Location and characterization of opiate receptors regulating pituitary secretion

The site at which opiate agonists and antagonists act to alter secretion of prolactin, growth hormone and luteinizing hormone as well as the pharmacological specificity of the opiate receptors mediating these effects were examined in rats. Injection of β-endorphin but not a 10 fold higher dose of the non opiate peptide β-endorphin, increased release of prolactin and growth hormone in male rats while inhibiting luteinizing hormone release in ovariectomized, estrogen primed female rats. Prior treatment with naltrexone i.p. blocked these responses. Injection of naltrexone into the hypothalamus lowered prolactin release. In rats with a surgically formed hypothalamic island systemic administration of morphine or naltrexone altered prolactin release in the same manner as was observed in intact animals. In contrast no effects of β-endorphin or naltrexone were observed on the spontaneous secretion of prolactin $\text{in}$$\text{vitro}$. In addition β-endorphin did not alter the inhibition of prolactin release produced by apomorphine $\text{in}$$\text{vitro}$. The ED₅₀ for stimulation of prolactin release following intraventricular administration of β-endorphin or the synthetic enkephalin analog FK 33-824 was the same, approximately 0.1 ng/rat. However FK 33-824 at 0.2 ng/rat was able to produce much greater analgesia and catatonia than β-endorphin. The metabolism and distribution of β-endorphin was examined but did not account for these differential effects. These results indicate that opiate agonists and antagonists can act at the hypothalamic but not the anterior pituitary level to alter release of prolactin, growth hormone and luteinizing hormone. In addition the data suggest that the opiate receptors mediating release of prolactin may have a different pharmacological specificity from those involved with analgesia and catatonia.     

Effect of nicotine on in vivo secretion of melanocorticotropic hormones in the rat

Corticosterone, ACTH, β-endorphin and α-MSH were measured in rat plasma by radioimmunoassay before and 2,5,15,30 minutes after an intraperitoneal injection of nicotine (500 μg/Kg b.w.). Nicotine induced an increase of plasma corticosterone (p < 0.05 at t + 15 min), ACTH and β-endorphin (p < 0.01 at t + 5 min) and a decrease of α-MSH (p < 0.005 at t + 15 min). Dose response experiments showed an increase of corticosterone, ACTH, β-endorphin 15 min after 250 μg/Kg b.w. nicotine I.P., no effect being observed after injection of 100 μg/Kg b.w. The decrease of α-MSH was observed 15 min after 100, 250 or 500 μg/Kg b.w. nicotine I.P. Our results suggest that the increase of corticosterone is mediated through ACTH release.     

Effects of thyrotropin-releasing hormone on behavioral and hormonal changes induced by beta-endorphin.

Adult male rats were injected intraventricularly either with saline or TRH (10 μg) 5 min prior to a second injection of either saline or β-endorphin (50 μg). The tripeptide produced a 100% increase of motility counts recorded over a 15 min period following the last injection, whereas β-endorphin decreased general motor activity. TRH pretreatment completely abolished the depressant effect of β-endorphin. In addition, TRH enhanced the PRL secretion induced by β-endorphin and antagonized the slight elevation of plasma GH levels observed in β-endorphin-treated rats. These results do not seem to be related to an interaction of TRH with opiate receptors since the tripeptide (10^?8, 10^?6 M) added $\text{in vitro}$ to rat brain homogenates did not alter the specific binding of ³H-naloxone nor affect the displacement by β-endorphin of such binding.     

β-endorphin proteolysis by guinea-pig ileum myenteric plexus membranes: Increased γ-endorphin turnover after chronic exposure to morphine

The influence of chronic morphine exposure $\text{in vitro}$ on the biotransformation of β-endorphin (βE) was investigated using the myenteric plexus-longitudinal muscle of guinea-pig ileum. A membrane preparation was incubated with βE and the degradation of βE as well as the accumulation of several βE fragments in the incubation medium were followed with time. The levels of peptides were determined by specific radioimmunoassays after separation by high-pressure liquid chromatography. It was found that exposure to morphine did not affect the disappearance of βE, but altered the time course of accumulation of βE fragments. In fact, the accumulation of γ-endorphin, α-endorphin and des-tyrosine¹-α-endorphin was enhanced, while that of des-tyrosine¹-γ-endorphin was not changed. Additionally, the disappearance of γ-endorphin appeared to be stimulated by morphine exposure. These data provide evidence that the fragmentation of βE is changed by chronic morphine exposure in such a way that the turn-over of γ-endorphin is increased.     

