Exercise and insulin resistance in PCOS: muscle insulin signalling and fibrosis.

OBJECTIVE: Mechanisms of insulin resistance in polycystic ovary syndrome (PCOS) remain ill defined, contributing to sub-optimal therapies. Recognising skeletal muscle plays a key role in glucose homeostasis we investigated early insulin signalling, its association with aberrant transforming growth factor ß (TGFß)-regulated tissue fibrosis. We also explored the impact of aerobic exercise on these molecular pathways. METHODS: A secondary analysis from a cross-sectional study was undertaken in women with (n = 30) or without (n = 29) PCOS across lean and overweight BMIs. A subset of participants with (n = 8) or without (n = 8) PCOS who were overweight completed 12 weeks of aerobic exercise training. Muscle was sampled before and 30 min into a euglycaemic-hyperinsulinaemic clamp pre and post training. RESULTS: We found reduced signalling in PCOS of mechanistic target of rapamycin (mTOR). Exercise training augmented but did not completely rescue this signalling defect in women with PCOS. Genes in the TGFß signalling network were upregulated in skeletal muscle in the overweight women with PCOS but were unresponsive to exercise training except for genes encoding LOX, collagen 1 and 3. CONCLUSIONS: We provide new insights into defects in early insulin signalling, tissue fibrosis, and hyperandrogenism in PCOS-specific insulin resistance in lean and overweight women. PCOS-specific insulin signalling defects were isolated to mTOR, while gene expression implicated TGFß ligand regulating a fibrosis in the PCOS-obesity synergy in insulin resistance and altered responses to exercise. Interestingly, there was little evidence for hyperandrogenism as a mechanism for insulin resistance.

Testosterone modulates cardiomyocyte Ca(2+) handling and contractile function.

The extent to which sex differences in cardiac function may be attributed to the direct myocardial influence of testosterone is unclear. In this study the effects of gonadal testosterone withdrawal (GDX) and replacement (GDX+T) in rats, on cardiomyocyte shortening and intracellular Ca(2+) handling was investigated (0.5 Hz, 25 oC). At all extracellular [Ca(2+)] tested (0.5-2.0 mM), the Ca(2+) transient amplitude was significantly reduced (by approximately 50 %) in myocytes of GDX rats two weeks post-gonadectomy. The time course of Ca(2+) transient decay was significantly prolonged in GDX myocytes (tau, 455+/-80 ms) compared with intact (279+/-23 ms) and GDX+T (277+/-19 ms). Maximum shortening of GDX myocytes was markedly reduced (by more than 60 %) and relaxation significantly delayed (by more than 35 %) compared with intact and GDX+T groups. Thus testosterone replacement completely reversed the cardiomyocyte hypocontractility induced by gonadectomy. These results provide direct evidence for a role of testosterone in regulating functional Ca(2+) handling and contractility in the heart.

Role of sex and sex steroids in mediating pituitary-adrenal responses to acute buspirone treatment in sheep.

Systematic characterisation of sex differences in the serotonergic modulation of the hypothalamic-pituitary-adrenal (HPA) axis may assist with our understanding of why stress-related disorders are disproportionately represented in women. In this study, we examined the acute effects of buspirone, a serotonergic 1A receptor subtype agonist, on the endocrine endpoints of adrenocorticotrophin (ACTH) and cortisol secretion in gonadectomised male and female sheep. Each sheep was treated with an acute i.v. injection containing vehicle or buspirone (0.03, 0.1 and 0.3 mg/kg) in the presence and absence of sex steroid replacement (SSR). In males, SSR treatment consisted of testosterone (2 x 200 mg s.c. pellets) and, in females, the mid-luteal phase of the oestrus cycle was simulated by treatment with oestradiol (1 cm s.c. implant) and an intravaginal controlled internal drug release device containing 0.3 g progesterone. ACTH, cortisol, testosterone and progesterone were measured in jugular blood. Basal ACTH levels were higher in males, whereas basal cortisol levels were higher in females, regardless of sex steroid status. The magnitude of the increase in ACTH and cortisol secretion following buspirone treatment was dose-dependent. There were no differences in the ACTH responses of males and females to buspirone treatment, either in the presence or absence of sex steroid replacement. However, although the cortisol response to buspirone was greater in females, there was no discernable effect of sex steroid status in addition to this sex difference on either basal or buspirone-stimulated cortisol release. We conclude that the larger basal and buspirone-stimulated cortisol response measured in females may reflect a sex difference, either in the sensitivity of the adrenal gland to ACTH or in the catecholaminergic innervation of the adrenal gland. The lack of effect of sex and sex steroids in the ACTH secretory response to buspirone may indicate that the sex differences in serotonergic modulation of the HPA axis, as reported previously by our group, were mediated via serotonergic receptor subtypes other than the 1A receptor.

