Alpha and luteinizing hormone beta subunit messenger ribonucleic acids during the rat estrous cycle

Alpha and LH beta subunit mRNAs were measured in pituitaries of 4-day cycling rats during the estrous cycle. A two-fold increase in alpha mRNA occurred between 0800-2000 h on diestrus, but alpha mRNA concentrations were stable during other days of the cycle. LH beta mRNA concentrations were low during estrus and metestrus (11-16 pg cDNA bound/100 micrograms pituitary DNA), but were elevated (27-30 pg) between 0800-2000 h on diestrus. A second increase in LH beta mRNA was observed on the afternoon of proestrus, prior to the onset of the LH surge with maximum values (45 pg) coincident with peak LH secretion. LH beta mRNA concentrations declined rapidly and had fallen to basal values by midnight on proestrus. These data show that alpha and LH beta mRNAs change in a similar manner during metestrus, diestrus and estrus, suggesting coordinate regulation of alpha and LH beta gene expression at these times. During the LH surge, however, LH beta mRNA alone is increased, suggesting that the LH beta gene can be differentially expressed at times when maximum LH secretion is occurring.     

Modulation of endogenous opioid influence on luteinizing hormone secretion by progesterone and estrogen

Studies were undertaken using the opiate receptor antagonist naloxone (NAL) to evaluate the relative influence of endogenous opioid peptides (EOP) on LH secretion in cycling and ovariectomized, steroid-treated adult rats. Intact animals received NAL (2 mg/kg, sc) or saline (control vehicle) at 0800 and 1400 h on estrus, 0800 h on diestrus day 1,2000 h on diestrus day 2, and before (at 0800, 1200, and 1400 h) and during the preovulatory LH surge (at 1600 and 1800 h) on proestrus. NAL stimulated LH release by 2- to 3-fold at all stages of the estrous cycle, including during the proestrous gonadotropin surge. Ovariectomized rats were treated with estradiol benzoate (EB; 7.5 micrograms/rat, sc) and 2 days later received NAL (2 mg/kg, sc) or saline at 1000, 1200, 1400, 1600, and 2000 h. NAL induced a relatively small (44-73%), but significant, increase in LH release before (1000, 1200, and 1400 h), during (1600 h), and after (2000 h) the afternoon LH rise. While progesterone (P) treatment (5 mg, sc, day 2 at 1000 h) of EB-primed ovariectomized rats augmented NAL-induced LH release before the LH surge (1200 h), it abolished the LH secretory response to NAL during the LH surge (1400, 1600, and 1800 h). The NAL-induced LH response returned after the LH surge at 2000 h. Likewise, administration of P on proestrus morning (0900 h) abolished the LH secretory response to NAL during the LH surge. These studies indicate that central opioid neurons participate in the tonic inhibition of LH secretion at all stages of the estrous cycle of the rat. The ability of exogenous P to advance and amplify the LH surge on proestrus and in EB-primed ovariectomized rats appears to result in part from a reduction in the EOP inhibitory influence on LH secretion and may indicate a role for EOP in mediating the stimulatory effects of endogenous steroids on LH secretion in the female rat.     

Follicle-stimulating hormone beta subunit messenger ribonucleic acid concentrations during the rat estrous cycle

Serum follicle-stimulating hormone (FSH), pituitary FSH content and FSH beta subunit mRNA concentrations were measured at 1 to 3h intervals throughout the 4 day estrous cycle in rats. Serum FSH was stable (range 200-320 ng/ml) apart from the biphasic proestrus surge (5 fold elevation) which was present from 1800 h of proestrus through 0800 h on estrus. Basal FSH beta mRNA concentrations from late metestrus through the afternoon of proestrus were 0.10 +/- 0.04 f mol cDNA bound/100 micrograms pituitary DNA. The major increase in FSH beta mRNA began at 2000 h on proestrus, 2 h after the initial rise in serum FSH and peak mRNA concentrations (0.43 +/- 0.08 f mol cDNA bound) occurred at 0200 h on estrus. FSH beta subunit mRNA concentrations were again increased at 2300 h on estrus (peak 0.24 f mol cDNA bound) and remained elevated through 1700 h on metestrus. Pituitary FSH content was transiently increased during metestrus and diestrus, but was elevated at 1000 h through 1900 h on proestrus (peak 5-fold increase). FSH content fell rapidly at 2000 h and remained low until 1400 h on estrus when values again rose. These data show that FSH beta mRNA is increased 4-5 fold during the proestrus FSH surge, and a smaller increase occurs on metestrus in the absence of elevated FSH secretion. The increased concentrations of FSH beta mRNA occurred at different times to the previously reported changes in alpha and LH beta mRNAs. Therefore, the data suggest that different mechanisms are involved in the regulation of LH and FSH beta subunit gene expression during the 4-day estrous cycle in rats.     

