Pulsatile cerebrospinal fluid and plasma ghrelin in relation to growth hormone secretion and food intake in the sheep.

As in other species, exogenous administration of ghrelin, an endogenous ligand for the growth hormone (GH) secretagogue receptors can stimulates feeding behaviour and GH secretion in the sheep. However, the importance of endogenous ghrelin for these two functions as well as its central or peripheral origin remained to be established. In the present study, cerebrospinal fluid (CSF) ghrelin concentrations were measured in five anoestrous ewes and found to be more than 1000-fold lower than circulating plasma levels, in keeping with the even lower concentration in hypothalamic compared to abomasum tissue extracts. Cluster analysis indicated that CSF ghrelin levels were markedly pulsatile, with a greater number of peaks than plasma ghrelin. Pulsatility parameters were closer for GH and CSF ghrelin than between GH and plasma ghrelin. Plasma ghrelin and GH levels were significantly correlated in three out of five ewes but CSF ghrelin and GH in one ewe only. Half of the CSF ghrelin episodes were preceded by a ghrelin peak in plasma with a 22-min delay. Cross-correlations between plasma GH and plasma or CSF ghrelin did not reach significance but a trend towards cross-correlation was observed from 20 to 0 min between plasma and CSF ghrelin. At 09.00 h, when food was returned to ewes, voluntary food intake did not elicit a consistent change in plasma or CSF ghrelin levels. By contrast, a peripheral ghrelin injection (1 mg, i.v.) immediately stimulated feeding behaviour and GH secretion. These effects were concomitant with a more than ten-fold increase in plasma ghrelin levels, whereas CSF ghrelin values only doubled 40-50 min after the injection. This suggests that peripherally-injected ghrelin crosses the blood-brain barrier, but only in low amount and with relatively slow kinetics compared to its effects on GH release and food intake. Taken together, the results obtained in the present study support the notion that, in the ovariectomised-oestradiol implanted sheep model, peripheral ghrelin injection rapidly induces GH secretion, and feeding behaviour, probably by acting on growth hormone secretagogue receptor subtype 1 located in brain regions in which the blood-brain barrier is not complete (e.g. the arcuate nucleus).

Effects of age on thermoregulatory responses during cold exposure in a nonhuman primate, Microcebus murinus.

Cold resistance appears altered with aging. Among existing hypotheses, the impaired capacity in response to cold could be related to an altered regulation of plasma IGF-1 concentration. The combined effects of age and cold exposure were studied in a short-living primate, the gray mouse lemur (Microcebus murinus), which adjusts its energy balance using a daily torpor phase, to avoid high energy cost of normothermia maintenance. Changes in body mass, core temperature, locomotor activity, and caloric intake were monitored under 9-day exposures to 25 degrees C and 12 degrees C in captive animals in winter conditions. Short-term (after 2 days) and long-term (after 9 days) cold-induced changes in IGF-1 levels were also evaluated. In thermoneutral conditions (25 degrees C), general characteristics of the daily rhythm of core temperature were preserved with age. At 12 degrees C, age-related changes were mainly characterized by a deeper hypothermia and an increased frequency of torpor phases, associated with a loss of body mass. A short-term cold-induced decrease in plasma IGF-1 levels was observed. IGF-1 levels returned to basal values after 9 days of cold exposure. No significant effect of age could be evidenced on IGF-1 response. However, IGF-1 levels of cold-exposed aged animals were negatively correlated with the frequency of daily torpor. Responses exhibited by aged mouse lemurs exposed to cold revealed difficulties in the maintenance of normothermia and energy balance and might involve modulations of IGF-1 levels.

Pituitary cocaine- and amphetamine-regulated transcript expression depends on the strain, sex and oestrous cycle in the rat.

