Reduction in endotoxin-induced organ dysfunction and cytokine secretion by a cyclic nitrone antioxidant.

Multiple organ dysfunction (MOD) is the leading cause of mortality in septic patients with circulatory shock. Recent evidence suggests that the overproduction of the cytokine, tumor necrosis factor-alpha(TNF), and oxygen free radical molecules may mediate the progression of sepsis to MOD and death. In this study, we have examined the ability of MDL 101,002, a free radical scavenger, to reduce organ dysfunction and cytokine secretion induced by lipopolysaccharide (LPS) administration in rats. Treatment with MDL 101,002(10-60 ng/kg, i.p.) 30 min prior to an LPS challenge resulted in a dose-dependent reduction in several markers indicative of organ dysfunction and mortality. MDL 101,002 markedly decreased LPS-induced liver and kidney damage as indicated by serum levels of aspartate aminotransferase (AST) and alanine aminotransferase (ALT) or urea and creatinine, respectively. MDL 101,002 also prevented LPS-induced pulmonary edema, but did not prevent leukopenia and only partially reduced thrombocytopenia. Associated with these improvements in organ dysfunction and survival was a modest decrease in LPS-stimulated interleukin-1 alpha (IL-1 alpha) and interleukin-1 beta (IL-1 beta) secretion and a marked ( > 90%) inhibition of TNF secretion by MDL 101,002. The data are consistent with a role for oxygen free radicals in the development of endotoxin-induced organ dysfunction and shock and suggest that free radical scavengers could reduce the mortality consequent to sepsis by decreasing organ dysfunction, at least in part, through a reduction in free radical stimulated cytokine secretion.

Dual inhibition of angiotensin-converting enzyme and neutral endopeptidase in rats with hypertension.

Angiotensin converting enzyme (ACE) and neutral endopeptidase (NEP), are two mechanistically similar enzymes involved in the metabolism of several vasoactive peptides. Selective inhibitors of ACE are effective antihypertensive agents in high-renin, renovascular rats and normal-renin, spontaneously hypertensive rats (SHR), but are not effective in the low-renin, deoxycorticosterone acetate (DOCA)-salt hypertensive rats. In contrast, NEP inhibitors are only effective in the low-renin model of hypertension. Treatment with a combination of selective inhibitors or with a dual inhibitor of both enzymes produces an antihypertensive response regardless of basal plasma renin activity. In this study, we compared the activities of MDL 100,173, a novel subnanomolar inhibitor of both ACE and NEP, with those of equimolar doses of captopril, a selective ACE inhibitor, following intravenous administration in these three rat models of hypertension. Treatment with MDL 100,173 significantly lowered blood pressure compared to vehicle treatment in all three models, whereas captopril treatment lowered blood pressure in the renovascular and SHR models only. Administration of MDL 100,173 also significantly elevated diuresis and natriuresis compared to either vehicle or captopril treatment in the SHR and DOCA-salt rats. Urinary excretion of atrial natriuretic peptide (ANP) was increased by MDL 100,173 treatment in all three models of hypertension. Treatment with captopril did not alter urine, sodium, or ANP excretion in any of the models. However, plasma-renin activity was elevated by both MDL 100,173 and captopril '''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''' ''''''''

Growth hormone-releasing hormone immunoreactivity in mouse placenta, maternal blood, and amniotic fluid: molecular characterization and secretion from primary cell cultures in vitro.

The GH-releasing hormone (GRH) gene, along with those of many other hypothalamic hormones, is abundantly expressed in mouse and rat placenta. The presence of GRH immunoreactivity (GRH-IR) is described in mouse placenta, maternal blood, and amniotic fluid, and its molecular form has been characterized using HPLC. Two different molecular forms of mouse GRH-IR (mGRH-IR) were detected in the mouse hypothalamus and one in placenta. Twenty-five percent of mGRH-IR in the hypothalamus corresponded to mGRH(1-42)OH, whereas the remainder, and all of the mGRH-IR in placenta, had a retention time consistent with the GRH precursor. High levels of mGRH-IR were detected in both maternal plasma and amniotic fluid. In addition, a mouse placental cell primary culture system was established to study the regulation of mGRH-IR release. Turnover of mGRH in placental cells was rapid, resulting in a 24-h media content of 10 times that present in cells. Both 1-oleoyl-2-acetyl-sn-glycerol and 1,2-dioctanoyl-sn-glycerol significantly stimulated the release of mGRH-IR from cultured placental cells into the incubation media but had no effect on total peptide synthesis. These results suggest that the release of mGRH-IR from placental cells is mediated, at least in part, by the activation of protein kinase C. The HPLC elution profiles of mGRH-IR released from placental cells under basal and 1-oleoyl-2-acetyl-sn-glycerol-stimulated conditions were similar to those in placental tissue. Although the biological function of mGRH-IR in placental, maternal plasma, and amniotic fluid is not yet clear, the presence of mGRH-IR in these tissues and circulating fluids suggests the possibility that mGRH-IR may exert an important role in both fetal and maternal physiology.

