Proenkephalin and opioid mu-receptor mRNA expression in ovine hypothalamus across the estrous cycle

The neural mechanism underlying the preovulatory surge of gonadotropin-releasing hormone (GnRH) and luteinizing hormone (LH) is thought to include reduced opioid inhibition of GnRH secretion (disinhibition). Possible mechanisms for disinhibition include reduced endogenous opioid peptide or receptor mRNA expression. Proenkephalin and opioid mu-receptor mRNA expression were measured by in situ hybridization using 35S-labeled cRNA probes and computer-assisted grain counting in hypothalamic nuclei of ovary-intact ewes (n = 4) killed on day 10 of the luteal phase or 24 or 48 h into the follicular phase. In a second experiment, proenkephalin and mu-receptor mRNA expression were compared in ewes killed on day 10 of the luteal phase or during the preovulatory LH surge. Cells expressing proenkephalin mRNA were more widely distributed in ovine hypothalamus than previously described. In the periventricular nucleus, there was a significant reduction in the grain count per cell and the number of labeled cells during the follicular phase and during the LH surge, as compared to the luteal phase. In the ventromedial hypothalamus, there was a significant reduction in the grain count per cell during the follicular phase and LH surge as compared to the luteal phase, but no change in the number of labeled cells. No differences in proenkephalin mRNA expression were detected in the medial septum, diagonal band of Broca, preoptic area, anterior hypothalamic area or paraventricular nucleus across the estrous cycle. Cells expressing opioid mu-receptor mRNA were also widely distributed. No difference in mu-receptor mRNA expression was detected in the medial septum, diagonal band, medial preoptic area, anterior hypothalamus or bed nucleus of the stria terminalis across the cycle. We conclude that in sheep, proenkephalin gene expression in the periventricular nucleus and ventromedial hypothalamus is reduced during the follicular phase and at the time of the LH surge. This may be part of the neural mechanism underlying the GnRH/LH surge in this species.     

Effects of immobilization stress on estrogen-induced surges of luteinizing hormone and prolactin in ovariectomized rats

Reproductive function has been known to be impaired by various kinds of physical and emotional stress, but the mechanism by which stress impairs the reproductive axis has not been clearly understood. In the present study, the effects of immobilization stress were studied on the surges of luteinizing hormone (LH) and prolactin (PRL) induced by 17β-estradiol (E₂) in ovariectomized rats. Two weeks after bilateral ovariectomy, animals were implanted with the capsule containing E₂ or vehicle at 1000 h (designated as d 0). Immobilization was started at 1000 h and continued to 2100 h on d 2. Blood samples were collected according to the time schedule by a jugular vein catheter procedure. Immobilization stress inhibited basal release of LH and abolished E₂-induced LH and PRL surges in ovariectomized (OVX) rats. Daily repeated immobilization (from 1200 h to 1800 h, 6 h/d) for 3 d also abolished LH and PRL surges when examined at 1800 h on d 2. Although daily repeated immobilization stress reduced E₂-induced PRL mRNA levels, this stress failed to change LHβ mRNA levels in the anterior pituitary as determined by Northern blot analysis. Gonadotropin-releasing hormone (GnRH) receptor mRNA levels in the anterior pituitary were lowered by immobilization stress in the OVX, E₂-treated group. Dopamine D2 receptor mRNA levels in the anterior pituitary of OVX, E₂-treated rats were significantly decreased at 1800 h, compared with those at 1000 h. However, immobilization prevented a decrease in dopamine D2 receptor mRNA levels at 1800 h. GnRH content was increased in the mediobasal hypothalamus by immobilization in the OVX, E₂-treated group, suggesting that GnRH release was inhibited. Interestingly, GnRH mRNA levels in the preoptic area-anterior hypothalamic area were suppressed by immobilization stress in OVX, E₂-treated rats when determined at 1800 h. Therefore, we concluded that immobilization stress blocks E₂-induced LH surge possibly by inhibiting synthesis and release of GnRH at the hypothalamic level, and an increase of dopaminergic activity via D2 receptor at the pituitary level might be involved in the stress blockage of E₂-induced PRL surge.     

