Catecholaminergic axonal varicosities appear to innervate growth hormone-releasing hormone-immunoreactive neurons in the human hypothalamus: the possible morphological substrate of the stress-suppressed growth.

CONTEXT: Stress is considered to be a major factor in the regulation of growth. Psychosocial dwarfism, characterized with short stature, delayed puberty, and depression, is typically preceded by psychological harassment or stressful environment. It has been observed that stress suppresses GH secretion, possibly via the attenuation of GHRH secretion. However, the exact mechanism of the impact of stress on growth has not been elucidated yet. OBJECTIVE: Our previous studies revealed intimate associations between neuropeptide Y (NPY)-immunoreactive (IR) axonal varicosities and GHRH-IR perikarya in the human hypothalamus. Because NPY is considered to be a stress molecule, NPY-GHRH juxtapositions may represent an important factor of stress-suppressed GHRH release. In addition to NPY, catecholamines are among the major markers of stress. Thus, in the present study, we examined the putative juxtapositions between the catecholaminergic tyrosine hydroxylase (TH)-/dopamine-ß-hydroxylase-/phenylethanolamine N-methyltransferase-IR and GHRH-IR neural elements in the human hypothalamus. To reveal these juxtapositions, double-label immunohistochemistry was used. RESULTS: Our findings revealed that the majority of the GHRH-IR perikarya formed intimate associations with TH-IR fiber varicosities. The majority of these juxtapositions were found in the infundibular nucleus/median eminence. CONCLUSIONS: The lack of phenylethanolamine N-methyltransferase-GHRH associations and the small number of dopamine-ß-hydroxylase-GHRH juxtapositions suggest that the vast majority of the observed TH-GHRH juxtapositions represent dopaminergic associations. The density of the abutting TH-IR fibers on the surface of the GHRH perikarya suggests that these juxtapositions may be functional synapses, and thus, in addition to NPY, catecholamines may regulate GHRH secretion via direct synaptic mechanisms.

A construct of interactive feedback control of the GH axis in the male.

Growth hormone (GH) secretion is controlled by GH-releasing hormone (GHRH), the GH release-inhibiting hormone somatostatin (SRIF), and autofeedback connections. The ensemble network produces sexually dimorphic patterns of GH secretion. In an effort to formalize this system, we implemented a deterministically based autonomous feedback-driven construct of five principal dose-responsive regulatory interactions: GHRH drive of GH pituitary release, competitive inhibition of GH release by SRIF, GH autofeedback via SRIF with a time delay, delayed GH autonegative feedback on GHRH, and SRIF inhibition of GHRH secretion. This formulation engenders a malelike pattern of successive GH volleys due jointly to positive time-delayed feedback of GH on SRIF and negative feedback of SRIF on GH and GHRH. The multipeak volley is explicated as arising from a reciprocal interaction between GH and GHRH during periods of low SRIF secretion. The applicability of this formalism to neuroendocrine control is explored by initial parameter sensitivity analysis and is illustrated for selected feedback-dependent experimental paradigms. The present construct is not overparameterized and does not require an ad hoc pulse generator to achieve pulsatile GH output. Further evolution of interactive constructs could aid in exploring more complex feedback postulates that confer the vivid sexual dimorphism of female GH profiles.

Interactions of growth hormone secretagogues and growth hormone-releasing hormone/somatostatin.

The class of novel synthetic compounds termed growth hormone secretagogues (GHSs) act in the hypothalamus through, as yet, unknown pathways. We performed physiologic and histochemical studies to further understand how the GHS system interacts with the well-established somatostatin (SRIF)/growth hormone-releasing hormone (GHRH) neuroendocrine system for regulating pulsatile GH secretion. Comparison of the GH-releasing activities of the hexapeptide growth hormone-releasing peptide-6 (GHRP-6) and GHRH administered intravenously to conscious adult male rats showed that the pattern of GH responsiveness to GHRP-6 was markedly time-dependent, similar to that observed with GHRH. Immunoneutralization of endogenous SRIF reversed the blunted GH response to GHRP-6 at trough times, suggesting that GHRP-6 neither disrupts nor inhibits the cyclical release of endogenous hypothalamic SRIF. By striking contrast, passive immunization with anti-GHRH serum virtually obliterated the GH responses to GHRP-6, irrespective of the time of administration. These findings suggest that the GHSs do not act by altering SRIF release but, rather, stimulate GH release via GHRH-dependent pathways. Our dual chromogenic and autoradiographic in situ hybridization experiments revealed that a subpopulation of GHRH mRNA-containing neurons in the arcuate (Arc) nucleus and ventromedial nucleus (VMN) of the hypothalamus expressed the GHS receptor (GHS-R) gene. These results provide strong anatomic evidence that GHSs may directly stimulate GHRH release into hypophyseal portal blood, and thereby influence GH secretion, through interaction with the GHS-R on GHRH- containing neurons. Altogether, these findings support the notion that an additional neuroendocrine pathway may exist to regulate pulsatile GH secretion, possibly through the influence of the newly discovered GHS natural peptide, ghrelin.

