Characterization of the stimulatory effect of galanin on growth hormone release from the rat anterior pituitary.

The present study was undertaken to investigate the direct actions of rat galanin (R-GAL) on growth hormone (GH) release from the rat anterior pituitary in vitro. R-GAL modestly but significantly stimulated GH release without an increase in intra- and extracellular cyclic AMP levels in monolayer cultures of rat anterior pituitary cells. This stimulatory effect of R-GAL was dose-dependent but not additive with that of GH-releasing factor (GRF). R-GAL-stimulated GH release was less sensitive to the inhibitory effect of somatostatin than was GRF-stimulated GH release. In perfusions of rat anterior pituitary fragments, R-GAL induced a gradual and sustained increase of GH release. Incremental GH release derived in part from preformed stored GH. These data confirm that R-GAL acts at the pituitary level to stimulate GH release by a mechanism distinct from that of GRF.     

The episodic secretory pattern of growth hormone regulates liver carbonic anhydrase III. Studies in normal and mutant growth-hormone-deficient dwarf rats.

Carbonic anhydrase III (CAIII) occurs in male rat liver at concentrations twenty times those in the female, and is sensitive to the pattern of growth hormone (GH) release. Males release GH episodically and have high concentrations of CAIII; females produce GH in a more continuous fashion and have lower CAIII levels. In normal female rats, the endogenous GH secretory pattern was masculinized, either by regular injections of GH-releasing factor (GRF) or by intermittent infusions of somatostatin (90 min on/90 min off). Both treatments induced regular GH pulses and stimulated growth, but only intermittent somatostatin infusions raised CAIII levels (controls, 1.5 +/- 0.5; somatostatin-treated, 9.0 +/- 2.9 micrograms/mg; means +/- S.D.). GRF pulses (4 micrograms every 4 h) did not however raise CAIII levels (controls 1.8 +/- 0.5; GRF-treated 1.4 +/- 0.4 micrograms/mg). Surprisingly, hepatic CAIII is also sexually dimorphic (males, 18.8 +/- 3; females, 2.22 +/- 0.4 micrograms/mg) in a GH-deficient dwarf rat strain which has low plasma GH levels without 3-hourly GH peaks. Intermittent somatostatin infusions in female dwarf rats partially masculinized hepatic CAIII, an effect reduced by co-infusion with GRF. This CAIII response was not secondary to growth induction, since neither somatostatin nor GRF stimulated growth in dwarf rats, and pulses of exogenous GH stimulated growth in female dwarfs without masculinizing CAIII levels. Furthermore, continuous GH infusion in male dwarf rats partially feminized hepatic CAIII levels (to 9.1 +/- 2.4 micrograms/mg), whereas infusions of insulin-like growth factor-1, which induced the same body weight gain, did not affect hepatic CAIII (20.8 +/- 6 micrograms/mg). These results show that hepatic CAIII expression is highly sensitive to the endogenous GH secretory pattern, independent of growth. They also implicate the low basal GH levels between pulses, rather than the peak GH levels, as the primary determinant of the sexually dimorphic hepatic CAIII expression in the rat.     

Growth hormone secretion during pregnancy: altered effects of growth hormone releasing factor and insulin-like growth factor-I in vitro

Growth hormone (GH) secretion is controlled by growth hormone releasing factor (GRF) but changes in the circulating level of this hormone are difficult to measure. Insulin-like growth factor (IGF-I) is a GH-dependent growth factor which significantly but slightly inhibits stimulated GH release in vitro. We have tested the effects of GRF and IGF-I on GH release in pregnancy, a state in which serum concentrations of GH are elevated and levels of IGF-I are lowered. We have found, in a system of acutely dispersed adenohypophysial cells prepared from pregnant (day 21-23) or control cycling female rats, that adenohypophysial cells from pregnant rats have an increased GH release with GRF. In contrast, IGF-I inhibition is similar but slightly smaller. These altered responses may result in elevated serum GH levels during pregnancy.     

Galanin stimulates immunoreactive growth hormone-releasing factor secretion from rat hypothalamic slices perifused in vitro.

