Metformin decreases GnRH- and activin-induced gonadotropin secretion in rat pituitary cells: potential involvement of adenosine 5' monophosphate-activated protein kinase (PRKA).

Metformin is an insulin sensitizer molecule used for the treatment of infertility in women with polycystic ovary syndrome and insulin resistance. It modulates the reproductive axis, affecting the release of gonadotropin-releasing hormone (GnRH) and luteinizing hormone (LH). However, metformin's mechanism of action in pituitary gonadotropin-secreting cells remains unclear. Adenosine 5' monophosphate-activated protein kinase (PRKA) is involved in metformin action in various cell types. Here, we investigated the effects of metformin on gonadotropin secretion in response to activin and GnRH in primary rat pituitary cells (PRP), and studied PRKA in rat pituitary. In PRP, metformin (10 mM) reduced LH and follicle-stimulating hormone (FSH) secretion induced by GnRH (10(-8) M, 3 h), FSH secretion, and mRNA FSHbeta subunit expression induced by activin (10(-8) M, 12 or 24 h). The different subunits of PRKA are expressed in pituitary. In particular, PRKAA1 is detected mainly in gonadotrophs and thyrotrophs, is less abundant in lactotrophs and somatotrophs, and is undetectable in corticotrophs. In PRP, metformin increased phosphorylation of both PRKA and acetyl-CoA carboxylase. Metformin decreased activin-induced SMAD2 phosphorylation and GnRH-induced mitogen-activated protein kinase (MAPK) 3/1 (ERK1/2) phosphorylation. The PRKA inhibitor compound C abolished the effects of metformin on gonadotropin release induced by GnRH and on FSH secretion and Fshb mRNA induced by activin. The adenovirus-mediated production of dominant negative PRKA abolished the effects of metformin on the FSHbeta subunit mRNA and SMAD2 phosphorylation induced by activin and on the MAPK3/1 phosphorylation induced by GnRH. Thus, in rat pituitary cells, metformin decreases gonadotropin secretion and MAPK3/1 phosphorylation induced by GnRH and FSH release, FSHbeta subunit expression, and SMAD2 phosphorylation induced by activin through PRKA activation.

Bone morphogenetic protein-4 interacts with activin and GnRH to modulate gonadotrophin secretion in LbetaT2 gonadotrophs.

We have shown previously that, in sheep primary pituitary cells, bone morphogenetic proteins (BMP)-4 inhibits FSHbeta mRNA expression and FSH release. In contrast, in mouse LbetaT2 gonadotrophs, others have shown a stimulatory effect of BMPs on basal or activin-stimulated FSHbeta promoter-driven transcription. As a species comparison with our previous results, we used LbetaT2 cells to investigate the effects of BMP-4 on gonadotrophin mRNA and secretion modulated by activin and GnRH. BMP-4 alone had no effect on FSH production, but enhanced the activin+GnRH-induced stimulation of FSHbeta mRNA and FSH secretion, without any effect on follistatin mRNA. BMP-4 reduced LHbeta mRNA up-regulation in response to GnRH (+/-activin) and decreased GnRH receptor expression, which would favour FSH, rather than LH, synthesis and secretion. In contrast to sheep pituitary gonadotrophs, which express only BMP receptor types IA (BMPRIA) and II (BMPRII), LbetaT2 cells also express BMPRIB. Smad1/5 phosphorylation induced by BMP-4, indicating activation of BMP signalling, was the same whether BMP-4 was used alone or combined with activin+/-GnRH. We hypothesized that activin and/or GnRH pathways may be modulated by BMP-4, but neither the activin-stimulated phosphorylation of Smad2/3 nor the GnRH-induced ERK1/2 or cAMP response element-binding phosphorylation were modified. However, the GnRH-induced activation of p38 MAPK was decreased by BMP-4. This was associated with increased FSHbeta mRNA levels and FSH secretion, but decreased LHbeta mRNA levels. These results confirm 1. BMPs as important modulators of activin and/or GnRH-stimulated gonadotrophin synthesis and release and 2. important species differences in these effects, which could relate to differences in BMP receptor expression in gonadotrophs.

Fetal gonadotrope cell origin of FSH-secreting pituitary adenoma - insight into human pituitary tumour pathogenesis.