Cocaine- and amphetamine-regulated transcript (CART) mRNA and peptides are abundant in the adenohypophysis, but their role in pituitary function has not yet been elucidated. CART peptides were recently shown to colocalise with luteinising hormone (LH) or prolactin in rat anterior pituitary, and contradictory results concerning the peptide effects on pituitary hormonal secretions were obtained in vitro from pituitary cell cultures. Thus, we reinvestigated the expression of CART mRNA within the pituitary. Immunohistochemistry for pituitary hormones was performed on sections from adult male Wistar rats followed by in situ hybridisation using CART mRNA antisense 35S-labelled probes. The most represented CART-expressing cells were lactotrophs (42 +/- 1% of CART cells) and gonadotrophs (32 +/- 3%), followed by thyrotrophs (10 +/- 2%), corticotrophs (7 +/- 2%) and somatotrophs (6 +/- 1%). In the pars tuberalis, CART mRNA was easily detectable in gonadotrophs and lactotrophs and, to a lesser extent, in corticotrophs and thyrotrophs. CART peptide was quickly and potently released from perifused pituitary by depolarisation (K+ 30 mM for 15 min; 465 +/- 37% over basal release, n = 5). Gonadotrophin-releasing hormone and thyrotrophin-releasing hormone (0.1 microM) were also active to a lesser extent (138 +/- 11% and 71 +/- 17, n = 7, respectively). CART (0.1 microM) did not modify basal LH or prolactin release but selectively inhibited K+-induced LH release without affecting K+-induced prolactin secretion. Pituitary CART mRNA and content were sex dependent and varied during the oestrous cycle, being lower in dioestrous 2. Pituitary CART content also varied widely amongst rat strains being five to six-fold higher in Wistar and Fischer rats compared to Brown Norway and Lou C rats. Ageing differentially affected pituitary CART mRNA and content, resulting in a marked decrease in Lou C and an increase in Wistar and Sprague-Dawley rats. Taken together, these results suggest that pituitary CART expression is dependent of the sex steroid environment and may be physiologically involved in LH secretion.

Donepezil restores GH secretion in old rats without affecting the sleep/wake cycle.

A chronic treatment with a cholinesterase inhibitor, donepezil (0.085 mg/kg/h for 30 days) increases significantly the number and amplitude of growth hormone (GH) pulses in 3- and 24-month-old rats without modifying nadir GH values. This treatment does not reduce age-related alterations in sleep/wake cycle but it increases immobility-related high-voltage spindles (HVS) in old animals. These data suggest that cholinergic mechanisms involved in age-related alterations in GH and sleep regulation are different.

A century of GH research revisited: from linear models to network complexity.

The history of GH started with the pioneer clinical and anatomical observations of Pierre Marie, who described the symptoms of acromegaly in 1886. Progressively, histochemical and histophysiological methods made it possible to characterize most cell types responsible for normal or pathological pituitary hormone secretion. Although the methods applied were indirect, and hormonal function assigned to each cell type could only be inferred from correlations, the quality of the corresponding studies was such that most of their results proved correct. In the second half of the XXth century, biochemical methods and bioassays led, between 1943 and 1956, to the production from pituitary extracts of highly purified fractions containing somatotropin activity. The subsequent demonstration that hypothalamo-hypophyseal interactions are of a neurohumoral nature permitted isolation of neuropeptides, a new class of neurotransmitters, many of which turned into major therapeutic agents. Subsequent purification of hundreds of neuropeptides, many with hypophysiotropic activity, and mapping of neurons producing them permitted to shift from relatively simple theories, postulating that stimulatory and inhibitory peptides are sufficient to account for the physiological control of pituitary secretion to more complex models. These permitted to understand how complex neuronal networks can produce a fine tuning of multiple combinations of neuropeptides and neurotransmitters, which interact with each other to adapt hormonal secretion to discrete physiological and pathological conditions.

Endogenous ghrelin regulates episodic growth hormone (GH) secretion by amplifying GH Pulse amplitude: evidence from antagonism of the GH secretagogue-R1a receptor.

