Steroid-monoamine feedback interactions in discrete brain regions using as a model the monosodium glutamate (MSG)-lesioned rat

The present studies examine the effects of neonatal treatment with monosodium glutamate (MSG) on dopamine (DA), 5-hydroxytryptamine (5-HT) and norepinephrine (NE) metabolism in discrete brain regions and correlate them with steroid receptor kinetics in the anterior pituitary (PIT), preoptic hypothalamus (POA) and caudal hypothalamus (HYP), and with steroid negative and positive feedback effects on luteinizing hormone (LH) secretion. Substantial decreases in the neuronal activity of all three amines in the arcuate nucleus, decreased DA and 5-HT metabolism in the suprachiasmatic nucleus and, surprisingly, increased metabolism of 5-HT and NE in the median eminence was observed in adult ovariectomized (OVX), MSG-treated versus OVX, vehicle-treated litter mate controls. Measurement of estradiol receptors in the nuclear and cytosolic fractions of the POA, HYP and PIT from MSG- and vehicle-treated rats killed during diestrus or 2 weeks after OVX revealed no differences. Similarly, no differences in cytosolic progestin receptors between control and MSG unprimed or estradiol-primed, OVX rats or on progestin receptor translocation induced by progesterone in Eb-primed rats were observed. Negative and positive feedback effects of estradiol or the positive feedback of progesterone on LH secretion were not significantly impaired in MSG rats, and indeed, MSG animals actually were hyper-responsive to the administration of the steroids or of luteinizing hormone-releasing hormone. These results indicate that the MSG-induced damage to DA, 5-HT and NE elements observed within several preoptic and hypothalamic nuclei does not impair estrogen and progestin receptor kinetics, nor does it prevent adequate negative or positive steroid feedback responses, if appropriate steroid regimens are employed, and that the impaired gonadal function reported in these animals does not result primarily from inadequate steroid feedback mechanisms.     

Down-regulation of progestin receptors in guinea pig brain: new findings using an immunocytochemical technique

Progesterone injection in estradiol-primed, ovariectomized guinea pigs results in down-regulation of hypothalamic progestin receptors determined by in vitro binding assays. In order to determine if progesterone also decreases immunostaining of progestin receptors and if progestin receptors are down-regulated preferentially in particular neuroanatomical areas, ovariectomized guinea pigs were injected with doses of estradiol benzoate (10 micrograms at 42 h before progesterone injection) and progesterone (500 micrograms at 4, 12, or 24 h before perfusion) that reliably induce the expression of lordosis and subsequent behavioral refractoriness to progesterone. Progestin receptor-immunoreactive cells were counted in sections from discrete parts of the preoptic area and hypothalamus. As expected, estradiol dramatically increased cell nuclear, and, to a lesser extent, cytoplasmic, immunostaining in defined regions of the preoptic area and hypothalamus. By 12 h after progesterone injection, the number of progestin receptor-immunoreactive cells had decreased in some areas, but not others. The rostral and caudal aspects of the ventrolateral hypothalamus were particularly responsive showing a substantial decrease in progestin receptor-immunoreactivity by 12 h after injection. No decreases in the progestin receptor-immunoreactive cell number were observed in any of the preoptic regions examined, although obvious decreases in immunostaining intensity were seen. The results of these immunocytochemical experiments extend earlier findings from in vitro progestin binding experiments and demonstrate that as with progestin binding, progestin receptor-immunoreactivity decreases when progesterone is injected in a behavioral desensitization procedure. Furthermore, they point to the ventrolateral hypothalamus as one site in which the down-regulation of progestin receptors may be particularly responsive to progesterone.     

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.     

Effects of estrogen deprivation on brain estrogen and progestin receptor levels and the activation of female sexual behavior