OBJECTIVE: The pathogenesis of human pituitary adenomas remains unclear, but we report a case of FSH-secreting pituitary adenoma whose monohormonal phenotype suggests it was of fetal origin. PATIENTS: A 28-year-old woman presented with abdominal discomfort and irregular menses, enlarged multicystic ovaries and elevated serum oestradiol, with sustained high-normal FSH and low LH levels. MEASUREMENTS: Endocrine studies were performed before and after curative surgery, with assessment of tumour hormone secretion in vitro, and immunostaining of tumour tissue for a series of gonadotrope proteins. RESULTS: Immunocytochemistry showed that tumour cells were monohormonal for FSH. Normal components of gonadotrope signalling pathways were expressed, including oestrogen receptor-alpha, activin receptors, secretogranin-II and chromogranin-A. beta-glycan, the putative inhibin coreceptor, was absent. Tumour culture in vitro confirmed secretion of FSH with minimal LH, that was unsuppressed by oestradiol or inhibin-A. Human fetal pituitary tissue contained FSH-only cells at 18 weeks gestation, whereas normal adult pituitary tissue contained only bihormonal gonadotropes. CONCLUSIONS: We propose that this pituitary adenoma represents an indolent tumour of monohormonal fetal gonadotrope cells that originated early in gestation. Pituitary tumours may therefore arise from abnormal persistence of fetal cell types, with extremely slow growth over many years until reaching a size threshold to generate an endocrine syndrome. Understanding fetal pituitary architecture and function may be more informative for new insights into pituitary tumour pathogenesis than classical theories of cancer biology that invoke unrestrained cell proliferation.

Differential secretion of gonadotrophins: investigation of the role of secretogranin II and chromogranin A in the release of LH and FSH in LbetaT2 cells.

This study investigated the role of the secretory granule proteins, secretogranin II (SgII) and chromogranin A (CgA), in the differential secretion of FSH and LH from LbetaT2 mouse gonadotroph cells. Exogenous activin, which synergises with GnRH, is essential for the release of FSH from these cells, but also has stimulatory effects on LH and enhances GnRH-induced LH secretion. Two experiments are reported. In experiment 1, cultures were supplemented with activin (0-50 ng/ml), with and without a daily 1 h treatment of 10 nM GnRH, for 3 days. Protein secretion and mRNA levels were measured. In experiment 2, cells were treated with activin (50 ng/ml) alone, a daily 1 h treatment of 10 nM GnRH, or a combination of both for 6 days. In addition, cells exposed to activin+GnRH for 3 days were subsequently left untreated or given activin or GnRH alone for a further 3 days for comparison with cells maintained in activin+GnRH for 6 days. Protein secretion, intracellular protein and mRNA levels were measured. FSH secretion was stimulated, dose dependently, by activin and this effect increased synergistically in the presence of GnRH. The close correlation between secreted and intracellular FSH and FSHbeta mRNA levels was maintained in cells that had undergone treatment withdrawal after previous exposure to activin+GnRH, but there was no correlation between FSH and the granins. These results are consistent with the view that FSH released in response to activin/GnRH is constitutively secreted via a granin-independent pathway. SgII secretion mirrored the GnRH-induced secretion of LH, but was unaffected by activin, which stimulated LH secretion and had a detrimental effect on CgA mRNA transcription. This confirms previous observations that the LH released in response to GnRH is co-released with SgII via a regulated, granin-dependent pathway, and, in addition, suggests that activin may stimulate LH secretion through a constitutive, granin-independent pathway.

No evidence for pituitary priming to gonadotropin-releasing hormone in relation to luteinizing hormone (LH) secretion prior to the preovulatory LH surge in ewes.

The purpose of this study was to determine the occurrence of and the regulatory mechanisms involved in priming of the pituitary to GnRH before the preovulatory LH surge in sheep. Experiment 1: Forty-two ewes had progestagen devices removed after 14 days and were assigned to luteal (Lut) or follicular (Foll) groups. Fifteen days later, blood sampling was initiated either immediately or 36 h after induced luteolysis in groups Lut and Foll, respectively. After 4 h, ewes were administered either saline (n = 5) or 250 ng (n = 8) or 10 microg (n = 8) of GnRH. Five ewes per treatment group were killed 1 h later, while remaining animals were blood sampled for a further 7 h. Experiment 2: Eighteen ewes were allocated to Lut and Foll groups (described above). Blood samples were collected from 2 h before GnRH (10 microg) treatment until 7 h after. Despite up-regulated GnRH-R mRNA levels in Foll ewes, pituitary content and plasma levels of LH and LHbeta mRNA levels were similar between groups. Mean FSHbeta mRNA and plasma FSH levels were elevated in Lut ewes but declined after GnRH treatment. Inversely, plasma estradiol and inhibin-A concentrations were higher in Foll ewes and declined after GnRH treatment. Fewer LH(+ve)/secretogranin II(-ve) (SgII(-ve)) granules were present in gonadotropes of Foll ewes, coincident with increased basal LH levels. Fewer smaller sized granules were present after GnRH treatment. In conclusion, there was no evidence of self-priming before onset of the preovulatory LH surge. Constitutive release of LH(+ve)/SgII(-ve) granules may maintain basal LH levels while smaller sized, presumably mature granules may be preferentially released after GnRH stimulation.

