Comparative effects of progesterone, norgestrel, norethisterone and tamoxifen on the abnormal uterus of the anovulatory rat.

Progesterone therapy results in partial reversibility of histological abnormalities of the rat uterus exposed to constant oestrogen stimulation and is associated with a decrease in nuclear oestrogen receptor content, which may underlie the tissue response to hormone treatment [White, Moore, Elder & Lim (1982) Biochem. J. 202, 535-41]. The synthetic progestins norgestrel and norethisterone used in this study were as effective as progesterone in decreasing the content of nuclear oestrogen receptor. However, only norgestrel had an ameliorative effect on epithelial hyperplasia and metaplasia. The non-steroidal anti-oestrogen tamoxifen caused a significant decrease in both nuclear and cytosol oestrogen receptor content without any change in luminal epithelial hyperplasia and metaplasia. Each progestin caused an increase, whereas tamoxifen caused a decrease, in the proportion of nuclear oestrogen receptors that were unoccupied. Each compound caused a decrease in the content of cytosol progesterone receptor. The effectiveness of compounds used as oestrogen antagonists is discussed with reference to their mode of action.     

The relationship of the oestrogen and progestin receptors in the abnormal uterus of the adult anovulatory rat. Effects of neonatal treatment with testosterone propionate or clomiphene citrate.

The neonatal administration of testosterone propionate to Wistar rats resulted in anovulatory adults in persistent vaginal oestrus. Clomiphene citrate had a similar effect. In both groups of adults, hyperplasia of the uterine epithelium and occasional metaplasia was observed. The uterine nuclear and cytosol oestrogen and progestin receptors of these anovulatory rats were found to have affinities for their respective ligands similar to those of normal females. The nuclear oestrogen receptor comprised occupied and unoccupied components, as in normal females. The content of the nuclear oestrogen receptor was comparable with that of females in the late dioestrous or pro-oestrous phase. This content was higher in the clomiphene-treated group. Despite the relatively high nuclear oestrogen receptor content the content of progestin receptors, a putative index of the oestrogenic response, was lower in the treated rats than in normal adult females throughout the cycle. Administration of oestradiol to both treatment groups resulted in depletion of cytosol oestrogen receptor content 1 h later, which, however, was not reflected by an increase in the content of nuclear oestrogen receptors. There was no measurable increase in progesterone receptor content in treated rats after daily administration of oestrogen (5 microgram/rat) for 3 days. These changes in sex-hormone-receptor interactions involving an impairment of the normal oestrogenic response may be associated with the abnormal differentiation of the uterus in these sterile, anovulatory animals.     

Progesterone regulation of estrogen receptor in the rat uterus: A primary inhibitory influence on the nuclear fraction

The purpose of this study was to determine the short-term effects of progesterone action on estrogen receptor (Re) levels in the rat uterus. Ovariectomized, adrenalectomized rats were maintained on subcutaneous Silastic implants containing crystalline estradiol. Progesterone treatment with serum estradiol maintenance caused a rapid decrease (within 4 h) of total Re, attributable to loss of nuclear Re without a significant change in cytosol Re levels. Removal of estradiol implants resulted in an increase in total Re and cytosol Re at all time periods studied without a significant decrease in nuclear Re until 8 h. Combined estradiol withdrawal and progesterone treatment resulted in lower total Re levels and a more rapid decrease in nuclear Re than with estradiol withdrawal alone. These results demonstrate that progesterone rapidly and selectively decreases nuclear Re levels in rat uterus and suggest that this process is not dependent on cytosol Re or serum estradiol levels.     

Synergistic effects of antiprogestins and iNOS or aromatase inhibitors on establishment and maintenance of pregnancy

Progesterone is known to be involved in many steps in female reproduction including control of implantation and uterine-cervical function during pregnancy. Our studies in rats and guinea pigs indicate that progesterone inhibits uterine contractility and cervical softening during pregnancy. Progesterone levels or actions decline near the end of pregnancy leading to the onset of labor. Treatment with progestin agonists prolongs pregnancy and inhibits cervical softening, whereas treatment with antiprogestins (mifepristone or onapristone) stimulates uterine contractility, cervical softening and premature delivery. Thus the effect of progesterone receptor modulators in the uterus and cervix depend up on the degree of intrinsic agonistic/antagonistic activities. Our recent studies show that progesterone interacts with nitric oxide (NO) to maintain pregnancy and that administration of progesterone antagonists with NO synthase inhibitors act synergistically to stimulate labor. In addition our studies show that combinations of progesterone antagonists with aromatase inhibitors act synergistically to induce labor. Similarly antiprogestins interact with NO synthase or aromatase inhibitors to block implantation through action on the endometrium. These studies suggest new applications for combined therapies of progestin receptor modulators with aromatase inhibitors or agents that modify NO production for contraception, stimulation of labor, estrogen-dependent diseases and improved outcomes in pregnancy.     