Testosterone regulates gonadotropin-releasing hormone-induced calcium signals in male rat gonadotrophs.

As the GnRH-induced secretion of gonadotropins is critically dependent upon an increase in the intracellular calcium ion concentration ([Ca2+]i) and modulated by gonadal factors, the effects of gonadal steroids on the pattern of calcium mobilization in single gonadotrophs of the male rat were examined using the fluorescent Ca2+ indicator fura-2/AM. In cells from intact rats, low concentrations of GnRH induce repetitive oscillations in [Ca2+]i, whereas spike-plateau responses are observed at higher concentrations in single gonadotrophs. After castration, there was a significant change in the relationship between the GnRH concentration and the changes in [Ca2+]i. Increasing concentrations of GnRH (to 1 micron) generate fewer spike-plateau responses in gonadotrophs from castrate rats, with oscillatory responses predominating. This change develops with time after castration, with the proportion of cells oscillating in response to 100 nM GnRH peaking by 7 days. This effect of castration on GnRH-induced [Ca2+]i signals was reversed by treatment with testosterone propionate (100 microgram/100 g BW-day). Castration-induced decreases in serum testosterone, seminal vesicle, and prostate weights and increases in serum LH concentration were also corrected by testosterone propionate treatment. These findings demonstrate that testosterone regulates GnRH-stimulated Ca2+ signals in gonadotrophs and suggest that gonadal steroids exert a regulatory role in the secretion of gonadotropins at the level of Ca2+ mobilization.

The regulation of gonadotropin-releasing hormone-induced calcium signals in male rat gonadotrophs by testosterone is mediated by dihydrotestosterone.

The biological effects of testosterone (T) may be mediated directly by T or indirectly by its metabolites, dihydrotestosterone (DHT) and estradiol. The present study examined whether the metabolism of T is involved in the regulation of GnRH-induced Ca2+ signaling at the pituitary. In gonadotrophs from castrated rats, a significantly greater percentage of gonadotrophs demonstrated oscillatory Ca2+ responses to 100 nM GnRH than cells from intact rats (72% vs. 24%; P < 0.05). This increase was prevented by the administration of T propionate (0.1 mg/kg x day), DHT benzoate (2 mg/kg x day,), estradiol benzoate (EB; 5 microg/kg x day), or the combination of the above doses of DHT benzoate and EB. In all cases the proportion of gonadotrophs from the steroid-treated rats having oscillatory Ca2+ responses to 100 nM GnRH was between 21-25% (P > 0.05, compared with intact rats). To assess the importance of T metabolism, intact male rats were treated with the aromatase inhibitor letrozole (1 mg/kg x day), the 5alpha-reductase inhibitor finasteride (50 mg/kg x day), or their respective vehicles for 7 days. Letrozole had no effect on GnRH-induced Ca2+ signals, serum LH concentrations, or ventral prostate or testes weight. Finasteride treatment, however, mimicked the effects of castration, with significantly more gonadotrophs exhibiting Ca2+ oscillations in response to 100 nM GnRH than gonadotrophs from the vehicle-treated group (71% vs. 20% respectively; P < 0.05). Finasteride also caused a significant (P < 0.05) decrease in prostatic weight and DHT concentration, but had no significant effect on either prostatic T or serum LH concentrations. These findings suggest that in the intact male rat, the effects of T on GnRH-induced Ca2+ signaling are preferentially mediated via DHT. The results of this study also show that in the absence of androgens, estradiol may regulate GnRH-induced Ca2+ signaling in the male rat pituitary.

Pituitary adenylate cyclase-activating polypeptide regulates cytosolic Ca2+ in rat gonadotropes and somatotropes through different intracellular mechanisms.