Ghrelin was purified from rat stomach as an endogenous ligand for the GH secretagogue (GHS) receptor. As a GHS, ghrelin stimulates GH release, but it also has additional activities, including stimulation of appetite and weight gain. Plasma GH and ghrelin secretory patterns appear unrelated, whereas many studies have correlated ghrelin variations with food intake episodes. To evaluate the role of endogenous ghrelin, GH secretion and food intake were monitored in male rats infused sc (6 mug/h during 10 h) or intracerebroventricularly (5 microg/h during 48 h) with BIM-28163, a full competitive antagonist of the GHS-R1a receptor. Subcutaneous BIM-28163 infusion significantly decreased GH area under the curve during a 6-h sampling period by 54% and peak amplitude by 46%. Twelve hours after the end of treatment these parameters returned to normal. Central treatment was similarly effective (-37 and -42% for area under the curve and -44 and -49% for peak amplitude on the first and second days of infusion, respectively). Neither peripheral nor central BIM-28163 injection modified GH peak number, GH nadir, or IGF-I levels. In this protocol, food intake is not strongly modified and water intake is unchanged. Subcutaneous infusion of BIM-28163 did not change plasma leptin and insulin levels evaluated at 1200 and 1600 h. On the contrary, central BIM-28163 infusion slightly increased leptin and significantly increased insulin concentrations. Thus, endogenous ghrelin, through GHS-R1a, acts as a strong endogenous amplifier of spontaneous GH peak amplitude. The mechanisms by which ghrelin modifies food intake remain to be defined and may involve a novel GHS receptor.

Plasma and hypothalamic peptide-hormone levels regulating somatotroph function and energy balance in fed and fasted states: a comparative study in four strains of rats.

Both growth hormone (GH)/insulin growth factor (IGF)-1 axis and energy balance have been implicated in longevity independently. The aim of the present study was to characterize the effect of a 72-h fasting period at 3 months of age in four different rat strains: (i) Wistar and (ii) Fischer 344 rats, which develop obesity with age, and (iii) Brown Norway and (iv) Lou C rats, which do not. Wistar rats ate more, were significantly bigger, and presented with higher plasma leptin and lower ghrelin levels and hypothalamic growth hormone-releasing hormone (GHRH) content than rats from the three other strains. Plasma insulin and IGF-1 levels were lower in Brown Norway and Lou C rats, and somatostatin content was lower in Brown Norway rats only. Glycaemia was lower in Lou C rats that displayed a lower relative food intake compared to Fischer and Wistar rats. Brown Norway rats showed a greater caloric efficiency than the three other strains. Concerning major hypothalamic neuropeptides implicated in feeding, similar amounts were detected in the four strains for neuropeptide Y, agouti-related peptide, galanin, melanin-concentrating hormone, alpha-melanocortin-stimulating hormone (alpha-MSH) and corticotropin-releasing hormone. Orexin A appeared to be slightly elevated in Fischer rats and cocaine amphetamine-regulated transcript (CART)(55-102) diminished in Brown Norway. At the mRNA level, orexin A, GHSR1, alpha-MSH and CART expression were higher in Wistar and Lou C rats. Principal component analysis confirmed the presence of two main factors in the ad libitum rat population; the first being associated with growth-related parameters and the second being associated with food intake regulation. Hypothalamic GHRH and somatostatin content were positively correlated with feeding-related neuropeptides such as alpha-MSH for GHRH, and orexin A and CART for both peptides. Plasma ghrelin levels were negatively correlated with leptin and IGF-1 levels. Finally, a 72-h fasting period affected minimally body weight, plasma IGF-1 and leptin levels in Lou C rats compared to the three other strains, and plasma insulin levels were less affected in Brown Norway rats. In conclusion, Wistar shorter life span is consistent with its already fatter phenotype at 3 months of age. In terms of IGF-1, glycaemia and leptin responses to fasting, the Lou strain, which presents with a low food intake/body weight and caloric efficiency, is the least affected. The link between food intake regulation, GH axis and ageing is further demonstrated by principal component analysis, where GHRH and somatostatin were found to be strongly associated with energy homeostasis parameters.

Age-associated changes in hypothalamic and pituitary neuroendocrine gene expression in the rat.

