Growth hormone-releasing factor-sensitive adenylate cyclase system of purified somatotrophs: effects of guanine nucleotides, somatostatin, calcium, and magnesium

The purpose of this study was to characterize the adenylate cyclase system in a purified population of normal somatotrophs derived from rat pituitary and to determine the responses of this system to GRF, somatostatin, guanine nucleotides, and cations. Additionally, experiments were performed to evaluate the interrelationships among changes in adenylate cyclase activity, cellular cAMP levels, and GH release induced by GRF and somatostatin. The results obtained using homogenates and membrane preparations from somatotrophs included the following. 1) GRF caused guanine nucleotide-dependent concentration-related (Ka, approximately 10(-8) M) stimulation of adenylate cyclase activity. 2) Guanine nucleotides were effective in stimulating cyclase in the absence of GRF; the concentration of guanine nucleotide required for half-maximal stimulation was decreased more than 10-fold in the presence of GRF. 3) Adenylate cyclase activity increased with increasing concentrations of free Mg2+ (0.25-20 mM); activation by GRF and guanine nucleotide resulted in an approximately 7-fold increase in the enzyme's affinity for free Mg2+. 4) Somatostatin, up to 10(-6) M, did not alter basal or GRF-stimulated adenylate cyclase activity. 5) Ca2+ (0.5-11.9 microM) produced concentration-dependent inhibition of basal (up to 28%) and GRF-stimulated (up to 47%) cyclase activities; the inhibitory effect of Ca2+ was accompanied by a decrement (2- to 3-fold) in the apparent affinities of the enzyme for both GRF and guanine nucleotide. In intact somatotrophs, GRF produced concentration-dependent stimulation of GH release (Ka, approximately 6 x 10(-11) M), preceded by a marked elevation of cAMP levels. While somatostatin blocked GRF-induced GH release, the augmented cAMP levels were only slightly reduced.(ABSTRACT TRUNCATED AT 400 WORDS)     

Somatostatin partially reverses desensitization of somatotrophs induced by growth hormone-releasing factor

The effect of somatostatin on GH-releasing factor (GRF)-induced desensitization of somatotrophs was studied in vitro. Primary cultures of rat anterior pituitary cells pretreated for 4 or 18 h with GRF(1-40) (100 nmol/l) showed a 50% or greater reduction in maximal GH release when rechallenged with 10 nmol GRF/l. Rechallenge GRF dose-response curves were either very flat, making accurate measurement of the dose giving 50% maximum stimulation (ED50) impossible, or the ED50 concentration was increased from 0.3 nmol/l (untreated) to 2 nmol/l (GRF pretreated). Although GRF pretreatment reduced cellular GH content by 40-50%, correction for this did not restore GRF responsiveness measured in terms of maximal GRF-stimulated/unstimulated GH release (maximal/basal ratio), or the GRF ED50 concentration. Maximal/basal GH release per 4 h from GRF-pretreated cells was reduced when cells were rechallenged with forskolin (5 mumol/l) or calcium ionophore (A23187; 10 mumol/l), to the same extent as when rechallenged with 10 nmol GRF/l. Although this might be explained by a reduction in the pool of releasable GH, an alternative explanation is that pretreatment with GRF d disrupts the GH release mechanism(s) at a common step(s) beyond cyclic AMP generation and Ca2+ influx. Co-incubation of cells with somatostatin and GRF (100 nmol/l) partially reversed the desensitizing action of GRF during both 4- and 18-h pretreatments in a dose-dependent manner, with 1 mumol somatostatin/l being most effective. Maximal GRF (100 nmol/1-stimulated/basal GH release was 4.4 +/- 1.0 (mean +/- S.E.M., n = four experiments), 1.55 +/- 0.09 and 2.43 +/- 0.1 for control, GRF-pretreated (4 h) and GRF plus somatostatin-pretreated cells respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Dopamine and somatostatin inhibit forskolin-stimulated prolactin and growth hormone secretion but not stimulated cyclic AMP levels in sheep anterior pituitary cell cultures