The hypothalamic factor pituitary adenylate cyclase-activating polypeptide (PACAP) stimulates an increase in the cytoplasmic free Ca2+ ion concentration ([Ca2+]i) in GH-secreting somatotropes and LH-secreting gonadotropes of the rat anterior pituitary gland. The dynamics of the PACAP-induced Ca2+ responses and their dependence on extracellular Ca2+ are markedly different in the two cell types, suggesting separate mechanisms of action of PACAP in somatotropes and gonadotropes. The present study reports a full characterization of the Ca2+ responses seen in the two cell types over a wide range of PACAP concentrations. In addition, the involvement of the cAMP-dependent protein kinase (PKA) system in the mediation of PACAP-stimulated Ca2+ was tested using the R-isomer of cAMP (RpcAMPs) as a specific inhibitor of PKA. In identified somatotropes, PACAP (10(-11)-10(-6) M) stimulated Ca2+ responses in 49% of the cells tested, with two types of Ca2+ response profile observed. The first was a slow rise in [Ca2+]i to a new level (Ca2+ step; 28% of somatotropes); the second was characterized by repetitive transient rises in [Ca2+]i (Ca2+ transients; 21% of somatotropes). The range of PACAP concentrations tested (10(-11)-10(-6) M) did not markedly alter the number of cells responding or the type of response observed. In some gonadotropes, PACAP stimulated Ca2+ step responses similar to those seen in somatotropes; however, the most common response observed was a rapid, high amplitude, but transient spike of [Ca2+]i, which was often accompanied by rapid oscillations in [Ca2+]i. This response profile was termed a Ca2+ spike-oscillations response, and the proportion of cells exhibiting this response increased from 25% at a PACAP concentration of 10(-11) M to 73% at 10(-6) M PACAP. PACAP-induced Ca2+ responses in somatotropes were blocked by pretreatment with the cAMP antagonist RpcAMPs (10(-3) M). In addition, other factors known to increase cAMP in somatotropes (GH-releasing factor and 8-bromo-cAMP) stimulated Ca2+ responses in these cells that were qualitatively similar to those induced by PACAP. In contrast, the Ca2+ responses in gonadotropes were insensitive to the cAMP antagonist RpcAMPs, and the membrane-permeable cAMP analog 8-bromo-cAMP failed to stimulate responses in this cell type. These results suggest that the intracellular mechanisms of PACAP action in the two cell types are markedly different. In somatotropes, the rise in [Ca2+]i stimulated by PACAP is probably through the production of cAMP and the activation of protein kinase-A.(ABSTRACT TRUNCATED AT 400 WORDS)

Paracrine communication regulates adrenocorticotropin secretion.

Local communication among cells of the anterior pituitary appears to play an important role in the regulation of ACTH secretion. Dissociated pituitary cells were plated as a monolayer at decreasing concentrations of cells (increasing the distance between cells and, thus, decreasing their potential interactions), and ACTH secretion was measured from individual corticotropes using a specific reverse hemolytic plaque assay. There was a critical intercell distance above which significant changes in the number of CRF-responsive corticotropes were observed. Provided that this critical distance was not exceeded the number of secretory corticotropes in response to CRF (10 nM) was relatively constant, thereby defining a fraction of corticotropes that was robustly CRF responsive. In contrast, when this critical distance between cells was exceeded, the number of CRF-responsive corticotropes progressively increased to almost double their original number, thereby defining a second fraction of CRF-responsive corticotropes that was previously repressed. These observations suggest the presence of a paracrine factor that profoundly inhibits CRF-stimulated ACTH secretion from a repressed fraction of corticotropes. Further independent studies confirmed and extended these observations. We identified the cellular source of the inhibitory factor as the robustly CRF-responsive fraction of corticotropes. Pituitary cells were identified by reverse hemolytic plaque assay and then destroyed using a laser photoablation procedure that did not compromise the remaining cells. The pituitary cells were separated by a distance at which the inhibitory factor was fully effective. Destruction of the cellular source of the paracrine inhibition would, therefore, allow secretion from the previously repressed fraction of corticotropes. Accordingly, when robustly CRF-responsive corticotropes were destroyed, a significant number of previously repressed corticotropes appeared in a second assay. Destruction of somatotropes or a cell adjacent to a robustly CRF-responsive corticotrope did not alter the number of CRF-stimulated corticotropes among the remaining cells. We conclude that a paracrine factor liberated by the robustly CRF-responsive corticotropes inhibits ACTH secretion from the repressed fraction of corticotropes. The robustly CRF-responsive corticotropes appear unresponsive to the effects of the factor, and the repressed corticotropes are unlikely to secrete it. A role of this paracrine communication is to hold corticotropes in reserve and, therefore, prevent the severe depletion of hormone. This form of paracrine communication may be a specialized adaption among cells where the physiological setting demands robust secretory responses to multiple stimuli. The experimental paradigms developed here may be extremely useful for 1) screening potential paracrine factors and 2) determining whether the secretion of the paracrine factor is regulated by adrenal or hypothalamic hormones.

Pituitary adenylate cyclase-activating polypeptide specifically increases cytosolic calcium ion concentration in rat gonadotropes and somatotropes.