A cDNA membrane array displaying 1183 probes was used to detect hypothalamic and pituitary changes in gene expression accompanying ageing and age-associated pituitary macroadenomas. Four groups of male Sprague-Dawley rats (3-, 15-, 24-month-old and 24-month-old with prolactinoma) were compared in two independent hybridizations. cDNA array data were confirmed and completed by comparative reverse transcriptase-polymerase chain reaction on selected genes. The expression of 454 and 116 mRNAs was detected in hypothalamus and pituitary, respectively. Growth hormone (GH) mRNA alone represented 85% of total gene expression in the gland of young rats, and other pituitary hormone transcripts 2.8%, while melanin-concentrating hormone (MCH) mRNA, the most expressed neuropeptide transcript involved in neuroendocrine regulation, accounted for only 0.8% of total hypothalamic transcripts. The proportion of genes modified in the hypothalamus and pituitary was rather modest: 1.5% and 5.2%, respectively, for ageing per se, and 1.1% and 5.2% for age-associated macroprolactinomas. Among pituitary specific RNAs, GH mRNA expression was notably decreased with age. At the hypothalamic level, expression of genes directly involved in GH regulation, such as somatostatin and growth hormone-releasing hormone, was not altered, while neuropeptide transcripts involved in feeding behaviour [orexin/hypocretin, MCH, pro-opiomelanocortin (POMC), cocaine- and amphetamine-regulated transcript (CART)] were significantly altered. In addition, a few ubiquitous transcripts (hnRNP-K, PFKm, CCND 2, calponin and set) were differently affected in both tissues. Modifications in hypothalamic orexigenic (orexin, MCH) and anorexigenic (POMC, CART) gene expression are in keeping with an age-associated decrease in energy consumption but a higher one in the presence of macroprolactinomas.

Growth hormone secretagogues and hypothalamic networks.

Growth hormone secretagogues (GHSs) act at distinct levels to control growth hormone (GH) secretion. At the pituitary level they reinforce or extend a tonic GH-releasing-hormone (GHRH)-induced activated state by mobilizing intracellular Ca2+ store. At the hypothalamic level GHS actions are more complex than originally anticipated. Chronic treatments with GHS result in loss of responsiveness to the secretagogues, an effect probably accounted for by indirect negative feedback of GHS stimulated plasma GH levels over GHRH release. Moreover, intracerebroventricular treatments with GHS can have paradoxical, inhibitory effects on GH secretion. Several mechanisms can account for such dual effects. GHS receptors were found to extend far beyond the arcuate nucleus and are mainly coexpressed by GHRH, somatostatin, and neuropeptide Y (NPY) neurons. Activation of GHRH neurons by GHS can be direct or indirect. Indeed using antisense strategy we found that sstl are physiological activators of arcuate GHRH neurons and we propose that activation of SRIH arcuate interneurons by GHS can increase GHRH neuron activity. Moreover, GHS can stimulate distinct populations of NPY neurons having opposite effects on GH secretion: arcuate NPY interneurons, act as indirect facilitators of GHRH release, whereas, on the contrary, a different subset of NPY neurons projecting to the periventricular hypothalamus (those also involved in mediating leptin effects on GH) seems able to activate SRIH release.

In vivo internalization of the somatostatin sst2A receptor in rat brain: evidence for translocation of cell-surface receptors into the endosomal recycling pathway.

To determine whether cellular compartmentalization of somatostatin receptors can be regulated in vivo, we examined the immunocytochemical distribution of the sst2A receptor (sst2AR) after stereotaxical injections of somatostatin analogs into the rat parietal cortex. Whereas CH-275, a sst1R agonist, failed to induce changes in the diffuse sst2AR immunostaining pattern characteristic of control animals, somatodendritic profiles displaying intracytoplasmic immunoreactive granules became apparent short-term after injection of either somatostatin or the sst2R agonist octreotide. Confocal microscopy revealed that 90% of sst2AR-immunoreactive endosome-like organelles displayed transferrin receptor immunoreactivity. At the electron microscopic level, the percentage of sst2AR immunoparticles dramatically decreased at the plasmalemma of perikarya and dendrites after octreotide injection. Conversely, it significantly increased in endosomes-like organelles. These results demonstrate that sst2ARs undergo, in vivo, rapid and massive internalization into the endocytic recycling compartment in response to acute agonist stimulation and provide important clues toward elucidating somatostatin receptor signaling in the mammalian brain.

In vivo and in vitro effects of ghrelin/motilin-related peptide on growth hormone secretion in the rat.