Effects of intraventricular injection of gastrin on release of LH,prolactin, TSH and GH in conscious ovariectomized rats

Conscious ovariectomized (OVX) rats bearing a cannula implanted in the 3rd ventricle were injected with 2 μl of 0.9% NaCl containing varying doses of synthetic gastrin and plasma gonadotropin, GH and TSH levels were measured by RIA in jugular blood samples drawn through an indwelling silastic catheter. Control injections of saline iv or into the 3rd ventricle did not modify plasma hormone levels. Intraventricular injection of 1 or 5 μg gastrin produced significant suppression of plasma LH and prolactin (Prl) levels within 5 min of injection. Injection of 1 μg gastrin had no effect on plasma GH, but increasing the dose to 5 μg induced a progressive elevation, which reached peak levels at 60 min. By contrast, TSH levels were lowered by both doses of gastrin within 5 min of injection and the lowering persisted for 60 min. Intravenous injection of gastrin had no effect on plasma gonadotropin, GH and TSH, but induced an elevation in Prl levels. $\text{In}$$\text{vitro}$ incubation of hemipituitaries with gastrin failed to modify gonadotropin, GH or Prl but slightly inhibited TSH release at the highest dose of 5 μg gastrin. The results indicate that synthetic gastrin can alter pituitary hormone release in unrestrained OVX rats and implicate a hypothalamic site of action for the peptide to alter release of a gonadotropin, Prl and GH. Its effect on TSH release may be mediated both via hypothalamic neurons and by a direct action on pituitary thyrotrophs.     

Acetylated and nonacetylated forms of beta-endorphin in rat brain and pituitary

Extracts of rat posterior intermediate pituitary and extracts of brains from normal and hypophysectomized rats were separated by gel filtration chromatography and fractions were analyzed by both a classical β-endorphin radioimmunoassay and by a radioimmunoassay specific for α-N-acetyl β-endorphin. In posterior intermediate pituitary extracts, more than 90 percent of the β-endorphin-sized immunoreactive material was α-N-acetylated. In extracts of brains from normal rats, less than 2 percent of the β-endorphin-sized immunoreactive material corresponded to α-N-acetylβ-endorphin, whereas in brains from hypophysectomized animals, no α-N-acetylβ-endorphin-like material could be detected. Immunofluorescence on normal brain sections, using either affinity purified antibodies to α-N-acetylβ-endorphin or conventional β-endorphin antibodies, showed no α-N-acetylβ-endorphin immunoreactivity in β-endorphin neurons. Only in brain sections which had been acetylated $\text{in}\text{vitro}$ prior to immunostaining could α-N-acetylβ-endorphin-like material be detected in the β-endorphin neurons. These results suggest that—in contrast to the cells in the intermediate lobe of the pituitary—the β-endorphin in brain neurons is not α-N-acetylated and that the small amount of α-N-acetyl β-endorphin which can be found in extracts of brains from normal animals is probably of pituitary origin.     

Absorption of α-MSH from subcutaneous and intraperitoneal sites in the rat

Pentobarbitone anesthetized rats were injected with 30 nmol (50 μg) α-MSH administered intraperitoneally (IP) and subcutaneously (SC) in an acid-saline vehicle, or SC in a zinc phosphate vehicle. Concentrations of α-MSH in plasma were measured by radioimmunoassay. The pharmacokinetic parameters for the three modes of administration were determined by fitting a one-compartment open model to the plasma level data. The $\text{t}\text{1}\text{2}$ for absorption using the saline vehicle was 7.3 and 5.6 min from the IP and SC sites, respectively. The $\text{t}\text{1}\text{2}$ for absorption from the zinc phosphate complex of 17.7 min was significantly longer. Five percent of the IP dose was absorbed into the systemic circulation giving a peak plasma level of 14.1 nmol/l. The absorption of 2–3 percent was significantly lower following SC administration; peak plasma levels were 8.3 and 4.8 nmol/l for the saline and zinc phosphate vehicles, respectively. The low percentage absorption values indicated a high degree of metabolism of the peptide by peripheral tissues on its passage from the injection sites into the circulation.     

