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.     

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.     

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)     

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.     

Reproductive endocrinology in Hatano high- and low-avoidance rats during the estrous cycle

The high- and low-avoidance animals (HAA and LAA rats) were originally selected from Sprague-Dawley rats for their shuttle-box task. Reproductive endocrinology during the estrous cycle was compared between HAA and LAA rats. All HAA rats showed a regular 4-d estrous cycle, whereas most LAA rats (70.8%) showed a regular 5-d estrous cycle. The peak level of preovulatory luteinizing hormone (LH) surge level was significantly lower in LAA rats than in HAA rats on the day of proestrus. In contrast, the peak level of prolactin surge on the day of proestrus was significantly higher in LAA rats than in HAA rats. Plasma concentrations of follicle-stimulating hormone (FSH) and estradiol-17β were significantly lower in LAA rats as compared with HAA rats at 12 h on the day of estrus and from 24 h on the day of diestrus to 18 h on the day of proestrus. On the other hand, plasma concentrations of progesterone were significantly higher in LAA rats compared with HAA rats on the day of diestrus. The number of antral follicles (300–600 μm in diameter) at 12 h on the day of proestrus was significantly fewer in LAA rats than in HAA rats. The size and number of corpus luteum at 12 h on the day of estrus were significantly greater in LAA rats than in HAA rats. These results clearly demonstrated that apparent differences are observed in reproductive endocrinology between two Hatano strains. These strain differences probably originated from neural regulation of pituitary hormones.     

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)     

Possible role of luteinizing hormone and follicle-stimulating hormone in modulating inhibin secretion and expression during the estrous cycle of the rat

In the female rat, plasma immunoreactive inhibin alpha (irl alpha) levels show marked changes during proestrus and estrus. We investigated the modulating effect of LH and FSH on these changes by injecting the GnRH antagonist DNal-DCpa-DPal-Dpr-(Ac)Dal-Leu-Arg-Pro-Asn-NH2, with or without exogenous LH replacement. Administration of the antagonist at noon on proestrus abolished the primary (proestrus) LH and FSH surge and markedly reduced the secondary (estrus) FSH surge. This treatment also reduced the release of irl alpha normally measured during proestrus afternoon, and partially prevented the decrease in irI alpha secretion on proestrus evening. Exogenous LH injected at 1545 h on proestrus had no measurable effect on irI alpha or FSH levels in control rats; however, in antagonist-treated animals, it restored the secondary FSH surge to control values while augmenting the late proestrus fall in irI alpha. This suggests that the decrease in inhibin secretion measured after exogenous LH treatment represents the mechanism through which LH induced the secondary FSH surge in antagonist-blocked rats. We also used in situ hybridization techniques to examine the changes in the expression of inhibin subunits in the ovary at 0200 h on estrus. The antagonist reduced expression of the alpha-, beta A-, and beta B-subunits in all follicle and tissue types, with the exception of the granulosa cells of large tertiary (possibly preovulatory) follicles where the signal appeared greatly enhanced. These changes were reversed by LH. The alteration in inhibin subunit messages caused by blockade of the primary gonadotropin surge suggests the presence of a cross-regulation between LH and inhibin/activin secretion, so that a decline in circulating LH levels might stimulate inhibin/activin secretion in the granulosa cells of preovulatory follicles, while reducing the production of these proteins in less mature follicles and in other ovarian cell types.     

Serum gonadotropins and follicular development in the Syrian hamster.

Hamster serum gonadotropins were measured by RIA at 4 h intervals during the estrous cycle. On the afternoon of proestrus both LH and FSH exhibited a surge, but unlike the situation in the rat and mouse FSH returned to "baseline" with LH by early evening of proestrus. Shortly following this return FSH concentrations increased and reached a second peak by noon on estrus which was equal in magnitude and longer in duration than that occurring on proestrus. FSH fell to its lowest levels on diestrus 2 (D2) and early proestrus. Serum gonadotropins were measured by RIA 6 h following unilateral ovariectomy on D2. A slight elevation of LH resulted while FSH increased to a level equal in magnitude to that found during the proestrous surge. In intact females administration of a total of 45 mug FSH in 5 injections on D2 resulted in ovulation of twice the normal number of eggs. The t1/2 of this rat FSH in the male hamster was found to be 122 minutes. The low levels of FSH during the cycle between D2 and proestrus, the large increase in serum FSH following unilateral ovariectomy, and the "doubled" ovulation in intact hamsters following the administration of FSH on D2, suggest that the serum FSH concentration on D2 is critical in determining the number of follicles which will be available for the subsequent ovulation.     