Protective effects of a cyclic nitrone antioxidant in animal models of endotoxic shock and chronic bacteremia.

Evidence of a role for oxygen-derived free radicals in the pathophysiology of endotoxic shock has been found in animal models. However, the importance of free radicals in chronic models of bacterial infection has not been examined. In this study a novel nitrone radical spin trap is described and its activity in animal models of endotoxic shock and chronic bacteremia were explored. MDL 101,002 is a cyclized variant of alpha-phenyl N-tert-butyl nitrone (PBN), an established spin trap. MDL 101,002 can react with free radicals to form persistent adducts as demonstrated by electron paramagnetic resonance (EPR) spectroscopy. This agent is about 10 times more potent than PBN as an in vitro antioxidant and scavenger of hydroxyl radicals. In a rat endotoxic shock model MDL 101,002 (3-30 mg/kg, i.p.) administered 30 min prior to endotoxin (30 mg/kg, i.p.) treatment reduced mortality in a dose-dependent manner. Peroxide-enhanced chemiluminescence in hepatic homogenates from endotoxin treated rats was elevated indicating that oxidative stress and antioxidant depletion was increased. Importantly, treatment with MDL 101,002 (30 mg/kg, i.p.) 30 min prior to, and 120 min following endotoxin, minimized the increase in chemiluminescence. MDL 101,002 also reduced mortality in a model of chronic bacteremia employing implantation of infected fibrin clots into the peritoneal cavity of gentamicin-treated leukopenic rats. MDL 101,002 (2.5 mg/kg/hr) increased survival from 24% to 52% in these rats. These data are consistent with a role for free radicals in the pathophysiology of endotoxic shock and suggest free radicals are also important mediators in chronic models of sepsis.

Development of neuroepithelial tumors of the adrenal medulla in transgenic mice expressing a mouse hypothalamic growth hormone-releasing hormone promoter-simian virus-40 T-antigen fusion gene.

Expression of the mouse GH-releasing hormone (GRH) gene is restricted to neurons within the hypothalamus and to placenta. In an attempt to generate immortalized mouse hypothalamic neurons expressing GRH, the proximal 872-nucleotide segment of the 5'-flanking region of the hypothalamic mouse GRH gene was cloned by polymerase chain reaction and ligated to a 2.7-kilobase DNA sequence encoding the simian virus-40 (SV40) T-antigen, so that regulation of SV40 T-antigen expression was dependent on sequences within the mGRH 5'-flanking region. This region contains both TATA and CAAT boxes. The mouse GRH/SV40 T-antigen fusion gene was injected into 1-cell mouse embryos, and SV40 T-antigen incorporation in the mouse genome was found in 11 of 77 live births (3 males and 8 females). Although no evidence of hypothalamic tumors was found, all mice that expressed the transgene also developed tumors originating in the adrenal medulla. Gene copy number varied from 1-20 and was inversely proportional to survival, which ranged from 7-16 weeks. Corticosterone levels were normal. The male transgenic mice were fertile, and their progeny expressed the transgene and developed similar tumors. Microscopic examination of the tumors revealed a primitive neuroectodermal neoplasm that exhibited hematogenous and lymph node metastases and contained 100 ng norepinephrine, 2.85 ng epinephrine, and 1.1 ng dopamine/mg tumor tissue. Primary culture of dispersed tumor cells released norepinephrine into the medium (180 pg/ml.24 h). Cell lines from 2 tumors were established and exhibited characteristics similar to those of mixed neuroblastoma or primitive neuroectodermal tumors. In conclusion, the proximal 872 nucleotides of the hypothalamic mouse GRH promoter contain elements directing tissue-specific expression limited to early adrenal neuroectodermal cells. Other GRH DNA sequences appear to be required for restricted expression of mouse GRH within the hypothalamus.