Forskolin, an activator of adenylate cyclase, has been used to investigate the effects of raising pituitary cell cyclic AMP concentrations on prolactin and growth hormone secretion and to examine the role of cyclic AMP in the inhibitory actions of dopamine and somatostatin. Incubation of cultured ovine pituitary cells with forskolin (0.1-10 microM; 30 min) produced a modest dose-related increase in prolactin release (120-140% of basal) but a much greater stimulation of growth hormone secretion (170-420% of basal). Cellular cyclic AMP concentrations were only increased in the presence of 1 and 10 microM forskolin (2-5.5 times basal). A study of the time course for forskolin (10 microM) action showed that stimulation of prolactin (1.5-fold) and growth hormone (4.7-fold) secretion occurred over 15 min; subsequently (15-60 min) the rate of prolactin secretion from forskolin-treated cells was equivalent to that measured in controls, while growth hormone release remained elevated. Cellular cyclic AMP concentrations were also rapidly stimulated by forskolin (10 microM); they reached a maximum (12 times control) within 15 min, and then declined (15-60 min) but remained elevated relative to those in untreated cells (4.9 times control at 60 min). Dopamine (0.1 microM) inhibited basal secretion of both prolactin and growth hormone. In the presence of forskolin (0.1-10 microM), dopamine (0.1 microM) inhibited prolactin secretion to below the basal level and considerably attenuated the stimulation of growth hormone secretion. Similarly, somatostatin suppressed both basal and forskolin-induced prolactin and growth hormone secretion. However, neither dopamine nor somatostatin significantly decreased the stimulatory effect of forskolin on cellular cyclic AMP accumulation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Influence of coexisting hypothalamic messengers on growth hormone secretion from rat anterior pituitary cells in vitro

An increasing number of messengers have recently been found to coexist with growth hormone (GH)-releasing factor (GRF) in hypothalamic neurons. In view of a possible cosecretion of these substances with GRF into the portal circulation, the effect of synthetic rat hypothalamic GRF(1-43) alone, or together with dopamine (DA), L-dopa, gamma-aminobutyric acid (GABA), neurotensin (NT) or galanin (GAL) on GH release was investigated by using dispersed rat anterior pituitary cells in monolayer culture. GRF in concentrations of 10(-16)-10(-7) M stimulated GH release from somatotrophs in a dose-related manner. DA (10(-5) M), L-dopa (10(-8) and 10(-5) M) and GABA (10(-9) and 10(-5) M) did not affect basal GH release, whereas DA, but not L-dopa or GABA, significantly suppressed GRF-induced GH secretion. However, the inhibitory effect of DA on GRF-stimulated GH secretion was not observed in the presence of somatostatin (10(-6) M). NT (10(-6) M) and GAL (10(-6) M) did not change basal GH release. GAL, but not NT, inhibited GRF-stimulated GH release, but the addition of NT abolished the inhibitory actions of both GAL and DA. These results indicate that substances, probably coreleased with GRF from the same nerve endings, interact in the regulation of GH secretion at the pituitary level.     

Release of Pituitary Growth Hormone by Prostaglandins and Dibutyryl Adenosine Cyclic 3′:5′-Monophosphate in the Absence of Protein Synthesis

