Discordances in the temporal pattern of the ACTH/beta-endorphin releasing effects of synthetic CRFs and partially purified bovine CRF in a superfusion system

Temporal characteristics of ACTH and beta-endorphin secretion induced by bovine hypothalamic CRF-A (void volume) and CRF-B (Kav = 0.583) separated by Sephadex G-100 were compared to those of synthetic ovine or rat CRF, sauvagine and vasopressin. Dispersed cells or minced fragments of rat adenohypophyses perifused in a column were exposed to various secretagogues, and ACTH and/or beta-endorphin concentrations of the effluent were measured by radioimmunoassays. CRF-A or CRF-B induced an immediate brisk rise of ACTH and beta-endorphin within 1 min after initiation of CRF perifusion. The maximum rate of ACTH or beta-endorphin secretion was reached 1-2 min later. Hormone secretion persisted throughout a 10-min exposure to these secretagogues. More than 80% of the total ACTH or beta-endorphin secretion induced by 10-min perifusion with bovine CRF occurred during exposure to CRF. With 10-min perifusion with 300 ng/ml ovine or rat CRF, the onset of the major CRF-stimulated ACTH or beta-endorphin secretion was markedly delayed compared to that following bovine CRF. During perifusion with ovine or rat CRF, a modest slow increase in ACTH or beta-endorphin secretion was observed. More than 60-70% of the total ACTH or beta-endorphin secretion induced by 10-min perifusion with rat or ovine CRF occurred after CRF withdrawal. The ACTH secretory patterns for sauvagine were very similar to those for synthetic rat or ovine CRF. These results suggest some qualitative differences between partially purified bovine CRF and synthetic ovine or rat CRF.     

Effects of synthetic ovine CRF on ACTH, cortisol and blood pressure in sheep

Intravenously administered synthetic ovine CRF at doses of 0.1, 1.0 and 10.0 micrograms/kg increased plasma ACTH and cortisol concentrations in a dose-dependent fashion in unanesthetized sheep. In two unanesthetized sheep, aortic blood pressure remained relatively unaffected after the intravenous administration of CRF at 5 and 20 micrograms/kg. These results suggest that peripherally administered ovine synthetic CRF specifically stimulates the sheep pituitary-adrenal axis. Unlike other species receiving intravenous synthetic ovine CRF, sheep did not show hypotensive effects.     

Distribution of corticotropin releasing factor-like immunoreactivity in the rat brain by immunohistochemistry and radioimmunoassay: comparison and characterization of ovine and rat/human CRF antisera

The distribution of corticotropin releasing factor (CRF)-like immunoreactivity in the rat brain has been demonstrated by immunohistochemistry and radioimmunoassay using 4 different antisera. Two antisera were directed against synthetic ovine CRF, two antisera were directed against synthetic rat/human CRF. Immunohistochemistry revealed that there are discrete regions where CRF immunoreactive cell bodies are seen with all 4 antisera (e.g., the paraventricular nucleus, the dorsolateral tegmental nucleus) whereas there are cells observed only with one rat CRF antiserum (e.g., in the cortex) or terminal fields observed only with ovine CRF antisera (e.g., the spinal trigeminal tract, the substantia gelatinosa, the spinal cord). Radioimmunoassay showed different cross reactivity of the antisera with synthetic ovine or rat/human CRF and sauvagine, however, there was no cross reactivity with a variety of other peptides. Tissue values of CRF obtained by RIA of micropunched brain nuclei with the 4 antisera were frequently dissimilar suggesting that different antisera recognize different substances. High performance liquid chromatography and radioimmunoassay of brain tissue samples, revealed that there is more than one form of CRF-like immunoreactivity present. There is indirect evidence that there exists at least one peptide in the rat brain, prominent in the medulla and the spinal cord, which cross reacts with antisera directed to ovine CRF only.     

A specific radioimmunoassay for Cortricotropin Releasing Factor (CRF) using synthetic ovine CRF

This newly developed specific radioimmunoassay for corticotropin releasing factor (CRF) had a sensitivity range of 25 pg/tube to 4 ng/tube. Intra and interassay coefficient of variation were 4.6% and 9.8%, respectively. Rat median eminence extracts showed a parallel dose response curve with synthetic ovine CRF and a significant cross reaction was not evident with other tested neuropeptides. The highest mean levels of CRF were found in the median eminence (6.61 ng/mg protein). Considerable amounts of CRF were found in the arcuate nucleus, paraventricular nucleus, dorsomedial nucleus, suprachiasmatic nucleus and ventromedial nucleus. The immunoreactive CRF of the rat medial basal hypothalamus coeluted with bioassayable CRF and with iodinated CRF on Sephadex G-75 chromatography. The results indicate that rat hypothalamus contains a CRF similar to ovine CRF.     