Radioimmunoassay for γ-endorphin

A double antibody radioimmunoassay technique for γ-endorphin has been developed. The antisera have been raised in rabbits against synthetic γ-endorphin coupled to bovine serum albumin by carbodiimide. The best antibody has a working titer of $\text{1}\text{35,000}$ and can detect less than 9 pg of peptide. The usable range of the standard curve is between 9 to 2400 pg. This antiserum probably binds the Glu⁸-Leu¹⁷ region of γ-endorphin and shows only weak cross-reactivity with α-endorphin, β-endorphin and β-lipotropin. Parallelism is observed between the standard curve and the inhibition curves obtained with rat neurohypophysis-pars intermedia extracts or rat plasma.     

Thyrotropin-releasing hormone stimulates the release of melanotropin from frog neurointermediate lobes in vitro

The hypothalamus of Amphibia contains large amounts of tripeptide P-Glu-His-Pro-NH₂ (mammalian thyrotropin-releasing hormone, TRH). However, synthetic TRH is unable to stimulate thyrotropin release from frog pituitary gland. The recent discovery of TRH in the skin of the frog suggests a possible role of this peptide in skin-colour adaptation. Thus we have investigated the role of TRH upon melanotropin (α-MSH) release from perifused frog neurointermediate lobes. A dose related increase in α-MSH release was observed when TRH was added to the perifusion medium. Half-maximum stimulation occurred with the 1 × 10^?8M dose. Theophylline at a dose of 2 × 10^?3M strongly enhanced TRH-induced α-MSH release, indicating that cyclic AMP may be the second messenger. α-MSH releade was not modified by crude homogenates of rat hypothalamus but was significantly reduced when the hypothalamus extracts were preincubated with specific TRH antibodies. As far is known, these results provide the first evidence that P-Glu-His-Pro-NH₂ stimulates the release of α-MSH from frog neurointermediate lobes $\text{in vitro}$. The present findings suggest a possible feedback loop between skin TRH and pituitary MSH in Amphibia.     

Stimulatory effect of prostaglandin E1 on thyroliberin-induced α-melanotropin release from perifused neuro-intermediate lobes of frog pituitary gland

A possible direct effect of prostaglandins on α-melanotropin (α-MSH) release at the level of the intermediate lobe of the frog pituitary was investigated $\text{in vitro}$ using a perifusion system technique. The effect of prostaglandins was studied on both spontaneous and TRH-stimulated α-MSH secretion. No significant effect of PGE₁, PGE₂, PGF_1α or PGF_2α on basal release of α-MSH could be detected. Indomethacin did not alter the α-MSH release induced by TRH. Conversely a significant increase in TRH-induced α-MSH secretion was observed in the presence of 1 x 10^?6M PGE₁. This magnifying effect was directly related to the concentration of TRH for doses ranging from 1 x 10^?8M to 1 x 10^?6M.     

Inhibition of the release of growth hormone in vitro by -melanocyte stimulating hormone

A polypeptide isolated from porcine hypothalami was found to inhibit the release of growth hormone (GH) from isolated rat pituitaries. This polypeptide was identified chemically and biologically as α-MSH. Pure natural α-MSH isolated from beef posterior pituitary extracts and synthetic α-MSH also inhibit the release of GH $\text{in vitro}$. In addition, other substances not yet identified, present in porcine hypothalamic extracts, also share this property.     

Effects of morphine and beta-endorphin on basal and elevated plasma levels of alpha-MSH and vasopressin.

Morphine induced an increase of plasma α-MSH levels and a decrease of AVP levels after peripheral or intracerebroventricular administration. This increase of α-MSH levels and decrease of AVP levels after morphine treatment was observed in non-stimulated animals as well as in rats in which the hormone levels were elevated by water deprivation or by administration of hypertonic saline. These latter effects of morphine on plasma levels of α-MSH and AVP could be blocked by simultaneous administration of naltrexone.β-Endorphin also increased plasma α-MSH levels and lowered plasma AVP levels. From these effects only the increase of the plasma α-MSH level and not the decrease of plasma AVP could be blocked by naltrexone. Moreover PLG treatment was ineffective with respect to the endorphin-induced decrease in plasma AVP, but it partly blocked the increase of plasma α-MSH when this tripeptide was given in combination with β-endorphin.     