Effects of prostaglandins on the incorporation of [4,5-(3)H]leucine into growth hormone and its subsequent release into the incubation medium were studied. Incubation of rat anterior pituitary glands with 10(-6) M prostaglandin PGE(1) in tissue culture medium 199 for 7 hr caused a 40-300% increase in the release of labeled growth hormone into the incubation medium. PGE(1) at 10(-8) M increased growth hormone synthesis but not release. At 10(-6) M, PGE(2) had effects similar to PGE(1); PGA(1) increased growth hormone synthesis but not release. PGF(2alpha) was without effect on either synthesis or release of growth hormone.Prolactin synthesis and release were not affected by prostaglandins. All of the prostaglandins, at 10(-4) M, increased adenyl cyclase activity in the pituitary gland but phosphodiesterase activity was unaltered. Dibutyryl cyclic AMP, with or without caffeine, caused an up to 300% increase in labeled growth hormone release. No consistent effect of prolactin was observed. If potassium concentration was increased 10-fold, a 215% increase in growth hormone release was observed. A combination of hypertonic potassium and 10(-6) M PGE(1) increased growth hormone release 325%, suggesting that potassium and prostaglandins act by independent mechanisms. Addition of theophylline to pituitary gland, incubated in vitro, increased both the synthesis and release of growth hormone. Although fluoride greatly stimulated growth hormone release, it completely inhibited the incorporation of leucine into the hormone. Similarly, puromycin inhibited synthesis of growth hormone but did not block release induced by prostaglandin, dibutyryl cyclic AMP, theophylline, or fluoride. Prostaglandins increase pituitary adenyl cyclase activity and, presumably via cyclic AMP, increase growth hormone release, independently of protein synthesis.     

Role of cyclic nucleotides in the inhibition of growth-hormone secretion by somatostatin

The effects of somatostatin on GH secretion, cyclic AMP and cyclic GMp concentrations in dispersed bovine anterior pituitary cells were studied following activation of adenylate cyclase with cholera toxin and inhibition of phosphodiesterase with isobutylmethylxanthine (IBMX). Cholera toxin (10(-5)M) increased intracellular cyclic AMP concentration 10-fold and cyclic GMP concentration 3-fold relative to control, and stimulated the secretion of GH. IBMX (10(-4) M) als increased intracellular concentrations of both cyclic AMP and cyclic GMP and the secretion of GH and potentiated the actions of cholera toxin particularly in raising intracellular cyclic AMP concentrations which were elevated 40-fold in the presence of cholera toxin and IBMX. Somatostatin (5 X 10(-7) M) completely prevented GH secretion elicited by cholera toxin and/or IBMX. Somatostatin was without effect on control cyclic AMP and cyclic GMp concentrations and on the increases in both cyclic AMP and cyclic GMP caused by cholera toxin and by IBMX alone, or in combination. The data suggest that bovine GH secretion is increased when concentrations of either or both cyclic nucleotides are elevated within the cells, although incubation of cells with extracellular concentrations of cyclic AMP and cyclic GMP derivatives up to 2 x 10(-3) M caused only small changes in GH release. We suggest that somatostatin inhibits cholera toxin-induced bovine GH secretion by preventing activation of the secretory process by either cyclic AMP or cyclic GMP.     

Effects of dopamine and somatostatin on phorbol ester-stimulated prolactin and growth hormone secretion

Incubation of cultured ovine pituitary cells with the tumor-promoting phorbol ester, 12-O-tetradecanoylphorbol 13-acetate (TPA) (0.1-100 nM), caused a dose-related stimulation of both growth hormone (ED50 approximately 4 nM) and prolactin (ED50 approximately 14 nM) secretion. Stimulation by TPA (100 nM) produced a substantial 10-fold increase in growth hormone with a smaller, 2-fold rise in prolactin secretion over 30 min; significant effects on the release of both hormones occurred within 2 min. Treatment with TPA also produced a small, time- and concentration-dependent rise in cellular cyclic AMP content which reached, at maximum, a level 20-30% over basal values. Non-tumor-promoting phorbol esters did not stimulate the secretion of either growth hormone or prolactin. In the presence of TPA (10 nM), dopamine (1-1000 nM) suppressed prolactin secretion to a level close to that observed for maximal inhibition of unstimulated cells. At high concentrations (0.1-1.0 microM) dopamine also partially attenuated (by 43%) the TPA-induced stimulation of growth hormone secretion. Somatostatin (0.01-1.0 microM) completely inhibited the substantial (approximately 9-fold) TPA-induced stimulation of growth hormone secretion (inhibitory ED50 approximately 47 nM), and also suppressed TPA-stimulated prolactin secretion to the control level. Our results suggest that activation of protein kinase-C may be involved in the stimulatory regulation of both growth hormone and prolactin secretion in sheep pituitary cells. Failure of TPA to attenuate the inhibitory activity of dopamine and somatostatin suggests that inhibitory regulation occurs at, or beyond, the point in the secretory process regulated by protein kinase-C.     