Impaired growth hormone-releasing hormone signal transduction in the dwarf (dw) rat is independent of a generalized defect in the stimulatory G-protein, Gs alpha.

The homozygous dwarf (dw) rat pituitary is characterized by a 95% reduction in GH content as well as a 75-80% reduction in the number of somatotrophs. The nature of the mutation responsible for this phenotype is unknown. Previous investigations from our laboratory indicate that dw somatotrophs exhibit decreased sensitivity and a reduced GH secretory response to GH-releasing hormone in vitro, accompanied by a decreased generation of cAMP. We hypothesized that dw rats have a defect in the pathway linking the GH-releasing hormone receptor to adenylyl cyclase and focused on the expression and function of the stimulatory G-protein, Gs alpha. When corrected for differences in pituitary size and cell number, GH mRNA content was reduced by 78% compared to that in controls. However, there was no difference in Gs alpha mRNA content or size in dw pituitaries. Similarly, there was no difference in the content or size of mRNA for the pituitary transcription factor pit-1 in dw pituitaries. Immunoblot analysis of pituitary membrane proteins using a Gs alpha-specific antibody revealed no differences in size, quantity, or relative distribution of Gs alpha peptides between control and dw pituitaries. In addition, cholera toxin effectively ribosylated dw Gs alpha, and there were no differences in the size, quantity, or relative distribution of ribosylated membrane proteins between dw and control pituitaries. Finally, to examine for mutations in other regions of the Gs alpha-coding sequence, we cloned the full-length Gs alpha cDNA from dw rat pituitaries by polymerase chain reaction. The sequence of this clone was identical to that of normal rat Gs alpha cDNA. These results indicate that 1) 52-kilodalton Gs alpha appears to predominate in both normal and dw pituitary; 2) the content, function, and sequence of Gs alpha in adult dw rats are normal; and 3) a generalized Gs alpha regulatory or structural mutation as the cause of the observed phenotype can be excluded. The results also demonstrate that there is no decrease in pit-1 expression in the adult dw pituitary.

Obesity-associated decrease in growth hormone-releasing hormone gene expression: a mechanism for reduced growth hormone mRNA levels in genetically obese Zucker rats.

The secretion of growth hormone (GH) is impaired in the genetically obese Zucker rat where GH gene expression and plasma GH levels are depressed; however, the underlying mechanism of this abnormality remains unclear. We have evaluated the potential causative role of hypothalamic GH-releasing hormone (GHRH) and somatostatin (SRIH) gene expression in the onset of the decreased GH mRNA levels by studying both GHRH and SRIH mRNA and peptide levels in obese and lean rats at 5 weeks of age when the decrease in GH mRNA is first detected. At that age both GHRH content and GHRH mRNA were significantly reduced in obese rats as compared to lean controls; hypothalamic SRIH content was also decreased in obese rats, but SRIH mRNA levels did not differ. Since GHRH is capable of stimulating GH gene expression, the decreased GHRH mRNA level could be a critical factor in causing the attenuation in GH gene expression and consequent diminution of circulating plasma GH.

Mouse hypothalamic growth hormone-releasing hormone and somatostatin responses to probes of signal transduction systems.

Signal transduction mechanisms involved in mouse growth hormone-releasing hormone (GRH) and somatostatin (SRIH) release were investigated using an in vitro perifusion system. Hypothalamic fragments were exposed to depolarizing agents, protein kinase A and C activators, and a calcium ionophore. The depolarizing agents, KCl (60 mM) and veratridine (50 microM), induced similar patterns of GRH and SRIH release. Somatostatin release in response to both agents was twofold greater than that of GRH. Forskolin (10 microM and 100 microM), an adenylate cyclase activator, stimulated both GRH and SRIH release, though with different secretory profiles. The SRIH response was prolonged and persisted beyond removal of the drug from the system, while the GRH response was brief, ending even prior to forskolin removal. Neither GRH nor SRIH were stimulated by 1,9-dideoxy-forskolin (100 microM), a forskolin analog with cAMP-independent actions. A23187 (5 microM), a calcium ionophore, stimulated the release of SRIH to a much greater extent than that of GRH. The GRH and SRIH secretory responses to PMA (1 microM), a protein kinase C activator, were similar, though delayed. The results suggest that 1) GRH and SRIH secretion are regulated by both protein kinase A and C pathways, and 2) depolarizing agents are important for the release of both hormones.