The effect of galanin (GAL) on the release of GH-releasing factor (GRF) and somatostatin (SRIF) was examined in an in vitro perifusion system of rat hypothalamic slices. GAL at doses of 10(-7) and 10(-6)M stimulated the release of immunoreactive GRF while it failed to affect SRIF release. Therefore, in vivo stimulation of GH release by GAL may be explained in part by the GRF-releasing effect of this peptide.     

Stimulation of growth hormone release in dwarf and normal chickens by thyrotrophin releasing hormone (TRH) or human pancreatic growth hormone releasing factor (hpGRF)

The effect of thyrotrophin releasing hormone (TRH) or human pancreatic growth hormone releasing factor (hpGRF) on growth hormone (GH) release was studied in both dwarf and normal Rhode Island Red chickens with a similar genotype except for a sex-linked dw gene. Both TRH (10 micrograms/kg) and hpGRF (20 micrograms/kg) injections stimulated plasma GH release within 15 min in young and adult chickens. The increase in GH release was higher in young cockerels than that in adult chickens. The age-related decline in the response to TRH stimulation was observed in both strains, while hpGRF was a still potent GH-releaser in adult chickens. The maximal and long acting response was observed in young dwarf chickens, suggesting differences in GH pools releasable by TRH and GRF in the anterior pituitary gland. The pituitary gland was stimulated directly by perifusion with hpGRF (1 microgram/ml and 10 micrograms/ml) or TRH (1 microgram/ml). Repeated perifusion of GRF at 40 min intervals blunted further increase in GH release, but successive perifusion with TRH stimulated GH release. The results suggest the possibility that desensitization to the effects of hpGRF occurs in vitro and that the extent of response depends on the number of receptors for hpGRF or TRH and/or the amount of GH stored in the pituitary gland.     

Growth hormone-releasing factor (GRF) stimulates PGE2 production in rat anterior pituitary. Evidence for a PGE2 involvement in GRF-induced GH release

Rat anterior pituitaries were incubated over a 3-h period. Both PGE2 and GH were increased by GRF in a concentration-related manner (ED50: 3.5 nM and 6.5 nM, respectively). A significant correlation (r = 0.88, n = 127) was observed between GH and PGE2 release over the range of GRF concentrations tested. Among the five prostanoids analyzed, only PGE2 was selectively increased. Somatostatin lowered GH release, without any effect on PGE2 production. Indomethacin (Id) and Aspirin reduced significantly PGE2 synthesis and GRF-induced GH release. The inhibitory effect of Id was counteracted by addition of PGE2 to the medium. GRF and PGE2, at maximal concentrations, had a partial additive effect on GH release. The increase in PGE2 production and the reduced GH release in the presence of cyclooxygenase inhibitors suggest that PGE2 is involved in GRF-induced GH release.     

Characteristics of phorbol ester stimulated growth hormone release: inhibition by insulin-like growth factor I, somatostatin, and low calcium medium and comparison with growth hormone releasing factor

TPA (12-O-tetradecanoylphorbol 13-acetate) is one of a class of compounds known as tumor promoters which perturb the inositol phosphate pathway in a number of cells. We have used TPA in a dispersed rat adenohypophysial cell system to probe the characteristics of growth hormone (GH) release. In this system we have found that the cells release GH in response to low concentrations of TPA: the EC50 was 0.23 +/- 0.05 nM (n = 6) and the maximal concentration was 5 nM. However, the maximal TPA-induced GH release was only 34 +/- 5% (n = 7) of the GH released by maximal growth hormone releasing factor (GRF) suggesting TPA releases a subpool of stored GH. Both somatostatin and insulin-like growth factor I inhibit GH release stimulated by TPA to the same extent as that stimulated by GRF, showing that the normal inhibitory control mechanism of release is not altered. Incubation in a low calcium medium that totally blocks GRF-stimulated GH release also inhibits TPA-stimulated GH release. The calcium channel blockers nifedipine and diltiazem both partly inhibit GRF- and TPA-stimulated GH release, showing some component of the calcium necessary for GH release arises from influx across the cell membrane.     