Ovariectomy (OVX) in rats is followed by a decline in behavioral sensitivity to combined estrogen and progesterone therapy. The purpose of this study was to further characterize this behavioral change, and to explore its biochemical basis in terms of estrogen and progesterone receptor concentrations in the brain. Sexually inexperienced female rats were used 5 (short-term) or 35 (long-term) days after OVX. Short- and long-term OVX animals were injected with estradiol-17β (E₂; 36 μg/kg body wt, iv) then subjected to one of the following three treatment schedules. (1) Animals were treated with progesterone (1 mg, sc in oil) 20–21 hr after E₂ injection, then tested at 24 hr for female sexual behavior. (2) One or twelve hours after the E₂, cell nuclear estrogen receptors (ER_n) were measured in the pituitary (PIT) and pooled preoptic area and mediobasal hypothalamus (POA-MBH). (3) Twenty-four hours after E₂, progestin receptor (PR_c) concentrations were measured in cytoplasmic fractions prepared from PIT and POA-MBH. Long-term OVX animals showed a reduced capacity to exhibit proceptive and receptive sexual behavior, and a lower PR_c level in the PIT and POA-MBH 24 hr after E₂ injection than animals that had been OVX for only 5 days. However, no differences were observed between long- and short-term OVX rats with respect to ER_n concentrations in PIT and POA-MBH cell nuclei 1 or 12 hr after E₂. Thus, it appears that the decline in behavioral responsiveness to E₂ which occurs after ovariectomy cannot be attributed to a decrease in the ability of E₂ to translocate estrogen receptors into POA-MBH cell nuclei, but is more probably associated with a change in the biochemical processes subsequent to ER_n binding. One of these processes may well be the induction of cytoplasmic progestin receptors.     

Progesterone receptors and ventilatory stimulation by progestin

Progestin is thought to be a ventilatory stimulant but its effectiveness in raising ventilation is variable in humans and other species. We hypothesized that the level of progesterone receptors was an important determinant of the ventilatory response to progestin. Since estradiol induces progesterone receptor formation, we compared the ventilatory effect of the synthetic progestin medroxyprogesterone acetate (MPA) given in combination with estradiol with the effects of estradiol alone, MPA alone, or vehicle (saline) in ovariectomized rats. Animals receiving MPA alone had low numbers of progesterone receptors (2.43 pmol/g uterine wt) and had no change in ventilation, arterial Pco2, or Po2. MPA administration raised ventilation 23 +/- 5%, lowered arterial Pco2 3.2 +/- 0.9 Torr (both P less than 0.01) and tended to raise arterial Po2 when given in combination with estradiol to animals with increased numbers of progesterone receptors (4.85 pmol/g uterine wt). Estradiol alone produced the highest number of progesterone receptors (12.3 pmol/g uterine wt) but had no effect on ventilation or arterial Pco2 and decreased arterial Po2. Combined estradiol plus MPA treatment produced a greater fall in arterial Pco2 than did treatment with MPA alone, estradiol, or saline (all P less than 0.05). These results suggest that both an elevation in progestin levels and progesterone receptor numbers are required to stimulate ventilation.     

Estrogenic effects of zearalenone on the expression of progestin receptors and sexual behavior in female rats

Zearalenone is a resorcylic acid lactone compound that is produced by fungal infection of edible grains and is believed to influence reproduction by binding to estrogen receptors. In order to study the potential estrogenic effects of this compound in the brain, we examined the effects of zearalenone on the expression of neuronal progestin receptors and feminine sexual behavior in female rats. Ovariectomized rats were treated with zearalenone (0.2, 1.0, or 2.0 mg), estradiol benzoate, or vehicle daily for 3 days. They were then either perfused, and progestin receptors visualized by immunocytochemistry, or injected with progesterone and tested for sexual receptivity with male rats. Progestin receptor-containing cells were counted in the medial preoptic area and ventromedial hypothalamus. The two highest doses of zearalenone increased the concentration of neuronal progestin receptors, as did 10 microg of estradiol. The highest dose of zearalenone (2 mg) also induced progestin receptor staining density comparable to that of 10 microg of estradiol benzoate. In behavioral tests, ovariectomized animals treated with 2 mg of zearalenone followed by progesterone showed levels of sexual receptivity comparable to females treated daily with estradiol benzoate (2 microg) followed by progesterone. These studies suggest that, although structurally distinct and less potent than estradiol, zearalenone can act as an estrogen agonist in the rat brain.     

Facilitation of lordosis in guinea pigs by an alpha-noradrenergic agonist is independent of progestin receptor stimulation

Because manipulations of the noradrenergic system affect both lordosis behavior and progestin receptor levels in female guinea pigs, the present study attempted to determine if the noradrenergic (NE) system affects lordosis solely because of its impact on progestin receptors. Although the progestin receptor antagonist RU486 significantly reduced progesterone-facilitated lordosis, it had no effect on lordosis induced by the alpha-NE agonist clonidine in estrogen-primed female guinea pigs. This indicates that although progesterone may facilitate lordosis in female guinea pigs via activation of progestin receptors, the alpha-noradrenergic agonist clonidine does not mediate lordosis through the same mechanism.     

