Reproduction in the Mexican Leaf Frog,Pachymedusa dacnicolor: VI. Presence and Distribution of Multiple GnRH Forms in the Brain

The presence and distribution of gonadotropin-releasing hormone (GnRH) has been investigated in the Mexican leaf frog,Pachymedusa dacnicolor,brain during development and in the adult. The ontogenetic pattern of GnRH neurons illustrates their extracranial as well as intracranial sites. Immunohistochemical analysis indicates that GnRH-immunoreactive neurons appear during the metamorphic climax. They are located in the mesencephalon and subsequently other GnRH neurons appear in the peripheral terminal nerve and anterior preoptic area of the brain. Use of specific antisera and homologous combined with heterologous preabsorption tests indicate that mammalian and chicken GnRH-II-like peptide-containing neurons are differentially located within the brain, the former in the anterior preoptic area and peripheral terminal nerve and the latter in the mesencephalon. HPLC and RIA data suggest the presence of three forms of immunoreactive GnRH in theP. dacnicolorbrain. A mammalian GnRH-like molecule and a chicken GnRH-II-like molecule are present. A third form, suspected to be [hydroxyproline⁹]mGnRH elutes before the mammalian GnRH.     

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.     

Immunohistochemical demonstration of the presence and localization of diverse molecular forms of gonadotropin-releasing hormone in the lizard (Podarcis s. sicula) brain.

The immunohistochemical presence and the distribution pattern of four different molecular forms of gonadotropin-releasing hormone (GnRH) were investigated in the brain of both sexes of the lizard, Podarcis s. sicula. Animals used in this study were collected in November and April, representing two different periods of the reproductive cycle. The antisera used were those raised against synthetic mammalian GnRH, chicken GnRH-I and II, and salmon GnRH. Strong immunoreaction was obtained for salmon, chicken-I, and chicken-II GnRHs, whereas a very weak reaction was seen for the mammalian form of GnRH. The distribution of immunoreactive-GnRH perikarya and fibers did not vary with the sex, the reproductive condition of the animals, or the antiserum used. Also, the intensity of immunoreaction with any one antiserum was quite similar in both periods of the year and in all brains examined. The immunoreactive perikarya was seen as two distinct groups, one in the mesencephalon and the other in the infundibulum. Immunoreactive fiber endings were seen in the telencephalon, the optic tectum, the anterior preoptic area, the median eminence, the central grey matter, the rhombencephalon, and the cerebellum. No immunoreactive perikarya were seen in the telencephalon or the anterior preoptic area.     

Reproduction in the Mexican leaf frog, Pachymedusa dacnicolor. V. Immunohistochemical localization of gonadotropin-releasing hormone in the brain.

The presence and distribution of immunoreactive gonadotropin-releasing hormone (GnRH) in brains of adult male and female Pachymedusa dacnicolor has been studied immunohistochemically using antisera against mammalian, chicken-II, and salmon GnRHs. The distribution map of the immunoreactive-GnRH elements in the brain of P. dacnicolor is extremely simple, being limited to the anterior preoptic area-infundibulum-median eminence circuit. No sex- or reproductive status-related difference in either the distribution pattern or intensity of immunoreaction was revealed in this study. This is also the first immunohistochemical evidence of the presence of different structural forms of GnRH in the brain of an amphibian.     

Quantitative distribution of nuclear androgen receptors in microdissected areas of the rat brain

The binding of androgens to specific high-affinity receptor sites in brain tissue is postulated as an initial event in the mechanism of central androgenic action. In an effort to assess the functional capacity of the androgen receptor system in the central nervous system, we measured the concentration of nuclear (ARn) as well as cytosolic androgen receptors (ARc) in 13 microdissected brain samples from intact male and female Sprague-Dawley rats. Tissues from 6 rats were combined for each determination and androgen receptor contents were measured with single-point in vitro assays that used saturating concentrations of high specific activity 3[H]dihydrotestosterone. We found that ARc levels tended to be higher in females than males although the general patterns of distribution were very similar. As expected, ARn concentrations were significantly higher in males than females. The highest concentrations of ARn (greater than 100 fmol/mg DNA) in males were measured in the ventromedial nucleus of the hypothalamus and medial amygdala; intermediate levels (50-100 fmol/mg DNA) were found in arcuate nucleus-median eminence, medial preoptic nucleus, periventricular preoptic area, bed nucleus of the stria terminalis, anterior hypothalamus, periventricular anterior hypothalamus, lateral septum, and parietal cortex, and low levels (less than 50 fmol/mg DNA) were measured in lateral preoptic nucleus and cortical amygdala. With the exception of the periventricular preoptic area (74 +/- 33 fmol/mg DNA), only very low concentrations of ARn were measured in females. These data provide the first quantitative profile of ARn in discrete brain nuclei and subregions of the rat.     