Somatostatin prevents the desensitizing action of growth hormone-releasing factor on growth hormone release

We have investigated the effect of prior exposure to somatostatin (SRIF) alone or in combination with growth hormone-releasing factor (GRF) on the subsequent cyclic AMP and GH responses to GRF in rat anterior pituitary cells in primary culture. The maximal 4.5-fold stimulation of GH release induced by a 3-hr incubation with GRF is reduced by 60% following a prior 3-hr exposure to 30 nM GRF. A 3-hr preincubation with GRF in the presence of 30 nM SRIF doubles spontaneous GH release while the maximal amount of GH released during a subsequent 3-hr exposure to GRF is similar to that measured in cells pretreated with control medium, thus completely preventing the loss of GH responsiveness induced by prior exposure to GRF. The prevention by SRIF of the desensitizing action of GRF on GH release is not observed on the cyclic AMP response which remains almost completely inhibited in GRF-pretreated cells. Similar protective effects are obtained when SRIF is incubated with prostaglandin E2 (PGE2), thus completely preventing the desensitizing action of PGE2 on GH release. Prior treatment with pertussis toxin completely prevents the protective action of SRIF on GH responsiveness. Pretreatment with GRF + SRIF increases by 85 and 60% the maximal amount of GH release induced by cholera toxin and 8-bromoadenosine 3',5'-monophosphate, respectively. The post-SRIF rebound effect on GH release occurs mainly during the first 30 min following withdrawal of the tetradecapeptide. The present data demonstrate that simultaneous preincubation with SRIF and GRF prevents the marked inhibition of GH release during subsequent exposure to GRF.(ABSTRACT TRUNCATED AT 250 WORDS)     

Dynamics of secretory granules in somatotrophs of rats after stimulation with growth hormone-releasing factor: a stereological analysis

The anterior pituitary tissue of male rats injected with growth hormone-releasing factor (GRF) was either processed for stereology at the light-and electron-microscopic levels, or homogenized for growth hormone (GH) assay 2–60 min after GRF injection. Secretory granules of somatotrophs became smaller but increased in numerical density 2 min after GRF injection. Their volume density began to increase at 5 min. The frequency of exocytosis of the granules was most prominent as early as 2 min after GRF injection and reduced thereafter. GH levels in the tissue were lowest at 2–5 min, and returned to the control value by 60 min. Serum GH levels were highest at 15 min; even at 60 min, this value was higher than in the controls. These findings suggest that secretory granules in somatotrophs are stimulated to divide by GRF, resulting in a decrease in size and an increase in number. The discrepancy between the earlier formation of new secretory granules and the later restoration of intracellular GH levels implies that GRF first stimulates the synthesis of constituents of granules other than GH, and only later the synthesis of GH, and that newly formed small secretory granules contain less GH. From the clearance rate of serum GH and the frequency of granule exocytosis, it can be estimated that about a half million granules are released to maintain 1 ng/ml of serum GH in rats.     

Cycloheximide blocks insulin-like growth factor I but not somatostatin inhibition of growth hormone secretion

Growth hormone secretion is controlled by the two hypothalamic hormones, growth hormone releasing factor (GRF) and somatostatin. In addition, the insulin-like growth factors (IGF or somatomedins) which are themselves growth hormone dependent, inhibit growth hormone release in vitro, therefore acting to close the negative feedback loop. The studies reported here examine some of the differences between inhibition of growth hormone secretion by somatostatin and IGF-I in vitro. The major finding is that cycloheximide, a protein synthesis inhibitor, blocks inhibition of GRF-stimulated growth hormone release caused by IGF-I, without changing the inhibition caused by somatostatin. The experiments were done by exposing mixed rat adenohypophysial cells to secretagogues with or without cycloheximide for 24 h in a short term culture. Somatostatin (0.6 nM) totally blocked rat GRF (1 nM) stimulated growth hormone release to values 48% of control (nonstimulated values), while IGF-I (27 nM) only reduced the GRF-stimulated growth hormone release by 27 +/- 3% (N = 5). Cycloheximide (15 micrograms/mL) totally blocked the effect of IGF-I but not somatostatin. A low concentration (0.12 nM) of somatostatin, which only partly inhibited growth hormone release, was also unaffected by cycloheximide. In purified rat somatotrophs, somatostatin (0.1 nM) inhibited GRF-stimulated cAMP levels slightly and reduced growth hormone release while IGF-I (40 nM) had no effect. We suggest that IGF-I inhibits only the secretion of newly synthesized growth hormone, while somatostatin inhibits both stored and newly synthesized growth hormone pools.     