Kisspeptin is essential for the full preovulatory LH surge and stimulates GnRH release from the isolated ovine median eminence

Kisspeptins are the product of the Kiss1 gene and potently stimulate GnRH secretion. In sheep, Kiss1 mRNA-expressing cells are found in the arcuate nucleus (ARC) and dorsal-lateral preoptic area and both appear to mediate the positive feedback effect of estradiol to generate the preovulatory GnRH/LH surge. To determine the role of kisspeptin in transmitting estrogen-positive feedback in the hypothalamus, we administered the kisspeptin antagonist p-271 to ewes subjected to an estradiol benzoate-induced LH surge. Kisspeptin antagonist treatment significantly attenuated these LH surges. We further examined the response to kisspeptin treatment prior to the LH surge. Kisspeptin significantly stimulated GnRH secretion into the hypophysial portal system, but the response to kisspeptin was similar in luteal and late-follicular phase ewes. Kiss1r mRNA expression in GnRH neurons was also similar across the estrous cycle. To examine alternative pathways for kisspeptin stimulation of GnRH neurons, we examined the origin of kisspeptin neuronal fibers in the external zone of the median eminence (ME) using neuronal tracing and immunohistochemical techniques. ARC populations of kisspeptin neurons project fibers to the ME. Finally, we showed kisspeptin stimulates GnRH release from ovine ME-cultured explants. This suggests direct kisspeptin to GnRH terminal-to-terminal communication within the ME. Overall, these data indicate an essential role for kisspeptin in receiving stimulatory estrogen signals and generating the full positive feedback GnRH/LH surge. Kisspeptin neurons of the ARC project to the external zone of the ME and kisspeptin acts upon the GnRH fibers at this level.     

The central effect of beta-endorphin and naloxone on the expression of GnRH Gene and GnRH receptor (GnRH-R) gene in the hypothalamus, and on GnRH-R gene in the anterior pituitary gland in follicular phase ewes.

The effect of prolonged intermittent infusion of beta-endorphin or naloxone into the third cerebral ventricle in ewes during the follicular phase of the estrous cycle on the expression of GnRH gene and GnRH-R gene in the hypothalamus and GnRH-R gene in the anterior pituitary gland was examined by Real time-PCR. Activation of micro opioid receptors decreased GnRH mRNA levels in the hypothalamus and led to complex changes in GnRH-R mRNA: an increase of GnRH-R mRNA in the preoptic area, no change in the anterior hypothalamus and decrease in the ventromedial hypothalamus and stalk/median eminence. In beta-endorphin treated ewes the levels of GnRH-R mRNA in the anterior pituitary gland also decreased significantly. These complex changes in the levels of GnRH mRNA and GnRH-R mRNA were reflected in the decrease of LH secretion. Blockade of micro opioid receptors affected neither GnRH mRNA and GnRH-R mRNA nor LH levels secretion. These results indicate that beta-endorphin displays a suppressive effect on the expression of the GnRH gene in the hypothalamus and GnRH-R gene in the anterior pituitary gland, but affects GnRH-R gene expression in a specific manner in the various parts of hypothalamus; altogether these events lead to the decrease in GnRH/LH secretion.     

Implication of dopaminergic systems on GnRH and GnRHR genes expression in the hypothalamus and GnRH-R gene expression in the anterior pituitary gland of anestrous ewes.

We examined by Real-time PCR how prolonged inhibition of dopaminergic D-2 receptors (DA-2) in the hypothalamus of anestrous ewes by infusion of sulpiride into the third cerebral ventricle affected GnRH and GnRH-R gene expression in discrete parts of this structure and GnRH-R gene expression in the anterior pituitary. Blockaded DA-2 receptors significantly decreased GnRH mRNA levels in the ventromedial hypothalamus but did not evidently affect GnRH mRNA in the preoptic/ anteriorhypothalamicarea. Blockaded DA-2 receptors led to different responses in GnRH-R mRNA in various parts of the hypothalamus; increased GnRH-R mRNA levels in the preoptic/anterior hypothalamic area, and decreased GnRH-R mRNA amounts in the ventromedial hypothalamus stalk/median eminence. An infusion of sulpiride into the III-rd ventricle increased GnRH mRNA levels in the anterior pituitary gland and LH secretion. It is suggested that the increase of GnRH gene expression in the anterior pituitary gland and LH secretion in sulpiride-treated ewes are related with an increase of biosynthesis GnRH with concomitant decreased biosynthesis of GnRH-R protein in the ventromedial hypothalamus/stalk median eminence allowing to an increase of GnRH release.     