Congenital gigantism due to growth hormone-releasing hormone excess and pituitary hyperplasia with adenomatous transformation.

The cause of gigantism in most patients is a GH-secreting pituitary tumor. In this report, a case of congenital gigantism due to probable central hypersection of GH-releasing hormone (GHRH) is described. Normal at birth (4.4 kg; 53 cm), our 7-yr-old male patient grew progressively thereafter to attain a height of 182 cm and a weight of 99.4 kg at the time of our evaluation. The markedly increased baseline plasma levels of GH (730 micrograms/L) did not suppress during a standard 3-h oral glucose tolerance test, but did increase 54% after iv infusion of GHRH. Baseline plasma levels of insulin-like growth factor-I, PRL, and immunoreactive GHRH were also markedly increased. Computed imaging of the head showed a large, partially cystic sellar and suprasellar mass. Extensive imaging studies did not localize a potential source of GHRH. Preoperative treatment with octreotide and bromocriptine for 4 months resulted in a 25% reduction of suprasellar tissue mass. The pituitary tissue removed at transsphenoidal and transfrontal operations showed massive somatotroph, lactotroph, and mammosomatotroph hyperplasia. Areas of GH- and PRL-secreting cell adenomatous transformation were also evident. No histological or immunohistochemical evidence of a pituitary source of GHRH was found. The peripheral plasma immunoreactive GHRH concentration remained unaffected by pharmacological and surgical interventions. We suspect that a congenital hypothalamic regulatory defect may be responsible for the GHRH excess in this case.

Morphologic effects of hGRH gene expression on the pituitary, liver, and pancreas of MT-hGRH transgenic mice. An in situ hybridization analysis.

Morphologic changes in the pituitary, liver, and pancreas of mice with the metallothionein-human growth hormone--releasing hormone (MT-hGRH) transgene were analyzed by in situ hybridization histochemistry (ISH). There was progression from somatotroph hyperplasia to neoplasia in pituitaries of transgenic mice. Pituitary neoplasms were present between 9 to 12 months of age in some mice. Magnetic resonance imaging (MRI) readily identified enlarged pituitaries in MT-hGRH transgenic mice. Serum mouse GH and hGRH levels were marked elevated in MT-hGRH transgenic mice. In situ hybridization histochemistry showed mRNA for hGRH in liver, pituitary, pancreas, spleen, and in most other tissues examined. Combined ISH and immunohistochemistry in the pituitary gland showed that some of the GH cells also produced hGRH, and ultrastructural immunohistochemical analysis of pituitaries showed that GH and hGRH were localized in the same cell and within the same secretory granules. Liver cells of MT-hGRH transgenic mice showed evidence of hypertrophy, and the pancreatic islets were hyperplastic with significant increases in the islet cell areas. The morphologic changes in the liver were distinctive enough to separate control littermates from MT-hGRH transgenic mice in all cases. The enlarged pancreatic islets had increased numbers of insulin-producing cells. Immunoreactive hGRH and hGRH mRNA were both localized in islet cells, and an intense hybridization signal of hGRH mRNA, but only weak staining for hGRH protein, were detected in the liver of transgenic mice. These results indicate that excessive hGRH production leads to distinct morphologic changes in various organs in MT-hGRH transgenic mice and that there is temporal progression from hyperplasia to adenomatous somatotrophs in pituitaries with chronic stimulation by hGRH that involves paracrine, endocrine, and autocrine mechanisms.

Growth hormone-releasing factor analogs with hydrophobic residues at position 19. Effects on growth hormone releasing activity in vitro and in vivo, stability in blood plasma in vitro, and secondary structure.