Rat hypothalamic GRF elicits its biologic action in GH3 cells by interaction with VIP- preferring receptor site(s)

GH3 cells can be used effectively to study the in vitro mechanism of action of GRF. In these cells, there is a time and concentration-dependent release of cAMP into the medium. Rat hypothalamic GRF, (rGRF) is 7 to 10 fold more active than human hypothalamic GRF (hGRF). VIP, a peptide which is structurally homologous to GRF, stimulates cAMP efflux in GH3 cells, with a higher affinity than hGRF or rGRF. We propose that in contradistinction to the normal rat pituitary, the stimulation of cAMP release by GRF in GH3 cells occurs via activation of VIP-preferring receptors and that GRF (rGRF in particular) behaves as a partial VIP agonist.     

Ontogeny of the response to growth hormone-releasing factor

Primary cell cultures were prepared from fetal, neonatal and adult rat pituitaries and evaluated for their ability to secrete growth hormone (GH) in response to growth hormone-releasing factor (GRF). Pituitary cells prepared from fetuses at days 19 and 21 of gestation, neonatal animals at the day of birth (day 0) or the following day (day 1) and peripubertal male rats showed full dose response curves to GRF with maximal GH release when stimulated with 1 X 10(-10) M rat GRF. At this concentration of GRF, the amount of GH released was not different from that elicited by activation of adenylate cyclase with 1 X 10(-5) M forskolin. In contradistinction, a preparation of cells from fetuses at day 18 of gestation did not show the same release of GH when challenged with 1 X 10(-10) M GRF and forskolin (0.057 +/- 0.001, compared to 0.076 +/- 0.003 micrograms/10(5) cells per 4.5 h), although the cells clearly responded to both secretagogues (basal levels of GH, 0.029 +/- 0.002 micrograms/10(5) cells per 4.5 h). While cells prepared from fetuses at day 21 of gestation or from animals after birth released 5-10% of their total cellular GH content, those prepared from 18- and 19-day fetuses released as much as 40% of their total GH suggesting there is a maturation of intracellular GH processing that occurs late in gestation. The results show that, in late pregnancy, the rat fetal pituitary is highly responsive to growth hormone-releasing factor and suggest that this peptide participates in regulating GH levels during the perinatal period.     

Hypothalamic growth hormone-releasing factor (GRF) participates in the negative feedback regulation of growth hormone secretion

Effects of growth hormone (GH) excess on immunoreactive hypothalamic GH-releasing factor (GRF) and somatostatin (SRIF) were studied in rats. Hypothalamic GRF content significantly reduced after 7-day daily treatment with 160 micrograms of rat GH or after inoculation of GH-secreting rat pituitary tumors, MtT-F4 for 9 or 13 days and GH3 for 3 months. Basal and 59 mM K+-evoked release of GRF from incubated hypothalami diminished, more than the content, by 43-51% in MtT-F4 tumor- or by 67-83% in GH3 tumor-bearing rats. In contrast, there was a small but significant increase in content or release of SRIF in rats harboring the GH3 or MtT-F4 tumor, respectively. These results indicate the existence of a negative feedback loop via hypothalamic GRF as well as SRIF in control of GH secretion.     

Dominant dwarfism in transgenic rats by targeting human growth hormone (GH) expression to hypothalamic GH-releasing factor neurons.

