Failure of growth hormone (GH) to feed back at the level of the pituitary to alter the response of the somatotrophs to GH-releasing factor

GH feeds back at the level of the central nervous system to alter the release of somatostatin and GRF, resulting in altered GH release. The purpose of this study was to see whether the concentration of GH, impinging directly on the somatotrophs of the adenohypophysis, would alter the responsiveness of the somatotrophs to GRF. Using a perifusion system and dispersed pituitary cells, we found that the GH response to a pulse of GRF is unaltered over a wide range of GH concentrations. We conclude that GH does not feed back at the level of the adenohypophysis to alter the responsiveness of the somatotrophs to GRF.     

Paradoxical enhancement of pituitary growth hormone (GH) responsiveness to GH-releasing factor in the face of high somatostatin tone

Pituitary GH secretion is regulated by a delicate interplay between stimulatory (GRF) and inhibitory [somatostatin (SRIF)] hypothalamic hormones, although the nature of the GRF/SRIF interaction remains to be elucidated. In the present study, we documented a significant elevation of plasma SRIF-like immunoreactivity in 72-h fasted rats compared to that in fed controls (129.0 +/- 17.9 vs. 38.2 +/- 5.8 pg/ml; P less than 0.01) and used this model of high SRIF tone to further delineate the interrelation between GRF and SRIF in physiological regulation of pulsatile GH secretion. We examined pituitary GH responsiveness to GRF, both in vivo and in vitro, after 72-h exposure to nutritional deprivation and high SRIF secretion. In vivo, GRF-induced GH release was markedly enhanced in the face of high circulating SRIF; freely moving, starved rats released 4- to 8-fold more GH than fed controls in response to rat GRF iv. In vitro, both basal and human GRF-induced GH release were augmented 2- to 4-fold in perifused dispersed anterior pituitary cells of starved rats compared to those in fed controls, and this enhanced responsiveness persisted in the presence of 10(-9) M SRIF. These results demonstrate that SRIF not only inhibits GH secretion stimulated by GRF, but that under different temporal conditions SRIF may act in a paradoxically positive manner to sensitize pituitary GH responsiveness to GRF. Such a cooperative interaction of the two peptides may be necessary to optimize pulsatile GH release. Our findings provide support for the hypothesis that the temporal patterning of hypothalamic GRF/SRIF signals to pituitary somatotrophs may be the major determinant for pulsatile GH secretion and, ultimately, body growth.     

Diminished pituitary responsiveness to growth hormone-releasing factor in aging male rats

The pattern of GH secretion undergoes substantial changes in the aging rat, resulting in decreased daily secretion of GH. In this study, the pituitary responsiveness to GH-releasing factor (GRF) was examined in young (2- to 5-month old) and aging (14- to 18-month old) male rats. In vivo studies were performed under sodium pentobarbital anesthesia. After injection of 250 ng GRF/100 g BW, young rats experienced more GH secretion [peak level, 544.5 +/- 209.5 (+/- SEM) ng/ml] than did 18-month-old rats (89.3 +/- 13.7 ng/ml). To investigate the locus of this insensitivity to GRF, anterior pituitary cells from young and aging rats were dispersed and placed in primary culture. While basal GH secretion from the cultured pituitary cells was similar in the two groups (49.7 +/- 3.5 vs. 47.8 +/- 2.7 ng/ml X 4 h for the 2- and 18-month old rats, respectively), the GH-releasing ability of GRF was partially but significantly impaired in cells derived from both 14- and 18-month old rats; 100 nM GRF stimulated the release of 96.7 +/- 1.8 ng/ml X 4 h in the 18-month old rats as opposed to 115.0 +/- 6.0 (P less than 0.05) ng/ml X 4 h in the 2-month-old rats. Since GRF stimulates GH release through the activation of adenylate cyclase, intracellular cAMP levels were measured in the cultured pituitary cells. GRF stimulated 65% less intracellular cAMP accumulation in the 18-month-old rats. In 14-month-old rats, the ability of forskolin and (Bu)2 cAMP to release GH was impaired, while phorbol ester-elicited GH secretion was unchanged. In conclusion, the GH response to GRF is blunted in aging rats. While much of the insensitivity to GRF may be mediated by the increased somatostatin tone reported in aging rats, a diminished pituitary cAMP response to GRF may also be an important etiological factor in the hyposomatotropinemia of the aging male rat.     

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)     

Galanin secretion from anterior pituitary cells in vitro is regulated by dopamine, somatostatin, and thyrotropin-releasing hormone.