Unmasking the progesterone receptor in the preoptic area and hypothalamus of the ewe: no colocalization with gonadotropin-releasing neurons

Progesterone powerfully inhibits GnRH secretion in ewes, as in other species, but the neural mechanisms underlying this effect remain poorly understood. Visualization of the neural ovine progesterone receptor has proved elusive but, using a high temperature antigen unmasking technique, the progesterone receptor was revealed in the ewe brain. Progesterone receptors were located in the preoptic-hypothalamic continuum, especially in the preoptic area, ventrolateral region of the ventromedial nucleus and the arcuate nucleus. This study also suggests that the inhibitory action of progesterone on GnRH release is not transduced directly through the GnRH neurons as a single GnRH perikaryon of 732 was immunoreactive for the progesterone receptor.     

Development and differentiation of gonadotropin hormone-releasing hormone neuronal systems and testes in the Japanese eel (Anguilla japonica).

In this study we investigated the relationship between the development of the olfactory, preoptic, and midbrain gonadotropin-releasing hormone (GnRH) neuronal systems and testicular differentiation in eels (Anguilla japonica) from embryonic stages through adulthood (5.4-50 cm body length). GnRH-synthesizing neuronal populations were first observed in the youngest fish ( approximately 5.0 cm) at the rostrobasal and caudalmost olfactory bulbs immunoreactive to a "promiscuous" (nonspecific) GnRH antiserum (635.5), and in the preoptic area and midbrain tegmentum immunoreactive to chicken GnRH II antiserum. The eel brains lacked salmon and seabream GnRH immunoreactivity. The evidence from our study suggests that the olfactory, preoptic, and midbrain GnRH populations have origins independent from those of proliferative periventricular zones within the brain. However, the olfactory GnRH neurons could have migrated out of the olfactory placodes during ages earlier than those observed in this study. Although all three GnRH neuronal populations contribute to pituitary innervation to some degree, the preoptic GnRH innervation was pronounced in the pituitary when primordial germ cells (animals approximately 5.0 cm) differentiated into male germ cells (animals 14-16 cm) and, therefore, an association can be assumed between preoptic GnRH expression and testicular differentiation in the Japanese eel.     

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.     

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.     

Estrogen induces neurotensin/neuromedin N messenger ribonucleic acid in a preoptic nucleus essential for the preovulatory surge of luteinizing hormone in the rat

Ovarian steroids act on unidentified neurons to trigger preovulatory secretion of GnRH. In the rat, important steroid target cells reside in the anterior medial preoptic nucleus (AMPN), a sexually dimorphic structure essential for stimulatory effects of ovarian steroids on LH secretion. The AMPN contains neurotensin (NT)-immunoreactive neurons, and immunoneutralization of NT in the preoptic region markedly attenuates steroid-induced LH surges. Using probes derived from the rat gene that encodes NT and neuromedin N (NT/N), we investigated the ability of estrogen to influence NT/N mRNA levels in the AMPN. Ovariectomized rats were treated for 14 days with sham capsules or capsules that produce supraphysiological serum levels of 17 beta-estradiol (250 +/- 20 pg/ml). As determined by in situ hybridization, estradiol markedly altered the distribution of NT/N mRNA in the medial preoptic region, causing a striking increase in NT/N mRNA abundance specifically in the AMPN and adjacent medial preoptic nucleus (MPN). In contrast, estradiol caused no obvious changes in labeling in the lateral septum, diagonal band of Broca, bed nucleus of the stria terminalis, and lateral preoptic area. The distribution of NT/N mRNA in the AMPN of normal male rats closely resembled that in ovariectomized rats, where labeled cells were rarely observed. Microdissection and S1 nuclease protection analysis were used to quantitate the effect of estradiol on NT/N mRNA levels. Supraphysiological estradiol treatment for 14 days caused a 3.4-fold increase (P less than 0.0002) in NT/N mRNA levels in the combined AMPN/MPN, whereas levels in the central amygdaloid nucleus remained constant, providing further evidence of regional specificity. Forty-eight hours of estradiol treatment, at concentrations (60 +/- 1 pg/ml) similar to those observed on the morning of proestrus, caused a 1.8-fold increase (P less than 0.001) in NT/N mRNA levels in the AMPN/MPN, indicating that the time course of NT/N mRNA induction by estrogen is compatible with events of the normal estrous cycle. Together with previous findings, our results strongly suggest that NT neurons mediate, directly or indirectly, stimulatory effects of ovarian steroids on GnRH secretion.     