Progestin receptor-mediated reduction of anxiety-like behavior in male rats

Background

It is well known progesterone can have anxiolytic-like effects in animals in a number of different behavioral testing paradigms. Although progesterone is known to influence physiology and behavior by binding to classical intracellular progestin receptors, progesterone''s anxiety reducing effects have solely been attributed to its rapid non-genomic effects at the GABA_A receptor. This modulation occurs following the bioconversion of progesterone to allopregnanolone. Seemingly paradoxical results from some studies suggested that the function of progesterone to reduce anxiety-like behavior may not be entirely clear; therefore, we hypothesized that progesterone might also act upon progestin receptors to regulate anxiety.

Methodology/Principal Findings

To test this, we examined the anxiolytic-like effects of progesterone in male rats using the elevated plus maze, a validated test of anxiety, and the light/dark chamber in the presence or absence of a progestin receptor antagonist, RU 486. Here we present evidence suggesting that the anxiolytic-like effects of progesterone in male rats can be mediated, in part, by progestin receptors, as these effects are blocked by prior treatment with a progestin receptor antagonist.

Conclusion/Significance

This indicates that progesterone can act upon progestin receptors to regulate anxiety-like behavior in the male rat brain.     

Diethylpyrocarbonate, a histidine selective reagent, inhibits progestin binding to chick oviduct cytosol

In this report we describe experiments showing that diethylpyrocarbonate, a histidine selective reagent, inhibits progestin binding to the chick oviduct progesterone receptor. Because this inhibition is reversed by hydroxylamine, we suggest that the chick oviduct progesterone receptor contains one or more histidine residues that regulate progestin binding. We also find that the progestin R5020 protects the progesterone receptor from diethylpyrocarbonate mediated inhibition of progestin binding. From this we infer that the progestin binding site contains a histidine residue(s) important for progesterone binding to its receptor in chick oviduct.     

Estradiol pulses induce progestin receptors selectively in substance P-immunoreactive neurons in the ventrolateral hypothalamus of female guinea pigs

Low doses of estradiol, administered as pulses, are as effective as higher doses for priming ovariectomized (OVX) guinea pigs to display progesterone-facilitated lordosis. High doses of estradiol, administered by constant-release implants, induce progestin receptors in many substance P-immunoreactive (SP-IR) neurons in the ventrolateral hypothalamus (VLH), a site at which estradiol primes OVX guinea pigs to respond behaviorally to progesterone. To test the hypothesis that behaviorally effective estradiol pulses induce progestin receptors selectively in substance P-containing neurons in the VLH, OVX females received estradiol implants 1 week prior to perfusion, or two pulses of estradiol- 17β, injected 39 and 11 h before perfusion. Colchicine was administered intracerebroventricularly prior to perfusion. No significant differences were observed in the total number of progestin receptor-immunoreactive (PR-IR) or substance P-immunoreactive cells in the VLH and VLH/ventromedial hypothalamus (VMH), respectively, of females receiving the two estradiol treatments. However, the percentage of PR-IR cells in the VLH also immunoreactive for SP was significantly higher in the estradiol pulse-treated (53%), than in the estradiol capsule-implanted animals (36%). These data suggest that behaviorally effective estradiol pulses induce progestin receptors selectively in substance P-containing neurons in the VLH and are consistent with the hypothesis that substance P is involved in progesterone-facilitated lordosis in guinea pigs.     

Estradiol pulses induce progestin receptors selectively in substance P-immunoreactive neurons in the ventrolateral hypothalamus of female guinea pigs.

Low doses of estradiol, administered as pulses, are as effective as higher doses for priming ovariectomized (OVX) guinea pigs to display progesterone-facilitated lordosis. High doses of estradiol, administered by constant-release implants, induce progestin receptors in many substance P-immunoreactive (SP-IR) neurons in the ventrolateral hypothalamus (VLH), a site at which estradiol primes OVX guinea pigs to respond behaviorally to progesterone. To test the hypothesis that behaviorally effective estradiol pulses induce progestin receptors selectively in substance P-containing neurons in the VLH, OVX females received estradiol implants 1 week prior to perfusion, or two pulses of estradiol-17 beta, injected 39 and 11 h before perfusion. Colchicine was administered intracerebroventricularly prior to perfusion. No significant differences were observed in the total number of progestin receptor-immunoreactive (PR-IR) or substance P-immunoreactive cells in the VLH and VLH/ventromedial hypothalamus (VMH), respectively, of females receiving the two estradiol treatments. However, the percentage of PR-IR cells in the VLH also immunoreactive for SP was significantly higher in the estradiol pulse-treated (53%), than in the estradiol capsule-implanted animals (36%). These data suggest that behaviorally effective estradiol pulses induce progestin receptors selectively in substance P-containing neurons in the VLH and are consistent with the hypothesis that substance P is involved in progesterone-facilitated lordosis in guinea pigs.     