A daily neural signal for luteinizing hormone release in the untreated ovariectomized rat: changes in gonadotropin-releasing hormone content of the preoptic area and hypothalamus throughout the day.

Gonadotropin-releasing hormone (GnRH) content of preoptic areas (POA) and hypothalami, and serum gonadotropins of rats ovariectomized six weeks earlier were measured throughout the day in two experiments. In the first, rats were decapitated at 2 h intervals between 0800 and 1800 h. The entire preoptic-hypothalamic region was removed and extracted for radioimmunoassay (RIA) of GnRH. Serum gonadotropins measured by RIA were highly variable but mean concentrations were not significantly different throughout the day. However, preoptic hypothalamic content of GnRH declined markedly between 1000 and 1200 h. In the second experiment, 75 rats were divided into three groups and were untreated or were implanted sc with empty Silastic capsules or capsules containing estradiol-17beta (E2). Two days later, groups of five rats from each of the three treatment groups were decapitated at 0800, 1100, 1400, 1700 and 2000 h. The preoptic area was separated from the hypothalamus by a transverse cut at the caudal aspect of the optic chiasm. POA and hypothalamic content of GnRH correlated well (r=0.74, P less than 0.001, n=75). Two-way analysis of variance failed to reveal any effect of treatment on the GnRH content in either the POA or hypothalamus. GnRH content of both regions decreased significantly between 1100 and 1700h regardless of whether E2 was administered. In striking contrast, gonadotropin surges occurred in the late afternoon only in the E2-treated rats. Serum GnRH was undetectable (less than 5 pg/ml) in all groups of animals. These experiments demonstrate that in the untreated ovariectomized rat GnRH content of the POA and hypothalamus decreases during the early afternoon. This study supports the concent of a daily neural signal for LH release and that E2 is necessary for expression of the daily LH surge in the ovariectomized rat.     

Differential gonadotropin-releasing hormone (GnRH) and GnRH receptor messenger ribonucleic acid expression patterns in different tissues of the female rat across the estrous cycle

GnRH, the main regulator of reproduction, is produced in a variety of tissues outside of the hypothalamus, its main site of synthesis and release. We aimed to determine whether GnRH produced in the female rat pituitary and ovaries is involved in the processes leading to ovulation. We studied the expression patterns of GnRH and GnRH receptor (GnRH-R) in the same animals throughout the estrous cycle using real-time PCR. Hypothalamic levels of GnRH mRNA were highest at 1700 h on proestrus, preceding the preovulatory LH surge. No significant changes in the level of hypothalamic GnRH-R mRNA were detected, although fluctuations during the day of proestrus are evident. High pituitary GnRH mRNA was detected during the day of estrus, in the morning of diestrus 1, and at noon on proestrus. Pituitary GnRH-R displayed a similar pattern of expression, except on estrus, when its mRNA levels declined. Ovarian GnRH mRNA levels increased in the morning of diestrus 1 and early afternoon of proestrus. Here, too, GnRH-R displayed a somewhat similar pattern of expression to that of its ligand. To the best of our knowledge, this is the first demonstration of a GnRH expression pattern in the pituitary and ovary of any species. The different timings of the GnRH peaks in the three tissues imply differential tissue-specific regulation. We believe that the GnRH produced in the anterior pituitary and ovary could play a physiological role in the preparation of these organs for the midcycle gonadotropin surge and ovulation, respectively, possibly via local GnRH-gonadotropin axes.     

Neurotensin gene expression increases during proestrus in the rostral medial preoptic nucleus: potential for direct communication with gonadotropin-releasing hormone neurons.