Chronic estrogen treatment causes an alteration in uterine estrogen receptor dynamics of rats

Estrogen receptor content and dynamics in the uteri obtained from chronically estrogenized rats were analyzed. 12 day treatment with a subcutaneous implantation of a diethylstilbestrol pellet resulted in maximal stimulation of uteri with regard to wet tissue weight, DNA content, as well as progesterone receptor content without significant alteration of the estrogen receptor level. Estrogen receptor dynamics in just ovariectomized or ovariectomized and diethylstilbestrol-stimulated rats elicited by a single injection of estradiol were next examined using the exchange methods. The cytosol receptor content rapidly declined, with a small and temporary accumulation of the nuclear receptor in the uterus from rats continuously exposed to diethylstilbestrol during the preceding 12 days. A relatively rapid cytosol receptor replenishment was also observed in rats pretreated with diethylstilbestrol. This was accompanied by a rapid decrease in the nuclear receptor level to 70% of the preinjection value at 5 h after estradiol administration. These data are in contrast to findings on uteri of ovariectomized and nonestrogen-treated rats, in which a single injection of estradiol resulted in a prolonged nuclear receptor retention and a delayed cytosol receptor replenishment. Adrenalectomy did not result in a significant change of receptor dynamic patterns, suggesting that adrenal steroids do not play a role in the alteration of receptor dynamics elicited by continuous stimulation with diethylstilbestrol. These observations suggest that a continuous exposure of rat uteri to the estrogen causes an altered regulation of estrogen receptor dynamics by the homologous steroid compared to those in chronically estrogen-deprived rats.     

The effects of oestrogens and progesterone on oestrogen receptors in female rat liver.

The administration of oestradiol-17 beta or ethynyloestradiol as well as the synthetic progestogen norethisterone acetate resulted in translocation of the oestrogen receptor. Progesterone and the synthetic progestogen (+)-norgestrel were ineffective. The increases in nuclear oestrogen receptor content 1 h after injection of each steroid were similar but different subsequently. The increase with oestradiol-17 beta extended for 3--6 h and for at least 9 h with ethynyloestradiol. With norethisterone acetate, nuclear content was still increased after 24 h. Oestrogen injection resulted in cytosol receptor depletion and a 'deficit' in receptor content extending for 6 h, whereas norethisterone acetate-induced translocation was quantitative. With injections of norethisterone acetate + ethynyloestradiol the increase at 1 h and retention of the nuclear receptors were similar to that with norethisterone acetate alone. In contrast, the depletion of cytosol receptor and its restoration were similar to that seen with ethynyloestradiol alone, suggesting that norethisterone acetate did not interfere with the oestrogen receptor replenishment. Specific binding in vitro of [3H]oestradiol-17 beta in liver cytosols was inhibited by (+)-norgestrel and norethisterone acetate, but not progesterone, at concentrations of 10--100 microM. Nuclear receptors present after norethisterone acetate injection bound oestrogen with high affinity (Kd = 1.52 nM), similar to receptors of oestrogen-injected animals. In the uterus, differential retention of nuclear receptors in response to oestrogens is associated with different cellular responses. The differences in the response of the receptor system in liver to the various steroids suggests that the corresponding tissue responses may also be dissimilar. These results are discussed in relation to the problems of liver dysfunction in oral-contraceptive users.     