Growth hormone-releasing factor affects macronutrient intake during the anabolic phase of zinc repletion: total hypothalamic growth hormone-releasing factor content and growth hormone-releasing factor immunoneutralization during zinc repletion.

Growth hormone-releasing factor (GRF) is thought to perform two distinct functions within the brain. GRF synthesized in the median eminence (ME) stimulates the release of growth hormone (GH) from the pituitary, while GRF in the suprachiasmatic nucleus and median preoptic area (SCN/MPOA) may stimulate selection of dietary protein. These two functions may be coupled to regulate and enhance growth. During zinc repletion, a period characterized by increased protein intake and accelerated growth, we examined this coupling by measuring GRF peptide content in hypothalamic sites and neutralizing GRF function by infusing anti-GRF antibody into the hypothalamus during zinc repletion. Total GRF content and GRF content in the ME and SCN/MPOA were decreased in zinc-deficient (Zn-) rats compared to zinc-adequate (Zn+) rats (P < 0.05). There were no differences in GRF content during zinc repletion in either nuclei. Subsequently, we investigated the macronutrient feeding patterns of rats chronically infused with anti-GRF IgG into the lateral ventricle of the brain during zinc repletion. All Zn- and Zn+ rats administered anti-GRF IgG exhibited a reduction in protein intake during zinc repletion. The Zn- rats receiving anti-GRF-IgG consumed equal amounts of total diet compared to those receiving vehicle during the repletion period however they consumed less carbohydrate (P < 0.05) and considerably more fat (P < 0.02). There were no significant differences in carbohydrate or fat intake in Zn+ rats receiving anti-GRF antibody. These results suggest that GRF likely directs protein intake during normal growth, but may interact with additional appetite-controlling neuropeptides during zinc repletion.

Humoral regulation of physiological sleep: cytokines and GHRH.

Interleukin-1, tumour necrosis factor, and growth hormone releasing hormone form part of the humoral mechanisms regulating physiological sleep. Their injection enhances non-rapid-eye-movement sleep whereas their inhibition reduces spontaneous sleep and sleep rebound after sleep deprivation. Changes in their mRNA levels and changes in their protein levels in the brain are consistent within their proposed role in sleep regulation. Furthermore, results from transgenic and mutant animals also are suggestive of their role in sleep regulation. The sites responsible for the growth hormone releasing hormone somnogenic activity seem to reside in the anterior hypothalamus/basal forebrain. Somnogenic sites for interleukin-1 and tumour necrosis factor likely include the anterior hypothalamus, but also may extend beyond that area. These substances elicit non-rapid-eye-movement sleep via a biochemical cascade that includes other known sleep regulatory substances.

Negative regulation of hypothalamic growth hormone-releasing factor messenger ribonucleic acid by growth hormone and insulin-like growth factor I.