The hypothalamic peptide, pituitary adenylate cyclase-activating polypeptide (PACAP), is a potent stimulator of cAMP accumulation in the anterior pituitary gland, though its physiological function has yet to be defined. To establish the target cells of PACAP action we have measured PACAP-induced changes in cytosolic free calcium ion concentration ([Ca2+]i) in single identified anterior pituitary cells. This was achieved by combining fura-2 videomicroscopy, to measure [Ca2+]i, and reverse hemolytic plaque assays, to identify the secreted hormone. PACAP (100 nM) increased [Ca2+]i in 32% of all pituitary cells. These responses were predominantly seen in identified gonadotropes and somatotropes, but rarely in corticotropes or lactotropes. PACAP induced two forms of Ca2+ response in gonadotropes; a "Ca2+ spike" (independent of extracellular Ca2+) in 72% of responding gonadotropes, and an extracellular Ca(2+)-dependent "Ca2+ plateau" (28% of cells). In somatotropes, PACAP stimulated either Ca2+ plateau responses (58% of responding somatotropes) or repetitive "Ca2+ transients" (42% of cells), both of which were dependent upon extracellular Ca2+. PACAP, therefore, produces distinct changes in [Ca2+]i in gonadotropes and somatotropes, which may be related to distinct intracellular messenger pathways. The identification of these cell types as targets of PACAP action suggests a role in the regulation of reproduction and growth.

Glucocorticoids regulate ovine hypophysial portal levels of corticotropin-releasing factor and arginine vasopressin in a stress-specific manner.

Hypophysial portal circulation levels of immunoreactive (ir) CRF, immunoreactive arginine vasopressin (ir-AVP), and systemic ir-ACTH and cortisol were determined in dexamethasone-infused (20 micrograms/h) ewes, both under basal conditions and in response to audiovisual and hypoglycemic stress. Glucocorticoid infusion lowered mean basal levels of ir-CRF (P less than 0.05), ir-ACTH (P less than 0.05), and cortisol (P less than 0.05), but not of ir-AVP. Audiovisual stress led to coordinate release of ir-AVP and ir-CRF, and although the hypothalamic response to this stress was not altered in dexamethasone (DEX)-infused sheep, the pituitary-adrenal response was blocked, suggesting that glucocorticoids act on the pituitary rather than on higher centers to inhibit this response. In contrast, hypoglycemia led to preferential release of ir-AVP over ir-CRF, and DEX infusion delayed and inhibited both hypothalamic and pituitary responses. Ketamine injection also led to preferential release of ir-AVP, but neither the hypothalamic nor pituitary-adrenal responses were affected by DEX infusion. These results suggest that different stressors evoke different patterns of hypothalamic secretagogue release, and that glucocorticoids act in a site-specific fashion to regulate the hypothalamo-pituitary-adrenal responses to stress.

Testosterone acts directly at the pituitary to regulate gonadotropin-releasing hormone-induced calcium signals in male rat gonadotropes.

We have recently shown that castration alters GnRH-induced calcium (Ca2+) signaling in the gonadotropes of male rats. Instead of generating spike-plateau Ca2+ responses to high concentrations of GnRH (100 nM), the majority of gonadotropes from castrated rats have oscillatory Ca2+ responses, which are generally only seen with low concentrations of GnRH in the gonadotropes of intact rats. This change in the nature of GnRH-induced Ca2+ responses is prevented by in vivo testosterone treatment. The aims of the present study were, therefore, to determine if testosterone acts directly at the pituitary or via the regulation of hypothalamic GnRH secretion. Accordingly, castrated male rats were treated with a GnRH antagonist to ablate the effects of increased GnRH secretion at the pituitary gland. GnRH antagonist treatment (10 microg/100 g BW, twice daily for 7 days from the time of castration) decreased the concentration of LH in the serum of castrated rats (0.4 +/- 0.1 ng/ml vs. 11.2 +/- 0.4 ng/ml in untreated castrated rats, mean +/- SEM) but had no effect on the proportion of gonadotropes having oscillatory Ca2+ responses to 100 nM GnRH when compared with untreated castrated rats (63% in antagonist-treated castrated rats vs. 70% in untreated castrated rats). The GnRH antagonist treatment did not, however, interfere with the ability of in vivo testosterone treatment (100 microg/100 g body weight/day) to decrease the proportion of gonadotropes having oscillatory Ca2+ responses to 100 nM GnRH (26% in testosterone-treated rats vs. 25% in testosterone and antagonist-treated rats). These findings indicate that testosterone acts directly at the pituitary, and not by altered GnRH secretion, to modulate GnRH-induced Ca2+ signals. To confirm this suggestion, cultured gonadotropes of castrated male rats were treated in vitro with 10 nM testosterone. Testosterone treatment for twelve, but not 4 h, restored the proportion of gonadotropes having oscillatory Ca2+ responses to that seen in gonadotropes from intact rats. The in vitro effects of testosterone over 12 h were prevented by concomitant treatment with the protein synthesis inhibitor cycloheximide (10 microM), which, when given alone, had no effect on GnRH-induced Ca2+ signals in cells from castrate male rats. Taken together, these findings suggest that testosterone has a direct genomic action at the pituitary to regulate GnRH-induced Ca2+ signals, via a process that involves new protein synthesis.

Hypothalamo-pituitary disconnection of the late-gestation ovine fetus results in profound changes in cortisol secretion that are not reflected in commensurate changes in adrenocorticotropin secretion.