Somatostatin receptors on pituitary somatotrophs, thyrotrophs, and lactotrophs: pharmacological evidence for loose coupling to adenylate cyclase

Pharmacological characterization of somatostatin (SRIF) receptors located on somatotrophs, thyrotrophs, and lactotrophs was attempted by measuring the effects of 14 structural agonists of somatostatin (SRIF) on the inhibition of basal and GRF-stimulated GH and basal and TRH-stimulated PRL and TSH secretion. We also checked the abilities of the analogs to displace [125I]N-Tyr-SRIF binding to pituitary cell membranes and their potency to inhibit adenylate cyclase activity. There was a very good correlation (r = 0.975) between the displacement of [125I]N-Tyr-SRIF and the inhibition of adenylate cyclase activity by the analogs. The effects of the analogs on secretion of the three hormones followed the same rank order of potency. However, the active analogs displayed 2-6 times lower affinities in inhibiting PRL than GH or TSH secretions. The shift in affinity was even more pronounced in the case of the lower potency of the analogs as inhibitors of adenylate cyclase activity compared to hormone secretions. Pretreatment of the cells with pertussis toxin (100 ng/ml; 24 h) blocked SRIF inhibition of basal and GRF-stimulated adenylate cyclase activity and decreased by 83% [125I]N-Tyr-SRIF binding. It also blocked the ability of SRIF to inhibit GRF-induced GH and TRH-induced PRL and TSH secretion. However, pertussis toxin also increased GRF stimulation of GH secretion and decreased TRH stimulation of both TSH and PRL secretion. We conclude from our data that SRIF-binding sites located on the three target cells of the adenohypophysis are of a single class. These binding sites are negatively coupled to adenylate cyclase, but the inhibition of hormone secretions by SRIF cannot be explained solely through adenylate cyclase inhibition. Another mechanism of transduction must be involved in the actions of SRIF on its three pituitary target cells.     

Modification of basal and GRF-stimulated cyclic AMP levels and growth hormone release by phospholipid metabolic enzyme inhibitors

The relative importance of several phospholipid pathways in cyclic AMP (cAMP) metabolism and growth hormone (GH) release was determined by an indirect, pharmacological approach in cultured anterior pituitary cells. The diglyceride lipase inhibitor RHC-80267 (30-100 microM) had no significant effect on cAMP levels but markedly inhibited basal and growth hormone-releasing factor-(GRF) stimulated GH secretion. A phospholipase A2 inhibitor quinacrine (30 microM) increased cellular cAMP content while decreasing GH release. Indomethacin, which reduces cyclooxygenase activity, affected neither cAMP levels nor GRF-enhanced GH release; this drug (30-100 microM) did reduce basal GH release. The lipoxygenase inhibitors nordihydroguaiaretic acid and BW-755c both reduced basal and GRF-stimulated GH release in a concentration-dependent manner. Both agents had various effects on cAMP levels. These results suggest that phospholipid metabolism, through both the cyclooxygenase and lipoxygenase pathways, contributes to basal GH release, while the lipoxygenase route predominates in GRF-stimulated GH release in vitro. Interestingly, cAMP metabolism can be dissociated from GH release with some of these probes, indicating an action of phospholipid metabolites distal or lateral to the cAMP-generating system.     

Effects of acute and prolonged glucose excess on growth hormone release by cultured rat anterior pituitary cells.

