Pharmacological characterization of recombinant rat corticotropin releasing factor binding protein using different sauvagine analogs

Little is known on the structural ligand requirements for corticotropin-releasing factor binding protein (CRFBP) of the rat used as an important experimental animal. To obtain such information recombinant rat CRFBP was produced in stably transfected HEK 293 cells. The primary structure and posttranslational processing of purified rat CRFBP was established by peptide mapping using HPLC combined with mass spectrometric analysis. Rat CRFBP was pharmacologically characterized employing a competition binding assay with tritium-labeled rat urocortin. The rank order of declining affinity of various CRF analogs was urotensin-I, human/rat CRF (h/rCRF), rat urocortin, sauvagine (Svg), and ovine CRF in agreement with the rank order found for human CRFBP. In contrast to astressin, the CRF receptor 2-selective antagonist anti-sauvagine-30 did not show any detectable specific binding to rat CRFBP. The significance of residues 10 to 12 and 21 to 24 of Svg for its low affinity binding was established by changing these residues of Svg to those of h/rCRF. The corresponding residues 22 to 25 of h/rCRF represented the ARAE motif determined to be crucial for binding in agreement with reported data on human CRFBP. Residues 11 to 13 of CRF introduced into Svg also enhanced the affinity to rat CRFBP.     

Effects of corticotropin releasing factor on locomotor activity in hypophysectomized rats

Corticotropin releasing factor (CRF) injected intracerebroventricularly to hypophysectomized and sham hypophysectomized rats produced a dose dependent increase in locomotor activity, but in untreated hypophysectomized rats 10× more CRF was needed to produce a significant increase in activity. Concomitant daily supplements of rat growth hormone, thyroxine, and corticosterone to the hypophysectomized rats eliminated locomotor activity differences between the two groups. There was no statistically significant difference in locomotor response to either saline, 0.1 μg CRF, 1.0 μg CRF or 10.0 μg CRF in the group of animals receiving hormonal supplements. These results demonstrate that CRF can produce behavioral activation in rats independently of its effects on releasing hormones from the pituitary gland.     

Structure of equine corticotropin releasing factor

A 41 amino acid peptide, probably identical in structure to human corticotropin releasing factor, was isolated from 70 equine hypothalami by methanol extraction, immunoaffinity chromatography and single step of reverse phase HPLC. The amino acid sequence was determined by gas phase sequence analysis. Probable carboxyl terminal amidation was demonstrated by similar retention times for equine and human corticotropin releasing factor on reverse phase HPLC at pH 8. The likely structure of equine corticotropin releasing factor is: Ser-Glu-Glu-Pro-Pro- Ile-Ser-Leu-Asp-Leu-Thr-Phe-His-Leu-Leu-Arg-Glu-Val-Leu-Glu-Met-Ala-Arg-Ala-Glu-Gln-Leu-Ala-Gln-Gln-Ala-His-Ser-Asn- Arg-Lys-Leu-Met-Glu-Ile-Ile-NH₂. The purified peptide is equipotent with human corticotropin releasing factor in an in vitro bioassay and in a human plasma binding protein assay.     

Effects of corticotropin releasing factor and growth hormone releasing factor on pituitary hormone secretion in patients with congenital thyrotropin deficiency. Abnormal response of growth hormone to corticotropin releasing factor

Blood concentrations of anterior pituitary hormones, ACTH, GH, TSH, PRL, LH, and FSH were determined in corticotropin releasing factor (CRF) test (synthetic ovine CRF 1.0 microgram per kg body weight) and growth hormone releasing factor (GRF) test (synthetic human pancreatic GRF-44 100 micrograms) in 2 female sibling patients with congenital isolated TSH deficiency, in their mother, in 2 patients with congenital primary hypothyroidism and in 8 normal controls. The patients with isolated TSH deficiency showed normally increased plasma ACTH and serum GH after CRF and GRF, respectively, and also showed an abnormal GH response to CRF. The serum GH showed a rapid increase to maximum levels (12.9 ng/ml) within 30 to 60 min followed by decrease. The possibility of secretion of abnormal GH could be excluded by the fact that on serum dilution, GH value gave a linear plot passing through zero. In addition, serum PRL, LH and FSH levels after CRF administration in case 1 and PRL after GRF in case 2 were also slightly increased but these responses were marginal. The mother of the patients, patients with congenital primary hypothyroidism, and normal healthy controls showed normal responses of pituitary hormones throughout the experiment. Data from the present study and a previous report show that abnormal GH response to the hypothalamic hormones (CRF, TRH and LHRH) may be observed in patients with congenital isolated TSH deficiency.     

Solid phase synthesis of ovine corticotropin releasing factor

Ovine corticotropin releasing factor was synthesized by the stepwise solid phase method under conditions anticipated to maximize yield. Final yields of fully active hormone were 34% based on peptide which could be removed from the resin and 24% on initial resin substitution.     