Lactotrophs, somatotrophs, and thyrotrophs have been shown to contain immunoreactive galanin. Furthermore, estrogen stimulates galanin mRNA and peptide levels in the rat anterior pituitary, particularly within lactotrophs. To determine whether galanin is released from the anterior pituitary in a regulated manner, we used cultured pituitary cells from male and ovariectomized Fischer 344 rats implanted with estrogen-containing capsules. Anterior pituitary cells (5 x 10(5) cells/well) were challenged (0.5-3 h) with hypothalamic factors known to regulate anterior pituitary hormone secretion, and medium galanin levels were measured by RIA. In female pituitary cells, galanin secretion was inhibited by dopamine (10 and 100 nM) and stimulated by TRH (20 and 100 nM). Although galanin release was significantly lower in male pituitary cells, dopamine and TRH inhibited and stimulated galanin secretion, respectively. Medium galanin levels were also significantly reduced by somatostatin (5 nM) in both female and male cells. The pattern of PRL release in response to dopamine, TRH, and somatostatin was similar to that observed for galanin, regardless of the sex of the pituitary donor. Although galanin has been localized in somatotrophs, 5 nM GH-releasing hormone (GRF) failed to alter galanin release in male as well as female pituitary cells; GH secretion was significantly increased by GRF. LHRH (5 nM) and CRF (5 nM) failed to alter galanin release in vitro. We conclude that in estrogen-exposed pituitary cells obtained from male and ovariectomized Fischer 344 rats: 1) galanin secretion is inhibited by dopamine and somatostatin, and stimulated by TRH; 2) GRF, LHRH, and CRF do not regulate galanin release in these cells; and 3) the profile of the regulated pathway for galanin release suggests that the primary location of galanin is the lactotroph, probably within secretory granules.     

Effects of sex steroids on the response of cultured rat pituitary cells to growth hormone-releasing hormone and somatostatin

In the male rat, GH secretion is characterized by high amplitude pulses that appear at regular intervals of 3-4 h, with low basal levels between such pulses. In the female, the pulses are irregular and more frequent, with lower amplitudes, while basal secretion is higher. The present study was designed to exclude the indirect effects of sex steroids on the pituitary, enabling investigation of the direct effects of sex steroids on the pituitary. Rats were gonadectomized at 22 days of age, and 12 days later their anterior pituitaries were trypsinized for cell dispersion. Testosterone (T) or 17 beta-estradiol (E2), 5 nM, was added to the medium for 6 days, and subsequently, GRF or somatostatin was added for 4 h. In a perifusion system, the male-derived cell response to GRF was augmented after pretreatment with T, but not with E2. The female-derived cell response to GRF was augmented by E2, but not by T. T increased the sensitivity of the cells to GRF from 3.0-0.03 nM and increased the maximal potency of GH secretion 3-fold. E2 had no significant effect on the sensitivity, but lowered the potency. Somatostatin (1 nM) inhibited GH secretion by 44% in T-treated cells. In E2-treated cells, somatostatin was ineffective. GRF increased the total amount of GH (medium plus cells) in both T- and E2-treated cells, but not in control pituitary cells. It is suggested that T has direct effects on the male somatotroph. By increasing the pituitary cell responses to GRF and somatostatin, T contributes to the high amplitude peak/low baseline pattern of the male. By decreasing the pituitary cell responses to GRF and somatostatin, E2 contributes to the low amplitude peak/high baseline pattern of the female.     

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.     

Physiological role of growth hormone (GH)-releasing factor and somatostatin in the dynamics of GH secretion in adult male rat

To investigate the physiological role of GRF and somatostatin (SRIF) in GH secretion in adult male rats, we prepared in vitro models using the perifusion system of cultured rat anterior pituitary cells exposed to various combinations of human GRF-(1-44)NH2 (hGRF) and SRIF. We studied the following three models on GRF secretion: 1) pulsatile GRF secreted at 1-h intervals, 2) pulsatile GRF secreted at 3-h intervals, and 3) GRF continuously secreted. When 5-min pulses of 20 nM GRF were delivered at 1-h intervals, the responses to GRF gradually declined. The addition of continuous 20 nM SRIF with short pauses prevented this attenuated response and produced high peaks of GH at 3-h intervals. When 5-min pulses of 20 nM GRF were delivered at 3-h intervals, three high peaks of GH were observed regardless of the addition of SRIF. Pretreatment with GRF pulses enhanced the peaks of GH during SRIF pauses. When 20 nM GRF was continuously delivered, a rapid attenuated response to GRF was observed. Although the addition of continuous 20 nM SRIF with short pauses produced three small peaks of GH, these results were caused by the post-SRIF rebound release. These observations suggest that preexposure to prolonged SRIF can prevent an attenuated response to repeated GRF pulses, and that pretreatment with GRF pulses enhances post-SRIF rebound release.     