A prepartum increase in fetal glucocorticoid concentrations is essential for the perinatal transition to extrauterine life for many mammalian species. In the case of the sheep, this increase in cortisol is also the trigger for parturition, and depends upon an intact hypothalamo-pituitary unit. Fetal sheep that have undergone hypothalamo-pituitary disconnection (HPD) fail to have a prepartum cortisol surge or initiate labor, despite apparently normal fetal ACTH concentrations in late gestation. We have investigated whether a defect exists in the regulation of pulsatile neurohormone secretion in the pituitaryadrenal axis of the HPD sheep fetus, by comparing immunoreactive (ir) ACTH and cortisol secretory dynamics in intact and HPD fetuses at 126 and 145 days of gestation (normal gestation length, 147 days). The fetal surgery was conducted at 115 days of gestation. Blood samples were collected at 5-min intervals for 2 h on each experimental day, and the resulting irACTH and cortisol concentrations were analyzed by multiple-parameter deconvolution and cross-correlation analysis. Basal irACTH secretion was less (P < 0.01) in HPD fetuses than intact fetuses at 126 days, but it had recovered by 145 days. There were no differences in irACTH half-life or the number or duration of irACTH secretory bursts between the two groups of fetuses or the two gestational ages (GAs). The size of the irACTH secretory bursts was not affected by the operation, but it increased with GA to a similar extent in both groups of fetuses (P < 0.01). In keeping with the observations for irACTH secretion, there was no effect of age or the operation on cortisol half-life or on the number or duration of cortisol secretory bursts. In contrast, there were dramatic age-related increases (P < 0.01) in the basal cortisol secretion rate and the size of the cortisol secretory bursts in the intact, but not the HPD, fetuses. Cross-correlation analysis revealed a significant (P < 0.01) concordance between irACTH and cortisol secretion in only the intact fetuses at 126 days; this was not apparent in the intact fetuses at 145 days, or in the young or old HPD fetuses. These findings confirm a major defect in cortisol secretion in the late-gestation HPD fetus but suggest that this is not caused by defects in irACTH secretion. Together with other observations, these data suggest that ACTH may not be the sole, or primary, regulator of adrenal cortisol secretion in the late-gestation ovine fetus.

Pituitary adenylate cyclase activating polypeptide, growth hormone (GH)-releasing peptide and GH-releasing hormone stimulate GH release through distinct pituitary receptors.

GH secretion has been thought traditionally to be regulated by the two hypothalamic hormones, GH-releasing hormone (GHRH) and somatostatin (SRIF). Recent evidence has suggested that other factors may be involved. These factors include the natural ligand for the synthetic hexapeptide GH-releasing peptide (GHRP) and the putative hypophysiotropic factor pituitary adenylate cyclase-activating polypeptide (PA-CAP). Accordingly, we examined the effects of GHRP and PACAP on GH secretion at the single cell level using the reverse hemolytic plaque assay which allows distinction of effects on the number of secreting cells and the amount of hormone each cell secretes. Both factors stimulated GH secretion in a dose-dependent fashion, with PACAP being more effective. PACAP increased both the number of cells secreting and the mean amount of hormone secreted per cell. In contrast, GHRP increased the number of secreting cells, although it had no effect on the amount of secretion per cell. GH secretion induced by GHRH, GHRP, and PACAP was inhibited by SRIF, but the effect was predominantly on the number of cells secreting rather than the amount secreted per cell. Specific antagonists to GHRP and GHRH inhibited GH secretion induced by the respective agonist but not that induced by the other factor nor by PACAP. These findings confirm the complex nature of the regulation of GH secretion at the level of the somatotrope. At least three factors, operating via distinct receptors, are able to increase GH secretion. In addition, they ascribe a potential physiological role for the hitherto putative hypophysiotropic factor PACAP.

Concomitant dopaminergic and glucocorticoid control of pituitary proopiomelanocortin messenger ribonucleic acid and beta-endorphin levels.