Neurotensin (NT)-containing neurons in the rostral portion of the medial preoptic nucleus (rMPN) of the brain may play a key role in regulating the pattern of secretion of GnRH, thereby influencing the reproductive cycle in females. The major goals of this study were to determine whether NT messenger RNA (mRNA) levels in the rMPN exhibit a unique pattern of expression in temporal association with the preovulatory LH surge and to assess whether NT neurons may communicate directly with GnRH neurons. We analyzed NT gene expression in rats using in situ hybridization over the day of proestrus and compared this with diestrous day 1. We also determined whether the high-affinity NT receptor (NT1) is expressed in GnRH neurons using dual-label in situ hybridization and whether this expression varies over the estrous cycle. We found that NT mRNA levels in the rMPN increase significantly on the day of proestrus, rising before the LH surge. No such change was detected on diestrous day 1, when the LH surge does not occur. Furthermore, we observed that a significant number of GnRH neurons coexpress NT1 mRNA and that the number of GnRH neurons expressing NT1 mRNA peaks on proestrus. Together with previous findings, our results suggest that increased expression of NT in the rMPN may directly stimulate GnRH neurons on proestrus, contributing to the LH surge. In addition, our results suggest that responsiveness of GnRH neurons to NT stimulation is enhanced on proestrus due to increased expression of NT receptors within GnRH neurons.     

Role of the progesterone receptor in restrained glutamic acid decarboxylase gene expression in the hypothalamus during the preovulatory luteinizing hormone surge

Previous work by our laboratory demonstrated that activation of the progesterone receptor through exogenous administration of progesterone suppressed glutamic acid decarboxylase-67 (GAD(67)) mRNA in the hypothalamus of the estrogen-primed ovariectomized rat. Since GAD(67) is the major synthetic enzyme for the inhibitory transmitter, gamma-aminobutyric acid, the finding raised the possibility that the endogenous activation of the progesterone receptor may act to restrain GAD(67) expression during the natural preovulatory gonadotropin surge during proestrus in the rat, thereby allowing GnRH secretion and the resultant LH surge. To test this hypothesis, the progesterone receptor antagonist, RU486, was administered to regularly cycling proestrous rats and the effect on GAD(67) and GAD(65) mRNA levels in the preoptic area (POA) and medial basal hypothalamus (MBH) was examined. Serum luteinizing hormone (LH) levels were also examined in order to identify correlations between changes in POA and MBH GAD levels and production of the LH surge. GAD(67) mRNA levels in the POA were increased in the cycling rat during proestrus at 18.00 h at the peak and just preceding the termination of the LH surge. There was no change in GAD(67) mRNA levels in the MBH, and GAD(65) expression was also unchanged during proestrus in the POA and MBH. Treatment with the antiprogestin RU486 resulted in an increase in GAD(67) mRNA levels at 12.00 and 14.00 h in the POA, and in the MBH at 14.00, 16.00, and 18.00 h during proestrus, effects which preceded and correlated with the attenuated LH surge in RU486-treated rats at 18.00 h. GAD(65) mRNA levels were also elevated by RU486 at 14.00 and 16.00 h in the POA, and at 14.00 h in the MBH during proestrus. These findings suggest that the progesterone receptor plays a role in restraining GAD expression in the hypothalamus during proestrus, and that this effect may be important for the production of the GnRH and LH surge.     

Neuropeptide Y gene expression in the arcuate nucleus is increased during preovulatory luteinizing hormone surges.

Recent studies have suggested that neuropeptide Y (NPY) plays an important role in the induction of the preovulatory LH surge. The present study was performed in order to determine if a change in NPY gene expression within arcuate nucleus NPY neurons is associated with the generation of the preovulatory LH surge. In Exp 1, in situ hybridization was used to measure NPY messenger RNA (mRNA) levels in the arcuate nucleus of female rats at 0900 h and every 2 h from 1400-2200 h on the day of proestrus (PRO). Comparisons between groups showed a clear, stepwise increase in NPY gene expression throughout the day of PRO. At 1600 h, when LH values were significantly greater than 0900 h values, NPY mRNA labeling intensities in the arcuate nucleus were significantly greater than 0900 h levels (P < 0.01). By 1800 h, the time at which the LH surge peaked, NPY mRNA levels also peaked and were nearly 3-fold greater than levels observed at 0900 h (P < 0.01). NPY mRNA levels at 2000 h and 2200 h remained elevated above 0900 h levels (P < 0.01) but by 2000 h had decreased significantly from 1800 h levels (P < 0.05). In Exp 2, NPY mRNA levels were measured once again at 0900 h and 1800 h on PRO, and then at 0900 h and 1800 h on metestrus (MET), in order to determine if the change in gene expression seen in Exp 1 was unique to the day of PRO, or if it simply reflected a daily rhythm of gene expression in the nucleus. Analysis of mRNA levels showed no difference in NPY mRNA levels between 0900-1800 h on MET. Also, NPY mRNA levels at 0900 h and 1800 h on MET were significantly less than levels at 1800 h on PRO (P < 0.01). These results are consistent with the hypothesis that NPY neurons participate in the generation of LH surges through increased production of NPY and subsequent potentiation of the release and/or actions of LHRH.     