The aim of this study was to verify whether prolonged exposure of cultured rat anterior pituitary cells to high glucose can alter growth hormone (GH) release and responsiveness to secretagogues. Therefore, we cultured anterior pituitary cells obtained from normal male Sprague-Dawley rats in presence of normal (6 mM) or high (22 mM) glucose concentrations. After 3 days, the acute effects of glucose, growth hormone-releasing factor (GRF), dibutyryl cyclic AMP(db-cAMP) and somatostatin were studied during 2-hour incubations. High glucose did not alter basal GH release from cells cultured in 6 mM glucose. However, basal GH release from cells cultured in 22 mM glucose was moderately higher in the 2-hour incubation (by 46%) than in cells cultured in 6 mM glucose. In contrast, GH stimulation by GRF or db-cAMP was significantly reduced in cells cultured in 22 mM as compared to cells cultured in 6 mM glucose. This inhibitory effect of high glucose on GRF-stimulated GH release was completely reversible after 24 h of exposure of the cultured cells to 6 mM glucose and testing on the 4th day of culture. Finally, GH inhibition by somatostatin was also attenuated in cells cultured with high glucose. We conclude that prolonged exposure to high glucose could act directly at the pituitary level to modulate GH release and responsiveness.     

Impaired generation of cyclic adenosine 3',5'-monophosphate in a somatomammotroph cell line derived from dwarf (dw) rat anterior pituitaries.

The dwarf (dw) mutation in rats results in 40-50% growth retardation associated with a selective reduction in pituitary somatotroph number, GH content, and GH mRNA levels and a decreased GH secretory response to GH-releasing factor (GRF). Recent studies in freshly dispersed pituitary cells have provided evidence for a defect in adenylate cyclase-linked GRF signal transduction in dw somatotrophs. To further examine this defect in a more specific cell population, we developed a somatomammotroph cell line (DP) derived from anterior pituitaries of male dw rats. A similar cell line from normal rats (Po) was used as control. We studied acute GH (4-h release) and cAMP (30-min intracellular accumulation) responses to GH secretagogues known to interact with the adenylate cyclase system. Basal GH release in both cell lines was 80-130% of the cell content, thus limiting the capacity for further GH responses. GRF (10(-8) M) produced a doubling of cAMP levels in Po and DP cells (P less than 0.01), but inconsistent effects on GH release. (Bu)2cAMP (5 x 10(-3) M) increased GH secretion by 50-100% in both groups (P less than 0.01). Cholera toxin (10(-9) M) increased GH release by 50% in both Po and DP (P less than 0.01), but the cAMP response in DP cells was only half that in Po cells (P less than 0.01). Forskolin (10(-5) M), a direct stimulator of adenylate cyclase, doubled GH release in both groups (P less than 0.01). However, cAMP generation was impaired in DP, with a maximal response to forskolin less than one third that in Po (P less than 0.01). In somatotrophs, cAMP mediates not only GRF-stimulated GH release, but also GH synthesis and mitogenesis. The impairment in maximal cAMP generation in DP cells, while not affecting acute GH release, may underlie the defect in somatotroph cell number and GH content in the dw pituitary gland.     

Somatostatin inhibits the isoproterenol-stimulated adenylate cyclase in the intermediate lobe of the male rat pituitary gland

Somatostatin-14 inhibited the isoproterenol-stimulated adenylate cyclase in cell-free homogenates of pituitary intermediate lobe of the male rat with a Ki of 7.25 +/- 0.31 X 10(-7) M. Somatostatin-28 was found to be a partial agonist. Other neuropeptides (met- and leu-enkephalin, beta-endorphin, alpha-melanocyte-stimulating hormone, ACTH, neurotensin, substance P, vasoactive intestinal polypeptide, and vasopressin) were without effect. Our results suggest a role for pituitary and/or brain somatostatin in the physiological regulation of the intermediate pituitary lobe, and the possibility of an interaction between somatostatins and catecholamines on the regulation of intermediate lobe adenylate cyclase.     