Synthesis and secretion of POMC-derived peptides appear to be differentially regulated in the anterior pituitary (AP) and neurointermediate lobe (NIL). In the AP, glucocorticoids inhibit, and CRF and arginine vasopressin stimulate, synthesis of POMC and release of immunoreactive (ir)-beta-endorphin (beta EP); in the NIL, synthesis and release of POMC and its derivatives are under tonic inhibitory dopaminergic control. There is, however, evidence for some overlap of these control mechanisms under certain circumstances. In the present study we have used specific RIA and Northern blot analysis to examine the effects of chronic treatment with dopaminergic agents and dexamethasone (DM) (both alone and in combination) on AP and NIL content of ir-beta EP and POMC messenger RNA (mRNA), and/or hypothalamic ir-arginine vasopressin and ir-CRF content. In the NIL, the dopamine agonist bromocriptine reduced and the antagonist haloperidol raised both POMC mRNA and ir-beta EP content. Long term DM treatment did not alter NIL ir-beta EP content in the intact rat, but increased levels of POMC mRNA. DM abolished the haloperidol-induced increase in NIL ir-beta EP content but further increased the haloperidol-induced rise in POMC mRNA. DM treatment lowered both ir-beta EP and POMC mRNA in the AP as well as lowering levels of hypothalamic ir-CRF. In DM-treated rats, haloperidol partially restored AP ir-beta EP and POMC mRNA to control untreated levels. These findings further support the proposition that both dopaminergic agents and glucocorticoids can modulate POMC mRNA levels and/or tissue content of ir-beta EP in both the NIL and AP of the rat. The effects of DM on the NIL, both alone or with haloperidol, suggest that glucocorticoids may have both direct and indirect effects on POMC gene expression in this tissue.

Arginine vasopressin and corticotropin releasing factor: binding to ovine anterior pituitary membranes.

In the sheep, in contrast to the rat, arginine vasopressin (AVP) is a more potent stimulus to ACTH secretion from the anterior pituitary (AP) than CRF. To further explore this difference, we have compared [3H]AVP and [125I]-[Nle21 Tyr32]ovine CRF binding in membranes prepared from rat and sheep AP. Between species, no difference in affinity of binding was found for either ligand. In contrast, the concentration of AVP receptors in sheep AP was twice that in rat, whereas that of CRF receptors was only one tenth. AVP receptor concentration in sheep AP was not altered by chronic (10 day) dexamethasone administration, but fell to 60% of control after chronic (60 day) hypothalamo-pituitary-disconnection. The increased level of AVP receptors and the much lower level of CRF receptors in sheep compared with rat may thus provide an explanation for our previous findings of increased sensitivity to AVP and a very poor response to CRF in stimulating ACTH release from the sheep AP. In addition the finding that AVP receptor numbers are reduced in the hypothalamo-pituitary-disconnected sheep suggests that hypothalamic factors may play a role in regulating AVP receptor concentration in the ovine AP gland.

Distinct classes of corticotropes mediate corticotropin-releasing hormone- and arginine vasopressin-stimulated adrenocorticotropin release.

ACTH release from the anterior pituitary gland is principally driven by the two hypothalamic hormones, corticotropin-releasing hormone (CRH) and arginine vasopressin (AVP). Using the reverse hemolytic plaque assay, we have compared the effects of CRH and AVP on ACTH release from individual, dispersed pituitary cells. A small percent (0.36 +/- 0.06%) of pituitary cells formed plaques when exposed to medium alone. AVP caused 3.44 +/- 0.10% of cells to form plaques (P less than 0.01 compared with medium alone), CRH produced 4.85 +/- 0.20% plaque-forming cells (P less than 0.01 compared with AVP), and the combination of CRH and AVP produced a still greater percent of plaque-forming cells (5.80 +/- 0.20%, P less than 0.01 compared with CRH alone). A double reverse hemolytic plaque assay was then employed to examine whether some cells formed plaques only in the presence of one or other secretagogue. Using this technique we found clear evidence of cells that formed plaques in response to CRH but not AVP (P less than 0.005); CRH or AVP (P less than 0.0001), and CRH and AVP (P less than 0.05). There was no evidence of a corticotrope forming a plaque with AVP but not CRH (P = 0.52). Thus there appears to be functionally distinct classes of corticotropes. These findings have important implications for our understanding of the relative responsiveness of the pituitary to hypothalamic secretagogues and provide a new physiological perspective on recent reports of stress-specific hypothalamic responses regulating ACTH release.

The posterior pituitary regulates prolactin, but not adrenocorticotropin or gonadotropin, secretion in the sheep.

The aim of this study was to determine the role of the posterior pituitary gland in the control of PRL, LH, FSH, and ACTH secretion in sheep. Posterior pituitary function was removed in ovariectomized ewes by electrical lesioning of the hypothalamo-neurohypophysial tract immediately posterior to the stalk-median eminence (LESION); controls were subjected to sham surgery (SHAM). LESION caused a 2-fold increase in plasma PRL concentrations on days 1-3 after surgery. Thereafter, concentrations gradually declined until they were similar to those in SHAM ewes. There was no change in plasma concentrations of LH, FSH, or ACTH after LESION. Plasma PRL responses to insulin in SHAM ewes were completely abolished, and the plasma PRL response to chlorpromazine was reduced to almost half by LESION. In contrast, audiovisual stress (barking dog) and serotonin challenge caused an immediate release of PRL in both LESION and SHAM ewes, with the amplitude of the responses indistinguishable between groups. LESION had no effect on the plasma ACTH responses to audiovisual stress, insulin, or serotonin. We conclude that the posterior pituitary gland is involved in the regulation of PRL under some circumstances, but not of LH, FSH, or ACTH secretion in the sheep. Accordingly, changes in PRL release after hypothalamopituitary disconnection in this species may reflect a loss of posterior lobe function rather than the removal of hypothalamic inputs. In addition, the PRL response to insulin is dependent on a functional posterior pituitary gland, whereas responses to audiovisual stress and serotonin appear to rely on inputs to the pituitary gland via the median eminence and the long hypothalamo-hypophysial portal blood vessels.