Radioimmunoassay of CRF-like material in rat plasma: validation of the method

The availability of antibodies against the ovine corticotropin releasing factor (CRF), which cross-react with a CRF-like immunoreactivity (CRF-LI) in the rat, has enabled us to develop a radioimmunoassay (RIA) for rat CRF-LI in plasma and crude hypothalamic extracts. 125I-Tyr CRF 1-41 was used as the tracer, and synthetic ovine CRF as the reference hormone. The precision profile of the assay indicates a high degree of reproducibility except for the lower dose range. The minimum detectable dose was 20 pg/tube. This assay can detect differences in plasma CRF-LI levels after various manipulations that simultaneously alter the ACTH levels in plasma. A wide range of CRF concentrations has been found in plasma of normal rats. Caution should be exercised in the interpretation of the values obtained since an ovine RIA system was used.     

Corticotropin releasing factor (CRF)-like immunoreactivity in the hypothalamus and posterior pituitary of the goat, bovine, rat, monkey and human

Goat hypothalamic extract prepared by HCl extraction and chromatographed on a Sephadex G-50 column showed two immunoreactive CRF peaks. Most of the immunoreactivity coeluted with synthetic ovine CRF, and a small peak eluted near the void volume. Bovine, monkey, rat and human hypothalamic extracts prepared by acid-acetone or acid-methanol extraction showed three immunoreactive peaks. Most of the immunoreactivity coeluted with ovine CRF, and other smaller peaks eluted near the void volume and slightly before arginine vasopressin. Goat hypothalamic extract showed the highest cross-reactivity with anti-ovine CRF serum, followed by bovine hypothalamic extract. Less cross-reactivity was found in human, rat and monkey hypothalamic extracts. CRF immunoreactivity in goat hypothalamic extract coeluted with ovine CRF on reversed phase high performance liquid chromatography (HPLC) and main CRF immunoreactivity in human and rat hypothalamic extracts eluted slightly later than ovine CRF. These results suggest that there is a heterogeneity among the CRF molecules in these species and that goat CRF may be more similar to that of sheep CRF and the amino acid sequence or molecular weight of other animals CRF may be different from that of sheep CRF. The monkey posterior pituitary and rat neurointermediate lobe showed similar elution patterns of CRF immunoreactivity to their hypothalamic extracts on Sephadex gel filtration and HPLC. These results indicate that the posterior pituitary contains a similar CRF to hypothalamic CRF.     

Structural characterization and localization of corticotropin-releasing factor in testis

To sequence and thereby definitively characterize corticotropin-releasing factor (CRF)-like material from a representative peripheral tissue, CRF was obtained from 76 ovine testes. The novel extraction procedure involved use of an immunoaffinity column to which a high-affinity CRF monoclonal antibody was attached as well as fast protein liquid chromatography. The complete sequence was elucidated by gas-phase sequencing, carboxyamidopeptidase digestion and cyanogen bromide cleavage. Aside from microheterogeneity at position 39, all the other amino acids were identical to ovine hypothalamic CRF. Additionally, in immunohistochemical studies in the rat, CRF was localized to the Leydig cell. These findings along with related observations by ourselves and others are compatible with the hypothesis that CRF plays a significant local role, possibly by paracrine or autocrine mechanisms.     

Identification of Two Corticotropin-Releasing Factor Receptors from Xenopus laevis with High Ligand Selectivity: Unusual Pharmacology of the Type 1 Receptor