Ovarian steroid modulation of gonadotropin secretion and pituitary responsiveness to luteinizing hormone-releasing hormone in the female hamster.

The significance of ovarian estradiol (E2) and progesterone secretion in the regulation of pituitary LH and FSH secretion and pituitary responses to LHRH was investigated in the hamster. Cycling females showed increased LH and FSH responses to LHRH on the morning of proestrus as compared to the responses observed on diestrus day 2. Pituitary responsiveness to LHRH declined on the evening of proestrus, after the preovulatory LH/FSH release. The secondary increase in serum FSH concentration on the morning of estrus was accompanied by a selective increase in the pituitary FHS response to exogenous LHRH. Hamsters ovariectomized (ovx) on diestrus day 2 exhibited daily afternoon LH surges but not FSH surges for at least 10 days after ovx. The magnitude of the LH surges in ovx hamsters was approximately 30-50% of that observed in proestrous females. The pituitary LH response to exogenous LHRH in ovx animals was about 25% as great as in proestrus hamsters. Serum FSH concentrations in ovx females increased by only 30% after LHRH injection, while similar treatment with LHRH resulted in 3- to 4-fold increments in serum FSH in proestrous hamsters. Implantation of E2 capsules in ovx hamsters resulted in increased gonadotropin responses to exogenous LHRH. Serum LH concentrations in the E2-implanted, LHRH-injected animals were as great as those observed after LHRH injection in proestrous females. Administration of LHRH, LH, or progesterone on the morning of proestrus failed to detectably alter the timing or magnitude of the proestrus afternoon FSH surge. The present results suggest that the increasing serum titers of estrogen on diestrus and early proestrus result in increased pituitary sensitivity to LHRH, and this increased sensitivity probably contributes to the magnitude of the preovulatory LH surge. The increases in LH and progesterone which occur during the afternoon do not seem to be responsible for triggering the proestrous FSH surge.     

Hypothalamic-pituitary interactions during the periovulatory secretion of follicle-stimulating hormone in the rat

We investigated the importance of anterior afferents to the medial basal hypothalamus (MBH) on the increases in plasma FSH during the periovulatory period in the 4-day cyclic rat. We served the anterior connections to the MBH either at 1200 h on proestrus (before the time of onset of the normal spontaneous LH surge in plasma and the associated first phase of FSH release) or near the end of the LH surge and first phase of FSH release at 2000 h on proestrus (before the onset of the second or selective phase of FSH release). Analyses of FSH and LH in blood collected through indwelling atrial catheters or from the trunk after decapitation showed that anterior deafferentation of the MBH at 1200 h on proestrus blocked the proestrous LH surge, the elevations in plasma FSH during proestrus and estrus, and ovulation. In contrast, when brain surgery was delayed until 2000 h on proestrus, the second phase of FSH release and ovulation occurred. In rats with retrochiasmatic transections made at 1200 h, a constant rate iv infusion of LHRH from 1500-1800 h on proestrus restored the LH surge, both phases of increased plasma FSH, and ovulation. The results suggest that 1) the prevolutory LH surge and the first phase of FSH release are dependent on rostral afferents to the MBH which result in hypothalamic LHRH release and 2) the role of rostral afferents to the MBH in the second phase of FSH release is solely to result in hypothalamic LHRH release during proestrus.     

Influence of continuous illumination on estrous cycle of rats: time course of changes in levels of gonadotropins and ovarian steroids until occurrence of persistent estrus