Mechanisms involved in the effects of TRH on GHRH-stimulated growth hormone release from ovine and bovine pituitary cells

Incubation of cultured ovine pituitary cells with growth hormone-releasing hormone (GHRH) (10(-12)-10(-7) M) stimulated growth hormone secretion up to 3-fold. At a maximal stimulatory concentration of GHRH (10(-10) M), thyrotropin-releasing hormone (TRH) (10(-7) M) caused an inhibition of growth hormone release to approx. 50% of the response obtained with GHRH alone (during a 15 min incubation period). TRH also caused a small inhibition of the GHRH-stimulated cellular cyclic AMP level but this effect was only significant at a relatively high concentration of GHRH (10(-9) M). Incubation of cultured bovine pituitary cells with GHRH (10(-11)-10(-8) M) plus TRH (10(-7) M) caused a significant stimulation of growth hormone release by up to 40%, compared with the response obtained with GHRH alone (at all concentrations of GHRH). TRH (10(-7) M) had no effect on GHRH (10(-8) M)-stimulated cellular cyclic AMP levels in a partially purified bovine pituitary cell preparation. The effects of varying extracellular [Ca2+] (0.1-10 mM) on intracellular [Ca2+] and on the responsiveness to releasing hormones were also determined using ovine pituitary cells. GHRH (10(-10) M)-stimulated growth hormone release was inhibited when cells were incubated at both high (10 mM) and low (0.1 mM) [Ca2+] (compared with 1 mM or 3 mM Ca2+) with or without TRH (10(-7) M). At 1 mM Ca2+, TRH produced a synergistic effect with GHRH to stimulate growth hormone release. However, at 3 mM Ca2+ TRH inhibited GHRH-stimulated growth hormone release.(ABSTRACT TRUNCATED AT 250 WORDS)     

Monensin influences basal and human growth hormone-releasing hormone 44-induced release of stored and new rat growth hormone and prolactin

When previous data suggested a growth hormone-releasing factor (GRF)-sensitive branch in intracellular hormone processing, the monensin-sensitive Golgi apparatus seemed a likely candidate. We examined monensin's effect on basal and GRF-stimulated release of newly synthesized and stored rat growth hormone (rGH) and rat prolactin (rPRL). 14C-Pre-labeled, perifused rat pituitary fragments were exposed to [3H]leucine in 0-10 microM monensin; a pulse of 3 nM GRF assessed subsequent secretory responsivity. Monensin dose-dependently reduced basal release of stored [14C]rGH and [14C]rPRL. GRF-stimulated release of stored [14C]hormone was doubled after 0.03 microM and 0.1 microM monensin; higher concentrations diminished stored hormone release. Low concentrations of monensin accelerated basal (0.03 microM and 0.1 microM) and GRF-stimulated (0.03 microM) [3H]rGH and [3H]rPRL release without altering recovery; higher monensin concentrations (greater than or equal to 1 microM) reduced basal, and abolished GRF-stimulated, new hormone release and reduced total [3H]rGH and [3H]rPRL recovery. These data are consistent with a GRF-sensitive and monensin-influenced branch in intracellular hormone processing that regulates the fraction of new hormone exiting the cell without prior immersion in storage compartments.     

Effects of a purified growth hormone releasing factor on growth hormone secretion and pituitary cyclic nucleotide content

We examined the effects of partially purified ovine GRF on medium growth hormone and tissue cyclic AMP and cyclic GMP content of incubated pituitary explants. Although hypothalamic extracts that contained numerous releasing factors had increased both cyclic AMP and cyclic GMP, the purified GRF promoted the accumulation of cyclic GMP, but not cyclic AMP. Six μg of the GRF increased medium growth hormone 240% above flasks containing only control buffer. These data support the concept that cyclic GMP is an important intracellular mediator of growth hormone release.     