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.     

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 desensitization in rat anterior pituitary cells

The possibility that desensitization to the inhibitory effects of somatostatin (SS) might develop following chronic exposure to this tetradecapeptide was examined in cultured rat anterior pituitary cells. Pretreatment with 1μM SS for 48 h caused a shift in the IC₅₀ of SS to inhibit 3-isobutyl-1-methylxanthine (IBMX) or growth hormone-releasing factor (GRF)-induced growth hormone (GH) and TRH + IBMX-induced thyroid-stimulating hormone (TSH) release by more than 2 orders of magnitude. Refractoriness developed after 12 h of exposure to doses of SS of 10 nM or more and became maximal at 48 h. Restoration of SS responsiveness followed a similar time-course upon removal of the pep tide. In superfused cells, 10 nM SS lowered GH secretion rates to < 5 ng/min within 2 h, but GH release began to rise after 16 h despite the continued presence of SS. However, when somatostatin was delivered in pulses, it remained fully effective for more than 36 h. Somatosvtatin-28 was also capable of inducing refractoriness in cultured pituitary cells. However, cells made refractory to either SS-14 or SS-28 were not made refractory to the same extent to the other form of somatostatin. These results indicate that the pituitary can become desensitized to the inhibitory actions of somatostatin just as it does to the stimulatory actions of the other hypothalamic releasing hormones.     

Influence of sex steroid hormones on rat growth hormone-releasing factor and somatostatin in dispersed pituitary cells

The modulatory effects of glucocorticoid and sex steroid hormones on the effects of rat GH-releasing factor (GRF) and somatostatin (SRIF) on GH release and biosynthesis were studied in monolayer cultures of rat anterior pituitary cells with RIA and quantitative immunoprecipitation methods. Dexamethasone (10(-7) M), a potent synthetic glucocorticoid, increased both the sensitivity and maximum response of GH release stimulated by GRF. Progesterone (10(-7) M) also enhanced GH release stimulated by GRF. The stimulatory effects of dexamethasone and progesterone were dose dependent and required a latent period of at least 24 h to be evident. Testosterone, dihydrotestosterone, and 17 beta-estradiol showed no apparent influence on GRF-induced GH release under the same conditions. None of the hormones studied showed significant influences on basal or SRIF-suppressed GH release. Progesterone added to the maximally effective concentrations of dexamethasone had no additional effects on GRF-induced GH release. The effect of progesterone was attenuated by both 5 alpha-dihydronorethindrone, a progesterone antagonist and 17 alpha-methyltestosterone, a glucocorticoid antagonist. In terms of GH synthesis, stimulatory effects of GRF on GH synthesis were apparent only when pituitary cells were pretreated with dexamethasone. These results indicate that: pretreatment with glucocorticoid or progesterone enhances the effects of GRF on GH release and/or synthesis; these two steroids share at least one common step to enhance GRF effects; and steroid hormones have little influence on basal or SRIF-suppressed GH release.     

Chronic exposure of cultured rat anterior pituitary cells to GRF causes partial loss of responsiveness to GRF

Pretreatment of primary cultures of rat anterior pituitary cells with 500 pM rhGRF for 24 h resulted in a partial loss of responsiveness to GRF. When pretreated cells were rechallenged with increasing concentrations of rhGRF, maximal GH secretion was significantly lower than control, since prolonged exposure to the peptide resulted in depletion of releasable GH pools: 3.04 +/- 0.39 and 0.63 +/- 0.08 micrograms GH per 0.15 X 10(6) cells in control and treated cells, respectively. Possible desensitization, however, was indicated, since chronic exposure to rhGRF increased the EC50 for GH secretion by 5.5-fold. Pretreatment with 2 mM 8BrcAMP for 24 h also caused significant depletion of cellular GH. Consequently, maximal GH secretory response of these cells was blunted as well. However, in contrast to rhGRF-pretreatment, 8BrcAMP-pretreatment did not significantly affect the EC50 value for GH secretion. As another index for cellular responsiveness, cAMP production was also monitored. After a 24-h incubation with 500 pM rhGRF, attenuation of adenylate cyclase activity was evident, since the EC50 value for cAMP production was 2.8-fold greater than control. These results suggest that prolonged pretreatment with GRF results in a partial loss of responsiveness to GRF and this may be explained by desensitization and to some extent by depletion of GH stores.     