Plasma concentrations of LH, FSH, 17 beta-estradiol, estrone and progesterone were determined chronologically by radioimmunoassays in two groups of adult female rats exposed to continuous illumination (LL). Group 1 rats showing vaginal estrous cycles were sacrificed at 3- to 6-hour intervals during late proestrus through early estrus of the first 5 cycles after exposure to LL. Group 2 animals which displayed persistent vaginal estrus in an early period of exposure to LL were killed on the 2nd, 3rd, 4th, 5th and 7th days of vaginal estrus. In Group 1 rats, surges of the hormones, except estrone, took place in all the 5 cycles. The occurrence of peak hormone levels in each cycle was invariably delayed after transfer of animals to LL. According to regression analyses, the lengths of secretion cycles of LH, FSH, 17 beta-estradiol and progesterone in rats under LL were 100.89, 100.46, 101.14 and 101.06 h, respectively. Elevation of 17 beta-estradiol levels was observed prior to the LH surge, and peaks of progesterone and FSH occurred following it. However, the secretion patterns of these hormones appear to be disrupted with length of exposure to LL. In group 2 rats, the mean concentration of LH during persistent estrus was approximately similar to that on the morning of the days of proestrus of the 4-day cycles of rats placed under an alternating 12-hour light-dark regimen (LD), whereas the mean FSH concentration was continuously low. While the concentrations of 17 beta-estradiol and estrone in persistent-estrous rats were elevated, progesterone levels remained low.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Recruitment and maturation of small subsets of luteinizing hormone gonadotropes during the estrous cycle.

Small and medium-sized gonadotropes may enlarge and produce more LH in order to contribute to the proestrous surge. To test this hypothesis, dispersed pituitary cells from cycling female rats were separated by centrifugal elutriation into small, medium, and large fractions and labeled for LH beta antigens or mRNA (by in situ hybridization with a biotinylated oligonucleotide probe complementary to sequences encoding amino acids 28-40). The percentage of cells bearing LH beta mRNA in the pituitary cell population increased from 6 +/- 0.4% in the evening of diestrous day 2 to 16 +/- 0.7% in the morning of estrus (average +/- SEM). Over 80% of these labeled cells were large or small subtypes. The proportion of small gonadotropes labeled with LH beta mRNA declined from 43 +/- 3% at metestrus to 29 +/- 1% on the evening of proestrus as the proportion of medium-sized gonadotropes labeled for LH beta antigens (15 +/- 1%) or mRNA (17 +/- 1%) increased to 25 +/- 2% or 38 +/- 2%, respectively. Because the overall percentage of immunoreactive LH cells did not change after diestrus, small LH cells may have enlarged or increased their density to join the medium-sized pool. During proestrus, the proportion of large immunoreactive LH gonadotropes increased from 41 +/- 2% to 65 +/- 2% (by the morning of estrus) as the proportion of small or medium-sized LH cells declined to 17-18 +/- 1%, suggesting further increases in size or density. These data suggest that small or medium-sized gonadotropes are activated during early diestrus to enlarge and produce LH beta. They contribute to the increased number of cells in medium-sized and large fractions in proestrous or estrous rats. The predominance of the smaller subtypes during metestrus and diestrus suggests that LH gonadotropes may revert to a smaller or lighter subset to await activation during the next cycle.     

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.     

Cytological factors that support nonparallel secretion of luteinizing hormone and follicle-stimulating hormone during the estrous cycle

Gonadotropes from cycling female rats were studied to investigate possible mechanisms for the nonparallel release of LH and FSH. The percentages of total gonadotropes increased from 14% during estrus (E) to 18% by diestrous day 2. More of these cells became multihormonal on the morning of proestrus (P; from 46% during diestrus to 69%). Since LH-containing cells increased from 7% at E to 13.3% during early proestrus, this suggests that monohormonal FSH cells may have contributed by synthesizing LH. Gonadotrope cell areas were greatest just before the LH surge (P 1600 h). Microdensitometric measurements demonstrated that the amount and density of immunoperoxidase stain for either gonadotropin subunit were highest during the midafternoon of P. Interestingly, the amount of stain for LH continued to increase during the LH surge, suggesting that the stain had detected newly synthesized LH beta. At the same time, the average density of the LH beta stain decreased. In contrast, the amount, concentration, and density of stain for FSH beta increased during the afternoon of P and decreased during late P and early E. The percentages of granules that contained immunogold stains for only LH or FSH (monohormonal granules) at P 1600-P 1700 h were 3-4 times higher than those in diestrous rats. The percentages of monohormonal LH granules declined during the proestrous surge, whereas percentages of monohormonal FSH granules declined during the first rise (P 1900 h) and after the second rise in serum FSH (E 0800 h). Finally, the average number of gold particles per micron 2 granule area rose over the value in diestrous rats during P 1600-P 1700 h. These studies suggest that multihormonal gonadotropes support nonparallel gonadotropin release by changing the rate of subunit packaging and transit in the Golgi complex.     