Progesterone, but not progesterone-independent activation of progestin receptors by a mating stimulus, rapidly decreases progestin receptor immunoreactivity in female rat brain

Recent studies suggest that progestin receptors may be activated in vivo by neurotransmitters in the absence of ligand. More specifically, vaginal-cervical stimulation (VCS) can influence sexual behavior by activating progestin receptors in the absence of progesterone. Another way to test if progestin receptors are influenced by particular stimuli is to examine progestin receptor immunostaining. We report that progestin receptor immunoreactivity is decreased in the forebrain of estradiol-primed ovariectomized (OVX) rats within 1 h after a subcutaneous injection of progesterone, a time by which rapid down-regulation of progestin receptors does not seem to have occurred. In estradiol-primed OVX rats, VCS also decreased progestin receptor immunoreactivity within 1 h in the medial preoptic area, but not in any other area examined. To determine if the decrease in immunoreactivity by VCS was due to adrenal secretions or by ligand-independent activation of progestin receptors, we repeated the experiment in estradiol-primed OVX/adrenalectomized rats. Prior removal of the adrenal glands blocked the rapid decrease in progestin receptor immunoreactivity, even though data from other experiments suggest that progestin receptors are activated by VCS at this time. These studies suggest the possibility that progestin receptors may be affected differentially by progesterone-dependent or by progesterone-independent pathways. This raises the possibility that activation of progestin receptors by these two distinct pathways may lead to different neuronal consequences.     

Role of 17 beta-hydroxysteroid dehydrogenase in the modulation of nuclear estradiol receptor binding by progesterone in the rat anterior pituitary gland and the uterus

Progesterone has been shown to decrease occupied pituitary and uterine nuclear estradiol receptor (E2R) binding in mature and immature estrogen-primed rats. Progesterone has also been shown to stimulate pituitary but not uterine 17 beta-hydroxysteroid dehydrogenase (17 beta-HSD) in the rat. The conversion of estradiol to its less active metabolite estrone by 17 beta-HSD and activation of phosphatase are among mechanisms considered to be involved in the reduction of E2R. To determine if 17 beta-HSD stimulation was a mechanism by which progesterone induced nuclear E2R decrease, the synthetic estrogen ethinylestradiol, which is not oxidized by 17 beta-HSD, was used instead of estradiol to prime adult ovariectomized rats. When ethinylestradiol-primed rats received 0.8, 2.0 or 4.0 mg/kg body wt of progesterone 2 h before sacrifice, the total and occupied nuclear E2R accumulation in the anterior pituitary by a subsequent ethinylestradiol injection 1 h later did not show any decrease. This response was different from that observed previously in estradiol-primed animals in which progesterone showed a multiphasic decrease of occupied form of nuclear E2R. However, in the uterus of ethinylestradiol-primed rats, a partial decrease of total and occupied nuclear E2R accumulation was observed in the presence of the three doses of progesterone used. The decrease of uterine nuclear E2R with the three progesterone doses was different from the dose-dependent effect of progesterone observed in the uterus of estradiol-primed rats. Affinity constants of the interaction between [3H]estradiol and the nuclear E2R were similar among groups treated with ethinylestradiol, estradiol and progesterone. These results demonstrate the involvement of 17 beta-HSD in the reduction of anterior pituitary gland E2R by progesterone in the estradiol-treated animals. Furthermore, the mechanism of decrease of E2R by progesterone in the uterus appears to be different from the pituitary gland.     

Integration of the effects of estradiol and progesterone in the modulation of gonadotropin secretion

Estradiol secreted by the maturing follicle is the primary trigger for the surge of gonadotropins leading to ovulation. Progesterone has stimulatory or inhibitory actions on this estrogen-induced gonadotropin surge depending upon the time and dose of administration. The administration of progesterone to immature ovariectomized rats primed with a low dose of estradiol induced a well-defined LH surge and prolonged FSH release, a pattern similar to the proestrus surge of gonadotropins. A physiological role of progesterone is indicated in the normal ovulatory process because a single injection of the progesterone antagonist RU 486 on the day of proestrus in the adult cycling rat and on the day of the gonadotropin surge in the pregnant mare's serum gonadotropin stimulated immature rat resulted in an attenuated gonadotropin surge and reduced the number of ova per ovulating rat. Progesterone administration brought about a rapid LHRH release and an decrease in nuclear accumulation of estrogen receptors in the anterior pituitary but not the hypothalamus. The progesterone effect was demonstrated in vitro in the uterus and anterior pituitary and appears to be confined to occupied estradiol nuclear receptors. In in vivo experiments the progesterone effect on estradiol nuclear receptors appeared to be of approximately 2-h duration, which coincided with the time period of progesterone nuclear receptor accumulation after a single injection of progesterone. During the period of progesterone effects on nuclear estrogen receptors, the ability of estrogens to induce progesterone receptors was impaired. Based on the above results, a model is proposed for the stimulatory and inhibitory effects of progesterone on gonadotropin secretion.     