Follicle-stimulating hormone beta subunit messenger ribonucleic acid concentrations during the rat estrous cycle

Serum follicle-stimulating hormone (FSH), pituitary FSH content and FSH beta subunit mRNA concentrations were measured at 1 to 3h intervals throughout the 4 day estrous cycle in rats. Serum FSH was stable (range 200-320 ng/ml) apart from the biphasic proestrus surge (5 fold elevation) which was present from 1800h of proestrus through 0800 h on estrus. Basal FSH beta mRNA concentrations from late metestrus through the afternoon of proestrus were 0.10 +/- 0.04 f mol cDNA bound/100 micrograms pituitary DNA. The major increase in FSH beta mRNA began at 2000 h on proestrus, 2 h after the initial rise in serum FSH and peak mRNA concentrations (0.43 +/- 0.08 f mol cDNA bound) occurred at 0200 h on estrus. FSH beta subunit mRNA concentrations were again increased at 2300 h on estrus (peak 0.24 f mol cDNA bound) and remained elevated through 1700 h on metestrus. Pituitary FSH content was transiently increased during metestrus and diestrus, but was elevated at 1000 h through 1900 h on proestrus (peak 5-fold increase). FSH content fell rapidly at 2000h and remained low until 1400 h on estrus when values again rose. These data show that FSH beta mRNA is increased 4-5 fold during the proestrus FSH surge, and a smaller increase occurs on metestrus in the absence of elevated FSH secretion. The increased concentrations of FSH beta mRNA occurred at different times to the previously reported changes in alpha and LH beta mRNAs. Therefore, the data suggest that different mechanisms are involved in the regulation of LH and FSH beta subunit gene expression during the 4-day estrous cycle in rats.     

The relation between the effects of hysterectomy, decidual tissue, prolactin, or luteinizing hormone (LH) and the ability of indomethacin to prevent luteolysis in rats bearing LH-dependent corpora lutea

In adult rats hysterectomized on day 8 of pseudopregnancy, the mean serum progesterone (P) level fell from 88 ng/ml on day 8 to 44 ng/ml on day 15 (n = 61). In response to a single sc injection of 0.5 ml of a specific antiserum to LH (LHAS) on day 10, the P level fell to less than 10 by day 15 in 29 of 33 rats; however, this fall, which was indicative of luteolysis, was briefly interrupted by a return to the control level 36 h after treatment. Indomethacin (400 micrograms, sc) administered 12 h before, during, and 12 h after the LHAS injection prevented the luteolysis that followed the 36 h surge in 10 of 15 rats (P less than 0.001). Treatment with 400 micrograms 2Br-alpha ergocryptine (CB 154), sc, on day 10, with or without indomethacin, however, induced a rapid, uninterrupted, and permanent fall to less than 10 in 13 of 13 rats. Treatment with both LHAS and CB 154 reduced the luteolytic effect of CB 154 (P less than 0.001), and indomethacin treatment combined with both LHAS and CB 154 tended to further reduce the luteolytic effect of CB 154 (P less than 0.01). Hypophysectomy on day 10, however, induced rapid, uninterrupted and permanent luteolysis in all rats (15); this was not affected by indomethacin (7 rats) or LHAS (8 rats). Pituitary homotransplantation on day 8 prevented the luteolytic effect of LHAS on day 10 in 6 of 6 rats (P less than 0.003). In decidual tissue (DT)-bearing rats, LHAS on day 10 induced rapid, uninterrupted, and permanent luteolysis in 18 of 18 rats. The response to LHAS on day 10 changed to that of the hysterectomized rat when the DT-bearing uterus was removed on day 8 (12 of 12 rats) or 10 (7 of 7 rats) (P less than 0.001), but did not change when it was removed on day 11 (5 of 5 rats). In DT-bearing rats hysterectomized on day 8, indomethacin in intrabursal Silastic wafers prevented luteolysis in response to LHAS on day 10 (6 of 6 rats; P less than 0.001). Intrabursal indomethacin had no effect on the response to LHAS in intact DT-bearing rats (3 of 3 rats). These results suggest that even when the corpus luteum becomes LH dependent, PRL may retard or prevent LHAS-induced luteolysis in hysterectomized rats. (ABSTRACT TRUNCATED AT 400 WORDS)     