The differential secretion of FSH and LH: regulation through genes, feedback and packaging.

While the role of oestradiol and progesterone in the control of GnRH pulsatile secretion and generation of the preovulatory GnRH surge to induce release of the LH surge has been fully investigated, less attention has been given to changes in the pituitary gland that may sensitize gonadotrophs to switch from pulsatile release to surge release of LH, in particular. Furthermore, in the follicular phase while pulsatile secretion of LH is maximal, FSH secretion is reduced, yet both hormones are produced by the same gonadotrophs. The mechanisms whereby this differential release can occur are still unclear. The main regulator of FSH secretion is through the negative feedback effects of oestradiol and inhibin, which directly affect FSHbeta mRNA content and subsequent synthesis of FSH. FSH is then released predominantly via a constitutive pathway and the amount released is closely related to the rate of synthesis. In contrast, while basal LH secretion occurs via a constitutive pathway, the principal release of LH through pulsatile secretion is through the regulated pathway with GnRH stimulating the release of pre-synthesized LH contained in storage granules without significant changes in LHbeta mRNA. Secretogranin II (SgII) is associated with LH in these electron-dense storage granules and LH-SgII granules appear to be the principal form of granule released in response to GnRH through the regulated pathway. At the time of the preovulatory LH surge, granule movement to the gonadotrope cell membrane abutting a capillary, polarization, appears to play an important part in the priming mechanism for release of LH during the preovulatory LH surge in response to the GnRH surge. As there appears to be limited or no gonadotroph cell division in the adult pituitary gland, each gonadotroph passes through this synthesis and secretion pathway repeatedly through successive oestrous cycles. Packaging of LH and FSH into different secretory granules within the same cell is thus pivotal for the differential secretion of these gonadotrophins.

Influence of steroids and GnRH on biosynthesis and secretion of secretogranin II and chromogranin A in relation to LH release in LbetaT2 gonadotroph cells.

The granin proteins secretogranin II (SgII) and chromogranin A (CgA) are commonly found associated with LH and/or FSH within specialised secretory granules in gonadotroph cells, and it is possible that they play an important role in the differential secretion of the gonadotrophins. In this study we have examined the regulation of the biosynthesis and secretion of SgII and CgA, in relation to LH secretion, in the LbetaT2 mouse pituitary gonadotroph cell line. Three experiments were carried out to investigate the effects of oestradiol (E2) and dexamethasone (Dex) in the presence and absence of GnRH (experiment 1), differing GnRH concentrations (experiment 2) and alterations in GnRH pulse frequency (experiment 3). In experiment 1, exposure to E2, Dex or E2+Dex, either with or without GnRH treatment, resulted in increased LH secretion. Steroids alone had no effect on LHbeta mRNA levels, but in the presence of GnRH LHbeta mRNA levels were increased in Dex- and E2+Dex-treated cells. GnRH receptor (GnRH-R) mRNA levels were up-regulated by Dex and E2+Dex, but were unaffected by GnRH. There were no steroid-induced changes in SgII or CgA mRNA, but increased levels of CgA mRNA were observed after GnRH treatment in cells cultured in the presence of Dex. In experiment 2, increasing concentrations of GnRH resulted in increases in LH secretion that were inversely dose-dependent. No changes in LHbeta, GnRH-R or SgII mRNA levels were observed, but there were dose-dependent increases in CgA mRNA levels. In experiment 3, GnRH was given as either 1 pulse/day or 4 pulses/day for 3 days. Both pulse regimes resulted in increased LH, SgII and CgA secretion compared with controls during the first 15 min pulse on day 3. Exposure to GnRH at 4 pulses/day increased LH and SgII secretion compared with controls during all 4 pulses, but secretion of both proteins was reduced during pulses 2-4 compared with pulse 1. CgA secretion also increased due to GnRH in pulse 1, but was decreased by GnRH treatment during pulse 2, and unchanged by GnRH during pulses 3 and 4. Total daily secretion of LH and SgII from cells given 1 pulse/day of GnRH increased compared with controls on all three treatment days, while total CgA secretion increased in response to GnRH on days 2 and 3 only. Intracellular levels of SgII, but not LH, decreased after GnRH treatment. In contrast, intracellular CgA was increased, but only after 4 pulses/day of GnRH. Levels of LHbeta, but not SgII, mRNA were increased by both pulse regimes, while CgA mRNA levels increased after 1 pulse/day of GnRH. These results indicate that there is a close correlation between the GnRH-stimulated release of LH and SgII from LbetaT2 cells, suggesting that SgII may have an influential role in the regulated secretion of LH, possibly by inducing LH aggregation to facilitate trafficking into secretory granules. CgA secretion does not appear to be closely associated with that of LH, but CgA expression does appear to be regulated by GnRH, which may indicate involvement in the control of LH secretion, possibly by influencing the proportion of LH in the different types of secretory granules.