Pituitary content of gonadotropins and receptors for gonadotropin-releasing hormone (GnRH) and hypothalamic content of GnRH during the periovulatory period of the ewe

Studies were undertaken to determine if the number of hypophyseal receptors for GnRH changes at the time of the preovulatory surge of LH in ewes. Concentrations of LH, FSH, progesterone, and estradiol in serum and concentrations of LH and FSH in pituitary were measured. The content of GnRH in the hypothalamus was also determined. Estrus was synchronized in 35 cross-bred ewes by injecting prostaglandin F2 alpha (PGF2 alpha) at 0 and 4 h (7.5 mg each, im) on day 14 of a naturally occurring estrous cycle, followed 30 h later by the injection of estradiol (25 micrograms in safflower oil, im). Five ewes were killed at each of the following times relative to the first injection of PGF2 alpha: 0, 24, 32, 44, 50, 56 and 96 h. Blood samples were collected throughout the course of the experiment. Concentrations of progesterone in serum decreased markedly by 8 h after PGF2 alpha and were uniformly undetectable (less than 300 pg/ml) by 34 h. Concentrations of estradiol in serum increased after the injection of estradiol and returned to basal values 10 h later. Surges of LH, which were usually coincident with surges of FSH, occurred between 43 and 53 h. Concentrations of both LH and FSH in the pituitary declined after the LH surge. There were no significant changes in the amount of GnRH contained in the preoptic area, the median eminence, or the hypothalamus. The number of receptors for GnRH increased at 24 and 32 h compared to the 0 h value and remained elevated at 44 and 50 h. After the LH surge (56 h), the number of GnRH receptors declined and at 96 h was not different from the number measured at 0 h. Since an increase in the number of receptors will result in the formation of more receptor-hormone complex and may lead to an augmented response, these data suggest that an increase in the number of hypophyseal receptors for GnRH may contribute to the preovulatory LH surge in ewes.     

Galanin's functional significance in the regulation of the neuroendocrine reproductive axis of the monkey

Galanin stimulates the neuroendocrine reproductive axis in the rat, but whether galanin acts similarly in primate species is unknown. To test the hypothesis that galanin acts within the hypothalamo-hypophyseal axis to stimulate luteinizing hormone (LH) and gonadotropin-releasing hormone (GnRH) secretion in the primate, galanin was administered either systemically or directly into the arcuate nucleus-median eminence of ovariectomized macaques (pigtailed or rhesus, respectively) that were maintained on estradiol. The mean plasma levels of LH were significantly elevated in pigtailed macaques after peripheral injection of galanin (2 mg) as compared with vehicle treatment. In rhesus monkeys, galanin (80 microM) administered by push-pull perfusion into the arcuate nucleus-median eminence did not significantly alter either GnRH or LH release. To determine whether in the monkey, as in the rat, subpopulations of medial forebrain GnRH neurons coexpress galanin mRNA, we used single- and double-label in situ hybridization and computerized imaging techniques. GnRH mRNA-containing cells were identified in both the medial and lateral forebrain of the female pigtailed macaque. No galanin mRNA expression was detectable in GnRH neurons located in either the medial preoptic area or mediobasal hypothalamus; however, within the substantia innominata a subset of GnRH mRNA-expressing neurons did coexpress galanin mRNA. Taken together, these results suggest that galanin induces LH release in primates, but galanin may not act directly on hypothalamic GnRH neurons. Presently, we have confirmed in another primate species the existence of GnRH gene expression in the lateral forebrain and discovered that a small subset of these neurons coexpress galanin. These particular cells may have a unique and as of yet undefined physiological function that is distinct from those GnRH neurons serving a hypophysiotropic function.     

Evidence for the dependence of serum luteinizing hormone surge on a transient, enhanced secretion of gonadotropin-releasing hormone from the hypothalamus.