Sex differences in androgen receptors and aromatase activity in microdissected regions of the rat brain

Males are generally more responsive than females to the behavioral and neuroendocrine actions of androgens. The present experiments were performed to determine whether these differences may result from sex differences in the number of androgen receptors (AR) in specific brain areas. For this reason, AR binding was compared in both cytosol (ARc) and cell nuclear KCl extracts (ARn) from microdissected brain regions of gonadectomized male and female rats treated with doses of testosterone (T) that produced equivalent physiological circulating androgen levels. In addition, microsomal aromatase activity was measured as a biochemical index of tissue responsiveness to T, since estrogen formation in certain brain areas is regulated by androgen. One week after exogenous T administration, males exhibited significantly higher levels of ARn than females in the bed nucleus of the stria terminalis, periventricular preoptic area, and ventromedial nucleus. Males also had significantly higher aromatase levels in these same areas plus the medial preoptic nucleus and anterior hypothalamus. There were no significant differences in ARn concentrations in eight other nuclei that were examined for significant sex differences in ARc levels observed under these experimental conditions. When ARc levels were compared in untreated gonadectomized male and female rats, males had greater levels of ARc in the bed nucleus of the stria terminalis only, indicating that new receptor synthesis may be responsible for the sex differences observed in T-treated rats. These results suggest that sex differences in neural responsiveness to androgens may be due in part to sex differences in ARn occupation in specific brain regions.     

Pro-gonadotropin-releasing hormone (ProGnRH) and GnRH content in the preoptic area and the basal hypothalamus of anterior medial preoptic nucleus/suprachiasmatic nucleus-lesioned persistent estrous rats

The content of GnRH and its precursor peptide were quantified in female rats bearing lesions in the anterior medial preoptic nucleus (AMPO) and the suprachiasmatic nucleus (SCN), and the effects of the lesions on the synthetic activity of the GnRH neurons were evaluated. Electrolytic lesions which induced persistent estrous (PE), or irregular estrous cycles, were produced by passing 5-10 microA of direct current into the AMPO or the SCN of female rats which exhibited regular 4 days estrous cycles before the lesions. Approximately 5 weeks after lesion placement, blood samples were withdrawn from catheterized, freely moving animals and plasma LH, PRL, estrogen, and progesterone were determined by RIA. The preovulatory surges of LH and PRL were eliminated in AMPO- or SCN-lesioned PE rats. Moreover, the LH surge was eliminated and the PRL surge significantly attenuated after estrogen and progesterone treatment of rats bearing complete lesions, irrespective of the presence of ovaries. Irregular cycling animals with incomplete AMPO or SCN lesions, exhibited attenuated LH surge and PRL surge similar to proestrous controls. In one incidence this occurred spontaneously, and could also be induced by sequential estrogen and progesterone injections. After ovariectomy, plasma LH levels were significantly lower in the lesioned animals as compared to sham operated rats (P less than 0.05). Similar secretory patterns of LH and PRL were obtained from a second series of sham-operated rats during the different stages of the estrous cycle or from AMPO- or SCN-lesioned rats during persistent estrus. After 2 months the animals were killed between 0830 and 0930 h, and the preoptic area and the basal hypothalamus were microdissected from the brain sections. After extraction and purification, proGnRH and GnRH levels were measured by RIA. ProGnRH levels in the preoptic area were significantly reduced in AMPO- or in SCN-lesioned rats, compared to proestrous controls (P less than 0.01). In contrast, GnRH levels in either area did not differ in AMPO- or in SCN-lesioned animals compared to sham-operated, proestrous controls. Therefore, lesions of the AMPO or the SCN produce PE and reduce proGnRH without reducing GnRH levels. These data would suggest that the AMPO and the SCN participate in the control of the estrous cycle and are necessary for preovulatory surges of PRL and LH to occur and that the AMPO and the SCN form part of the neural circuit that regulates GnRH synthesis and/or release.     