Promotion of intragranular co-aggregation with LH by enhancement of secretogranin II storage resulted in increased intracellular granule storage in gonadotrophs of GnRH-deprived male mice.

Intracellular associations indicate that granins may play a role in the regulatory mechanisms involved in differential secretion of gonadotrophins. The effect of GnRH on mRNA expression, storage and secretory patterns of granins and gonadotrophins was investigated in male mice. GnRH antiserum (G/A) was injected into mice in the treatment group (n = 15) at 12 h intervals for 2 days and a subset (n = 9) was killed. Buserelin (G/A + B) was administered to the remaining mice (n = 6), which were killed 2 h later; control mice (n = 6) were killed at the onset of the study. LHb mRNA content was lower in G/A and G/A + B mice compared with controls, whereas plasma LH concentrations were higher in G/A + B mice. FSHbeta mRNA content did not change, whereas plasma FSH concentrations were lower in G/A mice compared with controls, and higher in G/A + B mice compared with both G/A and control mice. Secretogranin II (SgII) and CgA mRNA contents were not different between experimental groups. There were more granules per gonadotroph in G/A mice, and considerably fewer after Buserelin treatment. Immunogold labelling of gonadotrophs revealed the presence of LH(+ve)/SgII(+ve) and LH(+ve)/SgII(-ve) granules, and negligible numbers of LH(-ve)/SgII(+ve) granules. Both the numbers of LH(+ve)/SgII(+ve) granules and overall granule antigenicity for SgII were higher in G/A mice compared with controls and G/A + B mice. In contrast, there were fewer LH(+ve)/SgII(-ve) granules per gonadotroph in G/A mice compared with controls. In conclusion, absence of GnRH input to the pituitary gland resulted in preferential storage of SgII and subsequently increased intragranular co-aggregation with LH. Administration of Buserelin to G/A mice resulted in the apparent release of LH(+ve)/SgII(+ve) granules that was reflected by an increase in plasma LH concentrations, indicating that these granules were in the regulated secretory pathway. In contrast, secretion of LH(+ve)/SgII(-ve) granules did not appear to be influenced by the actions of Buserelin and, therefore, may have been destined for constitutive release, possibly to maintain basal plasma LH concentrations.

Manipulating the in vivo mRNA expression profile of FSH beta to resemble that of LH beta does not promote a concomitant increase in intracellular storage of follicle-stimulating hormone.

The beta-subunits of luteinizing hormone (LH beta) and follicle-stimulating hormone (FSH beta) are differentially expressed, and this may contribute to the unique expression and storage patterns of LH and FSH. Therefore, to determine if the in vivo expression profile of FSH beta could be altered to that of LH beta, a truncated ovine FSH beta (oFSH beta) gene, which would encode a mRNA lacking the putative destabilizing 3' untranslated region, was fused downstream of the ovine LH beta (oLH beta) promoter and expressed in transgenic mice. In two independent lines, line 16 and 17, we measured oFSH beta, mouse LH beta (mLHbeta) and mouse FSH beta (mFSH beta) mRNA levels: (i) after castration in males; (ii) after administering inhibin to ovariectomized mice; and (iii) during the oestrous cycle. In each experiment, the expression profile of oFSH beta mRNA mimicked mLH beta and not mFSH beta mRNA. In addition, after actinomycin D treatment of pituitary cultures, while mFSH beta mRNA did decay, there was no measurable decay of the oFSH beta mRNA transcript. These differences increased total FSH beta steady-state mRNA expression levels in male transgenics. However, there was no detectable increase in pituitary FSH by either radioimmunoassay or western blotting analysis of pituitary extracts. Subsequent analysis revealed that pituitary FSH beta in line 16 was heavily glycosylated; in contrast, pituitary FSH beta in line 17 was largely unmodified. These differences in post-translational modification of the beta-subunit, and the lack of intracellular storage, contributed to increased plasma FSH levels and ovulation rate in line 16, but not line 17. In conclusion, the expression profile of oFSH beta mRNA was manipulated to mimic mLH beta mRNA and this increased FSH beta mRNA expression levels, but did not increase storage of FSH. This suggests that, regardless of the levels of synthesis, post-translational sorting preferentially promotes FSH secretion from the pituitary.