Regulation of progesterone receptor mRNA by oestradiol and antioestrogens in breast cancer cell lines

The induction of progesterone receptor mRNA by oestradiol and antioestrogens has been characterised in the MCF-7 breast cancer cell line. Progesterone receptor mRNA was induced more than 100-fold by oestradiol. The induction was half-maximal in the presence of 10(-10) M oestradiol and maximum levels were reached after 24 h treatment. Progesterone receptor mRNA was induced to 10% of the oestrogen-induced level by tamoxifen and its metabolite 4'-hydroxytamoxifen. The increase was half-maximal in the presence of 5 X 10(-8) M tamoxifen or 5 X 10(-10) M 4'-hydroxytamoxifen. In contrast, neither the benzothiophene antioestrogen LY117018 nor the 7 alpha-alkyl steroidal antioestrogen ICI 164,384 had any effect on progesterone receptor mRNA. The progesterone receptor mRNA was also induced by oestrogen in a T47D subline and in two other oestrogen-responsive breast cancer cell lines (ZR-75, EFM-19). Tamoxifen was a partial oestrogen for progesterone receptor mRNA induction in each of these cell lines. The large induction of the progesterone receptor mRNA by oestrogen in all 4 breast cancer cell lines supports the contention that the progesterone receptor may be a good predictive marker of hormonal response in human breast cancer.     

A comparison of the relationships between progestin receptors and oestrogen receptors in neural and non-neural target tissues of the rat during the oestrous cycle.

Similar cyclic changes in the content of nuclear oestrogen receptor occurred in the hypothalamus, cerebral cortex, uterus and pituitary during the oestrous cycle. The relationship of the unoccupied to the total nuclear oestrogen receptor at each phase was similar in all these tissues. However, cyclic changes in the content of the cytosol progestin receptor occurred only in the uterus and pituitary (where they paralleled changes in the nuclear oestrogen receptor), but not in the hypothalamus or cerebral cortex.     

Modulation of Progestin Binding Activity in Cultured Human Breast Carcinoma Cells: The Effect of Serum Type and Concentration

Abstract

Progesterone receptor levels in MCF-7 human breast cancer cells increase as a specific response to estrogen and to some nonsteroidal antiestrogens. In the present study we demonstrate that the type and quantity of serum present during culture of these cells modifies the level of progestin binding activity, but not the level of estradiol binding activity.

MCF-7 cells maintained in media supplemented with 5% charcoal-dextran treated calf serum (CDCS) contain 0.3 - 0.4 pmol of cytosol progesterone receptor (PR_c) per mg DNA. When cells previously maintained in 5% CDCS-media are shifted to media containing 5% charcoal-dextran treated fetal calf serum (CDFCS), the level of progestin binding increases after day 16, and stabilizes at 2 - 3 pmol/mg DNA at days 30 to 40. Shifting these cells back to 5% CDCS-media, reduces PR_c to 0.2 - 0.4 pmol/mg DNA within 3 days. This reduction is dose dependent with a half-optimal decrease at 1% CDCS, and a full decrease at 2% CDCS (4d incubation). Nuclear progestin binding was uniformly low (0.2 - 0.4 pmol/mg DNA) and unaffected by type or concentration of serum, and no consistent change in cytosol or nuclear estrogen receptor levels was observed. These cytoplasmic progestin binding sites are translocated to the nucleus by progesterone, and are similar to estradiol (E₂) induced sites by Scatchard binding and sucrose gradient analysis. Similar serum-dependent changes are also observed in the T₄₇D human breast cancer cell line where growth in CDFCS-media results in 4-fold higher progestin binidng levels than observed in CDCS-media. Our findings suggest the presence of non-dialyzable stimulatory factor(s) in CDFCS that influence the progestin receptor level the highlight the fact that serum components can alter dramatically the cellular progestin binding activity.     