Pubertal changes in gonadotropin-releasing hormone and proopiomelanocortin gene expression in the brain of the male rat

Pubertal development in mammals is in part attributable to a brain-dependent process, whereby increased pulsatile GnRH secretion leads to the awakening of the entire reproductive system. However, the brain mechanisms controlling this event are unknown. The apparent increase in GnRH secretion at puberty could reflect an autonomous change in the activity of GnRH neurons themselves or in the afferent networks leading to GnRH neurons. If there were a significant increase in the secretion of GnRH with puberty onset, we hypothesized that there would be a commensurate increase in the biosynthetic capacity of GnRH neurons to meet the increasing demand. We tested this hypothesis by comparing the level of cellular prepro-GnRH mRNA (GnRH mRNA) observed between prepubertal (25-day-old; n = 5) and adult (75-day-old; n = 4) male rats by in situ hybridization. We detected no significant change with puberty in GnRH mRNA signal levels in any of the anatomical areas examined, which included the vertical limb of the diagonal band of Broca, medial septum, lateral preoptic area, and medial preoptic area. Given the variance of our analytical technique, we determined that there was a greater than 90% probability that we would have detected a 20% increase in GnRH mRNA had there been one. Endogenous opioid peptides have been implicated in timing the onset of puberty in the rat, with the argument being that a loss in opioid tone could effect a disinhibition of GnRH secretion. One opioid peptide, beta-endorphin, is among several peptides cleaved from the precursor POMC. We hypothesized that with puberty, POMC neurons in the arcuate nucleus would have an attenuated capacity to produce beta-endorphin. We tested this hypothesis by comparing cellular pre-POMC mRNA (POMC mRNA) levels in the arcuate nuclei of prepubertal (n = 6) and adult (n = 7) male rats with in situ hybridization. We observed an increase in POMC mRNA levels with puberty; prepubertal rats had relative POMC mRNA signal levels of 119 +/- 10 grains/cell, while adult rats contained 167 +/- 12 grains/cell (P less than 0.02). This increase in cellular POMC mRNA was confined to the rostral portion of the arcuate nucleus. We conclude that the GnRH gene is fully expressed well before the time of normal puberty onset and that the increase in POMC mRNA that occurs with the onset of puberty may be important for the development of pulsatile GnRH secretion.     

Presence of prolactin-like immunoreactivity and bioactivity in rat spinal cord

Pursuant to our identification of prolactin-like immunoreactivity (PLI), widely distributed in rat brain, the spinal cord was examined for the presence of this pituitary-hormone-like protein. PLI was present in all spinal cord extracts examined and averaged 500 +/- 53 pg/mg protein. Hypophysectomy, causing a fall in serum prolactin to undetectable levels, was not associated with any change in levels of PLI in spinal cord. Recovery of rat prolactin standards added to spinal cord homogenates was 97.6 +/- 3.9%. When increasing concentrations of spinal cord extract were assayed in a prolactin radioimmunoassay, displacement of rat 125I-Prolactin from antiserum was parallel to that displacement produced by increasing concentrations of rat anterior pituitary standards. Upon subjection to gel permeation chromatography, the elution profiles of immunoreactive prolactin from spinal cord were different from the profiles of anterior pituitary prolactin. In addition to an immunoreactive prolactin peak eluting with pituitary prolactin, spinal cord extracts showed a large void volume peak and late eluting low-molecular-weight materials not seen with anterior pituitary. In the Nb2 lymphoma cell assay, all spinal cord extracts demonstrated prolactin-like bioactivity with a bioactivity/immunoreactivity ratio of 1.05 +/- 0.13. We conclude: (1) PLI, widely distributed in rat brain, is also present in spinal cord; (2) spinal cord prolactin levels are independent of levels in pituitary and peripheral circulation; (3) this immunoreactive prolactin is bioactive, and (4) differing gel permeation chromatographic elution profiles indicate that there may be some molecular differences between pituitary and spinal cord prolactin.     