To test the hypothesis that replacing Ala19 in growth hormone-releasing factor (GRF) with more hydrophobic residues will increase growth hormone releasing activity, four GRF analogs were prepared and tested. The molecules were made by substituting Val, Ile, or Leu at position 19 of [Thr2,Ala15,Leu27]bGRF(1-29)NH2. The compounds were evaluated for growth hormone (GH) releasing activity in vitro (rat anterior pituitary cells) and in vivo (steers). Additionally, their half-life in vitro was determined in bovine plasma, and their secondary structure was examined by circular dichroism. In pituitary cells, peptides with substitutions at position 19 had the following potencies: Ala (native), 0.37; Val, 1.16; Ile, 0.37; Leu, 0.043. When assayed in steers as a single iv bolus, over a 2-h period, the compounds gave the following integrated GH response: Ala, 2.75; Val, 2.67; Ile, 2.57; Leu, 1.55. Only the Leu analog was statistically different from the other three (p = 0.05). In bovine plasma, the half-lives (hours) were as follows: Ala, 4.9; Val, 6.6; Ile, 12.3; Leu, 14.7. In phosphate buffer the compounds were calculated to have the following percent helical content: Ala, 26; Val, 21; Ile, 27; Leu, 32. For these analogs, helicity in aqueous buffer is inversely related to their in vitro activity. Using a linear multiple regression model, the plasma half-life of the analogs positively correlated (r2 = 0.999) with both the hydrophobicity of the residue at position 19 and the helicity of the analog. Although the Val analog had both increased inherent activity and increased plasma stability in vitro compared to the Ala analog, in this study we were unable to demonstrate an increase in activity in vivo. The in vivo GH releasing activity of the analogs was not simply related to a combination of their intrinsic GH releasing activity and their in vitro plasma half-life. This suggests that in vivo additional factors are moderating the expression of activity.

Regulation of growth hormone secretion.

The secretion of growth hormone (GH) is controlled by a complex regulatory system. The primary control is exerted by two neuroendocrine hormones, GH-releasing hormone and somatostatin, though other hypothalamic neuropeptides directly and indirectly participate in this process. The regulation of each of these neurohormones is now being clarified at both physiologic and molecular levels, as are their respective roles in the generation of pulsatile GH secretion and in GH feedback regulation. Considerable information has been amassed concerning signal transduction systems mediating the effects of hypothalamic hormones on GH secretion. Although multiple second messengers have been implicated, the adenylate cyclase-cyclic AMP-protein kinase A system appears to exert a predominant role. The developmental regulation of the somatotropes and of GH gene expression is also of importance in determining the GH responses to releasing and inhibiting hormones. The availability of several rodent strains with genetic disorders of growth associated with impaired GH secretion, along with the development of transgenic models, has permitted a more detailed analysis of the role of cytokines and growth factors on both somatotrope biology and hormone secretion. Finally, knowledge gained from studies in animals is permitting a better understanding of the mechanisms involved in physiologic GH secretion and altered GH secretion associated with specific disease states in humans.

Biosynthesis of human growth hormone-releasing hormone (hGRH) in the pituitary of hGRH transgenic mice.

We have studied the posttranslational processing of prohuman GH-releasing hormone (pro-hGRH) to the mature hormones, hGRH(1-44)-NH2 and hGRH(1-40)-OH, and its carboxyl-terminal peptide (hGCTP) in pituitary cells from transgenic mice bearing a metallothionein-hGRH fusion gene after incubation with [35S]methionine. After separation on HPLC, 35S-labeled and unlabeled hGRH in medium and cell extracts were characterized by RIA and immunoprecipitation with antisera against hGRH and against hGCTP. After a 4-h pulse, unlabeled and [35S]pro-hGRH, hGRH(1-44)-NH2, and hGRH(1-40)-OH were identified in medium and cell extracts by both RIA and immunoprecipitation with anti-hGRH serum. In cell extracts, after a 0.5-h pulse, [35S]pro-hGRH and hGRH(1-44)-NH2 but not [35S]hGRH(1-40)-OH were detectable. After a 0.5-h chase, however, 35S-labeled hGRH(1-40)-OH, pro-hGRH, and [35S]hGRH(1-44)-NH2 were all measurable. After a 4-h chase, comparable levels of [35S]hGRH(1-44)-NH2 and hGRH(1-40)-OH were present, and very little intracellular 35S-pro-hGRH remained. A progressive decrease in the ratio of immunoprecipitable pro-hGRH to mature hGRH peptides and an increase in the ratio of hGRH(1-40)-OH to hGRH(1-44)-NH2 was observed in the two chase periods. In medium, [35S]hGRH(1-44)-NH2 was detectable at all times, whereas only minimal amounts of [35S]hGRH(1-40)-OH were present. Labeled and unlabeled pro-hGRH in cell extracts was also detected with anti-hGCTP serum, and another peak, which coeluted with synthetic hGCTP, was also identified. The low molar ratio of intracellular immunoreactive hGCTP to hGRH (less than 0.02) suggests a more rapid turnover rate of hGCTP than of hGRH. These results demonstrate the processing of hGRH prohormone to both mature forms of hGRH and provide evidence that hGRH(1-40)-OH is derived from hGRH(1-44)-NH2.