Neonatal handling and reproductive function in female rats

Neonatal handling induces anovulatory estrous cycles and decreases sexual receptivity in female rats. The synchronous secretion of hormones from the gonads (estradiol (E2) and progesterone (P)), pituitary (luteinizing (LH) and follicle-stimulating (FSH) hormones) and hypothalamus (LH-releasing hormone (LHRH)) are essential for the reproductive functions in female rats. The present study aimed to describe the plasma levels of E2 and P throughout the estrous cycle and LH, FSH and prolactin (PRL) in the afternoon of the proestrus, and the LHRH content in the medial preoptic area (MPOA), median eminence (ME) and medial septal area (MSA) in the proestrus, in the neonatal handled rats. Wistar pup rats were handled for 1 min during the first 10 days after delivery (neonatal handled group) or left undisturbed (nonhandled group). When they reached adulthood, blood samples were collected through a jugular cannula and the MPOA, ME and MSA were microdissected. Plasma levels of the hormones and the content of LHRH were determined by RIA. The number of oocytes counted in the morning of the estrus day in the handled rats was significantly lower than in the nonhandled ones. Neonatal handling reduces E2 levels only on the proestrus day while P levels decreased in metestrus and estrus. Handled females also showed reduced plasma levels of LH, FSH and PRL in the afternoon of the proestrus. The LHRH content in the MPOA was significantly higher than in the nonhandled group. The reduced secretion of E2, LH, FSH and LHRH on the proestrus day may explain the anovulatory estrous cycle in neonatal handled rats. The reduced secretion of PRL in the proestrus may be related to the decreased sexual receptiveness in handled females. In conclusion, early-life environmental stimulation can induce long-lasting effects on the hypothalamus-pituitary-gonad axis.     

Prolactin messenger ribonucleic acid concentrations in 4-day cycling rats and during the prolactin surge

Pituitary PRL mRNA concentrations were measured during the 4-day rat estrous cycle. Adult female Sprague-Dawley rats were killed at 3-h intervals throughout the cycle and hourly between 1000 and 2400 h on proestrus (n = 5-12). Serum PRL was increased on the afternoons of proestrus (P) and estrus (E), with peak concentrations at 1700 h (P, 624 +/- 126; E, 261 +/- 107 ng/ml). PRL mRNA concentrations were elevated during the evening on P and E (2300 h: P, 14.4 +/- 1.5; E, 16.1 +/- 1.3 ng cDNA bound/100 micrograms pituitary DNA) to values 2-fold higher than those at 0800 h on each respective day. On diestrus (D) PRL mRNA levels decreased abruptly during the morning (1100 h, 1.7 +/- 0.3 ng cDNA bound), followed by a 6- to 7-fold increase between 1700 and 2000 h on the same evening. In contrast, PRL mRNA levels were elevated at 0800 h on metestrus (M). The changes in PRL mRNA concentrations obtained on M and D were not associated with increased PRL secretion. A more detailed examination of P revealed that PRL mRNA levels increased during the morning (1000 h, 9.9 +/- 2.6 ng cDNA bound), then decreased abruptly at 1100 h (4.9 +/- 1.2). The morning rise in mRNA concentrations was followed by a 2-fold rise in pituitary PRL content. As serum PRL rose during the afternoon surge, a coincident decrease in pituitary PRL content and an increase in PRL mRNA levels were observed. The relationship between PRL secretion and gene expression was further examined in ovariectomized estradiol-replaced rats receiving either bromocriptine (1.2 mg/day, sc) or vehicle control sc. The vehicle-treated group expressed a characteristic afternoon PRL surge between 1500 and 2100 h. Pituitary PRL decreased during the surge to 10% of morning values, and PRL mRNA levels increased 2-fold beginning 2 h after initiation of the surge. These changes in serum PRL, pituitary PRL, and PRL mRNA levels were abolished by bromocriptine administration. These data reveal that alterations in PRL mRNA concentrations occur on a daily basis during the rat estrous cycle. Increases occur during the evenings of P and E at the time of the increase in PRL secretory activity. The effect of blocking the PRL surge in ovariectomized estradiol-replaced rats suggests a regulatory interaction between secretion and gene expression.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparison of the effects of antiprogestins RU38486, ZK98299 and ORG31710 on periovulatory hypophysial, ovarian and adrenal hormone secretion in the rat

