment with leuprorelin acetate (100 nmol/liter) reduced dexamethasone + IL-1beta-induced activity and a mRNA level of aromatase by 28% and 42%, respectively. These results indicated that leuprorelin acetate inhibits the expression of aromatase P450 in leiomyoma cells, which contributes to the rapid regression of leiomyoma during leuprorelin acetate therapy.
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