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

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

Growth hormone and insulin-like growth factor-I measurements in high growth (hg) mice.

Effects of a recessive gene causing high growth (hg) were studied on two major components of the growth axis in mice. Plasma and pituitary levels of growth hormone and plasma levels of insulin-like growth factor I (IGF-I) were measured in three lines homozygous for hg, each compared with a control line of alike genetic background but wild type for the hg locus (Hg). Line Gh (hghg) and line GH (HgHg) are from a line which had undergone long-term selection for high postweaning weight gain; line Ch (hghg) and line CH (HgHg) were extracted from the second backcross of Gh to C57BL/6J; line L54 (hghg) was from the sixth backcross to C57BL/6J (B6) (HgHg). Pituitary GH levels and plasma IGF-I levels were measured in both sexes at 3, 4.5, 6 and 9 wk of age. Plasma growth hormone was measured in 8- to 12-wk-old males at hourly intervals from 08.00 to 17.00. Body weight in lines homozygous for hg at 6 and 9 wk of age was 10-30% greater than in control lines. The ontogeny of this increased growth depended on genetic background. Pituitary growth hormone content was 52% lower in the two hghg lines measured (lines Ch and Gh) than in control lines at 4.5, 6 and 9 wk. Plasma growth hormone levels were also much lower in hg mice, with values only 20-30% of those in their respective controls. hg lines showed consistently low plasma growth hormone levels throughout the 9 hr sampling period, while control lines expressed the characteristic pulsatile hormone secretion.(ABSTRACT TRUNCATED AT 250 WORDS)

Evidence for a defect in growth hormone-releasing factor signal transduction in the dwarf (dw/dw) rat pituitary.

Dwarf (dw/dw) rats exhibit a 40% reduction in body growth, isolated GH deficiency (less than 5% of normal pituitary content), and a decreased number of pituitary somatotrophs (15-20% of normal). Since GH-releasing factor (GRF) stimulates GH synthesis and secretion and somatotroph proliferation, and its effects are probably mediated by cAMP, we have assessed GH secretion and cAMP production in dw rat pituitaries in response to various GH secretagogues. Dispersed pituitary cells from dw rats were less sensitive (2.5-fold) to stimulation of GH secretion by GRF and showed a 25% reduction in the maximal GH response even after normalization of their reduced GH content. Intracellular cAMP was elevated 63-fold over basal levels in normal cells after 4 h in response to maximal GRF stimulation, but only 1.9-fold in dw cells, and even larger differences between the groups were found at earlier time points. The GH responses of dw cells to exogenous cAMP, however, were indistinguishable from normal. Forskolin, a direct stimulator of adenylate cyclase, elicited comparable maximal GH and cAMP responses, but an increased ED50, in dw cells. Activation of GS alpha by cholera toxin showed an increased ED50 and reduced GH and cAMP responses in dw cells, and marked decreases in these responses were observed in response to prostaglandin E1. Phorbol ester stimulation resulted in a reduced maximal GH response in dw cells without a change in sensitivity. These results provide evidence for a defect in the GRF signal transduction pathway associated with a decreased ability of GS alpha to stimulate adenylate cyclase in dw rat somatotrophs that may be causally linked to their GH deficiency.

Synthesis and biological evaluation of mouse growth hormone-releasing factor.

The recently described mouse growth hormone-releasing factor (mGRF) was synthesized by the solid phase procedure, purified by 2 stages of preparative high performance liquid chromatography and fully characterized. The biologic activity of the 42-amino acid peptide (H-His-Val-Asp-Ala-Ile-Phe- Thr-Thr-Asn-Tyr- Arg-Lys-Leu-Leu-Ser-Gln-Leu-Tyr-Ala-Arg-Lys-Val-Ile-Gln-Asp-Ile-Met-Asn- Lys- Gln-Gly-Glu-Arg-Ile- Gln-Glu-Gln-Arg-Ala-Arg-Leu-Ser-OH) was assessed in primary cultures of both mouse and rat anterior pituitary cells and compared to synthetic rat (rGRF) and human (hGRF) growth hormone-releasing factors. mGRF was equipotent to rGRF in mouse somatotrophs but slightly less potent in rat somatotrophs, while hGRF was 3-5 times less potent in both rodent species.