On the role of the peptide galanin in regulation of growth hormone secretion.

The effects of the peptide galanin on growth hormone secretion were studied in vitro using cultured rat and human anterior pituitary cells, and in vivo by iv administration of galanin in both rats and humans. Galanin in concentrations from 10 nmol/l to 1 mumol/l did not alter basal GH release, but slightly inhibited GHRH-stimulated GH release from cultured rat anterior pituitary cells. Galanin (1 mumol/l) did not significantly change basal or GHRH-stimulated GH secretion from cultured human anterior pituitary cells. In contrast, iv injection of 1 microgram (300 pmol) galanin to rats induced an increase in plasma GH that was reproducible at repetitive injections. The galanin-induced GH release in rats was of a lower magnitude than the increase in plasma GH after iv injections of GHRH, and was seen with a 5-15 min delay in comparison to iv administered GHRH. In man, iv infusions of galanin (40 pmol.kg-1.min-1.(40 min)) also caused a significant increase in plasma GH, but it occurred 25-30 min after the beginning of the infusion. These results suggest an indirect action of galanin on GH release in both rats and humans, i.e. galanin does not directly affect the somatotropes. In agreement with a central action, no binding sites for galanin could be demonstrated in the rat anterior pituitary by autoradiography. Since galanin did not affect somatostatin release from fragments of rat mediobasal hypothalamus, the stimulatory effects of galanin on GH release are most likely mediated via a stimulatory effect on GHRH neurons.     

Characterization of the glucose-dependent release of growth hormone-releasing factor and somatostatin from superfused rat hypothalami

The glucose-dependent secretion of the neuropeptides, growth hormone-releasing factor (GRF) and somatostatin (SRIF), by hypothalamic fragments was studied in vitro using a superfusion system. After equilibration of mediobasal hypothalami in HEPES-buffered Krebs-Ringer solution containing 5.5 mM glucose, glucose levels in the superfusion medium were altered. Lowering the glucose concentration in the medium from 5.5 to 2.7 or 1.1 mM provoked a rapid increase in GRF and SRIF release in a concentration and Ca2+-dependent manner. At 1.1 mM glucose, neuropeptide secretion was elevated 3- to 4-fold. The increase of GRF and SRIF release induced by low glucose was transient since stimulated neuropeptide secretion declined to basal levels in the continued presence of low glucose. Furthermore, after reequilibration in 5.5 mM glucose, no second stimulation of neuropeptide release could be induced by reduced glucose. Intracellular glucopenia induced by addition of 2-deoxy-D-glucose (16.5 mM) to the superfusion medium containing 5.5 mM glucose, also evoked increases in GRF and SRIF release. The sensitivity of GRF and SRIF neurons to glucose was absent in the postnatal period until day 9 after birth and then gradually increased. The parallel increases of GRF and SRIF release in response to low glucose observed in the present in vitro study, together with the suppression of plasma GH levels occurring in hypoglycemia in the rat, suggest that, in this condition, the inhibition of GH release induced by elevated SRIF levels predominates whereas the increase of GRF release might serve to attenuate this effect of SRIF.     

Effects of rat growth hormone (rGH)-releasing factor and somatostatin on the release and synthesis of rGH in dispersed pituitary cells

The effects of rat hypothalamic GH-releasing factor (GRF) and somatostatin (SRIF) on the release and biosynthesis of rat GH were studied by RIA and quantitative immunoprecipitation using monolayer cultures of rat anterior pituitary cells. In kinetic studies, GRF stimulation of GH release appeared at the first sampling time (20-min incubation) and the effect began to diminish after 2-h incubation with GRF. On the other hand, total (cell plus medium) content of GH significantly increased only after 24-h incubation. To examine the GH-synthesizing effect of GRF more directly, newly synthesized GH labeled by [35S]methionine during incubation with GRF was quantified by immunoprecipitation. The amount of immunoprecipitable GH increased significantly and specifically (compared with the total amount of labeled proteins) also only after 24-h incubation. When GH pools were labeled with [35S]methionine under different schedules, the basal release of newly synthesized GH, which was labeled for 1 h immediately before chase incubation was lower during the first 15 min than stored GH which had been labeled earlier. Basal newly synthesized GH secretion exceeded stored GH secretion after 30 min. GRF stimulated the release of GH from both pools but the stimulation of stored GH was greater. In this system, SRIF suppressed both the basal and stimulated release of GH but did not modify GH biosynthesis under either condition. Newly synthesized GH showed significant degradation during 24-h incubation; neither GRF nor SRIF affected the rate of GH degradation during the same incubation period. These results indicate that 1) GRF stimulates both release and synthesis of GH; 2) these two effects have different kinetics and different sensitivities to SRIF; and 3) GRF stimulates the release of GH from heterogeneous pools disproportionally.     