Data that a substantial, transient release of gonadotropin-releasing hormone (GnRH) from the hypothalamus is a prerequisite for the serum luteinizing hormone (LH) surge are presented. Ovariectomized rats, in which daily afternoon LH peaks can be induced by estradiol benzoate (EB), were used as the experimental model. These rats present a homogenous, synchronized population having low hypothalamic stores of GnRH, thus facilitating detection of small physiological fluctuations in the levels of hypothalamic GnRH. Blockade, by Nembutal administration, of the serum LH surge on 2 consecutive afternoons results in elevated GnRH levels in the hypothalamus (1.79 ng in blocked rats vs 0.94 ng in controls). Abolition of LH secretion by administration of antiserum to GnRH, unlike the Nembutal blockade, does not affect GnRH levels. These results indicate that the afternoon LH surge is dependent on a transitory, enhanced release of GnRH from the hypothalamus, reflected by a depletion of GnRH stores.     

Changes in hypothalamic gene expression associated with the arrest of pulsatile gonadotropin-releasing hormone release during infancy in the agonadal male rhesus monkey (Macaca mulatta)

This study examined whether changes in the levels of the messenger RNAs (mRNAs) encoding the gamma-aminobutyric acid (GABA) synthesizing enzymes, glutamate decarboxylase (GAD)65 and GAD67 and transforming growth factor-alpha (TGFalpha) in the hypothalamus are correlated with the arrest of pulsatile GnRH release during infancy in the agonadal male monkey. This experiment also provided the opportunity to examine changes in hypothalamic GnRH gene expression during this critical phase of primate development. Male rhesus monkeys were castrated at 1 week of age: four were killed 4-7 weeks after orchidectomy while pulsatile GnRH release was robust as reflected by high circulating LH levels, and four were killed at 12-15 months of age after establishing that pulsatile GnRH release had been arrested. GAD65, GAD67, TGFalpha, and GnRH mRNA levels were estimated using RNase protection assays employing homologous probes and the results were expressed relative to cyclophilin mRNA levels. GnRH peptide was measured by RIA. GAD65 and GAD67 mRNA levels in the hypothalamus of juveniles were significantly greater than those in neonatal monkeys. On the other hand, hypothalamic TGFalpha and GnRH mRNA (and peptide) levels in agonadal neonate and juvenile monkeys were indistinguishable. These results indicate that the molecular concomitants associated with bringing the hypothalamic GnRH pulse generator into check in agonadal neonatal males are not a mirror image of those previously reported at the time this neuronal network is reactivated at puberty when TGFalpha and GnRH gene expression increase and GAD65 and GAD67 mRNA levels remain unchanged. Thus, the neurobiological mechanism that reactivates pulsatile GnRH release at puberty is likely to involve more than a simple reversal of that underlying inhibition of the same network in late infancy.     

Effects of age on GABA turnover rates in specific hypothalamic areas in female rats.

During aging in female rats the estrous cycle ceases and the animals develop phases of constant estrous (CE) or constant diestrous (CD) prior to the irreversible transition into anestrous. In young rats, gamma-aminobutyric acid (GABA) is of pivotal importance for the release of GnRH. In the medial-preoptic area (MPO) where the majority of the GnRH perikarya are located in the rat, GABA release decreases at the time of the preovulatory LH surge. The suprachiasmatic nucleus (SCN) contains numerous GABA neurons. Neurochemical signals from this hypothalamic nucleus provide temporal information to GnRH neurons and thereby influence the preovulatory LH surge and the length of estrous cycles. To investigate aging-related changes of the activity of hypothalamic GABAergic neurons, we determined GABA turnover rates in various hypothalamic nuclei of CE and CD rats and compared them to those determined in young estrous (E) or diestrous rats (D1). In old female rats, GABA activity in the MPO was significantly decreased compared to E and D1 rats. A selective increase of GABA turnover rates was observed in the SCN of CE animals. No age-related changes were observed in the other examined brain areas. These data provide the first evidence for alterations in GABAergic activity in specific hypothalamic areas that depend on age and reproductive status. These may cause changes in ability to induce preovulatory LH surges and to maintain regular estrous cyclicity.     