Effects of corticotropin releasing hormone on appetitive behaviors.

Corticotropin releasing hormone (CRH) is a 41-residue hypothalamic neuropeptide that has been shown to have potent behavioral effects in animals and has been implicated in clinical disorders in man. This review focuses on those aspects of the behavioral effects of CRH related to food-associated behaviors. The effects of CRH on food intake are compared with its effects on performances maintained by food presentation, and contrasted with the effects of CRH on performances maintained by other events. The effects of CRH antagonists and drugs that interact with the behavioral effects of CRH are also reviewed, particularly with respect to their direct effects on food intake. Lastly, data assessing the effects of CRH administration on central neurotransmitter levels are presented and compared with levels seen in clinical populations. The effect of CRH on food intake seen in animals is consistent with a putative role for CRH in clinical syndromes where appetite suppression is apparent. Since some of the effects of CRH on food intake are subject to pharmacological intervention, strategies directed at peptidergic mechanisms of psychiatric disorders should be explored.     

Endogenous corticotropin releasing factor regulates adrenergic and opioid receptors

Previous work from this laboratory demonstrated that intracerebroventricular (i.c.v.) administration of IgG antibodies directed against selected neuropeptides changed the density of opioid receptors, suggesting that neuropeptides in the CNS can perform a regulatory role. To further test this hypothesis, we administered anticorticotropin (CRF) IgG to rats via the i.c.v. route and measured the density of opioid mu and delta receptors and also beta- and alpha₂-adrenergic receptors. The results demonstrated that anti-CRF IgG upregulates mu and beta-adrenergic receptors. We conclude that CRF in the cerebrospinal fluid may exert regulatory effects throughout the brain.     

PD-sauvagine: a novel sauvagine/corticotropin releasing factor analogue from the skin secretion of the Mexican giant leaf frog, Pachymedusa dacnicolor

Sauvagine is a potent and broad-spectrum biologically active peptide of 40 amino acid residues originally isolated from the skin of the South American frog, Phyllomedusa sauvagei. Since its discovery, no additional sauvagine structures have been reported. Following the discovery of sauvagine, peptides with similar primary structures/activities were identified in mammalian brain [corticotropin-releasing factor (CRF) and urocortin]. Here, we report the identification of a second sauvagine from the Mexican giant leaf frog, Pachymedusa dacnicolor, which displays primary structural features of both sauvagine and CRF. A cDNA encoding the peptide precursor was "shotgun" cloned from a cDNA library constructed from lyophilised skin secretion by 3'- and 5'-RACE reactions. From this, the primary structure of a 38-mer peptide was deduced and this was located in reverse phase HPLC fractions of skin secretion and both its mass and structure were confirmed by mass spectrometry. The biological activities of synthetic replicates of PD-sauvagine and sauvagine were compared using two different mammalian smooth muscle preparations and the novel peptide was found to be more potent in both. Bioinformatic analyses of PD-sauvagine revealed that it shared different regional sequence identities with both sauvagine and CRF.     

Monensin inhibition of corticotropin releasing factor mediated ACTH release

Monensin is a sodium selective carboxylic ionophore that has been helpful in studying the intracellular mechanisms of protein secretion by its ability to inhibit transport of secretory proteins, particularly through the Golgi apparatus, and by its capacity to block intracellular posttranslational processing events. We studied in rat anterior pituitary cell culture the effects of monensin on: CRF stimulated ACTH release; presynthesized (stored) ACTH release; and on forskolin- (activator of adenylate cyclase) and KCl- (a membrane depolarizer which does not stimulate ACTH synthesis) induced ACTH release. Monensin inhibited CRF stimulated ACTH release in a dose-dependent fashion. The ED50 was 2.7 x 10(-8) M and maximal inhibition was 52% at 1.5 x 10(-7) M. Inhibition at 40 minutes of CRF incubation was similar to the percent inhibition noted at 1 hr 40 min and 2 hr 40 min. Monensin (1.5 x 10(-6) M) decreased the amount of ACTH release from cells incubated with cycloheximide plus CRF by 32% (p less than 0.01). Monensin individually inhibited forskolin (2 x 10(-6) M) and dibutyryl cyclic AMP (3 x 10(-3) M) mediated ACTH release in a dose-dependent fashion. The inhibition of forskolin and dibutyryl cyclic AMP mediated ACTH release by 1.5 x 10(-6) M monensin was 48% and 46% respectively. Monensin (1.5 x 10(-6) M) also reduced KCl (50 mM) stimulated ACTH release by 48%. This study demonstrates that monensin inhibits CRF mediated ACTH release.(ABSTRACT TRUNCATED AT 250 WORDS)     

Adrenal modulation of the inhibitory effect of corticotropin releasing factor on feeding