Loss of oocytes in Dazl knockout mice results in maintained ovarian steroidogenic function but altered gonadotropin secretion in adult animals.

Within 2 days of birth, the mouse ovary is mainly composed of oocytes surrounded by a few pregranulosa cells forming primordial follicles that remain quiescent until they are recruited by intraovarian or other unknown factors to initiate growth of the oocyte and proliferation of the attendant granulosa cells. However, the role of the oocyte in this early development and organization of the follicle is poorly understood. The Dazl knockout (-/-) mouse in which there is total ablation of oocytes in fetal life has allowed us to address this issue. Ovaries from -/- females lack any follicular structure and have no cells positive for either Mullerian inhibiting factor or sulfated glycoprotein-1, indicating a lack of small follicles or corpora lutea. However, by immunocytochemistry, there are cells positive for 3beta-hydroxysteroid dehydrogenase, 17alpha-hydroxylase, and aromatase, indicating the presence of steroidogenically active cells capable of producing estrogen. This was confirmed by the presence of hypertrophied uterine endometrium expressing both estrogen receptor alpha (ER alpha) and ER beta together with normal levels of plasma estradiol. In addition, these steroidogenically active cells contain ER beta, inhibin alpha, and betaB-subunits, and -/- mice have low measurable plasma inhibin A and B levels. The ovarian steroids and inhibins had no significant effect on either plasma or pituitary gonadotropin levels, with significantly (P < 0.01) lower LH and FSH in intact +/+ and +/- females. However, significantly (P < 0.05) increased plasma inhibin B together with significantly (P < 0.05) lower FSH were observed in the +/- females. In conclusion, our data showed that despite oocyte loss in fetal life, the adult ovaries contained steroidogenically active cells capable of producing estradiol and inhibin. Furthermore, in the +/- mice, the enhanced plasma inhibin B implies a role for Dazl protein within the oocyte either from more small follicles or increased inhibin B production from each follicle.

Extra- and intracellular effects of divergent selection for pituitary responsiveness to gonadotropin-releasing hormone in prepubertal ram lambs.

Divergent selection based on the response of 10-wk-old male lambs to a GnRH challenge has produced two lines of sheep, referred to as high and low lines, that differ in their ability to release LH in response to pharmacological and physiological doses of GnRH. The aim of this study was to determine whether the between-line differences in pituitary sensitivity were related to differences in GnRH receptor number and/or the transduction of the intracellular signal following GnRH receptor activation. Pituitary glands were collected from fourteen 20-wk-old ram lambs from each line, weighed, and sampled for GnRH receptor analysis. The remaining tissue from 9 lambs from each line was dispersed. Of the resultant cell suspension, a sample was stored for measurement of GnRH receptor content and the remainder was plated and cultured for 24 h. The LH responses of cultured cells were measured after exposure to GnRH, A23187, or the phorbol ester phorbol 12,13 dibutyrate (PDB). The results indicated that the pituitary glands of the high line contained significantly higher concentrations of GnRH receptors than did those of the low line and released significantly more LH after stimulation with either GnRH or the Ca2(+)-calmodulin or protein kinase C intracellular second messenger systems. Therefore, the between-line difference in the regulation of pituitary LH secretion occurs at a step distal to the stimulatory sites of action of A23187 and PDB.

Characterization of the ovine LH beta-subunit gene: the promoter is regulated by GnRH and gonadal steroids in transgenic mice.

We have previously demonstrated that 1.9 kb of ovine LH beta promoter fused to bacterial chloramphenicol transferase (CAT) coding sequence is sufficient to target expression of the transgene specifically to the gonadotroph cells of the anterior pituitary in mice with no expression being observed in other tissues. However, it is not known if this region of the ovine LH beta promoter contains the necessary elements that confer transcriptional regulation by gonadal steroids and GnRH. Following gonadectomy, both endogenous pituitary LH and CAT activity significantly (P > 0.001) increased as did plasma LH. This post-gonadectomy increase in CAT, pituitary and plasma LH could be suppressed in females by treatment with oestradiol alone or oestradiol and progesterone, with an additional significant (P < 0.05) reduction in CAT activity being observed in one line following the combined steroid treatment. In castrated males, testosterone suppressed CAT activity in one line. Treatment of transgenic ovariectomized females with oestradiol alone significantly suppressed plasma LH (P < 0.01) with no change in pituitary LH content. There was no difference in pituitary LH between oestradiol-treated ovariectomized transgenic and non-transgenic females. Treatment of intact females from both lines with either GnRH antiserum or agonist demonstrated a decrease in pituitary CAT activity whereas similar treatment in intact males had no effect. While endogenous pituitary LH concentrations were variable, plasma LH was lower in all treated animals irrespective of line, sex or expression of the transgene. In conclusion, these results indicate that (1) the presence of CAT protein is not toxic and does not compromise either endogenous LH synthesis, storage and secretion and (2) the ovine LH beta-CAT gene is regulated in a similar but more variable manner to the endogenous LH beta gene. This may relate to the use of CAT as a reporter where its release is not necessarily related to that of the endogenous hormone whose synthesis, storage and release may differ.