Impaired suppression of growth hormone release by somatostatin in cultured adenohypophyseal cells of spontaneously diabetic BB/W rats

The effects of the diabetic state on the somatotroph's responsiveness to the secretagogues GRF and (Bu)2-cAMP and to the inhibitor somatostatin (SRIF) were evaluated in enzymatically dissociated rat adenohypophyseal cells in primary monolayer culture. Primary cultures were prepared from pituitary tissue of spontaneously diabetic BB/W rats 23-51 days after the onset of hyperglycemia and glycosuria and of age-matched diabetes-resistant control rats. Dose-related stimulation of GH release by GRF and (Bu)2cAMP did not differ significantly in the two preparations. There was no evidence of abnormal sensitivity to TRH in cultured somatotrophs of diabetic rats. Dose-related suppression of (Bu)2cAMP (0.5 mM)-stimulated GH release by 0.01-10 nM SRIF, on the other hand, was significantly affected by diabetes, as indicated by a parallel shift of the dose-response curve to the right and an increase in the IC50 value from 76 +/- 2 to 204 +/- 5 pM (mean +/- SEM; n = 3; P less than 0.001). Maximal suppression by 10 nM SRIF was identical in the two preparations. The degree to which the cultured cells' responsiveness to SRIF was reduced was unrelated to the duration and severity of the diabetic state. Hypothalamic SRIF content did not differ significantly between diabetic and diabetes-resistant rats (186 +/- 12 vs. 178 +/- 10 ng/mg protein). Nevertheless, the SRIF concentration may be elevated in hypophysealportal blood of diabetic rats; we, therefore, examined the effect of prolonged exposure of the cell cultures to SRIF or SMS 201-995 on the subsequent suppression of (Bu)2cAMP-stimulated GH release by SRIF. Addition of either SRIF (10 nM) or SMS 201-995 (5.5 nM) to the culture medium for 4 days significantly increased the IC50 values for SRIF to values similar to those obtained in cultured cells of diabetic rats. We conclude that the somatotrophs of diabetic rats are relatively resistant to SRIF. Since prolonged exposure to SRIF in vitro produced similar resistance, the desensitization in diabetic rats may be due to elevated concentrations of SRIF in hypophyseal-portal blood. This impaired responsiveness to SRIF may contribute to aberrant GH secretion in diabetes.     

Evidence for direct action of estradiol on growth hormone-releasing factor (GRF) in rat hypothalamus: localization of [3H]estradiol in GRF neurons

Sex steroids have been shown to influence the secretion of GH. There appears to be no good evidence of the effect of estradiol on the anterior pituitary, while the central site of estradiol action on the regulation of GH secretion is not known. The present investigation was carried out to determine whether some of the GH-releasing factor (GRF) neurons and somatostatin (SRIF) neurons in the hypothalamus and GH cells in the pituitary contain estradiol receptors. Colocalization of [3H]estradiol and antibodies to GRF or SRIF in brain and antibodies to GH in pituitary was studied to show interrelationships between estrogen target cells and peptidergic cells. Eight female Sprague-Dawley rats were ovariectomized, each rat was treated with colchicine, and 24-48 h later the animals were given an iv injection of [2,4,6,7,16,17-3H]estradiol (SA, 166 Ci/mM) at a dose of 0.5 micrograms/100 g BW. One hour after the injection, the rats were perfused with 4% paraformaldehyde in 0.1 M phosphate buffer (pH 7.4). The hypothalami from the perfused rats and the pituitaries from unperfused rats were frozen in isopentane precooled in liquid nitrogen (-190 C) and processed for autoradiography. The brain autoradiograms were immunostained for GRF, SRIF, and tyrosine hydroxylase [TH; an enzyme for the synthesis of dopamine (DA)], and the pituitary autoradiograms were immunostained for GH by the avidin-biotin peroxidase method. The majority of GRF-containing neurons were found in the arcuate nucleus, with some scattered cells in the lateral region of the ventromedial nucleus and the basal lateral hypothalamus. In the central portion of the arcuate nucleus, 20-30% of GRF-containing neurons showed nuclear concentration of [3H]estradiol. In the anterior portion of the hypothalamus, 10-15% of immunoreactive GRF-containing neurons were labeled with [3H]estradiol. In the lateral basal hypothalamus and the lateral region to the ventromedial nucleus, a few GRF neurons showed nuclear concentration of radioactivity. In contrast, a few SRIF cells in hypothalamic periventricular nucleus showed nuclear labeling with [3H]estradiol. Dual immunostaining with GRF and TH antibodies revealed that the estradiol-labeled GRF neurons did not contain TH immunoreactivity. In addition, 80-90% of GH cells in the anterior pituitary showed nuclear concentration of [3H]estradiol. The present studies demonstrate for the first time that certain populations of GRF neurons are targets for estradiol and indicate that estradiol acts directly on certain hypothalamic GRF neurons. The results suggest that estradiol may have a role in the regulation of GH secretion by modulating GRF release and acting directly on the somatotrophs.     