Ghrelin (Ghr), a 28 amino acid gastric peptide with an n-octanoylation on Ser 3, has recently been identified as an endogenous ligand of the growth hormone secretagogue (GHS) receptor. A cDNA was also isolated from a mouse stomach library encoding a protein named prepromotilin-related peptide (ppMTLRP) which shares sequence similarities with prepromotilin. Mouse and rat ppMTLRP sequences (rGhr) are identical and show 89% identity with human ghrelin (hGhr). By analogy with promotilin, cleavage of proMTLRP into an 18 amino acid endogenous processed peptide can be assumed on the basis of a conserved dibasic motif in position 9-10 of its sequence. In the present work, we compared the GH-releasing activity of rGhr28/MTLRP and of hGhr28/MTRLP with that of a shorter form of the peptide, hGhr18. A short peptide devoid of Ser-3 n-octanoylation hGhr18[-] was also tested. Addition of rGhr28, hGhr28 and hGhr18 stimulated GH release to the same extent from superfused pituitaries. The effect was dose dependent in a 10(-8) to 10(-6) M concentration range. In contrast, hGhr 18[-] was inactive. In freely moving animals, both rGhr28 and hGhr28 (10 microg, i.v.) stimulated GH release, whereas the same dose of hGhr18 or of hGhr18[-] was ineffective. After rGhr28, GH plasma levels increased as early as 5 min after injection and returned to basal values within 40-60 min. Expressed as percent stimulation, administration of rGhr28 was equally effective when injected during troughs or peaks of GH. Plasma concentrations of prolactin, adrenocorticotropin and leptin were not modified. Spontaneous GH secretory episodes were no longer observed within 3 h of rGhr28 treatment, but repeated administration of the secretagogue at 3- to 4-hour intervals resulted in a similar GH response. Activation of somatostatin (SRIH) release by ether stress did not blunt the GH response to rGhr28. This suggests that the secretagogue acts in part by inhibiting endogenous SRIH, as further substantiated by the ability of rGhr28 (10(-6) M), to decrease the amplitude of 25 mM K+-induced SRIH release from perifused hypothalami. In conclusion, (1) n-octanoylation of Ghrs and the shorter form hGhr18 is essential for the direct pituitary GH-releasing effect of this new family of endogenous GHSs; (2) only the longer forms are active in vivo and (3) inhibition of SRIH release appears involved in the mechanism of Ghr action.

Involvement of sst2 somatostatin receptor in locomotor, exploratory activity and emotional reactivity in mice.

Somatostatin (SRIF) controls many physiological and pathological processes in the central nervous system but the respective roles of the five receptor isotypes (sst1-5) that mediate its effects are yet to be defined. In the present study, we attempted to identify functions of the sst2 receptor using mice with no functional copy of this gene (sst2 KO mice). In contrast with control 129Sv/C57Bl6 mice, sst2 mRNA was no longer detectable in the brain of sst2 KO mice; 125I-labeled Tyr0DTrp8-SRIF14 binding was also greatly reduced in almost all brain structures except for the hippocampal CA1 area, demonstrating that sst2 accounts for most SRIF binding in mouse brain. Invalidation of this subtype generated an increased anxiety-related behaviour in a number of behavioural paradigms, while locomotor and exploratory activity was decreased in stress-inducing situations. No major motor defects could be detected. sst2 KO mice also displayed increased release of pituitary ACTH, a main regulator of the stress response. Thus, somatostatin, via sst2 receptor isotype pathways, appears involved in the modulation of locomotor, exploratory and emotional reactivity in mice.

Involvement of the Sst1 somatostatin receptor subtype in the intrahypothalamic neuronal network regulating growth hormone secretion: an in vitro and in vivo antisense study.

Five somatostatin (SRIH) receptors (sst1-5) have been cloned. Recent anatomical evidence suggests that sst1 and sst2 may be involved in the central regulation of GH secretion. Given the lack of specific receptor antagonists, we used selective antisense oligodeoxynucleotides (ODNs) to test the hypothesis that one or both of these subtypes are involved in the intrahypothalamic network regulating pulsatile GH secretion. In mouse neuronal hypothalamic cultures the proportion of GHRH neurons coexpressing sst1 or sst2 messenger RNAs (mRNAs) was identical. In contrast, sst1 mRNAs were more often present than sst2 in SRIH-expressing neurons. Firstly, sst1 antisense ODN in vitro treatment abolished sst1, but not sst2, receptor modulation of glutamate sensitivity and decreased sst1, but not sst2, mRNAs. The reverse was true after treatment with sst2 antisense. Sense ODNs did not alter the effects of SRIH agonists. In a second series of experiments, nonanaesthetized adult male rats were infused for 120 h intracerebroventricularly with ODNs. Only the sst1 antisense ODN diminished the amplitude of ultradian GH pulses without modifying their frequency. In parallel, sst1 antisense ODN strongly diminished sst1 immunoreactivity in the anterior periventricular nucleus and median eminence, as well as sstl periventricular nucleus mRNA levels. The effectiveness of the sst2 antisense ODN was attested by the inhibition of hypothalamic binding of [125I]Tyr0-D-Trp8-SRIH. Scrambled ODNs had no effect on GH secretion or on sst mRNAs or SRIH binding levels. These results favor a preferential involvement of sst1 receptors in the intrahypothalamic regulation of GH secretion by SRIH.