Corticotropin releasing factor stimulates adrenocorticotropin and beta-endorphin release from AtT-20 mouse pituitary tumor cells

Corticotropin releasing factor (CRF) was tested for its ability to stimulate ACTH and β-endorphin secretion from clonal $\text{AtT-20}\text{D16-16}$ mouse pituitary tumor cells. Release of both hormones was stimulated 4 to 5-fold over the basal release at nanomolar concentrations of synthetic CRF. CRF analogues stimulated $\text{ACTH}\text{β-endorphin}$ release with the same order of potency in the tumor cells as in primary cultures of anterior pituitary cells. A 90-min exposure to CRF elicited a 29–35% increase in total ACTH and β-endorphin immunoreactivity in tumor cell cultures. Dexamethasone markedly inhibited CRF-stimulated and basal ACTH and β-endorphin release. $\text{AtT-20}\text{D16-16}$ cells may serve as a good model system for studying the biochemistry of CRF receptor-mediated events involved in $\text{ACTH}\text{β-endorphin}$ release and synthesis.     

Altered levels of β-endorphin fragments after chronic morphine treatment of guinea-pig ileum invitro and invivo

The isolated myenteric plexus-longitudinal muscle of the guinea-pig ilem (GPI) was used as testsystem to study the influence of chronic morphine treatment on the levels of enkephalins, β-endorphin and some of its fragments. The peptides were assayed by means of a combination of high pressure liquid chromatography and radioimmunoassays. It was found that the levels of methionine- and leucine-enkephalin and β-endorphin were not altered by chronic morphine treatment of guinea-pigs $\text{in}$$\text{vivo}$ nor in GPI exposed to morphine $\text{in}$$\text{vitro}$. However, the levels of some β-endorphin fragments i.c. γ-endorphin and des-tyrosine-γ-endorphin were elevated after morphine treatment $\text{in}$$\text{vitro}$ and $\text{in}$$\text{vivo}$ respectively. It is suggested that β-endorphin and its fragments are involved in homeostatic processes during development of opiate tolerance.     

Site of action for β-endorphin-induced changes in plasma luteinizing hormone and prolactin in the ovariectomized rat

A number of sites have been hypothesized as loci at which opioid substances act to alter the secretion of luteinizing hormone (LH) and prolactin (PRL) (1–8). The aim of the present study was to determine the site(s) at which the opioid peptide β-endorphin (β-END) acts to influence plasma LH and PRL levels in the ovariectomized (OVX) rat. β-END, administered into the third ventricle of conscious OVX rats fitted with jugular catheters, significantly decreased plasma LH in doses ? 50 ng and increased PRL levels at all doses administered (10, 50, 100 and 250 ng) in a dose dependent fashion. To identify possible central nervous system sites of action, 250 ng β-END was unilaterally infused into various brain sites. Plasma LH was significantly decreased and plasma PRL significantly increased by infusions into the ventromedial hypothalamic area, the anterior hypothalamic area, and the preoptic-septal area. There was no significant effect of β-END infusions into the lateral hypothalamic area, amygdala, midbrain central gray, or caudate nucleus. When hemipituitaries of OVX rats were incubated $\text{in}$$\text{vitro}$ with β-END (10^?7M to 10^?5M), there was no suppression of basal or LHRH-induced LH release, nor was there any alteration of basal PRL release. It is concluded that β-END acts at a medial hypothalamic and/or preoptic-septal site and not the pituitary, to alter secretion of LH and PRL.     