The antiprogestin (AP) RU38486 (RU) blocks progesterone (P) and glucocorticoid (G) actions. Administration of 4 mg RU on proestrous morning to cyclic rats dissociates LH and FSH secretion on proestrous afternoon, early estrus and on estrous afternoon. In order to ascertain which action blocked by RU is predominant in the control of periovulatory LH and FSH secretion, a study was made on the effects of: a) 1 or 4 mg of ZK98299 (ZK) (type I P antagonist; Schering), b) 2 or 8 mg of Org31710 (OR) (type II P antagonist lacking anti-G actions; Organon) or c) 1 or 4 mg of RU (type II P antagonist; Exelgyn) to 4-day cyclic rats on proestrous morning on serum concentrations of LH, FSH, inhibin-alpha (I), estradiol-17beta (E), progesterone (P) and corticosterone (B) at 18:30 h on proestrus and at 02:00 and 18:30 h on estrus. Controls, receiving 0.2 ml oil, had elevated serum concentrations of all six hormones on proestrous afternoon; at early estrus, only serum concentrations of FSH and P remained elevated, and, on estrous afternoon, all hormones but I and B, that peaked again, had reached their lowest serum levels. All AP treatments except 1 mg ZK had the same effects. On proestrous afternoon serum LH concentrations were reduced and serum FSH concentrations were suppressed whereas serum levels of I, E, P and B were unaffected. At early estrus, basal serum concentrations of LH and E increased while FSH secretion was abolished. Serum levels of I, P and B did not differ from controls. AP treatments increased basal LH concentration, hyperstimulated FSH secretion and reduced serum I concentration on the afternoon of estrus. E, P and B serum levels did not differ from controls at this stage. Treatment with 1 mg ZK was less effective in reducing serum FSH on proestrous afternoon and at early estrus, and had no effect on serum concentrations of any hormone on estrous afternoon. These results indicate that blockade of P receptor activation by P is, predominantly, the mechanism of AP action on periovulatory gonadotropin secretion in rats.     

Effect of naloxone on luteinizing hormone, follicle-stimulating hormone, and prolactin secretion in the different phases of the estrous cycle

It is becoming increasingly clear that the effects exerted by opioid agonists and antagonists on the release of gonadotropins and of PRL may vary according to the endocrine milieu. To investigate this issue further, female rats with a regular 4-day estrous cycle have been injected sc with the opioid antagonist naloxone at different hours of the day, during each of the various days of the estrous cycle. The animals were killed 20 min after the sc administration of naloxone (2.5 mg/kg dissolved in 0.9% saline solution) at 1000 and 1600 h on the first and second day of diestrus and at 1000, 1200, 1400, 1600, 1800, and 2000 h on proestrus and estrus. Animals were killed by decapitation, and trunk blood was collected and assayed for LH, FSH, and PRL. The data obtained from naloxone-treated animals were compared to those derived from controls injected sc with 0.9% saline solution and killed at the same time intervals. The sc injections of naloxone stimulated LH release in every phase of the estrous cycle; however the magnitude of the responses was highly variable. Increases of the order of 700-1.000% were observed during the 2 days of diestrus, at 1000 and 1400 h of the day of proestrus, and at 1600, 1800, and 2000 h of the day of estrus. Much higher responses (of the order of 2.700-3.300%) were observed at 1600 h of the day of proestrus and at 1000, 1200, and 1400 h of the day of estrus. The LH response to naloxone appeared to be obliterated at 1800 and 2000 h of the day of proestrus. Serum levels of FSH and PRL were not affected by the treatment at any of the time intervals considered. These findings suggest that, in normally cycling adult female rats, naloxone exerts a stimulatory effect on LH release during each day of the estrous cycle; that the stimulatory effect of naloxone is minimal at the time of the spontaneous proestrous LH surge; and that the effect of naloxone on LH release is, on the contrary, maximal just before the spontaneous proestrous LH surge and up to 1400 h of the day of estrus. The observation that naloxone does not affect FSH and PRL release underlines once more that the central mechanisms controlling LH, FSH, and PRL secretion are different.     

Anterior pituitary gland secretion after forebrain ablation: periovulatory gonadotropin release

We sought to determine whether the estrous phase of FSH release in cyclic female rats is dependent on the immediate presence of the diencephalon. A piece of forebrain, the diencephalon and part of the telencephalon, was surgically removed from female rats between 1130--1300 or 2000-2200 h on proestrus. Blood was withdrawn through indwelling venous cannulae during the afternoon and evening of proestrus and the early morning of estrus for RIA of plasma LH, FSH, and PRL concentrations. In rats sham operated at either time period, plasma LH, FSH, and PRL levels rose from 1345 to 1800 h on proestrus. Whereas the plasma LH and PRL concentrations fell from 1800 h on proestrus to 0300 h on estrus, the plasma FSH concentrations remained elevated during this period. The removal of the piece of forebrain around noon on proestrus blocked the rises in the plasma LH and FSH levels and caused high plasma PRL concentrations from 1345 h on proestrus to 0300 h on estrus. The removal of the piece of forebrain during the evening of proestrus did not interfere with the fall in plasma LH concentrations or the maintenance of elevated plasma FSH concentrations during either late proestrus or the early morning estrus, but did cause high plasma PRL levels during that time interval. Hypophysectomy combined with removal of the forebrain piece during the evening of proestrus resulted in a drop in plasma FSH and PRL concentrations. The results confirm that in the rat, 1) the prosencephalon plays an acute stimulatory role n causing the preovulatory LH surge and the proestrous phase of FSH release, 2) the prosencephalon exerts effects during the afternoon and/or early evening of proestrus that cause the estrous phase of FSH release, and 3) the estrous phase of FSH release occurs in the absence of acute diencephalic stimulation.     