EMK protein kinase-null mice: dwarfism and hypofertility associated with alterations in the somatotrope and prolactin pathways.

Gene trapping was used in embryonic stem (ES) cells in an attempt to inactivate genes involved in development. The Emk (ELKL motif kinase) gene has been disrupted and a mutant mouse line derived. Previous work had shown that EMK kinases, called MARK in the rat, exert a major control on microtubule stability by phosphorylating microtubule-associated proteins and that genes homologous to Emk in yeast or Caenorhabditis elegans are essential for cell and embryonic polarity. Although we found the Emk gene to be active in the preimplantation mouse embryo and then to show a widespread expression, Emk-null mice had no embryonic defect and were viable. They show an overall proportionate dwarfism and a peculiar hypofertility: homozygotes are not fertile when intercrossed, but are fertile in other types of crosses. Insulin-like growth factor I (IGF I) and IGF-binding protein 3 (IGFBP3) were reduced in the plasma of homozygotes of both sexes. A direct implication of the EMK kinase in IGF I plasmatic production is unlikely because the Emk gene does not seem to be expressed in hepatocytes. Nevertheless, GH assayed at arbitrary times in plasma did not show differences between genotypes and GH concentrations in pituitary extracts were not found to be altered in homozygotes. Our results, though, do not exclude the possibility that in the mutants the overall quantity of GH secreted daily is reduced. Our observation of a smaller size of the pituitaries of the mutants is in favor of this hypothesis. The prolactin concentration in the pituitaries was much lowered in homozygous females, but it was normal in males. The possible involvement of EMK protein kinase in hormone secretion in the pituitary and/or the hypothalamus, via the microtubule network, is discussed.

Hypothalamic and hypophyseal regulation of growth hormone secretion.

1. Regulation of pulsatile secretion of growth hormone (GH) relies on hypothalamic neuronal loops, major transmitters involved in their operation are growth hormone releasing hormone (GHRH) synthetized mostly in arcuate nucleus (ARC) neurons, and somatostatin (SRIH), synthetized both in hypothalamus periventricular (PVe) and ARC neurons. 2. Neurons synthetizing both peptides can inhibit each other in a reciprocal manner. Other neuropeptides synthetized in ARC neurons, such as galanin, or in ARC interneurons, such as neuropeptide Y (NPY), are able to modulate synthesis and release of GHRH and SRIH into the hypothalamohypophyseal portal system. 3. In addition, the hitherto uncharacterized endogenous ligand of the recently cloned growth hormone releasing peptide receptor, expressed mostly in the ARC, triggers GH release, presumably by actions on ARC interneurons. 4. Thyroid, gonadal, and adrenal steroid hormones also affect the GHRH-SRIH balance; a differential distribution of sex steroid receptors in the ARC and the PVe is likely to account for the different pattern of GH secretion in male and female animals. 5. Growth hormone itself is able to inhibit the amplitude of GH secretory episodes and to increase their frequency, by entering the brain (presumably by receptor-mediated internalization at the level of the choroid plexus) and acting subsequently on ARC neurons. 6. At the pituitary level, major neurotransmitters regulating GH cells act on receptors of the VIP/PACAP/GHRH family and of the somatostatin family, in particular, sst2 and sst3. Those are coupled to accumulation of cAMP as a second messenger. 7. In addition, patch-clamp experiments and measurement of intracellular Ca2+ indicate that GH cells present characteristic, GHRH-dependent, but self-maintained Ca2+ spikes and [Ca2+]i transients, which reflect adaptive mechanisms to constraints of episodic release. 8. Recent data on transcription factors affecting GH gene expression and somatotrope differentiation are also summarized. 9. Regulation and differentiation of somatotropes also depend upon paracrine processes within the pituitary itself and involve growth factors and several neuropeptides, for instance, vasoactive intestinal peptide, angiotensin 2, endothelin, and activin. 10. Finally, characteristic changes occur in the GH secretory pattern under discrete, pathological conditions, such as abnormal growth and dwarfism, diabetes, and acromegaly, as well as during inflammatory processes.

