Steroid sulfatase activity in amnion tissue and amnion cells maintained in monolayer culture

Steroid sulfate sulfatase in human benign prostatic hyperplasia: characterization and quantification of the enzyme in epithelium and stroma

Characteristics and activities of estrone sulfate (E1S) and dehydroepiandrosterone sulfate (DHAS) sulfatases were studied in epithelium and stroma of benign hyperplastic tissues from human prostates. Tissues were obtained by suprapubic prostatectomy, and epithelium and stroma were separated mechanically by standard techniques. The assay procedure comprised homogenization in Tris-buffer, incubation of the homogenate with [3H]E1S or [3H]DHAS, separation of free steroids from nonhydrolyzed steroid sulfates by extraction with ether, and their final quantification by LSC. The main results were: (1) The pH-optimum of the sulfatase was found at pH 7.0. (2) The highest specific sulfatase activity was found in the epithelium and was associated with its nuclear fraction. (3) Michaelis-Menten constants Km (microM) were 8.7 +/- 1.4 (7) and 4.3 +/- 0.8 (5), maximum velocity rates Vmax (nmol/h x mgDNA) were 47.4 +/- 8.8 (7) and 8.4 +/- 1.5 (5) for E1S and DHAS, respectively (means +/- SEM (n]. (4) The enzymatic cleavage of E1-sulfate was competitively inhibited by DHA-sulfate and vice versa with inhibition constants Ki (microM) of 4.0 +/- 0.5 (2) for E1S and 2.7 +/- 0.4 (2) for DHAS. On the basis of these findings, possible roles of steroid sulfate-sulfatases in forming precursors of active androgens and estrogens from the high amounts of E1S and DHAS in blood are discussed.

Differential metabolism of dehydroepiandrosterone sulfate and estrogen conjugates by normal or malignant AXC/SSh rat prostate cells and effects of these steroid conjugates on cancer cell proliferation in vitro

Normal AXC/SSh rat ventral prostate and clonally derived AXC/SSh rat prostate cancer cells were evaluated for ability to metabolize estrone sulfate (E1S), estrone glucuronide (E1G), or dehydroepiandrosterone sulfate (DHEAS). Both normal and malignant prostate cells converted E1S to estrone. Neither normal nor malignant prostate cells had significant ability to metabolize DHEAS to DHEA, indicating differential specificity of prostate sulfatases(s) for estrogen and androgen sulfates. Both normal and neoplastic prostate cells possess beta-glucuronidase which hydrolyzed E1G to estrone. To assess potential physiologic consequences of these enzymatic activities, we determined the effect of steroid conjugates on in vitro proliferation of selected clonal lines of AXC/SSh rat prostate cancer cells. DHEAS, 10(-6) to 10(-9) M in decade intervals, did not affect in vitro proliferation of AXC/SSh prostate cancer cells; however, 10(-5) M DHEAS decreased in vitro proliferation of these cells. Neither E1S nor E1G, 10(-5) to 10(-9) M in decade intervals, affected in vitro proliferation of AXC/SSh prostate cancer cells. These findings suggest that low residual levels of steroid conjugates, which are not removed by charcoal stripping of serum, do not affect demonstrated in vitro androgen modulation of AXC/SSh rat prostate cancer cell proliferation (Cancer Res. 46, 3775-3781, 1986).

Steroid synthetic and prostaglandin metabolizing activity is present in different cell populations from human fetal membranes and decidua

We examined whether different cell subpopulations from human fetal membranes and decidua produce steroids (estrone and progesterone) and metabolize prostaglandins (prostaglandin F2 alpha to 13, 14-dihydro-15-keto-prostaglandin F2 alpha and if these changed with labor. Amnion, chorion, and decidua were obtained at elective cesarean section at term or at spontaneous labor. Cells were dispersed with collagenase and separated by density on discontinuous Percoll gradients. At cesarean section there was a major broad band of cells from amnion and chorion. This band contained most of the estrone sulfatase (estrone sulfate to estrone) activity. The 3 beta-hydroxysteroid dehydrogenase (pregnenolone to progesterone conversion) and prostaglandin F2 alpha metabolizing activities were present in these cells and those that migrated at greater Percoll densities. Amnion and chorion obtained after spontaneous labor had two major bands of cells. Estrone sulfatase was present in cells from both hands, whereas progesterone output from pregnenolone and prostaglandin F2 alpha metabolism predominated in the second band of cells with greater density. This pattern was particularly apparent in chorion. Dispersed cells from decidua tended to migrate throughout the gradient. In general, estrone sulfate to estrone conversion predominated in lighter cells whereas progesterone output from pregnenolone and prostaglandin F2 alpha metabolism predominated in cells of greater density. The output of progesterone from pregnenolone was significantly lower in cell preparations from chorion and decidua at spontaneous labor compared with cesarean section. We conclude that human amnion, chorion, and decidua contain distinct cell subpopulations based on Percoll migration and that in the membranes these change between cesarean section and spontaneous labor. Partial separation of estrone sulfatase from 3 beta-hydroxysteroid dehydrogenase and prostaglandin F2 alpha metabolizing activities has been demonstrated, which raises the possibility of paracrine interactions in vivo.