Increased growth hormone-releasing factor messenger ribonucleic acid (GRF mRNA) and decreased somatostatin (SRIF) mRNA levels have been reported in the hypothalamus of hypophysectomized rats as well as of dwarf mice. In order to elucidate the effect of the growth hormone-insulin-like growth factor I (GH-IGF-I) axis on hypothalamic GRF and SRIF synthesis, we measured levels of mRNA coding for GRF and SRIF and for pituitary GH in pubertal male rats treated for 3 weeks with antirat GRF gamma-globulin (GRF-ab), anti-SRIF gamma-globulin (SRIF-ab) or both. Immunoneutralization of circulating endogenous GRF resulted in a marked decrease in serum IGF-I and pituitary GH mRNA levels in Northern blot analysis, whereas it caused a significant increase in GRF mRNA levels in the arcuate nucleus as assessed by both Northern blot and in situ hybridization analysis. SRIF mRNA levels in the periventricular nucleus were slightly decreased by GRF-ab treatment when analyzed by in situ hybridization, but not significantly after Northern blot analysis. Immunoneutralization of circulating endogenous SRIF failed to affect mRNA levels of hypothalamic GRF and SRIF but caused a slight reduction in pituitary GH mRNA levels. Levels of mRNA coding for hypothalamic GRF and pituitary GH were also measured by Northern blot analysis in young male rats treated with rat GRF-ab for 2 weeks and replaced with rat GH or IGF-I for the second 1 week. Replacement with either rat GH or IGF-I suppressed the increased hypothalamic GRF mRNA levels. These data indicate that endogenous GRF is essential for normal synthesis of pituitary GH and that both GH and IGF-I negatively regulate the synthesis of hypothalamic GRF.

Characterization and localization of mouse hypothalamic growth hormone-releasing factor and effect of gold thioglucose-induced hypothalamic lesions.

Hypothalamic growth hormone-releasing factor (GRF) in higher mammals, including human GRF, is a 44 amino acid residue peptide and is highly homologous in structure. By contrast, mouse GRF (mGRF) recently deduced by cDNA cloning consists of only 42 residues and shows relatively low homology to the GRFs of higher mammals and the same rodent species, rat. To characterize and localize the predicted mature mGRF peptide in the hypothalamus, we have generated its antiserum and developed a homologous radioimmunoassay. Immunoreactive mGRF in the acid hypothalamic extract was eluted as a single peak at a position identical to that of synthetic peptide on both gel filtration chromatography and reverse-phase high-performance liquid chromatography (HPLC). Secretion of immunoreactive mGRF from incubated hypothalami increased several fold in response to 50 mM K+, and this rise was abolished in the absence of medium Ca2+. Only a single peak of immunoreactive mGRF that coeluted with synthetic replicate was observed after the K(+)-stimulated medium was extracted on Bond Elut C18 cartridges and applied on reverse-phase HPLC. Immunohistochemistry identified many mGRF-positive cell bodies in the arcuate nucleus and dense bundles of immunoreactive fibers in the median eminence. Treatment of mice with gold thioglucose (GTG), a chemical agent known to cause hypothalamic lesions, markedly depleted both content and in vitro secretion of immunoreactive mGRF. The decline in mGRF secretion was greater in GTG obese than in nonobese mice, whereas somatostatin secretion was not affected by GTG treatment.(ABSTRACT TRUNCATED AT 250 WORDS)

Long-term changes of somatotrophic function induced by deprivation of growth hormone-releasing hormone during the fetal life of the rat.

We have studied the effects of intra-amniotic administration of an anti-GH-releasing hormone serum (GHRH-Ab) on day 16 of fetal life in the rat, when the ontogenetic development of the GHRH neuronal system occurs. Control animals received normal rabbit serum. Following delivery, body weight was monitored for the next 30 days as an index of somatic growth, and the following indices of somatotrophic function were determined: plasma and pituitary GH, pituitary GH mRNA, hypothalamic GHRH and somatostatin mRNA, and the in vivo GH responsiveness to GHRH. At birth, GHRH-Ab-treated rats had a body weight that was equivalent to that of control rats but, starting from postnatal day 6 up to day 30, they had a significantly reduced body weight. Pituitary weight, the absolute pituitary GH content and GH mRNA levels were lower in experimental compared with control rats, while pituitary GH concentrations were similar in the two groups, thus implying that there was a defect, not only in GH synthesis, but also in GH release. In agreement with this theory, basal GH levels and GHRH-stimulated GH secretion were reduced in GHRH-Ab-treated rats but, in contrast, hypothalamic regulation of GH secretion appeared to be working in these rats as they were still able to respond to the low plasma GH by increasing GHRH and decreasing somatostatin mRNA levels. These findings indicate that deprivation of GHRH during fetal life induces long-lasting changes of growth rate and somatotrophic function.(ABSTRACT TRUNCATED AT 250 WORDS)

Deprivation of growth hormone-releasing hormone early in the rat's neonatal life permanently affects somatotropic function.