Intrahypothalamic growth hormone feedback: from dwarfism to acromegaly in the rat.

Two different dwarf rat models with primary (dw/dw, DW) or secondary (transgenic growth retarded, WF/Tgr) GH deficiency and contrasting hypothalamic GH-releasing hormone (GHRH) and somatostatin (SRIH) expression were implanted sc with GC cells. These form encapsulated rat GH-secreting tumors that maintain high plasma rat GH levels for several weeks. In both strains, GC cell tumors stimulated growth and raised GHBP levels, without affecting pituitary GH content. In DW rats, GC cell implants increased SRIH expression in the periventricular nucleus (PeV), but not in the arcuate nucleus (ARC), whereas their high GHRH expression in ARC was decreased by GC cells. In contrast, GC cell implants in WF/Tgr rats had little effect on the already high SRIH expression in PeV or low GHRH expression in ARC, although they reduced SRIH expression in ARC. GC cell implants also reduced GH receptor expression in both ARC and PeV in the WF/Tgr dwarves. Thus, chronic GH overexposure stimulates rapid growth in both dwarf strains, but has differential hypothalamic effects in these models. This experimental approach now makes it possible to study the effects of pathophysiological concentrations of GH ranging from dwarfism to acromegaly in the same animal model.

An enzyme immunoassay for rat growth hormone: validation and application to the determination of plasma levels and in vitro release.

A competitive enzyme immunoassay for rat growth hormone (rGH) has been developed using polyclonal anti-rGH antibodies and an acetylcholinesterase (EC 3.1.1.7.) enzymatic tracer coupled covalently with rGH. The assay was performed in 96-well microtiter plates coated with rabbit polyclonal anti-goat immunoglobulin antibodies. Molecular sieve filtration and Western blot analysis revealed a single immunoreactive peak for rat plasma or pituitary extracts. Cross-reactivity with other rat pituitary hormones or human GH was less than 1%. Assay of samples in a concentration range of 0.7 to 69 ng/ml by enzyme immunoassay and radioimmunoassay were well correlated (r = 0.87 and 0.85 respectively for plasma and culture medium samples). Intra- and inter-assay variations in plasma were 4 (n = 24) and 14% (n = 9) respectively. Minimal detectable amounts of rGH were 0.6 ng/ml. A two-site immunometric assay also developed with the same antibodies allowed a detection threshold of 0.25 ng/ml.

Continuous intracerebroventricular administration of a corticotropin releasing hormone antagonist amplifies spontaneous growth hormone pulses in the rat.

Involvement of endogenous corticotropin releasing hormone (CRH) in the regulation of spontaneous growth hormone (GH) secretion was investigated. A CRH antagonist, alpha helical CRH 9-41, was intracerebroventricularly infused for 36 h at a rate of 1 microgram/0.5 microliter/h to freely moving, cannulated adult male rats. Serial blood samples were drawn every 20 min for the last 8 hours of alpha helical CRH 9-41 infusion. The treatment induced a marked increase in GH peak amplitude without affecting either trough levels or numbers of peaks. In parallel, levels of growth hormone releasing hormone (GHRH) mRNA in the arcuate nucleus, but not of somatotropin release inhibiting hormone (SRIH) mRNA in the periventricular and arcuate nuclei, were increased. These data suggest that, in addition to its action in the stress-induced inhibition of GH secretion through regulation of periventricular SRIH neurons, CRH can also act as a modulator of endogenous GH secretion through regulation of arcuate GHRH neurons. Whether the modulatory effects of CRH on GHRH neurons are direct or indirect remains to be established.