Progesterone in high doses may overcome progesterone's desensitization effect on lordosis by translocation of hypothalamic progestin receptors

The cellular mechanism by which progesterone desensitizes the central nervous sytem to further facilitation of lordosis by progesterone was studied. In the first experiment guinea pigs were injected with doses of estradiol benzoate and progesterone that result in refractoriness to further stimulation of lordosis by moderate doses of progesterone. Confirming previous reports, a large dose of progesterone was effective in overcoming this desensitization, resulting in lordosis responses. A lower dose of progesterone was ineffective in this regard. In subsequent experiments, cytosol and nuclear progestin receptors were measured in the hypothalamus-preoptic area and cerebral cortex with an in vitro exchange assay using [³H]R 5020 as the ligand. A high, effective dose of progesterone resulted in 46–48% higher levels of nuclear progestin receptors assayed in the hypothalamus-preoptic area than did a lower, ineffective dose. These results are consistent with the idea that progesterone injection in estradiol-primed rodents causes a subsequent desensitization to itself by decreasing the concentration of cytoplasmic progestin receptors in hypothalamus-preoptic area. A subsequent progesterone injection then results in a lower level of nuclear progestin receptors. Large doses of progesterone may overcome this desensitization by causing accumulation of levels of nuclear progestin receptors sufficient to facilitate lordosis.     

Characteristics of the nuclear translocation of progesterone receptor in fetal guinea pig uterus "in vivo", "in vitro" and in organ culture

The translocation of progesterone receptor from the cytosol into the nucleus was studied under "in vivo" and "in vitro" conditions in the uteri of guinea pig fetuses exposed to progesterone or a synthetic progestin, R5020. Progesterone treatment of estrogen-primed fetuses leads to a rapid (before 1h) transfer of cytosol progesterone receptor into the nucleus which is, however, short-lived (less than 3h). A rapid decrease in the retention of the estrogen receptor in the nucleus also occurs. In the "in vitro" incubations of whole fetal uteri, translocation of progesterone receptor is temperature-dependent and specific for progesterone and R5020; estradiol and cortisol have no effect. Putative progesterone receptors can also be induced in explants of fetal guinea pig uteri in organ culture which translocate from the cytosol into the nucleus under the same "in vitro" conditions as in whole uteri. Fetal uterine progesterone receptor, either stimulated "in vivo" by estrogen-priming or induced in organ culture, translocates from the cytosol into the nucleus and this process seems to be accompanied by a decrease in retention of the estrogen receptor in the nucleus which appears to be the mechanism by which progesterone antagonises estrogen action in fetal guinea pig uterus.     

Hormonal control of pinocytosis in the uterine epithelium of the rat.

Ovariectomized rats were treated with oestradiol-17 beta and/or progesterone to mimic the hormonal parameters inducing uterine sensitivity for implantation. The degree of pinocytosis of trypan blue and ferritin in the endometrial cells was examined. Significant epithelial pinocytosis of trypan blue occurred after a 3-day treatment of progesterone, and uptake was independently increased by priming with oestrogen and by oestradiol given on the 3rd day of progesterone treatment. Progesterone treatment caused uptake of ferritin by the epithelial cells; in control animals epithelial and stromal cells were involved. Oestrogen priming enhanced ferritin absorption, while 'nidatory' oestrogen had no effect. Oestradiol given alone completely blocked pinocytosis of both intraluminally injected substances.     

Effect of ovariectomy and replacement therapy on the tissue lipid pattern in rats.

Ovariectomy increases the percentage of total lipids in liver, kidney and uterus of intact cyclic rats. Estrogen and progesterone, when administered individually to ovariectomized rats, caused a decrease in the total lipid content of all tissues. Th effect of progesterone in estrogen-primed rats is not significant. Triglyceride and cholesterol content increases after ovariectomy; treatment with estrogen in ovariectomized rats led to a decrease in the concentration of these lipids. Progesterone has no significant effect on these lipids but showed an antagonistic action when given in estrogen-primed ovariectomized rats. The proportions of ethanolamine, choline and inositol phospholipids decreased after spaying and increased when estrogen was given to spayed rats. Progesterone alone had effect only on the uterus whereas progesterone administered to estrogen-primed rats showed an antagonistic effect in all tissues.     

Detailed examination of the mechanism and site of action of progesterone and corticosteroids in the regulation of gonadotropin secretion: hypothalamic gonadotropin-releasing hormone and catecholamine involvement.