Central administration of leptin to ovariectomized ewes inhibits food intake without affecting the secretion of hormones from the pituitary gland: evidence for a dissociation of effects on appetite and neuroendocrine function.

We have studied the effect of leptin on food intake and neuroendocrine function in ovariectomized ewes. Groups (n = 5) received intracerebroventricular infusions of either vehicle or leptin (20 microg/h) for 3 days and were blood sampled over 6 h on days -1, 2, and for 3 h on day 3 relative to the onset of the infusion. The animals were then killed to measure hypothalamic neuropeptide Y expression by in situ hybridization. Plasma samples were assayed for metabolic parameters and pituitary hormones. Food intake was reduced by leptin, but did not change in controls. Leptin treatment elevated plasma lactate and nonesterified fatty acids, but did not affect glucose or insulin levels, indicating a state of negative energy balance that was met by the mobilization of body stores. Pulse analysis showed that the secretion of LH and GH was not affected by leptin treatment, nor were the mean plasma concentrations of FSH, PRL, or cortisol. Expression of messenger RNA for neuropeptide Y in the arcuate nucleus was reduced by the infusion of leptin, primarily due to reduced expression per cell rather than a reduction in the number of cells observed. Thus, the action of leptin to inhibit food intake is dissociated from neuroendocrine function. These results suggest that the metabolic effects of leptin are mediated via neuronal systems that possess leptin receptors rather than via endocrine effects.

The influence of sex and gonadectomy on the hypothalamo-pituitary-adrenal axis of the sheep.

There is a sex difference in the hypothalamo-pituitary-adrenal (HPA) axis of many species, although there are sparse data on the sheep. In the present study we have compared the HPA axes of intact and gonadectomised adult male and female sheep at the level of the median eminence, pituitary and adrenal glands using a variety of in vitro approaches. The concentration of arginine vasopressin (AVP) was higher (P<0.01) in the median eminence of male than female sheep, and was also elevated by gonadectomy of either sex (P<0.01). The concentration of corticotrophin-releasing factor (CRF) in the median eminence did not differ between the sexes, but was also elevated in both sexes following gonadectomy (P<0.01). Anterior pituitary pro-opiomelanocortin mRNA concentrations were higher (P<0.05) in intact male sheep than in intact females, with the levels in gonadectomised animals of both sexes being intermediate. In contrast to this finding, basal ACTH secretion from anterior pituitary cells was higher (P<0.05) in cultures derived from female sheep than those from males, but gonadectomy was without effect. There was no effect of sex or gonadectomy on in vitro ACTH secretion in response to AVP, CRF or the combination of AVP and CRF, and in all cases the combination of AVP and CRF generated greater (P<0.0001) ACTH secretion than AVP alone. AVP alone was more effective (P<0.01) than CRF alone as an ACTH secretagogue. The adrenal glands were larger (P<0.05) in female than male sheep, with no effect of gonadectomy. Basal cortisol production was greatest (P<0.05) in cultures of adrenal cells from intact male sheep, though ACTH- and 8BrcAMP-induced cortisol production was greater in the cultures of cells from females (P=0.05); there were no effects of gonadectomy. Cultures of adrenocortical cells from male sheep had greater (P<0.05) basal cAMP production, but ACTH-stimulated cAMP production did not differ between any of the groups of animals. These findings show a range of differences in the HPA axis of male and female sheep. Furthermore, they suggest that the heightened activity of the axis in the female occurs primarily due to differences at the level of the adrenal gland, and that greater adrenal responsiveness of female animals is due to differences in the latter stages of steroidogenesis, rather than an effect on ACTH signal transduction at its receptor.

Central administration of corticotrophin releasing hormone but not arginine vasopressin stimulates the secretion of luteinizing hormone in rams in the presence and absence of testosterone.

