Biological mechanisms underlying the clinical effects of mifepristone (RU 486) on the endometrium.

The abortifacient and menstrual effects of the potent antiprogestin, RU 486 (mifepriston) are associated with both endometrial hemorrhage and extracellular matrix (ECM) degradation. Such processes reflect reduced perivascular decidual cell hemostatic and increased ECM-degrading protease activity. In this review, we summarize the effects of RU 486 on different proteases involved in these processes and expressed by in vitro decidualized endometrium stromal cells.

Implications of decidualization-associated protease expression in implantation and menstruation.

During progesterone-induced decidualization of estradiol (E2)-primed human endometrial stromal cells (HESCs), the interstitial-type extracellular matrix (ECM) of the follicular phase endometrium is transformed in the luteal phase to a mixture of residual interstitial- and new basal laminar-type components. This transformation is accelerated by reduced proteolytic activity of HESCs undergoing decidualization (DZ). In cultured HESCs, progestins, but not E2, induce the expression of several DZ markers, and E2 enhances these effects despite the lack of response to E2 alone.

Human endometrial decidual cell-associated 11 beta-hydroxysteroid dehydrogenase expression: its potential role in implantation.

During pregnancy excess corticosteroid exposure can disturb the normal pattern of growth and differentiation of the primate fetus. This is normally prevented by the action of 11 beta-hydroxysteroid dehydrogenase (11 beta-HSD), which converts cortisol to its biologically inactive 11-oxo form, thereby ensuring that little or no cortisol is transferred to the fetus. During implantation, extravillous trophoblasts breech uterine vessels that are embedded in a decidual cell matrix.

Matrix metalloproteinase and matrix metalloproteinase inhibitor expression in endometrial stromal cells during progestin-initiated decidualization and menstruation-related progestin withdrawal.

Estradiol (E) primes human endometrial stromal cells (HESCs) for the decidualizing effects of progesterone in vivo and in vitro. Matrix metalloproteinase (MMP) expression was evaluated in confluent HESCs incubated in control medium, and in medium supplemented with either E, or the synthetic progestin medroxyprogesterone acetate (P), or E + P. Measurements with a specific ELISA indicated that basal pro-MMP-1 output was unaffected by E, whereas E + P, which induces the expression of several decidualization-related markers, produced a time-dependent inhibition in HESC-secreted levels of pro-MMP-1.

Decidual cell regulation of hemostasis during implantation and menstruation.

Progesterone stimulation of the estradiol (E2)-primed human endometrium initiates DZ of the stromal cells around the spiral arterioles. Under continued steroid stimulation, DZ spreads wave-like to establish the decidual cell as a major cell type of the luteal phase and pregnant endometrium. Because of their widespread distribution throughout the endometrium and concentration at perivascular sites, decidual cells are spatially and temporally positioned to mediate the opposing requirements of maintaining hemostasis during endovascular trophoblast invasion, yet promoting menstrual hemorrhage in the absence of implantation.

Biological mechanisms underlying the clinical effects of RU 486: modulation of cultured endometrial stromal cell stromelysin-1 and prolactin expression.

During in vitro decidualization of human endometrial stromal cells (HESCs), medroxyprogesterone acetate (MPA) inhibits expression of the potent extracellular matrix (ECM)-degrading protease stromelysin-1 (MMP-3), but enhances PRL expression. Consistent with its priming role in vivo, estradiol (E2) augments these effects. In the current study, immunoblot analysis revealed that coincubation with 10(-6) M RU 486 blocked the inhibition in HESC-secreted MMP-3 levels (50,000 mol wt) evoked by 10(-8) M E2 + 10(-7) M MPA.

Plasminogen activator activity during decidualization of human endometrial stromal cells is regulated by plasminogen activator inhibitor 1.

Progesterone acts on the estradiol (E2)-conditioned human endometrium to induce decidualization of stromal cells. Consistent with these differential hormone actions in vivo, progestins regulate several end points of decidualization in human endometrial stromal cell monolayers, and E2 augments the effects of progestin. This study shows that in vitro decidualization of the stromal cells is accompanied by diminished plasminogen activator (PA) expression.

The role of progestationally regulated stromal cell tissue factor and type-1 plasminogen activator inhibitor (PAI-1) in endometrial hemostasis and menstruation.

The physiologic mechanisms whereby the human endometrium maintains hemostasis during endovascular trophoblast invasion, yet permits menstrual hemorrhage, are unknown. This paradoxical relationship was investigated by evaluating endometrial expression of tissue factor (TF), the primary initiator of hemostasis, and plasminogen activator inhibitor-1 (PAI-1), the primary inhibitor of fibrinolysis. We observed increased immunostaining for TF and PAI-1 in sections of decidualized stromal cells from luteal phase and gestational endometrium.

Steroid-modulated stromal cell tissue factor expression: a model for the regulation of endometrial hemostasis and menstruation.

This study examined steroidal regulation of tissue factor expression by cultured endometrial stromal cells. Confluent stromal cell cultures derived from cycling human endometria were exposed to vehicle control, 10(-8) mol/L estradiol (E2), 10(-8)-10(-6) mol/L medroxyprogesterone acetate (MPA), or both E2 and MPA for 2-24 days in serum-containing medium. The progestin enhanced immunoreactive and functionally active stromal cell tissue factor content, achieving peak effects by 8-12 days of culture.

Progestational regulation of human endometrial stromal cell tissue factor expression during decidualization.

Decidualized endometrial stromal cells from mid- to late secretory phase and decidual cells from gestational human endometrium displayed prominent immunohistochemical staining for tissue factor, a primary initiator of hemostasis. Consistent with the regulation by progesterone of the decidualization process in vivo, medroxy-progesterone acetate elevated the tissue factor content of primary stromal cell cultures 8-fold over basal values. This increase paralleled the release of immunoreactive PRL, a marker of decidualization.

In vitro metabolism of C19 steroids in human endometrium.

In order to quantitate the extent of intracellular metabolic conversions of C19 steroids in human endometrium, specimens of proliferative and secretory tissue were superfused at a constant rate with several pairs of labeled compounds at low concentrations. About 16% of dehydroepiandrosterone sulfate interacting with endometrial cells was converted to dehydroepiandrosterone and about 3% of this compound was converted to androstenedione. Androstenedione was reversibly reduced to testosterone and the extent of this conversion was shown to be several-fold higher in secretory than in proliferative tissue.

Receptors, enzymes, and hormonal responses of endometrial cells.

Studies of hormone-related biochemical parameters of human endometrium are facilitated by the availability of a variety of types of endometrial tissue resulting from changes in hormonal environment during the menstrual cycle or from decidual, hyperplastic, and neoplastic transformations. Estrogen and progesterone receptors levels, rates of metabolism of ovarian hormones, enzymatic activities regulated by hormones or affecting intracellular concentrations of steroids, rates of production of prolactin and prostaglandins, and endogenous levels of hormones have been measured in samples of endometrial tissue and in separated glands and stroma. These studies have also included an evaluation of effects of estrogens and progestins administered to patients or added to the medium during in vito incubations of endometrium under organ culture conditions.