Progesterone and certain corticosteroids, such as deoxycorticosterone (DOC) and triamcinolone acetonide (TA), can stimulate gonadotropin surges in rats. The mechanism of these steroids could involve a pituitary or hypothalamic site of action, or both. Progesterone and TA did not alter the ability of GnRH to release LH or FSH either before, during, or after the gonadotropin surge induced by these steroids in estrogen-primed ovariectomized female rats. Furthermore, progesterone, TA and DOC were unable to induce a gonadotropin surge in short-term estrogen-primed castrated male rats. These results suggested a hypothalamic rather than a pituitary site of action of progesterone and corticosteroids in the release of gonadotropins. Since progestin and corticosteroid receptors are present in catecholamine neurons, a role for catecholamine neurotransmission in progesterone and corticosteroid-induced surges of LH and FSH in estrogen-primed ovariectomized rats was examined. Catecholamine synthesis inhibitors and specific alpha 1 (prazosin), alpha 2 (yohimbine), and beta (propranolol) receptor antagonists were used to determine the role of catecholamine neurotransmission in the steroid-induced surges of LH and FSH. Both of the catecholamine synthesis inhibitors, alpha-methyl-p-tyrosine HCl (alpha-MPT), a tyrosine hydroxylase inhibitor, and sodium diethyldithiocarbamate (DDC), an inhibitor of dopamine-beta-hydroxylase, attenuated the ability of progesterone, TA, and DOC to induce LH surges when administered 3 h and 1 h, respectively, before the steroid. DDC also suppressed the ability of progesterone, TA, and DOC to induce FSH surges. Rats treated with alpha-MPT had lower mean FSH values than did steroid controls, but the effect was not significant. Both the alpha 1 and alpha 2 adrenergic antagonists, prazosin and yohimbine, significantly suppressed the ability of progesterone, TA, and DOC to induce LH and FSH surges. In contrast, the beta adrenergic receptor blocker, propranolol, had no effect upon the ability of progesterone, TA, or DOC to facilitate LH and FSH secretion. Finally, the stimulatory effect of progesterone and TA upon LH and FSH release was found to be blocked by prior treatment with a GnRH antagonist, further suggesting hypothalamic involvement. In conclusion, this study provides evidence that the stimulation of gonadotropin release by progesterone and corticosteroids is mediated through a common mechanism, and that this mechanism involves the release of GnRH, most likely through catecholaminergic stimulation. Furthermore, catecholamine neurotransmission, through alpha 1 and alpha 2 but not beta receptor sites, is required for the expression of progesterone and corticosteroid-induced surges of LH and FSH in estrogen-primed ovariectomized rats.     

Progesterone induces a secretory protein in cultured rabbit endometrial stromal cells

Secretion of newly synthesized proteins by rabbit endometrial stromal cells in culture was studied. Progesterone (P) stimulated the synthesis and secretion of a protein with a mol. wt of approx 62 K and a pI of 6.5-7.0. Induction of 62 K protein synthesis was dose dependent; addition of 10 nM P to primary cultures caused a 2-fold or greater increase in the amount of this protein in the medium while addition of 1 microM P resulted in a 4.3-fold increase. Synthesis of this 62 K protein was not induced by estradiol, dexamethasone, or testosterone, nor was progesterone stimulation of the protein modified by estradiol. Thus, induction appears to be specific for a progesterone receptor mediated effect. Synthesis and secretion of this protein in the culture system described is potentially useful as a progestin bioassay.     

Mechanisms responsible for progesterone's protection against lordosis-inhibiting effects of restraint I. Role of progesterone receptors

Progestins and antiprogestins are widely used therapeutic agents in humans. In many cases, these are indicated for the treatment of reproductive activities. However, progesterone has widespread physiological effects including a reduction of the response to stress. We have reported that 5 min of restraint reduced lordosis behavior of ovariectomized rats hormonally primed with estradiol benzoate. When ovariectomized rats received both estradiol benzoate and progesterone priming, restraint had minimal effects on lordosis. Progesterone influences behavior through classical intracellular progesterone receptor-mediated nuclear events as well as extranuclear events. How these multiple events contribute to the response to stress is unclear. The current project was designed to initiate examination of the mechanisms responsible for progesterone's ability to protect against the effects of the restraint. In the first experiment, ovariectomized rats, primed with 10 μg estradiol benzoate, received 500 μg progesterone 4 h, 1 h, or 30 min before restraint. When progesterone was injected 4 h before restraint, progesterone eliminated the effects of restraint. In contrast, progesterone 30 min before restraint offered no protection. Effects of progesterone 1 h before restraint were equivocal allowing the suggestion that less than 4 h of progesterone priming might be sufficient. In the second experiment, the synthetic progestin, medroxyprogesterone, was shown to mimic effects of progesterone in preventing effects of restraint. Finally, the progesterone receptor antagonist, RU486, attenuated progesterone's protection against restraint. These findings offer evidence that ligand-activated progesterone receptor mechanisms contribute to the maintenance of lordosis behavior in the presence of mild stress.