Progestin, estrogen and androgen G-protein coupled receptors in fish gonads

The identities of the membrane receptors mediating the majority of rapid, cell surface-initiated, nongenomic (i.e. nonclassical) steroid actions described to date are unclear. Two novel 7-transmembrane spanning proteins, representing two distinct classes of steroid membrane receptors, membrane progestin receptor alpha (mPRalpha) and a membrane estrogen receptor (mER), GPR30, have recently been identified in several vertebrate species. Evidence that both receptors activate G-proteins and function as G-protein coupled receptors (GPCRs) is briefly reviewed. New data on progestin actions on fish gametes suggest a widespread involvement of mPRalpha in oocyte maturation and sperm hyperactivity in this vertebrate group. Information on the second messenger pathways activated upon estrogen binding to a membrane estrogen receptor in croaker gonads and preliminary evidence for the presence of a GPR30-like protein in fish gonads are discussed. Finally, initial characterization of the ligand binding, G-protein activation and molecular size of a membrane androgen receptor (mAR) in croaker ovaries suggests the presence of a third unique steroid receptor in fish gonads that also may function as a GPCR.     

Long-term ovariectomy and hormone-induced sexual behavior, progestin receptors, and hypothalamic morphology in female rats

Long-term ovariectomy reduces the ability of estradiol and progesterone treatment to induce sexual receptivity in female rats. Previous researchers suggested that this effect may be due to a decreased induction of neural progestin receptors by estradiol in the long-term ovariectomized rats. The present study was designed to replicate and extend this finding, and to search for neuroanatomical correlates by measuring the volume of the ventromedial nucleus (VMN) of the hypothalamus, a putative site of action of estradiol and progesterone for the induction of female sexual behavior. Long-term ovariectomy (5 to 6 weeks) as compared to short-term ovariectomy (1 week) reduced the ability of estradiol-17 beta and progesterone treatment to induce sexually receptive and proceptive behaviors. Consistent with previous reports, our data show that the reduced levels of cytosol progestin receptors after long-term ovariectomy and estradiol treatment are related to a reduced ability of estradiol to induce the receptors. Long-term ovariectomy did not affect the concentration of cytosol progestin receptors in the preoptic area, suggesting a neuroanatomical specificity to this effect. Contrary to our predictions, long-term ovariectomy did not affect the volume of the VMN. In fact, estradiol treatment, while blocking the effect of long-term ovariectomy on sexual behavior, decreased the volume of the VMN. Therefore, the measurement of the volume of the VMN is not a good predictor of the responsiveness to steroid hormone induction of sexual behavior.     

Honey, we need to talk about the membrane progestin receptors

The recent discovery of three closely related cell surface receptors that bind to progesterone and mediate its actions on various cytoplasmic signalling cascades has been heralded as a major break-through. The reason for this is all too obvious. Progesterone is an essential regulator of all major reproductive events and progestins and antiprogestins are widely used in the treatment of many different gynaecological and obstetrical disorders. The novel membrane progestin receptors (mPRalpha, beta, gamma) reportedly resemble and function as G-protein-coupled receptors and therefore are promising pharmaceutical targets. However, our studies failed to corroborate that mPRs are expressed on the cell surface, that they mediate rapid progesterone signalling events, and even that they are bona fide progestin binding moieties. While the reason for these startling opposing results remains unclear, a critical review of existing data may help to shed some light onto the controversial mPRs. Time has come to talk.     

Characterization of rat hypothalamic progestin binding by spheroidal hydroxylapatite chromatography.

The progestin-high-affinity-binding components in rat target tissues have been assayed by a simple and precise procedure by using spheroidal hydroxylapatite. The progestin 'receptors' in the uterus and hypothalamus of female rats are highly specific for progestins, which they bind with high affinity (Kd for [3H]progesterone in hypothalamus is 1.9 nM and in uterus is 3.7 nM). The dissociation of [3H]progesterone from receptor in vitro is rapid: t1/2 6 degrees C = 45 min in uterine cytosol; t1/2 6 degrees C = 160 min in hypothalamic cytosol. The binding is destroyed by proteinase. In the cytosol of hypothalamus and cortex of developing rats, progestin 'receptors' were present in both male and female rats by 2-3 days after birth; subsequent changes in concentration of these 'receptors' appeared to be independent of sex. Concentrations of progestin 'receptor' were close to adult values by 8-9 days, and thereafter changed relatively little.     