Expression of human growth hormone (hGH) was targeted to growth hormone-releasing (GRF) neurons in the hypothalamus of transgenic rats. This induced dominant dwarfism by local feedback inhibition of GRF. One line, bearing a single copy of a GRF-hGH transgene, has been characterized in detail, and has been termed Tgr (for Transgenic growth-retarded). hGH was detected by immunocytochemistry in the brain, restricted to the median eminence of the hypothalamus. Low levels were also detected in the anterior pituitary gland by radioimmunoassay. Transgene expression in these sites was confirmed by RT-PCR. Tgr rats had reduced hypothalamic GRF and mRNA, in contrast to the increased GRF expression which accompanies GH deficiency in other dwarf rats. Endogenous GH mRNA, GH content, pituitary size and somatotroph cell number were also reduced significantly in Tgr rats. Pituitary adrenocorticotrophic hormone (ACTH) and thyroid-stimulating hormone (TSH) levels were normal, but prolactin content, mRNA levels and lactotroph cell numbers were also slightly reduced, probably due to feedback inhibition of prolactin by the lactogenic properties of the hGH transgene. This is the first dominant dwarf rat strain to be reported and will provide a valuable model for evaluating the effects of transgene expression on endogenous GH secretion, as well as the use of GH secretagogues for the treatment of dwarfism.     

Dynamic of the GRF-induced GH response in genetically obese Zucker rats: influence of central and peripheral factors

To determine the time onset of the growth hormone (GH) alteration in the genetically obese rat, we studied the in vivo and in vitro rat growth hormone releasing factor (rGRF(1-29)NH2)-induced GH secretion in 6- and 8-week-old lean and obese male Zucker rats. Under sodium pentobarbital anesthesia, rGRF(1-29)NH2 (GRF) was injected intravenously at two doses: 0.8 and 4.0 micrograms/kg b.w. Basal serum GH concentrations were similar in lean and obese age-matched animals. The GH response to both GRF doses tested was unchanged in 6-week-old obese rats as compared to their lean litter mates. In contrast, a significant decrease of the GH secretion in response to 4.0 micrograms/kg b.w. GRF was observed in the 8-week-old obese rats. The effect of GRF (1.56, 6.25 and 12.5 pM) was further studied in vitro, in a perifusion system of freshly dispersed anterior pituitary cells of lean and obese Zucker rats. Basal GH release was similar in the 6-week-old animal group. In contrast, it was significantly decreased in 8-week-old obese rats as compared to their lean litter mates. Stimulated GH response to 1.56 and 6.25 pM GRF was significantly greater in the 6-week-old obese group than in the age-matched control group. In contrast, the GH response to all GRF concentrations tested was significantly decreased in the 8-week-old obese rats as compared to their respective lean siblings. In 8-week-old obese rats, a decrease of GH pituitary content and an increase of hypothalamic somatostatin (SRIF) concentration were observed. Insulin and free fatty acid serum were significantly increased in 8-week-old obese rats. In contrast, lower insulin-like growth factor I serum levels were observed in the obese animals as compared to their lean litter mates. Finally, to further clarify the role of the periphery in the inhibition of GH secretion observed in the 8-week-old fatty rats, we exposed cultured pituitary cells of 8-week-old lean animals to 17% serum of their obese litter mates. A significant decrease of GRF-stimulated GH secretion of lean rat pituitary cells exposed to the obese serum was noted (P less than 0.05). This study demonstrates that, in the obese Zucker rat, an alteration of the GH response to GRF is evident by the 8th week of life. This defective GH secretion could be related to peripheral and central abnormalities.     

In vitro release of growth hormone-releasing factor (GRF) from the hypothalamus: somatostatin inhibits GRF release.

The manner of release of growth hormone-releasing factor (GRF) from the rat hypothalamus was studied in a perifusion system using a highly sensitive radioimmunoassay for rat GRF. The recovery of GRF in this system was 50-60%. The release of GRF from the rat hypothalamic blocks was almost stable for 20-240 min after the start of the perifusion and was stimulated by depolarization induced by high K+ concentration. The release of GRF was inhibited by somatostatin at concentrations of 10(-11) to 10(-8) M with maximum inhibition to 52.5% of the basal release at a concentration of 10(-9) M. These results suggest that this system is useful in studying the regulatory mechanism of GRF release and that, in addition to its action on the pituitary, somatostatin appears to act at the level of the hypothalamus in inhibiting GRF release in the regulation of GH secretion.     

Effect of a bovine hypothalamic factor on the release and biosynthesis of growth hormone.