Effects of indirect selection for pituitary responsiveness to gonadotropin-releasing hormone on the storage and release of luteinizing hormone and follicle-stimulating hormone in prepubertal male lambs.

Divergent selection based on the LH response to a 5-micrograms dose of GnRH in 10-wk-old Finn Dorset ram lambs has created two lines of sheep that differ significantly in their response to both physiological and pharmacological dosages of GnRH. The aims of this study were to investigate whether there are between-line differences in endogenous LH and FSH secretion in ram lambs, as in the adult ewes, and to determine whether these differences are related to differences in storage of gonadotropins within the pituitary glands of the two lines. To address the first aim, endogenous LH and FSH secretion was monitored in 20 ram lambs from each line for a 6-h period at 2, 6, and 10 wk of age. To investigate potential between-line differences in gonadotropin storage, the LH responses to two acute challenges with either 0.5, 5.0, or 50.0 micrograms of GnRH were examined in 10-wk-old ram lambs from each line. The results demonstrated that the between-line difference in the LH response to a 5-micrograms GnRH challenge in ram lambs is accompanied by significant between-line differences in the regulation of endogenous gonadotropin secretion. Specifically, lambs from the High line secreted LH pulses of significantly greater amplitude than did lambs from the low line at 2 and 10 wk of age.(ABSTRACT TRUNCATED AT 250 WORDS)

Alterations in endogenous gonadotropin secretion and pituitary responsiveness to gonadotropin-releasing hormone in adult ewes, following indirect selection in prepubertal male lambs.

Indirect selection to improve reproductive performance in the female, through use of a physiologically related trait in prepubertal males, the LH response to a GnRH challenge, has created two lines of sheep with altered pituitary gland sensitivity to both physiological and pharmacological doses of GnRH. These lines also exhibit correlated between-line differences in female reproductive performance during the first, and at the beginning of the second, breeding season. This study was designed to determine whether the observed between-line differences in female reproductive performance were related to between-line differences in endogenous gonadotropin secretion during the luteal and follicular phases of the estrous cycle and whether the between-line difference in the LH response to a GnRH challenge was maintained in adult females. The results indicated that, despite similar mean gonadotropin and steroid concentrations during the luteal and follicular phases of the estrous cycle, significant between-line differences in LH pulse amplitude were present during the follicular phase (high line > low line). In addition, the results indicated that the between-line difference in the LH response to a GnRH challenge was maintained in adult ewes, being most apparent during the follicular phase, when the magnitude of the difference was similar to that in prepubertal female lambs. Therefore, in addition to showing maintenance of the between-line difference in the selected characteristic in postpubertal females, the results demonstrate that adult ewes from the two lines differ in additional, unselected but physiologically related traits and provide a model system with which to study steroidal regulation of gonadotropin secretion in the ewe.

Characterization of the ovine LH beta-subunit gene: the promoter directs gonadotrope-specific expression in transgenic mice.

The alpha- and beta-subunits of the gonadotropin hormones are expressed in the gonadotrope cells of the anterior pituitary. There are no adequate in vitro systems for the analysis of beta-subunit gene expression. In this study, therefore, transgenic mice have been used to investigate the regulation of expression of the ovine luteinizing hormone beta-gene (oLH beta) in vivo. oLH beta was isolated, characterized, and 1.9 kb of the promoter fused to the bacterial reporter chloramphenicol acetyl-transferase (CAT). Three lines of transgenic mice were generated. CAT enzyme was detected in the pituitary of two lines, whereas the third line did not express. Measurement of endogenous luteinizing hormone and follicle stimulating hormone levels in both expressing lines revealed small differences when compared to controls, but these did not affect the fertility of the animals. Immunostaining of the anterior pituitary revealed that the oLH beta CAT transgene was expressed specifically in gonadotrope cells.

The relationship between selection for pituitary responsiveness to gonadotrophin releasing hormone in sheep and differences in gonadotrophin subunit mRNAs.