This work investigated in rats whether passive immunization against the endogenous GHRF in the early postnatal period led to permanent alterations of somatotropic function, similar to those observed in several human growth disorders, e.g. constitutional growth delay (CGD). On postnatal days 1, 2, 4, 6, 8, and 10, rats were given an anti-GHRF-serum (GHRH-Ab, 100 microliters/rat, sc) and were tested 1, 30, and 60 days after this treatment for basal and GHRH-stimulated GH secretion both in vivo and in vitro. GHRH-Ab reduced both basal and GHRF-stimulated GH secretion at all intervals and induced marked and chronic impairment of growth rate. The following differences were observed in the GHRH-Ab treated rats compared to normal rabbit serum-treated controls: 1) GH biosynthesis (incorporation of L-[3H]leucine into the electrophoretic band of GH): reduction of about 70%, 1 day but not 30 days after treatment; 2) Pituitary weight: significant reduction in absolute weight (30-40%) at all posttreatment intervals, and relative weight, 1 and 30 days after treatment. 3) Pituitary GH concentration: significant reduction in GH content (about 40%) but not concentration, at all posttreatment intervals; 4) Percentage of somatotrophs (immunocytochemistry): about 40% reduction 1 day, but not 30 and 60 days after treatment; 5) Hypothalamic somatostatin messenger RNA (mRNA) levels in situ hybridization): selective reduction (40%) in the periventricular nucleus 1 day but not 30 days after treatment; 6) Hypothalamic somatostatin cell number (immunocytochemistry): no significant changes in any hypothalamic area at any interval; 7) Pituitary somatostatin binding (in situ autoradiography): significant reduction, 1 day and 30 days after treatment; 8) Somatostatin inhibition of GH release "in vitro": somatostatin effect on GH release was reduced 30 days after treatment. These and previous data indicate that: 1) Transient deprivation of GHRF in the immediate postnatal period of the rat leads to permanent impairment of growth rate and somatotropic function; 2) GHRF deficiency itself or through reduction of GH secretion impairs somatostatin functions temporarily in the hypothalamus and permanently in the pituitary; 3) This rat model may mimic some forms of growth disorders in humans and holds promise as useful tools for investigating the underlying pathophysiological mechanisms.

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.

Opioid control of growth hormone in the suckled sow is primarily mediated through growth hormone releasing factor.

Endogenous opioid peptides mediate the effect of suckling on LH and PRL in the domestic pig. However, the role of opioids in modulating GH during lactation in swine is not known. Primiparous sows that had been immunized against GRF(1-29) conjugated to human serum albumin (GRF-HSA, n = 5) or HSA (n = 4) were used to determine changes in GH after naloxone. Treatments were imposed in all sows on day 21 of lactation when antibody titers were 9100 +/- 1629. All sows received (i.v.) naloxone (0.25 mg/kg) or saline (0.0125 ml/kg) at 15 min intervals for 165 min. Active immunization against GRF-HSA during lactation decreased (P less than 0.05) mean concentration (4.8 +/- 0.2 vs 2.6 +/- 0.1 ng/ml) and frequency (1.5 +/- 0.3 vs 0.4 +/- 0.2 peaks/4 hr). Concentrations of LH and PRL were similar in GRF-HSA and HSA immunized sows. Naloxone suppressed (P less than 0.05) GH in all sows. In HSA sows, naloxone abolished episodic release of GH and decreased average, but not basal, concentrations of GH. In sows immunized against GRF-HSA, naloxone decreased (P less than 0.05) average and basal GH but failed to decrease frequency of GH release. Naloxone failed to alter frequency of LH release. Concentrations of PRL decreased (P less than 0.05) after naloxone in all sows. In conclusion, immunization against GRF-HSA blocked most of the effect of lactation on GH. Blocking opioid receptors with naloxone decreased GH and PRL in all sows. In contrast to previous findings naloxone had no effect on LH. Opioids alter concentrations of GH through a GRF dependent and GRF independent pathway.

A possible role of hypothalamic somatostatin in the maintenance of rat pituitary responsiveness to growth hormone-releasing factor.