Partial purification of growth hormone (GH)-releasing factor (GRF) by acid extraction followed by gel filtration on Sephadex G-25 has been attained from bovine hypothalami. When rat pituitaries were incubated in 2 ml Krebs Ringer-bicarbonate-glucose (KRBG) medium, a stimulatory effect of the GRF fraction on immunoreactive GH (IR-GH) release was observed, while that of the factor neither on GH synthesis nor release of the synthesized GH was demonstrated. Stimulation of the GH release was exerted maximally within 30 min of incubation. Cycloheximide and actinomycin D, at a concentration which inhibited protein and RNA synthesis to less than 5 and 20% of the control, respectively, were without effect on the stimulatory action of the factor on GH release. On the other hand, stimulation of GH synthesis was observed under incubation in 0.3 ml medium with the factor and enhancing effect of the factor on the IR-GH release was undetectable. These results suggest that stimulation of the release and synthesis of GH mediated by the hypothalamic GRF fraction is under influence of the pool size of incubation media.     

Rat growth hormone-releasing factor stimulates cyclic GMP formation and phosphatidylinositol metabolism in the median eminence.

The effects of rat growth hormone releasing factor (rGRF) on somatostatin (SRIF) secretion, cyclic nucleotide production and phosphatidylinositol metabolism were investigated in the median eminence (ME), using an in vitro system. Medium was discarded and replaced by medium containing various concentrations of rGRF or rGRF plus epinephrine (E, 6 x 10(-7) M). rGRF had no effect on basal or E-stimulated release of cAMP. In the same experiments rGRF markedly stimulated SRIF release. These results suggested that cAMP is not involved in the stimulatory effect of GRF on SRIF release. However, GRF significantly stimulated release of both SRIF and cGMP in a dose-related manner. Maximal stimulation was observed at 10(-10) M GRF (p less than 0.005) which also produces maximal SRIF release. 2'0-monobutyrylguanosine 3'5' cyclic phosphate (mbcGMP, 10(-11) to 10(-10) M) stimulated SRIF release from ME fragments (p less than 0.001 at 10(-10) M) whereas the control, sodium butyrate (10(-6) M), had no effect. GRF caused significant elevation of 30.6% in the concentration of labelled inositol phosphates [( 3H]-IPs) in the ME. These data indicate that GRF stimulation of SRIF release is accompanied by increased cGMP production and phosphatidyl-inositol (PI) metabolism but does not alter cAMP production. Because mbcGMP can directly stimulate SRIF release, we suggest that GRF causes a receptor-mediated increase in the metabolism of phosphatidylinositol and cGMP formation. These actions therefore may be among the early metabolic events in the mechanism of GRF-stimulated SRIF release from the ME.     

Phospholipid metabolism and prolactin secretion in vitro

The possible mechanisms by which phospholipid metabolism may be involved in the biochemical events underlying pituitary hormone secretion in basal and stimulated conditions were examined. Particular emphasis was given to the role of changes in the turnover of specific membrane phospholipids, the polyphosphoinositides, in the stimulatory effect of TRH and neurotensin on prolactin release in vitro. Finally, some comments on the involvement of arachidonate and/or its metabolites in the mechanisms of release of the hormone have been reported. In this respect, the possibility that a specific diacylglycerol lipase may represent a link between the 'phosphatidylinositol effect' and the production of arachidonate from mammotroph membranal phospholipids was examined using the rather selective inhibitor of diacylglycerol lipase RHC80267.     

The effect of thyroid hormone and glucocorticoids on carp growth hormone-releasing factor (GRF)-induced growth hormone (GH) release in rainbow trout (Oncorhynchus mykiss).

1. The effect of thyroid hormone and glucocorticoids on carp growth hormone-releasing factor (GRF)-induced growth hormone (GH) secretion was studied on rainbow trout using a dispersed pituitary cell culture system. 2. A combined administration of lower doses (0.01 microM) of 3,5,3'-triiodo-L-thyronine (T3) and dexamethasone (Dex) significantly increased spontaneous as well as carp GRF-induced GH release. 3. Lower doses of Dex alone had no effect, and T3 had a marginal effect on GH release. Higher doses of either Dex or T3 potentially reduced GH release. 4. This study indicates an important role of thyroid hormone and/or glucocorticoids in the hypothalamic regulation of GH secretion in fish.