Abstract: Two cDNA clones encoding distinct members of the corticotropin-releasing factor (CRF) receptor family have been isolated from Xenopus laevis with PCR-based approaches. The first full-length cDNA amplified from Xenopus brain encoded a 415-amino acid protein with ∼80% identity to mammalian CRF receptor type 1 (CRF-R1). The second full-length cDNA isolated from Xenopus brain and heart encoded a 413-amino acid protein with ∼81% identity to the α-variant of mammalian CRF receptor, type 2 (CRF-R2). No evidence could be obtained that the β-variant of CRF-R2 existed in Xenopus laevis . Binding studies using human embryonic kidney 293 (HEK 293) cells stably transfected with xenopus CRF-R2 showed that the CRF analogues urotensin I, urocortin, and sauvagine were bound with higher affinities than human/rat CRF, xenopus CRF, and ovine CRF. In contrast to human CRF-R1, xenopus CRF-R1 (xCRF-R1) was very selective for different CRF ligands. Urotensin I, urocortin, human/rat CRF, and xenopus CRF were bound with significantly (10–22-fold) higher affinities than ovine CRF ( K _D = 31.7 n M ) and sauvagine ( K _D = 51.4 n M ). In agreement with these binding data, EC₅₀ values of 39.7 and 1.1 n M were found for sauvagine and for human/rat CRF or xenopus CRF, respectively, when the cyclic AMP production in HEK 293 cells stably transfected with xCRF-R1 was determined.     

Production of antiserum to CRF associated with adrenal atrophy in a rabbit

Corticotropin releasing factor (CRF) was recently isolated from ovine hypothalami by its ability to stimulate adrenocorticotropin (ACTH) and β-endorphin release from dispersed rat pituitary cells. Intramuscular injection of synthetic ovine CRF conugated to bovine thyroglobulin with 1-ethyl-3(3-dimethylaminopropyl) carbodiimide and emulsified with Freund's complete adjuvant into a random bred New Zealand white rabbit resulted in antiserum production to CRF associated with adrenal atrophy. A decrease in the level of plasma coticosteroids was associated with an increase in mean total binding of ¹²⁵I-N-Tyr-CRF. Upon sacrifice, a decrease in pituitary content of ACTH and a decrease in adrenal weight and content of corticosteroids was observed in the rabbit producing antiserum to CRF. Adrenal atrophy was histologically verified with an observed decrease in the adrenal cortical zone not reflected in the zona glomerulosa. Individual cells were relatively larger either with more abundant pale cytoplasm or with distinctly vacuolated cytoplasm. The results presented here are consistent with a physiologically necessary role for this CRF or peptides with similar structures in the hypothalamic-pituitary-adrenal axis.     

Associated endocrine,physiological and behavioral changes in rhesus monkeys after intravenous corticotropin-releasing factor administration

The intravenous (IV) administration of synthetic ovine corticotropin-releasing factor (CRF) (10 and 125 μg/kg) to chair restrained rhesus monkeys stimulated the pituitary-adrenal axis. At these doses, increases in plasma concentrations of adrenocorticotropic hormone (ACTH) and cortisol were associated with blood pressure decreases and behavioral effects. These data demonstrate that synthetic ovine CRF (10 and 125 μg/kg) administered IV to the rhesus monkey results in associated endocrine, physiological, and behavioral changes.     

Plasma cortisol and catecholamine responses to intracerebroventricular administration of CRF to rhesus monkeys

Synthetic ovine corticotropin releasing factor (CRF) was administered directly into the 4th ventricle of rhesus monkeys. A dose dependent increase in plasma cortisol was observed following 10 μg/kg, 20 μg/kg, and 60 μg/kg of CRF. Increases in plasma epinephrine were also evident following the highest dose of CRF. Plasma norepinephrine, mean arterial pressure, and heart rate did not increase significantly following CRF administration. These data suggest that in the rhesus monkey, central administration of ovine CRF leads to activation of the pituitary-adrenocortical axis at doses that do not raise plasma catecholamines.     

Site of inhibitory action of CRE 9-41 on ACTH release from isolated rat pituitary cells

The corticotropin-releasing factor (CRF) analog CRF 9-41 inhibits CRF, but not forskolin or dibutyryl cyclic AMP, stimulated release of ACTH from isolated pituitary cells. CRF 9-41 also blocks CRF-stimulated accumulation of cyclic AMP in a parallel dose dependent fashion. CRF 9-41 has no effect on basal ACTH release or cAMP levels. This substantiates that the analog acts as a direct CRF antagonist and that the site of this inhibition is most likely at the level of binding of CRF to its receptor on the corticotrope. Various substances, including most prominently glucocorticoids, inhibit release of ACTH from the pituitary. In an effort to develop another class of inhibitors, Rivier et al recently synthesized analogs of corticotropin releasing factor (CRF). One among these, alpha-helical ovine CRF 9-41 blunts adrenalectomy and stress induced ACTH release in non-anesthetized rats. At micromolar concentrations, CRF 9-41, shifts rightward the dose response of isolated pituitary cells to ovine CRF. Thus, the authors suggested that CRF 9-41 acts as a competitive antagonist to CRF-induced ACTH secretion. CRF appears to act through stimulation of adenylate cyclase. To determine the potential site of action of CRF 9-41 in the activation sequence for adenylate cyclase, we studied its effects on pituitary cyclic AMP formation and ACTH secretion from dispersed anterior pituitary cells derived from normal adult rats, as well as, its interaction with cyclic nucleotide agonists.     