Corticotropin releasing factor (CRF) reduces food intake in rats after central administration. In these studies we examined whether the adrenal gland and the vagus were involved in CRF suppression of intake. One hour intake was reduced by a 5 μg (ICV) injection of CRF in sham but not adrenalectomized rats maintained on 0.9% NaCl. In a separate experiment on rats maintained on tap water, the inhibitory effect of CRF (5 μg) lasted at least 4 hours in sham rats whereas adrenalectomized rats did not significantly differ from controls. These experiments suggest that the adrenal gland modulates the feeding response to CRF. As replacement with corticosterone (0.75 mg/kg) in total adrenalectomized rats did not restore responsiveness to 5 or 10 μg of CRF, we next studied whether the adrenal medulla was responsible for the decreased responsiveness to CRF. In rats lacking the adrenal medulla only, food intake was reduced by a 5 μg injection of CRF; in sham rats, intake was significantly reduced by doses as low as 0.1 μg of CRF. An additional experiment examined the effect of gastric vagotomy on the CRF feeding response. Vagotomized rats were as responsive to 5 and 10 μg injections of CRF as sham rats, which suggests that the effect is not dependent on the vagus nerve. These findings indicate that the adrenal gland, primarily the medulla, plays an intermediate role in the reduction of food intake caused by central injections of CRF. This conclusion is consistent with the known effect of CRF on adrenomedullary discharge.     

Activation of corticotropin releasing factor receptor type 2 in the heart by corticotropin releasing factor offers cytoprotection against ischemic injury via PKA and PKC dependent signaling

Corticotrophin-releasing factor receptor 2β (CRFR2β) is expressed in the myocardium. In the present study we explore whether acute treatment with the neuropeptide corticotrophin-releasing factor (CRF) could induce cytoprotection against a lethal ischemic insult in the heart (isolated murine neonatal cardiac myocytes and the isolated Langendorff perfused rat heart) by activating CRFR2. In vitro, CRF offered cytoprotection when added prior to lethal simulated ischemic stress by reducing apoptotic and necrotic cell death. Ex vivo, CRF significantly reduced infarct size from 52.1±3.1% in control hearts to 35.3±3.1% (P<0.001) when administered prior to a lethal ischemic insult. The CRF peptide did not confer cytoprotection when administered at the point of hypoxic reoxygenation or ischemic reperfusion. The acute effects of CRF treatment are mediated by CRF receptor type 2 (CRFR2) since the cardioprotection ex vivo was inhibited by the CRFR2 antagonist astressin-2B. Inhibition of the mitogen activated protein kinase-ERK1/2 by PD98059 failed to inhibit the effect of CRF. However, both protein kinase A and protein kinase C inhibitors abrogated CRF-mediated protection both ex vivo and in vitro. These data suggest that the CRF peptide reduces both apoptotic and necrotic cell death in cardiac myocytes subjected to lethal ischemic induced stress through activation of PKA and PKC dependent signaling pathways downstream of CRFR2.     

Heteroatom-linked indanylpyrazines are corticotropin releasing factor type-1 receptor antagonists

Low nanomolar corticotropin releasing factor type-1 (CRF(1)) receptor antagonists containing unique indanylamines were identified from the heteroatom-linked pyrazine chemotype. The most potent indanylpyrazine had a K(i)=11+/-1 nM. The oxygen-linked pyrazinyl derivatives were prepared through a copper-catalyzed coupling of a pyridinone to a bromo- or iodopyrazine.     

Effects of human corticotropin releasing factor (CRF) on gastric and pancreatic secretion in vivo and in vitro

Human CRF given IV inhibited dose-dependently pentagastrin- but not histamine-induced gastric acid secretion. When added to the incubation medium of the isolated gastric glands, CRF did not alter the formation of HCl under basal conditions or after stimulation with histamine or DBcAMP. CRF caused a small but significant increase in pancreatic HCO3 and protein secretion. It augmented CCK-induced pancreatic protein and secretin-induced HCO3 secretion in vivo but failed to affect basal or stimulated (CCK and urecholine) amylase release by the in vitro dispersed pancreatic acini. This study indicates that CRF inhibits gastric and stimulates pancreatic secretion in vivo but not in vitro and these effects are indirect involving, at least in part, alterations in the pancreatic circulation.     

Stimulation of rat pancreatic exocrine secretion by urocortin and corticotropin releasing factor

Neural and hormonal mechanisms control pancreatic secretion. The effects of the corticotropin releasing factor (CRF) related neuropeptide urocortin (UCN) on pancreatic exocrine secretion were examined. In anesthetized male rats, pancreatic secretion volume and total protein were assayed. UCN increased pancreatic secretory volume and protein secretion and potentiated cholecytokinin-stimulated protein secretion. Astressin, a non-specific CRF receptor antagonist, inhibited UCN-stimulated protein output while CRF(2) receptor antagonist, antisauvagine-30, was without effect. Atropine, but not subdiaphragmatic vagotomy, inhibited UCN-mediated secretion. In acinar cells, UCN did not stimulate release of amylase nor intracellular cAMP. UCN is a pancreatic exocrine secreatagogue with effects mediated through cholinergic intrapancreatic neurons.     