Evidence that neuronal nitric oxide synthase but not heme oxygenase increases in the hypothalamus on proestrus afternoon

Nitric oxide (NO) has been implicated in the control of the proestrus luteinizing hormone (LH) surge in the rat but to date no studies have attempted to measure neuronal nitric oxide synthase (nNOS) or NO production on proestrus in the hypothalamus in order to determine if endogenous NO is increased on proestrus afternoon to activate gonadotropin-releasing hormone (GnRH) neurons. To address this deficit in our knowledge, we measured nNOS mRNA and protein levels as well as NOS activity levels in rat preoptic area (POA) and medial basal hypothalamus (MBH) fragments at 12.00, 14.00, 16.00, and 18.00 h of proestrus. Serum LH levels were also assessed to determine whether NOS changes correlate to the LH surge. To determine the specificity of observed changes we also measured mRNA levels for the enzyme heme oxygenase-2, which is responsible for production of another putative gaseous transmitter, carbon monoxide. In all studies a metestrus 12.00 h control group was included since steroid and LH levels would be basal at this time as compared to proestrus. The results revealed that nNOS mRNA and protein levels, as well as NOS activity did not change significantly in the MBH on proestrus. In contrast, nNOS mRNA levels were significantly elevated in the POA at proestrus 12.00 and 14.00 h, as compared to metestrus 12.00 h. Likewise, at the protein and activity level, nNOS protein levels in the POA were significantly elevated on proestrus at 14.00 and 16.00 h, with NOS activity significantly increased at 16.00 h on proestrus. The elevation of nNOS protein and activity levels in the POA occurred at the time of initiation of the LH surge. The elevation of nNOS was specific as mRNA levels for the CO-synthetic enzyme heme oxygenase-2 did not change significantly on proestrus in the POA or MBH. As a whole, the current studies provide new evidence that nNOS is elevated in the POA on proestrus, and thus could play a role in the activation of GnRH neurons to produce the preovulatory LH surge.     

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.     

The frequency of gonadotropin-releasing-hormone stimulation differentially regulates gonadotropin subunit messenger ribonucleic acid expression

The hypothalamic decapeptide GnRH is known to regulate the synthesis and secretion of LH and FSH by pituitary gonadotrope cells. The frequency of pulsatile GnRH secretion changes and LH and FSH are differentially secreted in various physiological situations. To investigate the potential role of altered frequency of GnRH stimulation in regulating differential secretion of LH and FSH, we examined the effects of GnRH frequency on expression of the alpha, LH beta, and FSH beta genes. GnRH pulses (25 ng/pulse) were administered to castrate testosterone-replaced rats at intervals of 8-480 min to cover the range of physiological pulsatile GnRH secretion. Fast frequency GnRH pulses (8-min pulse intervals) increased alpha-subunit mRNA concentrations 3-fold above those in saline-pulsed controls (controls, 1.01 fmol cDNA bound/100 micrograms pituitary DNA) and LH beta mRNA by 50% (controls, 0.18 fmol cDNA bound), but FSH beta mRNA was unchanged (controls, 0.38 fmol cDNA bound). GnRH pulses given every 30 min increased all three subunit mRNAs (alpha, 3-fold, LHbeta, 2-fold; FSH beta, 2-fold), and acute LH release and serum FSH concentrations were maximal after this frequency. Slower frequency GnRH stimuli (120- to 480-min pulse intervals) did not change alpha and LH beta mRNA levels, but increased FSH beta mRNA 2- to 2.5-fold, and FSH secretion was maintained. Equalization of the total dose of GnRH given at different intervals over 24 h confirmed the frequency dependence of subunit mRNA expression. Fast frequency GnRH stimuli (8 min) increased alpha mRNA 1.5- to 2.5-fold, while the same total GnRH doses were ineffective when given at slow frequency (480 min). Similarly, LH beta mRNA was only increased by GnRH pulses given at 8-min intervals. In contrast, FSH beta mRNA increased 2-fold after pulses given every 480 min, and the 8-min pulse interval was ineffective. The data show that the frequency of GnRH stimulation can differentially regulate gonadotropin subunit mRNA expression and may be a mechanism that enables a single GnRH peptide to selectively regulate gonadotropin subunit gene expression and hormone secretion.