Corticotropin-releasing factor (CRF) stimulates locomotor activity in intact and hypophysectomized newts (Amphibia)

Locomotor activity of rough-skinned newts (Taricha granulosa) was significantly higher in intact and hypophysectomized males injected intracranially with 100 ng CRF (ovine corticotropin-releasing factor) than in those injected with 10 ng CRF or saline. In addition, an injection of corticosterone or dexamethasone failed to stimulate newt locomotor activity. These results provide evidence that CRF can act independently of pituitary hormones to stimulate locomotor activity in a nonmammalian vertebrate.     

Extrahypothalamic distribution of CRF-like immunoreactivity in the rat brain

CRF-like immunoreactivity was measured by radioimmunoassay in the brains of normal adult rats and found to be widely distributed in extrahypothalamic areas (e.g., thalamus, amygdala, hippocampus, frontal cerbral cortex, striatum, midbrain, pons-medulla and cerebellum) at levels approximately 10% of the hypothalamus. Sephadex G-50 gel filtration reveals that CRF-like immunoreactivity in the hypothalamus coelutes with synthetic ovine CRF and is also present in the void volume. However, in the extrahypothalamic areas of the rat brain, only CRF-like immunoreactivity that coelutes with synthetic ovine CRF was detected. High performance liquid chromatography revealed equal amounts of immunoreactivity coeluting with CRF and methionine sulfoxide CRF in hypothalamic extracts.     

Immunohistochemical study on the development of CRF-containing neurons in the hypothalamus of the rat

Summary Appearance of immunoreactive corticotropin-releasing factor (CRF)-containing neurons was studied in developing hypothalamus of the rat by use of antisera against rat- and ovine CRF. These neurons were first recognized in the lateral and paraventricular nuclei on days 15.5 and 16.5 of gestation, respectively, when antiserum against rat CRF was employed. Antiserum against ovine CRF revealed the cells two days later exclusively in the latter nucleus. In both nuclei, the neurons increased in number with development. The neurons in the paraventricular nucleus appeared to project their immunoreactive processes to the median eminence via the periventricular and lateral pathways. In the median eminence, the immunoreaction with antiserum to rat CRF was first recognized in its anterior portion in the form of dots on day 16.5 of gestation but as beaded fibers in the external layer on day 17.5; these structures increased in amount with development in rostro-caudal direction. Although antiserum to ovine CRF was less potent in immunostainability than antiserum to rat CRF, it also revealed the beaded fibers in the median eminence on day 17.5 of gestation. Since evidence is available that the paraventricular nucleus is involved in corticotropin release, it is concluded that, in rats, the hypothalamic regulatory mechanism controlling the release of corticotropin initially appears on days 16.5–17.5 of gestation.     

The brain corticotropin-releasing factor (CRF) receptor is of lower apparent molecular weight than the CRF receptor in anterior pituitary. Evidence from chemical cross-linking studies