Sex difference in growth hormone feedback in the rat

Growth hormone inhibits its own secretion in animals and man but the mechanism for this inhibition is unclear: both stimulation of somatostatin release and inhibition of GH-releasing factor (GRF) release have been implicated. We have now studied the GRF responsiveness of conscious male and female rats under conditions of GH feedback induced by constant infusion of exogenous human GH (hGH). Intravenous infusions of hGH (60 micrograms/h) were maintained for 3 to 6 h whilst serial injections of GRF(1-29)NH2 (0.2-1 microgram) were given at 45-min intervals. The GH responses were studied by assaying blood samples withdrawn at frequent intervals using an automatic blood sampling system. We have confirmed that male and female rats differ in their ability to respond to a series of GRF injections; female rats produced consistent GH responses for up to 13 consecutive GRF injections, whereas male rats showed a 3-hourly pattern of intermittent responsiveness. In female rats, multiple injections of GRF continued to elicit uniform GH responses during hGH infusions, whereas hGH infusions in male rats disturbed their intermittent pattern of responsiveness to GRF, and their regular 3-hourly cycle of refractoriness was prolonged. We suggest that this sex difference in GH feedback may be due to GH altering the pattern of endogenous somatostatin release differentially in male and female rats. Such a mechanism of GH autofeedback could be involved in the physiological control of the sexually differentiated pattern of GH secretion in the rat.     

Desensitization to growth hormone-releasing factor (GRF) is associated with down-regulation of GRF-binding sites

The time course, concentration dependence, and mechanism of rat anterior pituitary desensitization to GRF were studied. Chronic stimulation of cultures of rat anterior pituitary cells with rat GRF (rGRF) resulted in desensitization to a subsequent challenge with the peptide. Despite a slight enhancement of GH synthesis, prolonged exposure to GRF caused substantial depletion of cellular GH pools. As a result, acute secretory responses were markedly blunted. Depletion was accompanied by a time-dependent decrease in sensitivity to rGRF; GRF EC50 values for GH release of 0.5 nM rGRF-pretreated cells were 24.8 +/- 6 (+/- SEM) pM after 2 h, 46.2 +/- 2.4 pM after 4 h, and 154.7 +/- 31 pM after 8 h compared to 9.2 +/- 0.6 pM for control cells. The process of desensitization was complete within 8 h, as cells pretreated for 24 h exhibited sensitivity to rGRF comparable to that of cells pretreated for 8 h. Desensitization was associated with a time-dependent decrease in rat anterior pituitary cell GRF-binding capacity; a 48% loss of binding sites was evident after a 2-h pretreatment with 0.5 nM rGRF, with a maximum loss occurring after 8 h. The dose of rGRF required to produce an attenuation of responsiveness did not completely correlate with the dose requirement for down-regulation of binding sites. The decrease in GRF-binding sites was not associated with any alteration of apparent Kd values, which were 0.36 (0.18-0.72) nM in control and 0.1 (0.01-0.82) nM after 8 h of exposure to 0.5 nM rGRF. Both the reduction in GRF-binding capacity and decreased sensitivity to GRF were reversible after 24 h, although cellular GH pools were not restored to control levels. These results suggest that rat anterior pituitary cells become desensitized to rGRF after chronic stimulation with a maximal concentration of the peptide. One mechanism for this decrease in apparent sensitivity to rGRF may be the pronounced reduction or down-regulation of GRF-binding sites.