To characterize the role of hypothalamic somatostatin (SRIF) in regulating pituitary responsiveness to GH-releasing factor (GRF) in vitro, we reduced SRIF input to the rat anterior pituitary through the portal vessels. Three different paradigms were used as follows: 1) anterolateral hypothalamic deafferentation, 2) electrolytic lesions of the periventricular nucleus, and 3) passive immunization with SRIF antiserum. Rat CRF content in the stalk-median eminence markedly decreased to 19% and 57% of that of sham-operated controls 10 days after the deafferentation and the lesions, respectively. In contrast, rat GRF content was unchanged by either operation. SRIF content markedly decreased to 78%, 12%, and 2% of the control level 1, 3, and 10 days after deafferentation, respectively, and to 48% and 8%, 1 and 10 days after the lesions, respectively. The serum GH concentration was significantly increased 1 and 3 days after the deafferentation (P less than 0.01) and also 1 day after the lesions (P less than 0.01), followed by no increase 10 days after either operation. Anterior pituitary weight and GH content markedly decreased 3 and 10 days and 10 days after the deafferentation and the lesions, respectively. The human GRF (0.1 microM)-induced GH release response of anterior pituitaries removed from these treated rats was examined in an in vitro perifusion system. Even 1 day after these treatments, GH responsiveness was clearly attenuated by anterolateral hypothalamic differentiation (8.61 +/- 0.78 vs. 3.62 +/- 0.54 micrograms GH/h; P less than 0.01), periventricular nucleus lesions (6.52 +/- 1.07 vs. 3.20 +/- 0.53 micrograms GH/h; P less than 0.01) and passive immunization with SRIF antiserum (5.80 +/- 0.43 vs. 2.54 +/- 0.16 micrograms GH/h; P less than 0.01). This attenuated responsiveness gradually deteriorated 3 and 10 days after the surgical operations. These results indicate that SRIF neurons in the anterior periventricular nucleus play a role in maintaining the pituitary responsiveness to GRF, in addition to the original action of inhibiting GH release.

[The effects of PGE2, 2-DG and L-arginine on hypothalamic GHRH and SRIF releases in conscious rats, with respect to GH secretion].

The effects of prostaglandin E2 (PGE2), 2-deoxy-D-glucose (2-DG) and L-arginine on hypothalamic GHRH and SRIF release with respect to GH secretion were studied in conscious male rats. Intracerebroventricular (icv) injection of 5 micrograms PGE2 and intravenous (iv) infusion of 1 g/kgBW L-arginine caused an increase in plasma GH levels, but icv (36 micrograms) or iv (400 mg/kgBW) injection of 2-DG suppressed spontaneous GH surge in conscious rats. The concentration of hypothalamic GHRH was decreased in all three groups of the animals, but the concentration of hypothalamic SRIF was decreased only in 2-DG-treated animals. In the perifusion system using rat hypothalamus, PGE2 (0.28 microM, 2.8 microM), 2-DG (22 mM) and L-arginine (3 mM) stimulated GHRH release from rat hypothalamus. 2-DG also stimulated SRIF release more predominantly than GHRH release. Passive immunization with anti-GHRH serum inhibited the GH secretion induced by icv injection of 5 micrograms PGE2 and by iv infusion of 1 g/kgBW L-arginine in conscious rats. In contrast, GH secretion induced by iv injection of 50 micrograms/kgBW PGE2 was not affected by the pretreatment with the antiserum. These results suggest that the central effect of PGE2 and peripheral effect of L-arginine to stimulate GH secretion are mediated by hypothalamic GHRH release, and that the inhibitory effect of 2-DG on GH secretion is predominantly mediated by hypothalamic SRIF release rather than GHRH release in rats.

Multiple forms of immunoreactive growth hormone-releasing hormone in human plasma, hypothalamus, and tumor tissues.