This study tested the hypothesis that central administration of corticotrophin-releasing hormone (CRH) and/or arginine vasopressin (AVP) will affect the secretion of LH in rams and that testosterone is necessary for these actions to occur. Plasma LH levels were measured in castrated rams during 1 h infusion of either 100 microliter vehicle/mock cerebrospinal fluid (CSF) or mock CSF containing 25 microgram CRH, 25 microgram AVP or 25 microgram of each peptide through guide cannulae into the third cerebral ventricle. These intracerebroventricular (i.c.v.) infusions were given to the castrated rams following injections (i.m.) each 12 h of oil or 8 mg testosterone propionate for 7 days. Blood samples were collected every 10 min for 4 h before i.c.v. infusion, during infusion and for 4 h following the infusion. Infusion of vehicle did not affect any endocrine parameters. In contrast, the plasma concentrations of LH and the amplitude of LH pulses were increased significantly during and following infusion of CRH, and this effect was not influenced by whether the castrated rams were treated with testosterone propionate or whether the CRH was administered in combination with AVP. Infusion of AVP alone did not affect LH secretion. The frequency of LH pulses and the plasma concentrations of FSH did not change with any of the i.c.v. treatments. The plasma concentrations of cortisol were significantly increased by CRH and AVP infusions. The plasma concentrations of cortisol achieved during and following i.c.v. infusion of CRH and AVP combined were greater than the concentrations achieved as a result of treatment with AVP alone but were similar to those with CRH. There was no effect of testosterone propionate on cortisol levels. These results show that CRH, but not AVP, is capable of acting either centrally or at the pituitary level to increase the secretion of LH in rams and these actions are not affected by testosterone. The stimulatory effects of CRH on LH secretion are to increase the amplitude of GnRH pulses and/or the responsiveness of the pituitary to the actions of GnRH with no effect on the frequency of GnRH pulses. The secretion of FSH in rams is not influenced by either CRH or AVP. The effect of CRH to increase LH pulse amplitude occurs in the face of increased cortisol levels, further reinforcing our belief that this adrenal steroid does not affect the reproductive axis in this species.

Suppression of the secretion of luteinizing hormone due to isolation/restraint stress in gonadectomised rams and ewes is influenced by sex steroids.

In this study we used an isolation/restraint stress to test the hypothesis that stress will affect the secretion of LH differently in gonadectomised rams and ewes treated with different combinations of sex steroids. Romney Marsh sheep were gonadectomised two weeks prior to these experiments. In the first experiment male and female sheep were treated with vehicle or different sex steroids for 7 days prior to the application of the isolation/restraint stress. Male sheep received either i.m. oil (control rams) or 6 mg testosterone propionate injections every 12 h. Female sheep were given empty s.c. implants (control ewes), or 2x1 cm s.c. implants containing oestradiol, or an intravaginal controlled internal drug release device containing 0.3 g progesterone, or the combination of oestradiol and progesterone. There were four animals in each group. On the day of application of the isolation/restraint stress, blood samples were collected every 10 min for 16 h for the subsequent measurement of plasma LH and cortisol concentrations. After 8 h the stress was applied for 4 h. Two weeks later, blood samples were collected for a further 16 h from the control rams and ewes, but on this day no stress was imposed. In the second experiment, separate control gonadectomised rams and ewes (n=4/group) were studied for 7 h on 3 consecutive days, when separate treatments were applied. On day 1, the animals received no treatment; on day 2, isolation/restraint stress was applied after 3 h; and on day 3, an i. v. injection of 2 microg/kg ACTH1-24 was given after 3 h. On each day, blood samples were collected every 10 min and the LH response to the i.v. injection of 500 ng GnRH administered after 5 h of sampling was measured. In Experiment 1, the secretion of LH was suppressed during isolation/restraint in all groups but the parameters of LH secretion (LH pulse frequency and amplitude) that were affected varied between groups. In control rams, LH pulse amplitude, and not frequency, was decreased during isolation/restraint whereas in rams treated with testosterone propionate the stressor reduced pulse frequency and not amplitude. In control ewes, isolation/restraint decreased LH pulse frequency but not amplitude. Isolation/restraint reduced both LH pulse frequency and amplitude in ewes treated with oestradiol, LH pulse frequency in ewes treated with progesterone and only LH pulse amplitude in ewes treated with both oestradiol and progesterone. There was no change in LH secretion during the day of no stress. Plasma concentrations of cortisol were higher during isolation/restraint than on the day of no stress. On the day of isolation/restraint maximal concentrations of cortisol were observed during the application of the stressor but there were no differences between groups in the magnitude of this response. In Experiment 2, isolation/restraint reduced the LH response to GnRH in rams but not ewes and ACTH reduced the LH response to GnRH both in rams and ewes. Our results show that the mechanism(s) by which isolation/restraint stress suppresses LH secretion in sheep is influenced by sex steroids. The predominance of particular sex steroids in the circulation may affect the extent to which stress inhibits the secretion of GnRH from the hypothalamus and/or the responsiveness of the pituitary gland to the actions of GnRH. There are also differences between the sexes in the effects of stress on LH secretion that are independent of the sex steroids.