The control of progesterone secretion during the estrous cycle and early pseudopregnancy in the rat: prolactin, gonadotropin and steroid levels associated with rescue of the corpus luteum of pseudopregnancy.

The hormonal factors associated with converting a corpus luteum of estrous cycle into a corpus luteum of pseudopregnancy were studied by measuring LH and FSH prolactin, estradiol and progesterone levels in decapitated rats during the 4-day estrous cycle and a comparable time of pseudopregnancy (lights on 0600-0800 hr.). During the estrous cycle, prolactin, LH and FSH remained low and unchanging except on the afternoon of proestrus, when typical proestrous surges were observed. In contrast, estradiol levels began to increase on D-1, from baseline values of 7 pg/ml to approximately 15-20 pg/ml. These levels were maintained until the afternoon of D-2 when estradiol further increased to reach peak levels of 40-50 pg/ml by 0900 hr on proestrus. Estradiol then declined in relation to the increase in LH secreation and had returned to baseline by estrus. Progesterone secretion by the corpora lutea of the cycle also increased on the afternoon of D-1 and reached a maximum value of 25-30 ng/ml early on the morning of D-2. At this time, a precipitious fall in progesterone occurred, returning to baseline values of 5-1- ng/ml by 0700 on D-2 signifying the regression of the corpora lutea of the cycle. Progesterone remained low thereafter until the afternoon of proestrus when levels increased in response to the proestrus when levels increased in response to the proestrous surge of LH. Following cervical stimulation at 1900 hr on proestrus, no differences were noted, with respect to the estrous cycle, in LH, FSH or estradiol secreation through the afternoon of D-2. Surprisingly, progesterone levels did not differ in the cycle and pseudopregnancy until the early morning of D-29 instead of progesterone levels falling to baseline as they had during the cycle, the corpora lutea of pseudopregnancy were rescused, progesterone increasing dramatically to reach levels of 45-50 ng/ml by 1700 hr on that same day. The only difference in hormone secretion that was noted which could account for this marked divergence in progesterone secretion was the pattern of prolactin secretion following cervical stimulation. In contrast to the low levels seen during the estrous cycle, biphasio surges of prolactin secretion occured each day, one being nocturnal (0100-0900 hr) and the other diurnal (1500-2100 hr). The rescue of the corpus luteum occured in association with the nocturnal surge on D-2. These results suggest that nocturnal surge on D-2, PROLACTIN IS THE MAJOR Luteotropic stimulus which transforms and estrous cycle into pseudopregnancy by prolonging progesterone secretion from the corpus luteum. Moreover, if LH is important for progesterone secretion, no changes were observed in the pattern of LH secretion which can account for the rescue of the corpus luteum.     

Effects of ghrelin upon gonadotropin-releasing hormone and gonadotropin secretion in adult female rats: in vivo and in vitro studies

A reproductive facet of ghrelin, a stomach-derived orexigenic peptide involved in energy homeostasis, has been recently suggested, and predominantly inhibitory effects of ghrelin upon luteinizing hormone (LH) secretion have been demonstrated in rat models. Yet, the modulatory actions of ghrelin on the gonadotropic axis remain scarcely evaluated. We report herein a detailed analysis of the effects of ghrelin upon LH and follicle-stimulating hormone (FSH) secretion in the female rat, using a combination of in vivo and in vitro approaches. Intracerebroventricular administration of ghrelin (3 nmol/rat) evoked a significant inhibition of LH secretion in cyclic female rats throughout the estrous cycle (proestrus afternoon, estrus, metestrus), as well as in ovariectomized females. In good agreement, gonadotropin-releasing hormone (GnRH) secretion by hypothalamic fragments from ovariectomized females was significantly inhibited by ghrelin. In contrast, ghrelin dose-dependently stimulated basal LH and FSH secretion by pituitary tissue in vitro; a phenomenon that was proven dependent on the phase of estrous cycle, as it was neither detected at estrus nor observed after ovariectomy. Conversely, GnRH-stimulated LH secretion in vitro was persistently inhibited by ghrelin regardless of the stage of the cycle, whereas stimulated FSH secretion was only inhibited by ghrelin at estrus. In addition, cyclic fluctuations in mRNA levels of growth hormone secretagogue receptor (GHS-R)1a, i.e. the functional ghrelin receptor, were observed in the pituitary, with low values at estrus and metestrus. GHS-R1a mRNA levels, however, remained unchanged after ovariectomy. In summary, our data illustrate a complex mode of action of ghrelin upon the gonadotropic axis, with predominant inhibitory effects at central (hypothalamic) levels and upon GnRH-induced gonadotropin secretion, but direct stimulatory actions on basal LH and FSH secretion. Overall, our results further document the reproductive role of ghrelin, which might be relevant for the integrated control of energy balance and reproduction.     