We examined the nature of GHRH in plasma of normal subjects and patients with acromegaly, hypothalamic tissue, pheochromocytoma, and GHRH-producing pancreatic tumor tissue using two RIAs of different specificity. One assay was a N-terminal assay that recognized GHRH-(1-44)-NH2, GHRH-(1-40)-OH, and GHRH-(1-37)-OH equally, and the other was a C-terminal assay that recognized only the COOH-terminal amidated sequence of GHRH-(1-44)-NH2. GHRH immunoreactivity was detectable in all samples in both assay systems, but the ratios of C- to N-terminal activity differed. The gel filtration profiles of plasma and tumor tissue revealed one peak in (or near) the position of synthetic GHRH-(1-44)-NH2. In contrast, two peaks were found in hypothalamic tissue; a major peak in the position of synthetic GHRH-(1-44)-NH2 and a higher mol wt peak. Ion exchange chromatography of the immunoreactive GHRH material from gel filtration of pooled plasma from normal subjects revealed three components of immunoreactive GHRH, one major peak in the position of GHRH-(1-40)-OH and two minor peaks in the positions of GHRH-(1-44)-NH2 and GHRH-(1-37)-OH. Two components of immunoreactive GHRH, a major peak in the position of GHRH-(1-44)-NH2 and a minor peak in the position of GHRH-(1-40)-OH, were found in hypothalamic tissue and pheochromocytomas. In the two ectopic GHRH-producing pancreatic tumors, three components of immunoreactive GHRH were detected: a major peak in the position of GHRH-(1-40)-OH, a smaller peak in the position of GHRH-(1-37)-OH, and a very small peak of GHRH-(1-44)-NH2. Synthetic GHRH-(1-44)-NH2 was not degraded by plasma during the extraction procedures. These results suggest that 1) the measured immunoreactive GHRH concentration differs when the same samples are measured by RIAs using antisera with different specificities; 2) such differences may be due to the presence of microheterogeneity of immunoreactive GHRH; 3) the microheterogeneity of immunoreactive GHRH in plasma is different from that in the hypothalamus; and 4) the posttranslational processing of GHRH in human hypothalamus is similar to that of pheochromocytomas but different from that of ectopic GHRH-producing pancreatic tumors.

The rebound release of growth hormone (GH) following somatostatin infusion in rats involves hypothalamic GH-releasing factor release.

We have studied the rebound secretion of GH following short-term somatostatin (SS) infusions in conscious rats, using an automatic sampling system for withdrawing frequent microsamples of blood. Intravenous infusions of SS (5-50 micrograms/h per rat) inhibited spontaneous GH secretion, but when SS was withdrawn there was a large burst of rebound GH secretion. A sub-anaesthetic dose of urethane reduced such rebound bursts of GH, suggesting a hypothalamic involvement in rebound GH secretion. Passive immunization with an antibody against rat GH-releasing factor (GRF) attenuated the rebound GH secretory response to the withdrawal of an SS infusion (GH concentration during rebound secretion was 26 +/- 21 micrograms/l vs 475 +/- 127 micrograms/l (mean +/- S.E.M.), after 0.5 ml anti-GRF serum or non-immune serum respectively). The inhibition of GH rebound secretion was related to the dose of anti-GRF serum administered. Intravenous infusions of human GH (20-100 micrograms/h per rat) also reduced the size of the rebound GH secretion following SS withdrawal, in both male and female rats. We suggest that the rebound GH secretion that follows SS withdrawal in vivo is caused mainly by a hypothalamic release of GRF. Exogenous GH inhibits SS-induced rebound GH secretion in the conscious rat, possibly by inhibiting hypothalamic GRF release.

Epinephrine mediates the growth hormone-releasing effect of galanin in infant rats.

The mechanism underlying the GH-releasing effect of galanin (GAL), a novel 29-amino acid peptide, was investigated in the neonatal rat. The effect of galanin was compared to that of clonidine (CLO), a drug known to release GH via endogenous GHRF. GAL administration (5-25 micrograms/kg BW, sc) induced in 10-day-old pups a clear-cut and dose-related rise in plasma GH 15 min postinjection. CLO (50-450 micrograms/kg BW, sc) induced a marked rise in plasma GH, but no dose-related effect was evident. Inhibition of hypothalamic norepinephrine and epinephrine biosynthesis by DU-18288 (6 mg/kg BW, ip) or selective inhibition of epinephrine biosynthesis by SKF-64139 (50 mg/kg BW, ip) completely abolished the GH-releasing effect of GAL (25 micrograms/kg, sc), but left unaltered the GH rise induced by CLO (150 micrograms/kg, sc). Passive immunization with an anti-GHRF serum decreased basal GH levels and prevented the GH-releasing effect of either GAL or CLO, whereas in pups pretreated with an antisomatostatin serum, CLO, but not GAL, increased the already elevated plasma GH titers. In all these data indicate that in the infant rat 1) GAL is a potent GH secretagogue; 2) the action of GAL is not exerted directly on GHRF- or somatostatin-secreting structures, but requires the intervention of catecholaminergic neurons; 3) the GH-releasing effect of GAL is ultimately exerted via GHRF release, although a mechanism operating to inhibit hypothalamic somatostatin release cannot be ruled out; and 4) differently from GAL, CLO releases GH via postsynaptic stimulation of GHRF-secreting neurons.