Selection of the luteinizing hormone (LH) response to exogenous gonadotrophin-releasing hormone (GnRH) in sheep has resulted in the establishment of two lines (High and Low) with a fivefold difference in pituitary sensitivity to GnRH. The effect of selection on gonadotrophin gene expression in the presence or absence of an exogenous gonadotrophin-releasing hormone (GnRH) challenge in twenty-week-old ram lambs from both lines was examined. Before treatment with either GnRH or saline, LH and follicle-stimulating hormone (FSH) concentrations were significantly higher in the High line than in the Low line animals (LH and FSH: P < 0.01). One hour after either GnRH or saline, all animals were slaughtered. In the absence of a GnRH challenge, there were significantly higher concentrations of all three gonadotrophin subunit mRNAs in the High line compared with the Low line, corresponding to the higher basal concentrations of LH and FSH. When comparing treatments between the lines, following a GnRH challenge, LH beta subunit mRNA was significantly (P < 0.001) higher in both lines than before the GnRH, whereas there was no significant change in either alpha or FSH beta subunit mRNA. These results indicate that the differences in basal gonadotrophin secretion are related to differences in gonadotrophin subunit mRNAs with the High line animals having an inherently greater amount of all three gonadotrophin subunit mRNAs. Selection has not altered the differential amounts of gonadotrophin subunit mRNAs, since there is an overall increase in all three gonadotrophin subunits. GnRH appears to preferentially control LH beta mRNA in both High and Low line animals.

Relationship between gonadotrophin subunit gene expression, gonadotrophin-releasing hormone receptor content and pituitary and plasma gonadotrophin concentrations during the rebound release of FSH after treatment of ewes with bovine follicular fluid during the luteal phase of the cycle.

The modulation of FSH secretion at the beginning and middle of the follicular phase of the cycle represents the key event in the growth and selection of the preovulatory follicle. However, the mechanisms that operate within the pituitary gland to control the increased release of FSH and its subsequent inhibition in vivo remain unclear. Treatment of ewes with bovine follicular fluid (bFF) during the luteal phase has been previously shown to suppress the plasma concentrations of FSH and, following cessation of treatment on day 11, a rebound release of FSH occurs on days 12 and 13. When luteal regression is induced on day 12, this hypersecretion of FSH results in an increase in follicle growth and ovulation rate. To investigate the mechanisms involved in the control of FSH secretion, ewes were treated with twice daily s.c. injections of 5 ml bFF on days 3-11 of the oestrous cycle and luteal regression was induced on day 12 with prostaglandin (PG). The treated ewes and their controls were then killed on day 11 (luteal), or 16 or 32 h after PG and their pituitaries removed and halved. One half was analysed for gonadotrophin and gonadotrophin-releasing hormone (GnRH) receptor content. Total pituitary RNA was extracted from the other half and subjected to Northern analysis using probes for FSH-beta, LH-beta and common alpha subunit. Frequent blood samples were taken and assayed for gonadotrophins. FSH secretion was significantly (P less than 0.01) reduced during bFF treatment throughout the luteal phase and then significantly (P less than 0.01) increased after cessation of treatment, with maximum secretion being reached 18-22h after PG, and then declining towards control values by 32h after PG. A similar pattern of LH secretion was seen after bFF treatment. Pituitary FSH content was significantly (P less than 0.05) reduced by bFF treatment at all stages of the cycle. No difference in the pituitary LH content was seen. The increase in GnRH receptor content after PG in the controls was delayed in the treated animals. Analysis of pituitary mRNA levels revealed that bFF treatment significantly (P less than 0.01) reduced FSH-beta mRNA levels in the luteal phase. Increased levels of FSH-beta, LH-beta and alpha subunit mRNA were seen 16h after PG in the bFF-treated animals, at the time when FSH and LH secretion from the pituitary was near maximum.(ABSTRACT TRUNCATED AT 400 WORDS)

Role of gonadal negative feedback on the gonadotrophin responses to gonadotrophin-releasing hormone (GnRH) in ram lambs from two lines of sheep selected for their luteinizing hormone response to GnRH.