Differential gene expression response to gonadal hormones by preoptic regulatory factors-1 and -2 in the female rat brain

Steroids and neuropeptides interact in the central nervous system (CNS) to regulate reproductive function and behavior. The preoptic regulatory factors, PORF-1 and PORF-2, are unique neuropeptides for which roles in gender-related brain development and function have been proposed. PORF-1 and PORF-2 expression in rat brain are age, region and gender dependent, and castration or hypophysectomy alter the metabolism of the PORF-1 and PORF-2 mRNAs in male rat brain and testes. If these two peptides have a role in gender-dependent brain function, then gonadal steroids might well affect their expression. The present study was designed to investigate the response of the PORF-1 and PORF-2 mRNAs to sex steroids in the female rat brain and to compare this response to that of two peptides whose roles in the neuroendocrinology of reproduction are well established, gonadotropin-releasing hormone (GnRH) and neuropeptide Y (NPY). Rats were ovariectomized and treated with placebo, estradiol (E2), progesterone (P4) or a combination of the two (E2/P4) and NPY, PORF-2, GnRH and PORF-1 mRNAs were quantified by nuclease protection assays. PORF-1, PORF-2 and GnRH mRNAs were also measured in intact rats during estrus and proestrus. Responses were compared in the preoptic anterior hypothalamus (POA), medial basal hypothalamus (MBH), cerebral cortex (CC) and hippocampus (HIPP). Expression of PORF-1 and PORF-2 was also confirmed in the female rat hypothalamus by in situ hybridization analysis. PORF-1 and PORF-2 mRNAs were detected in the adult female rat brain by both in situ hybridization and ribonuclease protection analyses. In situ hybridization analysis demonstrated that PORF-1 and PORF-2 mRNAs are expressed in hypothalamic neurons. RNase protection analysis showed that PORF-1, PORF-2 and NPY mRNAs were present in all four brain regions examined while GnRH expression was detected only in the MBH and POA. Estradiol alone upregulated expression of the PORF-1 and PORF-2 mRNAs in the ovariectomized rat in the POA and HIPP, and of NPY mRNA in the MBH and HIPP. Progesterone alone had a stimulatory effect on NPY mRNA in the MBH and HIPP. Treatment with a combination of E2/P4 downregulated PORF-2 mRNA in the POA as well as PORF-1, PORF-2 and NPY mRNAs in the CC. In contrast, E2/P4 upregulated the PORF-2 and NPY mRNAs in the HIPP and NPY mRNA in the MBH. In the cycling rat, PORF-1 mRNA levels were higher during proestrus than estrus in both the MBH and POA, while PORF-2 mRNA levels did not change. In contrast GnRH mRNA was lower in the POA and higher in the MBH during proestrus compared with estrus. Thus, intrinsic factors, most likely both ovarian and neuroendocrine, regulate PORF-1 and GnRH expression in the intact cycling rat CNS in a region-dependent manner. In the ovariectomized rat, PORF-1, PORF-2, NPY and GnRH mRNAs all respond in a region-specific manner to sex steroid treatment. These data support the role of PORF-1 and PORF-2 in gender-dependent brain function in the adult female rat.     

Characterization and localization of mRNA encoding the salmon-type gonadotrophin-releasing hormone precursor of the masu salmon.

Gonadotrophin-releasing hormone (GnRH) is considered to have an important role in the control of reproduction in salmonid fish, although we do not have any direct evidence. To clarify this problem by molecular techniques, we first determined the nucleotide sequence of the mRNA encoding the precursor of salmon-type GnRH (sGnRH) from the masu salmon, Oncorhynchus masou. The masu salmon sGnRH precursor was composed of a signal peptide, sGnRH and a GnRH-associated peptide (GAP) which was connected to sGnRH by a Gly-Lys-Arg sequence. The amino acid sequence of sGnRH and Gly-Lys-Arg were highly conserved when compared with the corresponding regions of African cichlid sGnRH and mammalian GnRH precursors. However, the GAP region was markedly divergent, with a 66% amino acid similarity to African cichlid GAP and an 8.3-15% similarity to mammalian GAPs. Northern blot analysis indicated the presence of a single mRNA species of about 600 bases in the olfactory bulb and telencephalon and in the diencephalon. The signal was more intense in the former regions. An in-situ hybridization study further revealed that sGnRH neurones were distributed in the olfactory nerve, the ventral part of the olfactory bulb, the ventral part of the telencephalon, the lateral preoptic area and the preoptic nucleus. The sGnRH neurones were thus longitudinally scattered between the olfactory nerve and the lateral preoptic area in the rostroventral part of brain. The intensity of the hybridization signals and the size of hybridization-positive somata were much greater in the olfactory nerve and the rostral olfactory bulb than in the other regions. Preoptic sGnRH neurones were scarcely detected in immature masu salmon, whereas they were more frequently observed in maturing animals. It is possible that the olfactory and the preoptic sGnRH neurones have different physiological roles in salmonid fish.     