Tissue-specific transcription initiation and effects of growth hormone (GH) deficiency on the regulation of mouse and rat GH-releasing hormone gene in hypothalamus and placenta.

Hypothalamic GRH gene expression has been shown to be negatively regulated by GH in both rat and mouse. The recent reports of different 5' untranslated sequences in mouse GRH cDNA from hypothalamus and placenta have raised the possibility of tissue-specific regulation of the GRH gene. To provide support for this possibility, we have studied rodent models with GH deficiency due to genetic defects in the pituitary. Complementary DNA probes for the hypothalamic and placental 5' regions were used to determine the tissue specificity of each mRNA. Although the hypothalamic form of GRH mRNA was detected in placenta, it constituted less than 0.7% of total placental GRH mRNA. A placental 5' probe (based on the previously reported sequence) hybridized only with a larger mRNA species and was not tissue specific, indicating that it was not related to GRH and was derived possibly from a cloning artifact. The correct 5' sequence of mouse placental GRH cDNA was determined and shown to be distinct from both that previously reported and the hypothalamic sequence. Although the placental form of GRH mRNA was detected in hypothalamus using the polymerase chain reaction, its levels were undetectable by Northern blotting. The 5' end of rat placental GRH cDNA was similarly sequenced and shown to exhibit no homology with the rat 5' hypothalamic sequence, but a high degree of homology with the corresponding mouse placental sequence. In GH-deficient dwarf (dw/dw) rats, hypothalamic GRH mRNA levels were significantly increased above control levels in both females and males, and pregnancy did not alter the levels in either (dw) or control rats.(ABSTRACT TRUNCATED AT 250 WORDS)

Tissue distribution and molecular heterogeneity of human growth hormone-releasing factor in the transgenic mouse.

Transgenic mice expressing the human growth hormone-releasing factor (hGRF) gene linked to the metallothionein promoter exhibit high circulating levels of hGRF and GH and increased growth. We have described the distribution of GRF immunoreactivity (GRF-IR) in various tissues and characterized its molecular heterogeneity using gel filtration and high performance liquid chromatography (HPLC) and two separate RIAs that recognized mid-molecule and carboxyl-terminal epitopes of hGRF. The highest levels of GRF-IR were in the pituitary, followed by the pancreas. Intermediate levels were present in hypothalamus and liver, and lower levels in visceral organs, heart, and gonads. The pituitary and brain revealed evidence of the two mature hormone forms [hGRF(1-44)-NH2 and hGRF(1-40)-OH and in addition a more hydrophobic form that is believed to represent the hGRF precursor (proGRF) on the basis of its estimated molecular size (approximately 9,000) and selective recognition by the mid-molecule RIA. The profiles of GRF in pancreas and gut were similar except that only minimal amounts of hGRF(1-40)-OH were detected. In contrast, neither mature hormonal form was present in the liver and plasma contained primarily hGRF(3-44)-NH2, the major circulating metabolite of hGRF. The results provide evidence for variable processing of the hGRF precursor that is tissue specific and indicate that several extrahypothalamic tissues possess the necessary complement of enzymes to generate the mature hormonal forms.

Somatostatin secretion and action in the regulation of growth hormone secretion.

The inhibition of growth hormone (GH) secretion by the hypothalamic peptide, somatostatin, is mediated by two critical factors: the concentration of the peptide in hypothalamic portal plasma and the number of somatostatin (SRIF) receptors on the somatotroph. The secretory patterns of SRIF and GH-releasing hormone (GRH) in portal blood of unanesthetized sheep is pulsatile and a close relationship of GRH pulses to those of GH secretion was documented, while those of SRIF appear to have more of a modulatory role on the responses to GRH. Peripheral infusion of SRIF at a rate to provide concentrations comparable to those in the portal system leads to a desensitization of SRIF effects on the somatotroph, likely mediated by down-regulation of SRIF receptors. These effects are believed to modulate the GH responses to GRH secretion in the generation of pulsatile GH secretion.