Age-associated increases in serum follicle-stimulating hormone levels on estrus are accompanied by a reduction in the ovarian secretion of inhibin

In light of recent data demonstrating age-related alterations in the secretion and production of follicle-stimulating hormone (FSH) during the secondary FSH surge on estrus, the following study was conducted to determine the effects of age on periovulatory inhibin secretion. Ovarian venous blood was collected from groups of ether-anesthetized 3- and 7-month-old rats exhibiting 4-day estrous cycles at the following times: 1200 and 2400 h on proestrus and 1600 h on estrus. Following a 10-min collection period, a terminal blood sample was obtained from the abdominal aorta. Peripheral serum concentrations of luteinizing hormone (LH), FSH, estradiol-17 beta (E2), progesterone (P) and testosterone (T) were measured by RIA. Inhibin activity in ovarian venous serum (OVS) was assessed by the ability of OVS to suppress basal FSH secretion from dispersed pituitary cells during a 24-hour culture period. At 1200 h on proestrus, serum FSH (and LH) levels were higher in 7-month-old rats than in younger rats while the FSH-suppressing activity of OVS did not differ between age groups at this time. Bioassayable inhibin activity substantially declined between 1200 and 2400 h on proestrus in both groups. By 1600 h on estrus, serum FSH levels and inhibin secretion were higher and lower, respectively, in the older age group compared to 3-month-old rats. Significant increases in inhibin secretion between 2400 h on proestrus and 1600 h on estrus were observed only in younger rats.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of hyperprolactinemia on estrous cyclicity, serum luteinizing hormone, prolactin, estradiol, and progesterone concentrations, and catecholamine activity in microdissected brain areas

The purpose of the present study was to determine the duration of PRL treatment required to suppress estrous cyclicity and preovulatory LH surges and to ascertain whether such treatment affects cyclicity by altering catecholamine activity and/or ovarian steroid secretion. Rats exhibiting 4-day estrous cycles were treated with ovine PRL (oPRL) or vehicle beginning on diestrous day 1 at 0900 h, diestrous day 2 at 2400 h, proestrus at 0600 h, or proestrus at 1200 h. Jugular veins of rats were cannulated to the level of the right atrium on diestrous day 2. Unrestrained rats were bled on proestrus. Preovulatory LH surges and ovulation were completely blocked, and vaginal cytology remained leukocytic on the expected day of proestrus and estrus when oPRL treatment was begun on diestrous day 1. Such treatment elevated progesterone levels beginning on diestrous day 2 and suppressed the preovulatory rise in estradiol observed on proestrous morning and afternoon in control rats. To determine the effect of oPRL on catecholamine activity, alpha-methylparatyrosine was administered to groups of oPRL- or vehicle-treated rats at 0900 or 1500 h on diestrous day 1, diestrous day 2, or proestrus. Animals were killed 0, 45, or 90 min later. Norepinephrine and dopamine concentrations were measured in the median eminence, suprachiasmatic nucleus, medial preoptic nucleus, striatum, ventral aspect of the stria terminalis, and posterior pituitary gland by radioenzymatic assay. Controls exhibited increased norepinephrine turnover rates in the median eminence, suprachiasmatic nucleus, and medial preoptic nucleus on proestrous afternoon concomitant with preovulatory LH surges. In contrast, oPRL-treated rats showed no such increase. In addition, median eminence dopamine turnover rates were elevated beginning on the afternoon of diestrous day 1 in oPRL-treated rats compared to control values. No other differences in norepinephrine and dopamine turnover rates were observed in oPRL-treated rats compared with controls in any other brain area on any day examined. Thus, the data indicate that elevated PRL concentrations have profound effects on reproductive cyclicity by disrupting ovarian steroid secretion and essential preovulatory neurochemical events in selected brain areas involved in the regulation of LHRH.     

Changes in alpha-estradiol receptor and progesterone receptor expression in the locus coeruleus and preoptic area throughout the rat estrous cycle