Age-related decreases in serum gonadotropin levels and gonadotropin-releasing hormone gene expression in the medial preoptic area of the male rat are dependent upon testicular feedback

In the male rat, age-associated reproductive decline is thought to be due in part to diminished GnRH secretion. We tested the hypothesis that the age-related decrease in GnRH secretion is due to decreased GnRH gene expression by comparing GnRH mRNA and peptide content in the anterior forebrain of intact young and old male rats. Since sex steroids modulate GnRH secretion, we also determined hypothalamic-pituitary responsiveness to removal of testicular feedback by comparing GnRH mRNA and gonadotropin levels in intact and orchidectomized young and old rats. In an initial study, 10 20-micron coronal sections from the medial preoptic area (MPOA) were anatomically matched and compared in intact young (3-month-old) and old (24-month-old) male F344 rats (n = 5/group). In another group of young and old male rats (n = 8-12/group), animals were randomly assigned to be either orchidectomized or sham operated. Rats were killed 21 days after surgery, and comparisons were made in 12 anatomically matched sections of MPOA and 4 matched sections of diagonal band of Broca. In both studies, GnRH mRNA was quantitated by in situ hybridization, using a 35S-labeled oligodeoxynucleotide probe complementary to rat prepro-GnRH mRNA and a computerized image analysis system. In a third study, GnRH content was measured by RIA in microdissected regions of the arcuate nucleus and median eminence in intact 3- and 24-month-old male rats (n = 10 and 8, respectively). Serum LH, FSH, and testosterone (T) levels were measured by RIA in trunk blood of all animals. The number of neurons expressing the GnRH gene in the MPOA was significantly lower in sham-operated old rats (mean +/- SEM, 10.5 +/- 0.5 cells/section) than in young rats (13.7 +/- 0.7 cells/section; P less than 0.01), while cellular GnRH mRNA content was unchanged with age (103 +/- 1 vs. 103 +/- 2 grains/cell). Similar results were obtained in intact old and young rats. GnRH peptide content was significantly decreased in the arcuate nucleus of intact old (0.5 +/- 0.08 ng/mg protein) compared to young animals (2.3 +/- 0.7 ng/mg protein; P less than 0.05), with a trend toward a decrease in the median eminence of old (53 +/- 2 ng/mg protein) vs. young rats (69 +/- 7 ng/mg protein; P = 0.06).(ABSTRACT TRUNCATED AT 400 WORDS)     

Cytoplasmic and nuclear Fos protein forms regulate resumption of spermatogenesis in the frog, Rana esculenta.

The role of Fos proteins in the regulation of germ cell progression during spermatogenesis has been studied in the frog, Rana esculenta. A peculiarity of this animal model is the finding of Fos in cytoplasmic compartment of primary spermatogonia during the resting period of the annual reproductive cycle. Interestingly, Fos is localized in the nuclear compartment when spermatogenesis resumes. Using Western blot analysis, we show that a 52-kDa Fos protein occurs in testicular cytosolic preparations, whereas two different Fos signals of 43 and 68 kDa are typical of the nuclear compartment. The 68-kDa Fos immunoreactive protein increases in nuclear extracts in concomitance with spermatogonia (SPG) proliferation either during the annual sexual cycle or in experimental animal groups where SPG proliferation was induced by thermal stimulus (24 C). Indeed, an increase in proliferating cell nuclear antigen was detectable after thermal induction of mitotic activity. A decrease in the 52-kDa signal and a concomitant increase in the 68-kDa signal is observed in testes of 24 C treated groups. The use of alkaline phosphatase and alkaline phosphatase inhibitors indicates that the 68-kDa protein is a phosphorylated form. Estrogens, which are able to induce SPG proliferation, are responsible for the appearance of the 43-kDa Fos form in nuclear testicular extracts. In conclusion, our results show, for the first time in a vertebrate species, that storage in the cytoplasm, on the one hand, and appearance as well as phosphorylation of Fos proteins in the nucleus of germ cells, on the other hand, regulate spermatogenesis progression during the seasonal breeding. Moreover, the phosphorylated 68-kDa Fos form may be involved in mechanisms underlying SPG proliferation.