GRF immunoreactive neurons in the paraventricular nucleus of the rat: an immunohistochemical study with monoclonal and polyclonal antibodies.

Our study demonstrates a complex GRF neuronal system within the rat hypothalamus. Using both high affinity polyclonal and high specificity monoclonal antibodies to rat (r) GRF, we have substantiated evidence for immunoreactive GRF (GRF-i) perikarya in the parvocellular portion of the paraventricular nucleus. Other hypothalamic areas containing rGRF-positive perikarya include the lateral arcuate nucleus, lateral hypothalamus, perifornical area and dorsomedial nucleus. GRF-i neuronal terminals were seen in the external zone of the median eminence, more rostrally in the periventricular nucleus, and near the suprachiasmatic nucleus and more caudally in the dorsomedial nucleus and ventral premammillary nucleus.

Unrelated peptide immunoreactivities coexist in neurons of the rat lateral dorsal hypothalamus: human growth hormone-releasing factor1-37-, salmon melanin-concentrating hormone- and alpha-melanotropin-like substances.

Antisera raised against 3 unrelated synthetic neuropeptides - salmon melanin-concentrating hormone, human growth hormone-releasing factor1-37, and alpha-melanotropin - stained the same extensive neuron population in lateral and dorsal areas of the posterior hypothalamus. Controls for specificity have shown that these 3 antisera bind 3 different epitopes. Differences in intracellular staining patterns suggest that these epitopes could be borne by distinct peptides.

Effect of oral glucose administration on plasma growth hormone-releasing hormone (GHRH)-like immunoreactivity levels in normal subjects and patients with idiopathic GH deficiency: evidence that GHRH is released not only from the hypothalamus but also from extrahypothalamic tissue.

Using a specific and sensitive RIA for GH-releasing hormone (GHRH), we examined the effect of oral administration of 75 g glucose on peripheral plasma GHRH-like immunoreactivity (GHRH-LI) in normal subjects (n = 12) and patients with idiopathic GH deficiency (IGHD) (n = 6). The normal subjects had two peaks of plasma GHRH-LI after oral glucose administration. The initial peak GHRH-LI levels occurred 30-150 min after glucose ingestion and corresponded to an increase in blood glucose. The increment in plasma GHRH-LI levels 30 min after glucose ingestion [7.4 +/- 2.4 (+/- SEM) pg/ml] was significantly higher (P less than 0.05) than that during a control study. Second peaks in plasma GHRH-LI occurred 3.5-6 h after glucose ingestion, and the mean increment 5 h after glucose ingestion was 9.4 +/- 2.4 pg/ml. This second rise of plasma GHRH-LI coincided with a significant increase in plasma GH after reactive hypoglycemia. This second GHRH-LI peak and the rise of plasma GH after hypoglycemia were absent in patients with IGHD, whereas the first peak of plasma GHRH-LI appeared shortly after glucose ingestion in these patients as well as in normal subjects. In addition, hypoglycemia produced by iv injection of regular insulin (0.1 U/kg) was not accompanied by increases in plasma GHRH-LI and GH levels in patients with IGHD, whereas insulin-induced hypoglycemia resulted in significant elevations of both plasma GHRH-LI and GH levels in normal subjects. These findings suggest that peripheral plasma GHRH-LI is derived from the hypothalamus as well as from an extrahypothalamic source(s); extrahypothalamic GHRH is released shortly after glucose ingestion; and secretion of GHRH from the hypothalamus is stimulated by hypoglycemia.

Coexpression of human growth hormone-releasing factor 1-37-like and alpha-melanotropin-like immunoreactivities in neurones of the rat lateral dorsal hypothalamus.

Antibodies recognizing the 29-37 sequence of the human somatocrinin specifically stain a large population of interneurones located in the lateral dorsal hypothalamus. Staining comparisons revealed that these perikarya also contain alpha-MSH-like immunoreactivity. The neurones exhibiting human GRF1-37-like immunoreactivity correspond to the system previously shown to present alpha-MSH-like and rat CRF-like immunoreactivities.