We have previously shown that the locus coeruleus (LC) is essential for triggering surges of LH. Since LC neurons are responsive to estradiol, which induces progesterone receptor (PR) expression, this study aimed to investigate whether LC neurons express the alpha-estradiol receptor (alphaER) and PR as well as comparing such responses to that observed in the preoptic area (POA). Female rats were perfused at 10, 14 and 16 h on each day of the estrous cycle, and a blood sample was collected for estradiol, progesterone and LH measurements. alphaER- and PR immunoreactive (ir) neurons were detected in POA and LC by immunocytochemistry (ICC). Higher plasma estradiol levels were observed on the day of proestrus, when a smaller number of alphaER-ir POA neurons were detected. An increase in the number of alphaER-ir neurons were observed at 16 h of proestrus and estrus. The number of PR-ir neurons increased in POA only at 16 h of proestrus, and remained unchanged during all other days and times. The profile of alphaER-ir and PR-ir neurons in LC changed over the estrous cycle, with a lower expression on metestrus morning and reaching a peak on diestrus afternoon before declining on the day of proestrus. However, on estrus afternoon, alphaER-ir neurons increased, while PR-ir neurons decreased which may be related to the prolactin surge of estrus. These data show that LC neurons express alphaER and PR and seem to be more sensitive to variations in estradiol than POA. Also, the fluctuation in alphaER and PR observed for LC neurons seems to accompany the hormonal events that occur during the estrous cycle. This profile of alphaER and PR expression might be related to the ability of estradiol and progesterone in regulating the activity of LC neurons, which could be associated to the control mechanisms of LH and prolactin release.     

Progesterone on an oestrogen background enhances prolactin-induced apoptosis in regressing corpora lutea in the cyclic rat: possible involvement of luteal endothelial cell progesterone receptors

Preovulatory surges of both prolactin (PRL) and progesterone have been suggested to be necessary for the induction of apoptosis in the regressing corpus luteum of the cyclic rat. The aim of these experiments was to study whether the administration of PRL and/or progesterone on the morning of pro-oestrus reproduces the regressive changes that happen in the cyclic corpus luteum (CL) during the transition from pro-oestrus to oestrus, and to analyse the temporal relationships between two characteristic features of structural luteolysis (luteal cell apoptosis and accumulation of macrophages). Cyclic rats (treated at 0900 h with an LHRH antagonist to block LH secretion) were injected at 1000 h with PRL and progesterone and killed at 0, 30, 60, 90 and 180 min after treatment. The number of apoptotic cells increased progressively from 60 min after treatment onward in hormone-treated rats, whereas the number of macrophages did not change throughout the period of time considered. Rats injected with PRL plus progesterone showed significantly greater numbers of apoptotic cells than those injected with PRL alone. The luteolytic effects of progesterone were in keeping with the presence of luteal endothelial cells showing progesterone receptor (PR) immunoreactivity in pro-oestrus. Treatment of rats during dioestrus and pro-oestrus with the specific antioestrogens LY117018 and RU58668 decreased the luteolytic effects of PRL and progesterone and the number of luteal endothelial cells immunostained for PR. These results strongly suggest that the preovulatory PRL surge and the preovulatory increase in progesterone together trigger structural regression of the corpus luteum. This seems to be dependent on oestrogen-driven cyclic changes in PRs in luteal endothelial cells.     

Role of proestrous progesterone secretion in suppressing basal pulsatile LH secretion during estrus of the estrous cycle

These studies examined the mechanisms responsible for the paucity of basal LH pulses during estrus. We confirmed our earlier observations that constant infusion of naloxone during estrus results in the immediate appearance of pulsatile LH secretion during estrus, consisting of LH peak heights and LH interpulse intervals that are similar to those observed during other days of the estrous cycle. We then tested whether the proestrous surge of progesterone was responsible for the suppression of pulsatile LH secretion during estrus. Three treatment regimens were used on proestrus to either block progesterone secretion (pentobarbital) or block its action (progesterone antiserum or the progesterone antagonist, RU 486). After treatment at 12.00 h on proestrus, blood samples were collected during estrus every 10 min for 4 h, and the plasma samples were analyzed for the pattern of LH secretion. Treatment with pentobarbital (35 mg/kg at 12:00 h) blocked the proestrous surges of LH and progesterone and resulted in pulsatile LH secretion during estrus. The LH interpulse interval (72 +/- 7 min) was somewhat slower than that observed in the naloxone-infused animals (54 +/- 8 min). Simultaneous treatment with pentobarbital and progesterone at 12:00 h on proestrus completely prevented the appearance of LH pulses during estrus. Treatment with either progesterone antiserum (0.5 ml, i.v.) or RU 486 (1 mg s.c.) resulted in the initiation of pulsatile LH secretion during estrus. In the RU 486-treated animals, LH peak heights and LH interpulse intervals were similar to those observed in naloxone-infused animals and during other days of the estrous cycle.(ABSTRACT TRUNCATED AT 250 WORDS)     

Variations of phospholipid methyltransferase(s) activity in the rat pituitary: estrous cycle and sex differences