A potential role for catecholamines in the development and progression of carcinogen-induced mammary tumors: hormonal control of beta-adrenergic receptors and correlation with tumor growth.

In order to gain further knowledge on the beta-adrenergic receptor system in DMBA-induced rat mammary tumors, we have studied the correlation between changes in tumoral beta-adrenergic receptor concentration and distribution, progesterone receptor status and tumor growth after ovariectomy and treatment with various ovarian and adrenal steroids, or induction of hyperprolactinemia. Autoradiographic localization of beta-adrenergic receptors in ovariectomized (OVX) animals shows very weak labeling with [125I]cyanopindolol. In these tumors, the connective tissue is predominant, while the epithelial cell content is very low. Similarly, when direct measurements of [125I]cyanopindolol are performed with membrane preparations, beta-adrenergic receptor concentration is sharply reduced 2-3 weeks following ovariectomy or treatment with LHRH against [D-Trp6, des-Gly-NH2(10)]LHRH ethylamide. This effect on the beta-adrenergic receptor population in the tumor is accompanied by the well known effect of castration on tumor growth and progesterone receptor levels, namely a marked regression of tumor growth and a significant decrease in progesterone receptor concentration. Treatment of OVX rats with 17 beta-estradiol (E2) alone or in combination with progesterone (P) caused a highly significant increase in beta-adrenergic and progesterone receptor levels, as well as tumor growth. A similar sharp increase in the value of the three parameters studied was observed following daily treatment of OVX rats with dehydroepiandrosterone (DHEA) or androst-5-ene-3 beta,17 beta-diol (5-ene-diol). The autoradiographic localization of beta-adrenergic receptors in OVX rats treated with 5-ene-diol showed that the epithelial cells were numerous with a high degree of labeling. On the other hand, treatment of OVX animals with the androgen dihydrotestosterone (DHT) did not produce significant changes in beta-adrenergic receptor levels or tumor growth. Finally, endogenously-induced hyperprolactinemia by implanting three anterior pituitary glands under the kidney capsule of OVX animals resulted in a significant increase in beta-adrenergic and progesterone receptor levels as well as tumor growth. The positive correlation observed between changes in beta-adrenergic receptor concentration, progesterone receptor levels and tumor growth indicates a high sensitivity of the beta-adrenergic receptor population of DMBA-induced rat mammary tumors to the hormonal milieu, and suggests that the beta-adrenergic receptor system may represent a valuable parameter of hormone responsiveness.     

Membrane actions of progestins at dopamine type 1-like and GABAA receptors involve downstream signal transduction pathways

In the ventral tegmental area (VTA), progestins facilitate lordosis via rapid actions at membrane dopamine Type 1-like (D(1)) and/or GABA(A) receptors (GBRs), rather than via cognate, intracellular progestin receptors (PRs). Downstream signal transduction pathways involved in these effects were investigated using lordosis as a bioassay. If progestins' actions at D(1) and/or GBRs in the VTA require activation of G-proteins, adenylyl cyclase, cyclic AMP-dependent protein kinase A (PKA), phospholipase C (PLC), and/or PKC, then pharmacologically blocking these pathways would be expected to attenuate progestin-facilitated lordosis and its enhancement by D(1) and GBR activity. Ovariectomized, estradiol-primed rats were infused first with vehicle or signal transduction inhibitor, and second with vehicle, a D(1) or GBR agonist, and then with vehicle or progestins to the VTA. Rats were tested for lordosis following infusions. Results indicated that initiation of G-proteins, adenylyl cyclase, PKA, PLC, or PKC in the VTA is required for rapid effects of progestins through D(1) and/or GBRs to facilitate lordosis. As well, progestins' actions at n-methyl-d-aspartate receptors (NMDARs) may modulate activity at D(1) and/or GBRs and mitogen activated protein kinase (MAPK) may be a common signaling pathway. Findings from a microarray study demonstrated that there was upregulation of genes associated with steroid metabolism, GBRs, D(1), NMDARs and signal transduction factors in the midbrain VTA of naturally receptive mated compared to non-mated rats. Thus, in the VTA, progestins have rapid membrane-mediated actions via D(1), GBRs, NMDARs and their downstream signal transduction pathways.