The interrelationship between the effects of somatostatin and human pancreatic growth hormone-releasing factor on growth hormone release by cultured pituitary tumor cells from patients with acromegaly

The effects of somatostatin (SRIF) and human pancreatic tumor GRF on GH release by cultured pituitary tumor cells obtained during transsphenoidal operation from 15 acromegalic patients were investigated. In a study of the sensitivity of pathological GH release to SRIF, 1-10 nM SRIF induced maximal inhibition of hormone release in 3 consecutive tumors. In 12 of 15 tumor cell cultures, 10 nM SRIF produced statistically significant inhibition of basal GH release by 39 +/- 3% (mean +/- SEM). In 2 of the 3 other tumors, SRIF inhibited GRF-stimulated GH release, while this was not investigated in the third tumor. A dose-response study of the effect of GRF on GH release by cultured pituitary tumor cells showed that doses of 0.1, 1, 10, and 100 nM induced similar maximal (35%) stimulation of hormone secretion. In four of five consecutive tumor cell suspensions, 1 and 10 nM GRF induced statistically significant GH stimulation by 18-300%. Preincubation of the tumor cells with 5 nM dexamethasone greatly increased the sensitivity and the maximal stimulation in response to GRF and made one tumor cell suspension, which did not react to GRF initially, sensitive to GRF. In the tumors of four patients, the interrelationship between the effects of SRIF and GRF on GH release were also studied. SRIF (10 nM) inhibited the stimulatory effects of GRF on GH release virtually completely. In conclusion, GH release by in vitro cell cultures of GH-secreting pituitary adenomas was inhibited by SRIF and stimulated by GRF. The interaction of GRF and SRIF on GH release by these pituitary tumor cells was similar to that in normal rat GH cells, as SRIF virtually completely overcame the GRF-induced GH release.     

Biochemical and physiological studies of the beta-adrenoceptor and the D-2 dopamine receptor in the intermediate lobe of the rat pituitary gland: a review

The intermediate lobe (IL) of the rat pituitary gland responds to catecholamines. Catecholamines interacting with the beta-adrenoceptor stimulate adenylate cyclase activity, enhance cyclic AMP formation and thereby trigger the release of alpha-melanocyte-stimulating hormone (alpha-MSH). Catecholamines interacting with a D-2 dopamine receptor (in the classification schema of Kebabian and Calne) diminish adenylate cyclase activity and thereby decrease the capacity of IL cells to synthesize cyclic AMP. Dopaminergic agonists also inhibit the release of alpha-MSH from IL cells. The homogeneity of the IL facilitates biochemical investigations of this tissue.     

Intracellular pH and growth hormone-releasing factor-stimulated adenosine 3'5'-monophosphate, intracellular calcium and growth hormone release from rat anterior pituitary cells.

In this study, we examined the effect of changes in intracellular pH (pHi) on basal and GH-releasing factor (GRF)-stimulated cyclic AMP (cAMP), intracellular Ca2+ and GH release using a static monolayer culture prepared from dispersed rat anterior pituitary cells. To modulate pHi, two approaches were used: variation of extracellular pH (pHo) and addition of sodium propionate and ammonium chloride which alter pHi directly. Direct pHi measurement with 2'7'-bis(carboxyethyl)-5(6)-carboxyfluorescein showed that for pHo values between 6.9 and 7.6, a change in pHo of 0.1 units resulted in a change in pHi of 0.045 units. Sodium propionate (30 mmol/l) reduced pHi by 0.06 units whereas ammonium chloride (30 mmol/l) increased pHi by 0.1 units. Increasing pHo from 6.6 to 7.8 enhanced the maximal GRF-stimulated cAMP and GH responses by 80% and 300% respectively, indicating that the GRF-stimulated cAMP and GH release were both pH-dependent. Acute elevation of pHo from 6.6 to 7.8 also increased basal GH release by sixfold. Reduction of pHi by sodium propionate, however, had no significant effect on GRF-stimulated cAMP levels while the corresponding GRF-stimulated GH release was reduced by up to 40%. In comparison, elevation of pHi by ammonium chloride enhanced the GRF-stimulated cAMP release by up to 75% and the corresponding increase in GH was less than 20%. When the relationship between pHi and intracellular Ca2+ was determined with the fluorescent Ca2+ indicator, Fura-2, it was found that increasing pHo and treatment with ammonium chloride increased intracellular Ca2+, while sodium propionate and reducing pHi had no effect on intracellular Ca2+. These results indicate that activation of adenylate cyclase and mobilization of intracellular Ca2+, two intracellular signalling pathways of importance to GH secretion, are both sensitive to changes in pHi.     