We previously demonstrated a specific stimulatory action of estrogens on phosphatidylethanolamine methylation in rat pituitary membranes. To investigate the physiological relevancy of this effect, the activity of methylating enzyme(s) was evaluated during the rat estrous cycle, a period in which both endogenous ovarian steroid levels and the sensitivity of pituitary membrane receptors fluctuate. Anterior pituitary membranes (P2) were prepared from adult female rats at different stages of the estrous cycle and assayed for phospholipid methylation in the presence of S-adenosyl-[methyl-3H]methionine as a donor of 3H-methyl groups. Methylated phospholipids were separated by TLC. Formation of phosphatidyl-mono- and dimethylethanolamine and that of phosphatidylcholine increased significantly in the morning, reaching maximal values on the afternoon of proestrus; they decreased thereafter during estrus, metestrus, and diestrus. Plasma estradiol concentrations increased in late diestrus and then varied similarly with the fluctuations of phospholipid methyltransferase activity throughout the cycle. In parallel, plasma levels of LH and PRL were significantly elevated during the afternoon of proestrus, but remained low throughout the rest of the cycle. Under the same experimental conditions, phospholipid methylation in membranes prepared from mediobasal-hypothalamic structures was not affected. These data demonstrate that under physiological conditions the increased pituitary methyltransferase activity is associated with the progressive increment of plasma estradiol levels occurring shortly before proestrus and precedes the release of LH and PRL. Ovariectomy significantly decreased methyltransferase activity; however, 17 beta-estradiol treatment of ovariectomized rats for 5 days restored the enzyme activity, which was further augmented after progesterone administration. Attempting to investigate variations of pituitary methyltransferase activity in male rats, we demonstrated that the intact males showed weaker activity than that of females; orchidectomy diminished the phospholipid methylation, but adrenalectomy had no effect.     

Direct actions of estradiol on the anterior pituitary gland are required for hypothalamus-dependent lactotrope proliferation and secretory surges of luteinizing hormone but not of prolactin in female rats

Estradiol induces surges of prolactin (PRL) and luteinizing hormone (LH) secretion as well as lactotrope proliferation in female rats. We examined whether these hypothalamus-dependent events require the direct action of estradiol on the anterior pituitary gland by selective blockade of its peripheral actions, using ICI182,780 (ICI), an antiestrogen that cannot cross the blood-brain barrier. Injection of ICI into ovariectomized rats, at a dose of 250 microg/day for 4 days, almost completely inhibited estradiol-induced growth of the uterus, proliferation of lactotropes as determined by bromodeoxyuridine incorporation, and afternoon surges of LH secretion. However, ICI only partially inhibited estradiol-induced surges of PRL secretion and had no effect on estradiol-induced tonic inhibition of LH secretion even at the highest dose of 1,000 microg/day. The inhibitory effects of ICI found at 250 microg/day were attributable to its selective peripheral, but not central actions since ICI did not alter hypothalamic expression of progesterone receptors, an estradiol-dependent brain process. Estradiol-induced increases in the number of progesterone receptor-immunoreactive cells in the hypothalamic ventromedial nucleus and the medial preoptic area were not inhibited by this dose of ICI but were inhibited by 500 microg/day tamoxifen, an antiestrogen that can cross the blood-brain barrier. Treatment of cycling female rats with 250 microg/day ICI beginning from diestrus day 2 was also effective in blocking estrous lactotrope proliferation and preovulatory surges of LH secretion but not PRL secretion. Finally, in ovariectomized estradiol-treated pup-deprived lactating rats, ICI did not affect suckling-induced PRL secretion but completely blocked lactotrope proliferation. These results suggest that a direct estradiol action on the anterior pituitary gland is required for lactotrope proliferation and the positive feedback action on LH secretion but not for the secretory surges of PRL or for negative feedback.     

Specific binding of LH-RH to the anterior pituitary gland during the oestrous cycle in the rat.

Specific binding of luteinizing hormone-releasing hormone (LHRH) to the anterior pituitary gland during the estrous cycle was investigated in the rat. The amount of iodine-125-LHRH bound was 150 fmole/,g protein at proestrus, 20 fmole/mg at estrus, and 16 fmole/mg at metestrus. Specific binding of LHRH to the pituitary was not detectable in rats ovariectomized during the afternoon of diestrous 1 or morning of estrus but it was restored by treatment with estradiol-17-beta along or with progesterone. Peripheral plasma LHRH levels were 5 pg/ml at diestrous and increased to 20 pg/ml at proestrus (p greater than .05). Plasma LH levels were 16.7 ng/m1 at 4-5 p.m. of proestrus, 4 ng/m1 at 1-2 p.m. of preoestrus and 1-2 ng/m1 at other times. Preovulatory LH surge was not observed in rats ovariectomized at diestrus or sacrificed at the expected time of proestrus, however, estradiol treatment elevated LH levels and progesterone augmented this effect. These results suggest that in the rat the ovulatory LH surge at proestrus involves the hypothalmic release of LHRH as well as increased LHRH binding in the pituitary gland, both of which may be stimualted by the prevolulatory rise in estrogen and/or progesterone.