Neurotransmitter modulation of corticotropin releasing factor secretion into the hypophysial-portal circulation

Secretion of corticotropin releasing factor (CRF) from the hypothalamic paraventricular nuclei into the hypophysial-portal circulation is modulated by a variety of neuronal afferents. Effects of intracerebroventricular acetylcholine (ACH), gamma-aminobutyric acid (GABA) and epinephrine (EPI) on immunoreactive (ir) CRF concentration in portal plasma were directly evaluated in urethanized male rats. ACH (0.1-10 nmole) administration was associated with a dose-dependent elevation of portal irCRF which was attenuated by pretreatment with either muscarinic or nicotinic receptor antagonists. GABA (0.1-10 nmole) also caused inhibition of irCRF concentration in the portal plasma which was prevented by bicuculline pretreatment. Finally, EPI (0.1-10 nmole) facilitated irCRF secretion via alpha 1- and beta-adrenergic mechanisms. These observations provide the first direct information on possible neurotransmitter actions on hypothalamic CRF secretion.     

Role of cyclic AMP in corticotropin releasing factor mediated ACTH release

To elucidate the role of cAMP in the secretion of ACTH, the effect of (1) three phosphodiesterase inhibitors, (2) forskolin, and (3) 8Bromo-cAMP, on CRF mediated ACTH release was studied in rat pituitary cell culture. The action of glucocorticoids on CRF induced cAMP accumulation and ACTH release was investigated. Isobutyl-methylxanthine (IBMX), caffeine, and forskolin augmented the release of ACTH induced from CRF 1.0 nM by 17%, 39%, and 20%, respectively. Also IBMX and caffeine potentiated CRF 10 nM stimulated ACTH release by 32% and 20%. Doses of forskolin and 8Bromo-cAMP, which alone stimulate large amounts of ACTH release, did not increase the amount of ACTH released from CRF 100 nM stimulated cells. Cortisol (500 nM) and corticosterone (500 nM) inhibited CRF induced intracellular cAMP by 39% and 26% while inhibiting pituitary ACTH release by 40% and 52%. In conclusion, cAMP plays an important role in the mechanism of ACTH secretion and it appears the final intracellular mechanism of CRF stimulated ACTH is via cAMP. Also, glucocorticoids exert their inhibitory influence prior to cAMP generation.     

In vivo potentiation of corticotropin releasing factor activity by vasopressin analogues

The ability of the neurohypophyseal hormones and related synthetic peptides to potentiate the action of synthetic ovine corticotropin releasing factor (CRF-41) was examined using male rats whose endogenous CRF release was blocked with chlorpromazine, morphine and nembutal. CRF potency was clearly related to the pressor activity of the analogues. However, the threshold dose for eliciting a significant corticosterone response with the neurohypophyseal hormones was greater than with CRF-41. When arginine vasopressin (AVP) was coadministered with CRF-41 at subthreshold doses of both peptides, a significant corticosterone response was observed. When the neurohypophyseal hormone analogues were compared with regard to intrinsic CRF bioactivity, it was observed that an L-basic residue in sequence position 8 is necessary for high intrinsic activity. With one exception, l-Deamino-(9-D-Ala) arginine vasopressin, the ability to potentiate the effect of CRF-41 was related to the intrinsic CRF potency of the analogues. These results support previous reports of in vitro potentiation of CRF-41 by AVP and point out the complexity of CRF-neurohypophyseal hormone interaction in vivo.     

Interaction of arginine vasopressin and corticotropin releasing factor demonstrated with an improved bioassay

We developed an improved in vivo bioassay for corticotropin releasing factor (CRF) by modifying the injection schedule in the standard chlorpromazine-morphine-pentobarbital assay procedure. A combined injection of chlorpromazine and morphine followed 75 min later by injection of pentobarbital produced low basal levels of corticosterone and rendered the animals highly sensitive to synthetic CRF but insensitive to the stress of ether or histamine. The lowest dose of CRF that significantly elevated plasma corticosterone levels was 0.01 micrograms/kg. Using this assay, we studied CRF-arginine vasopressin (AVP) interactions at doses that were expected to raise systemic peptide concentrations to levels measured in hypophysial portal blood. The threshold for a significant corticosterone response was found to be at least 250-fold lower for CRF-41 than for AVP. The order in which CRF and AVP are injected was also found to be important, potentiation being greater if CRF was given first. In addition, rats deprived of water for 24 hr were more sensitive to CRF than normally hydrated animals.