Occurrence of a new melanocyte stimulating hormone in the salmon pituitary gland

A new melanocyte stimulating hormone has been identified in the pituitary of the teleost, $\text{Oncorhynchus keta}$ (chum salmon). The newly isolated MSH like peptide is a heptadeca peptide, which differs in size from salmon α-MSH (13 residues) and β-MSH I and II (17 residues each). The structural determination, however, revealed that it is similar to but distinct form α-MSH, with following amino acid sequence, Ac-Ser-Tyr-Ser-Met-Glu-His-Phe-Arg-Trp-Gly-Lys-Pro-Ile-Gly-His-OH. This peptide, named α-MSH II is the third line of evidence in the salmon that the teleost pituitary gland secretes two different forms of processed hormones, for which the precursor molecules are coded on two separate genes.     

Synthesis and biological activity of four gamma-melanotropin peptides derived from the cryuptic region of the adrenocorticotropin/beta-lipotropin precursor.

A third melanotropin coding fragment named γ-MSH was discovered by Nakanishi et al (Nature $\text{278}$, 423–427 (1979)) in the cryptic region outside the portion coding for ACTH and β-LPH in the ACTH/β-LPH precursor mRNA isolated from the intermediate lobe of bovine pituitary. Four possible γ-MSH peptides derived from this coding fragment were synthesized by solid-phase methodology and their bioactivity determined in an $\text{in vitro}$ MSH assay as well as the anterior pituitary primary culture assay. Relative to α-MSH, the melanotropic activities of Ac-γ₁-MSH, γ₁-MSH, γ₂-MSH and γ₃-MSH are 7.3 × 10^?4, 3.3 × 10^?5, 1.4 × 10^?4 and 4.6 × 10^?7 respectively. None of these γ-MSH peptides releases LH, FSH, PRL, GH and TSH in the pituitary culture medium at a dose as high as 100 ng per dish.     

Stimulation of prolactin secretion in the rat by alpha-neo-endorphin, beta-neo-endorphin and dynorphin

Intraventricular injections of α-neo-endorphin, β-neo-endorphin and dynorphins (dynorphin[1–13], dynorphin[1–17], dynorphin[1–8]) resulted in an increase in plasma prolactin levels in urethane-anesthetized rats. Dynorphin [1–13] was the most potent to stimulate prolactin release among these opioid peptides. Plasma prolactin responses to these stimuli were blunted by naloxone, an opiate antagonist. In $\text{in}\text{vitro}$ studies, prolactin release from perfused pituitary cells was stimulated by α-neo-endorphin, and the effect was blunted by naloxone, whereas neither β-neo-endorphin nor dynorphin[1–13] affected prolactin release. These results suggest that newly identified “big” Leu-enkephalins in the brain stimulate prolactin secretion in the rat and that α-neo-endorphin has a possible direct action on the pituitary.     

Effect of bacitracin on the biodegradation of β-endorphin

β-endorphin was incubated with rat brain homogenate, and the amino acids released were measured by amino acid analysis. Phe, Leu, Tyr, and Lys were liberated in the greatest amount indicating that the cleavage of Leu⁷⁷-Phe⁷⁸ and some Lys-X peptide bonds with endopeptidases followed by the removal of the terminal residues by exopeptidases are the main routes of β-endorphin degradation in the brain. Bacitracin considerably reduced the amino acid release from β-endorphin incubated with rat brain homogenate, and its action is suggested to be due to the inhibition of brain amino- and carboxypeptidases. Bacitracin also potentiated and prolonged the $\text{in vivo}$ analgesic activity of β-endorphin.     

Lipotropin: precursor to two biologically active peptides.

Lipotropin appears to be the common precursor to β-MSH, a peptide with lipolytic activity, and C-Fragment, a peptide with potent opiate activity. The product formed is determined by the specificity of the activating enzymes.The amino acid sequence of β-MSH, the 18 residue melanocyte stimulating hormone, is contained within the central region of lipotropin (LPH), a 91 residue polypeptide. On this basis Li and his colleagues¹ suggested that LPH might be the prohormone of β-MSH. Bertagna, Lis and Gilardeau², on the other hand, were unable to demonstrate conversion of LPH to β-MSH $\text{in vitro}$ using pulse labelling techniques. If LPH is the precursor of β-MSH, formation of the hormone should be accompanied by release of the contiguous fragments of the prohormone and the fragments remain in the secretory particle of the gland. To obtain evidence on the biosynthetic origin of β-MSH, we have isolated peptides from pituitary in a search for the N- and C-fragments of the prohormone.