The relationship between somatostatin binding and cyclic AMP-stimulated protein kinase inhibition

Somatostatin binding and the ability to inhibit cyclic AMP stimulated protein kinase were investigated utilizing isolated pancreatic islets, anterior pituitary plasma membranes, adipocytes, erythrocyte ghosts, hepatic plasma membranes, and anterior pituitary secretion vesicles. Three types of response were observed. With type I response, somatostatin bound specifically to pancreatic islets and anterior pituitary secretion vesicles and inhibited cyclic AMP stimulated protein kinase. In type II response, adipocytes and anterior pituitary plasma membranes exhibited somatostatin binding but no effect of the ligand on the kinase. In erythrocyte membrane ghosts and hepatic plasma membranes, there was neither specific somatostatin binding nor protein kinase inhibition (type III response). The absence of somatostatin binding in erythrocytes or hepatic plasma membranes cannot be explained by degradation of the ligand per se. Secretory vesicles isolated from the anterior pituitary gland bind somatostatin with an average affinity which exceeds that observed in plasma membrane (for pituitary secretory vesicles Kd1 = 8.5 X 10(-8)M, Kd2 = 5.2 X 10(-7)M; for pituitary membranes Kd1 = 1.9 X 10(-8)M, Kd2 = 8.1 X 10(-7)M). The molar concentration of high affinity binding sites (Ro) for plasma membranes was 6.9 X 10(-10)M; for secretory vesicles 3.6 X 10(-9)M. Calculated in terms of somatostatin binding per U 5'nucleotidase activity, the binding for plasma membranes becomes 8.4 X 10(-14) mole/U 5'nucleotidase; secretory vesicles 4.4 X 10(-13) mole/U 5'nucleotidase. Thus, secretory vesicles are fivefold richer in high affinity receptor sites than plasma membranes. It is suggested that in order for somatostatin to act, both a receptor and an effector unit must be present. In the case of tissues secreting polypeptide hormones by granule extrusion, the secretory vesicle may possess both the receptor and the effector units. It is postulated that during the process of fusion of the plasma and secretory vesicle membranes, a high affinity binding site for somatostatin is incorporated into the plasma membrane, thereby allowing somatostatin to act at a specific locus in the cell in inhibiting hormone release.     

Triiodothyronine inhibition of thyrotropin-releasing hormone- and growth hormone-releasing factor-induced growth hormone secretion in anesthetized chickens

The ability of triiodothyronine (T3) to reduce basal and secretagogue-induced growth hormone (GH) release was examined in anesthetized young and adult male chickens. Infusion of T3 had no effect on basal plasma concentrations of GH in either young or adult chickens. However, GH secretion following challenge with either thyrotropin-releasing hormone (TRH) or growth hormone-releasing hormone (GRF) was reduced, in a dose-dependent manner, by the infusion of T3. In vivo sensitivity to T3 inhibition was greater with TRH- than GRF-stimulated GH release in either young (ED50 for TRH-induced GH release, 0.34 microgram T3/kg/min; ED50 for GRF-induced GH release, 0.49 microgram T3/kg/min) or adult chickens (ED50 for TRH-induced GH release, 0.11 microgram T3/kg/min; ED50 for GRF-induced GH release 1.89, micrograms T3/kg/min). Moreover, there was an increase in sensitivity of TRH-induced GH release to T3 with age.