Divergent selection has resulted in two lines of lambs (high and low) that have a 5-fold difference in their ability to release luteinizing hormone (LH) in response to 5 micrograms of gonadotrophin-releasing hormone (GnRH). Baseline gonadotrophin concentrations, the gonadotrophin responses to a GnRH challenge and the concentrations of testosterone and oestradiol were compared in lambs which were castrated at birth and intact lambs from both selection lines at 2, 6, 10 and 20 weeks of age. The pattern of LH and follicle-stimulating hormone (FSH) secretion was similar in the two lines, but differed between the intact and the castrated lambs. Basal LH and FSH secretion were significantly higher in the castrates than in the intact lambs from both selection lines. The high-line lambs had significantly higher basal FSH concentrations at all ages tested and significantly higher basal LH concentrations during the early postnatal period. The magnitude of the gonadotrophin responses to GnRH differed significantly between the intact and the castrated lambs within each line, the amount of gonadotrophins secreted by the castrated lambs being significantly greater. The removal of gonadal negative feedback by castration did not alter the between-line difference in either LH or the FSH response to the GnRH challenge. Throughout the experimental period, the concentration of testosterone in the intact lambs was significantly greater than in the castrated lambs in both selection lines, but no significant difference was seen in the concentrations of oestradiol. No significant between-line differences were found in the peripheral concentrations of testosterone or oestradiol in the intact lambs from the two selection lines. Therefore, despite similar amounts of gonadal negative feedback in the selection lines, there were significant between-line differences in basal gonadotrophin concentrations, at 2 and 6 weeks of age, and in the LH and FSH responses to an exogenous GnRH challenge, at all ages tested. Removal of gonadal negative feedback did not affect the magnitude of the between-line difference in the response of the lines to GnRH stimulation. The results indicate that the effects of selection on gonadotrophin secretion are primarily at the level of the hypothalamo-pituitary complex.

Alterations in pituitary gland sensitivity in ram lambs to physiological doses of gonadotrophin-releasing hormone (GnRH), after divergent selection based on the luteinizing hormone response to a pharmacological GnRH challenge.

Divergent selection in 10-week-old Finn-Dorset ram lambs was based on the luteinizing hormone (LH) response to a pharmacological dose of GnRH (5 micrograms). After eight generations of selection, the LH responses of the two lines (low and high) to GnRH differed by a factor of five. This study investigates the pituitary sensitivity of the two lines to exogenous GnRH. Initially, two pilot studies were performed: one to determine the range of doses of GnRH which would stimulate LH pulses of similar amplitude to those seen endogenously, and the other to confirm that sodium pentobarbitone prevents pulsatile LH secretion in prepubertal ram lambs. The results indicated that barbiturate anaesthesia suppressed pulsatile LH secretion in castrated and intact ram lambs. A model system was therefore constructed in 18 10-week-old intact ram lambs (high n = 7, low n = 11), whereby endogenous pulsatile LH secretion was prevented by sodium pentobarbitone anaesthesia and the amplitudes of LH pulses produced in response to different doses of exogenous GnRH could be measured. The GnRH dose-response curves demonstrated that there was a five-fold difference in the sensitivity of the pituitary glands of the two lines to stimulation with GnRH. The projected minimum concentration of GnRH required to produce a measurable pulse of LH was 4.75 ng for the high-line animals and 26.6 ng for the low-line animals. The results indicated that the low-line animals required five times more GnRH than the high-line lambs to stimulate LH pulses of similar amplitude (high line 43.67 ng; low line 206.55 ng). These results demonstrate that selection has produced two lines of sheep which differ in the control of LH secretion at the level of the hypothalamus-pituitary gland.

Gonadotrophin-releasing hormone modulation of gonadotrophins in the ewe: evidence for differential effects on gene expression and hormone secretion.

While the regulation of gonadotrophin secretion by gonadotrophin-releasing hormone (GnRH) has been well documented in both rats and sheep, its role in the synthesis of gonadotrophin subunits remains unclear. We have investigated the effects of the specific inhibition of GnRH by a GnRH agonist on the expression of gonadotrophin subunit genes and the subsequent storage and release of both intact hormones and free alpha subunit. Treatment with GnRH agonist for 6 weeks abolished pulsatile LH secretion, reduced plasma concentrations of FSH and prevented GnRH-induced release of LH and FSH. This was associated with a reduction of pituitary LH-beta mRNA and FSH-beta mRNA levels (to 5 and 30% of luteal control values respectively), but not alpha mRNA which was significantly increased (75% above controls). While there was a small decrease in the pituitary content of FSH (30% of controls), there was a drastic reduction in LH pituitary content (3% of controls). In contrast to the observed rise in alpha mRNA, there was a decrease in free alpha subunit in both the pituitary and plasma (to 30 and 80% of control levels). These results suggest that, while GnRH positively regulates the expression of both gonadotrophin beta-subunit genes, it can, under certain circumstances, negatively regulate alpha-subunit gene expression. Despite the complete absence of LH and FSH in response to GnRH, there remained a basal level of beta-subunit gene expression and only a modest reduction (50%) in the plasma levels of both FSH and LH, suggesting that there is a basal secretory pathway.(ABSTRACT TRUNCATED AT 250 WORDS)