Changes in oxytocin receptor in bovine preovulatory follicles between the gonadotropin surge and ovulation

In cattle, production of oxytocin by granulosa cells of preovulatory follicles is induced by the LH/FSH surge and intrafollicular oxytocin increases dramatically toward the end of the interval between the surge and ovulation. We reported previously that oxytocin modulates steroid production by both theca and granulosa cells obtained from bovine preovulatory follicles, implying actions of oxytocin on both cell types of preovulatory follicles. The objective of the present study was to examine the temporal expression of oxytocin receptor mRNA and protein in both theca and granulosa cells of bovine periovulatory follicles. To induce luteal regression and initiate a follicular phase, heifers were injected with prostaglandin F₂ on Day 6 or 7 of the estrous cycle and 36 h later, a GnRH analogue was administered to induce the LH/FSH surge. The periovulatory follicle was isolated at 0, 3.5, 12, or 24 h after GnRH injection. A significant increase in the levels of mRNA for oxytocin was detected in granulosa, but not theca, cells of periovulatory follicles at 12 and 24 h after GnRH injection, relative to time 0. In contrast, the levels of oxytocin receptor mRNA and specific binding sites for oxytocin in granulosa cells had decreased significantly at 12 and 24 h post-GnRH. In theca cells, the levels of oxytocin receptor mRNA were significantly lower at 12 and 24 h compared with values at 3.5 h, but specific binding of oxytocin to thecal cell membranes was not different at any time point. Immunopositive staining for oxytocin receptor was localized to both the theca and granulosa cell layer of periovulatory follicles at all four times of follicle isolation. These results suggest the direct action of oxytocin on both theca and granulosa cells of bovine periovulatory follicles through binding to its receptor, supporting the hypothesis that follicular oxytocin plays an important role(s) in the regulation of the final stage of follicular development. Down-regulation of oxytocin receptor mRNA and oxytocin binding may serve to temporally limit the actions of oxytocin on the preovulatory follicle.     

An opioid-neuropeptide-Y transmission line to luteinizing hormone (LH)-releasing hormone neurons: a role in the induction of LH surge

We tested the hypothesis that a decrease in hypothalamic inhibitory opioid tone produced by naloxone (NAL) will activate neuropeptide-Y (NPY) neurosecretion in 17 beta-estradiol (E2)-primed ovariectomized (ovx) rats. NPY neurosecretion was assessed in two ways. First, we studied the effects of iv saline (controls) or NAL infusion (2 mg/h) between 1100-1400 h on NPY concentrations in seven microdissected sites in the medial basal hypothalamus (MBH) and preoptic area in association with the increase in the rate of LH secretion, and then we examined the effects of NAL on the in vitro release of NPY and LHRH from the MBH of E2-primed ovx rats. We observed that in control rats, NPY concentrations in selected hypothalmic sites (median eminence, medial preoptic area, and arcuate nucleus) increased either just before LH rise at 1400 h or in association with the moderate LH surge in the afternoon. NAL infusion advanced the onset and amplified the magnitude of LH surge in the afternoon. In association with this augmentation of LH response, NAL infusion significantly increased NPY concentrations selectively in the median eminence, medial preoptic area, and arcuate nucleus. During NAL infusion at 1300 h and at the end of infusion at 1400 h, NPY concentrations in these sites increased compared to preinfusion levels at 1100 h and corresponding control levels at 1300 h. During the post-NAL infusion period until 1800 h, NPY levels remained elevated in these sites, but were not significantly different from those in control rats, which also displayed increments at this time. Further, NAL increased the in vitro efflux of both NPY and LHRH from the MBH; the increased release of two neuropeptides was dose related between 0.01-0.5 mg/ml, with the maximal increase occurring at 1.0 mg/ml NAL. Cumulatively, these studies show that 1) in association with the spontaneous LH surge in E2-primed rats, NPY concentration increased only in sites confined to the preoptic-tuberal pathway, which previously has been shown to mediate the induction of the LH surge; and 2) a decrease in the inhibitory opioid tone imposed by NAL readily augmented the hypothalamic NPY neurosecretion concomitant with an increase in duration and magnitude of the LH surge. These findings are in accord with the thesis that a decrease in the inhibitory opioid tone by the neural clock, postulated to occur before the LH surge, initiates a chain of neurosecretory events that may include a site-specific activation of NPYergic neurons.(ABSTRACT TRUNCATED AT 400 WORDS)     

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.