The ligand binding subunits of the corticotropin-releasing factor (CRF) receptors in brain and anterior pituitary of a number of species have been identified by chemical affinity cross-linking using the homobifunctional cross-linking agent disuccinimidyl suberate and 125I-Tyr0-oCRF (ovine CRF). In homogenates of rat, monkey, and human cerebral cortex, 125I-Tyr0-oCRF was covalently incorporated into a protein of Mr = 58,000. Under identical conditions in the anterior pituitary of rat, monkey, cow, and pig, 125I-Tyr0-oCRF was incorporated into a protein of apparent Mr = 75,000. The specificity of the labeling was typical of the CRF binding site since both the cerebral cortex- and pituitary-labeled proteins exhibited the appropriate pharmacological rank order profile characteristic of the CRF receptor (Nle21,Tyr32-oCRF approximately equal to rat/human CRF approximately equal to ovine CRF approximately equal to alpha-helical CRF(6-41) greater than alpha-helical oCRF(9-41) greater than or equal to oCRF(7-41) greater than rat/human CRF(1-20) approximately equal to vasoactive intestinal peptide). In addition to the major labeled proteins, 125I-Tyr0-oCRF was incorporated into higher molecular weight peptides which may represent precursors and into lower molecular weight components which may represent fragments of the major labeled proteins or altered forms of the CRF binding subunit. In summary, these data indicate a heterogeneity between brain and pituitary CRF receptors with the ligand binding subunit of the brain CRF receptor residing on a Mr = 58,000 protein, while in the anterior pituitary, the identical binding subunit resides on a protein of apparent Mr = 75,000.     

Radioimmunoassay of CRF-like material in rat hypothalamus

Corticotropin releasing factor (CRF) was recently isolated from ovine hypothalami by its ability to stimulate adrenocorticotropin (ACTH) and β-endorphin release from dispersed rat pituitary cells. In order to study the physiology of this peptide, we have developed a sensitive and specific radioimmunoassay (RIA) for CRF. Synthetic CRF was conjugated to bovine thyroglobulin and emulsified with complete Freund's adjuvant. A suitable antiserum was obtained which showed no crossreactivity with eight naturally occurring peptides. N-Tyr-CRF was iodinated and used as tracer. With this assay, CRF-like immunoreactivity which coeluted with ovine CRF on Sephadex G50 was detected in rat hypothalami.     

Expression, binding, and signaling properties of CRF2(a) receptors endogenously expressed in human retinoblastoma Y79 cells: passage-dependent regulation of functional receptors

Endogenous expression of the corticotropin-releasing factor type 2a receptor [CRF2(a)] but not CRF2(b) and CRF2(c) was observed in higher passage cultures of human Y79 retinoblastoma cells. Functional studies further demonstrated an increase in CRF2(a) mRNA and protein levels with higher passage numbers (> 20 passages). Although the CRF1 receptor was expressed at higher levels than the CRF2(a) receptor, both receptors were easily distinguishable from one another by selective receptor ligands. CRF(1)-preferring or non-selective agonists such as CRF, urocortin 1 (UCN1), and sauvagine stimulated cAMP production in Y79 to maximal responses of approximately 100 pmoles/10(5) cells, whereas the exclusive CRF2 receptor-selective agonists UCN2 and 3 stimulated cAMP production to maximal responses of approximately 25-30 pmoles/10(5) cells. UCN2 and 3-mediated cAMP stimulation was potently blocked by the approximately 300-fold selective CRF2 antagonist antisauvagine (IC50 = 6.5 +/- 1.6 nmol/L), whereas the CRF(1)-selective antagonist NBI27914 only blocked cAMP responses at concentrations > 10 microL. When the CRF(1)-preferring agonist ovine CRF was used to activate cAMP signaling, NBI27914 (IC50 = 38.4 +/- 3.6 nmol/L) was a more potent inhibitor than antisauvagine (IC50 = 2.04 +/- 0.2 microL). Finally, UCN2 and 3 treatment potently and rapidly desensitized the CRF2 receptor responses in Y79 cells. These data demonstrate that Y79 cells express functional CRF1 and CRF2a receptors and that the CRF2(a) receptor protein is up-regulated during prolonged culture.     

Growth hormone-releasing factor releases ACTH from an AtT-20 mouse pituitary tumor cell line but not from normal pituitary cells

Corticotropin-releasing factor (CRF) and both human pancreatic growth hormone-releasing factor (hp-GRF) and rat hypothalamic GRF (rh-GRF) stimulated ACTH release from neoplastic AtT-20 mouse pituitary tumor cells in a dose-dependent fashion, with CRF inducing a 10-fold increase and GRF a maximal increment of approximately one-half that of CRF. Neither rh-GRF nor hp-GRF induced ACTH release in normal anterior pituitary cells. Pretreatment with either dexamethasone or somatostatin prior to the addition of rh-GRF inhibited the increase in ACTH release. Both ovine CRF and rh-GRF stimulated adenosine 3,5-monophosphate production in AtT-20 cells. The weak but clearly discernible effect of GRF on ACTH release from AtT-20 cells may be due to an abnormality in the AtT-20 cell receptor.