Hypothalamo-posterior pituitary system in Brattleboro rats: immunoreactive levels of leucine-enkephalin, dynorphin (1-17), dynorphin (1-8) and alpha-neo-endorphin

The levels of immunoreactive leucine-enkephalin, alpha-neo-endorphin, dynorphin (1-17) and dynorphin (1-8) have been determined in the hypothalamus and posterior pituitary from male and female Brattleboro rats homozygous (unable to produce vasopressin) and heterozygous (producing vasopressin) for diabetes insipidus, and from male and female Long Evans rats. In the hypothalamus we found no significant differences in the levels of these peptides while there were great differences in extracts from the posterior pituitary: female homozygous animals have greatly reduced levels in all four peptides compared to the heterozygous controls. In male homozygous animals the differences in the dynorphin (1-17) and leucine-enkephalin levels were small whereas the concentrations of alpha-neo-endorphin and dynorphin (1-8) showed a significant decrease compared to the male heterozygous controls. The results indicate a reduction in opioid peptides linked to the vasopressin deficiency in a partially sex dependent manner.     

Effects of dehydration on pro-dynorphin derived peptides in the neuro-intermediate lobe of the rat pituitary

Dehydration significantly reduced the concentration of immunoreactive dynorphin A(1-17), dynorphin A(1-8), alpha-neo-endorphin, beta-neo-endorphin, and leu-enkephalin in the rat pituitary posterior-intermediate lobe. A statistically significant increase in immunoreactive dynorphin A(1-8), alpha-neo-endorphin and leu-enkephalin was observed in the hypothalamus. Comparison of the molar ratios of dynorphin A(1-17): dynorphin A(1-8) and alpha-neo-endorphin: beta-neo-endorphin showed an altered profile of stored pro-dynorphin cleavage products in the posterior-intermediate lobe of the pituitary of dehydrated rats.     

Subcellular localization of immunoreactive dynorphin and vasopressin in rat pituitary and hypothalamus

Dynorphin is found mainly in the particulate fraction of rat pituitary gland and hypothalamus homogenates. Dynorphin-like immunoreactivity (DYN-LI) from neurointermediate lobe (NIL) homogenates migrates at the same rate as vasopressin-like immunoreactivity (AVP-LI), in sucrose density gradients, whereas DYN-LI from the hypothalamus appears to migrate principally in a less dense region of the gradient. This suggests that dynorphin and vasopressin from pituitary are present in organelles of similar size and density, while the bulk of the dynorphin in the hypothalamus appears to be stored in a different subcellular organelle. Anterior lobe (AL) dynorphin appears to migrate in two separate bands on density gradients: the less dense band (slower) migrates at a similar rate to that of dynorphin and vasopressin from NIL. When alpha-neo-endorphin was measured in sucrose gradients of NIL and hypothalamus, it was found to co-migrate with DYN-LI.     

Evidence for a Selective Processing of Proenkephalin B into Different Opioid Peptide Forms in Particular Regions of Rat Brain and Pituitary

The distribution of five major products of proenkephalin B [dynorphin1-17, dynorphin B, dynorphin1-8, alpha-neo-endorphin and beta-neo-endorphin] was studied in regions of rat brain and pituitary. The distribution pattern of immunoreactive (ir) dynorphin B (= rimorphin) was found to be similar to that of ir-dynorphin1-17, with the highest concentrations being present in the posterior pituitary and the hypothalamus. HPLC and gel filtration showed the tridecapeptide dynorphin B to be the predominant immunoreactive species recognized by dynorphin B antibodies in all brain areas and in the posterior pituitary. In addition, two putative common precursor forms of dynorphin B and dynorphin1-17 with apparent molecular weights of 3,200 and 6,000 were detected in brain and the posterior pituitary. The 3,200 dalton species coeluted with dynorphin1-32 on HPLC. In contrast with all other tissues, anterior pituitary ir-dynorphin B and ir-dynorphin1-17 consisted exclusively of the 6,000 dalton species. Concentrations of dynorphin1-8 were several times higher than those of dynorphin1-17 in striatum, thalamus, and midbrain while posterior pituitary, hypothalamus, pons/medulla, and cortex contained roughly equal concentrations of these two opioid peptides. No dynorphin1-8 was detected in the anterior pituitary. Concentrations of beta-neo-endorphin were similar to those of alpha-neo-endorphin in the posterior pituitary. In contrast, in all brain tissues alpha-neo-endorphin was found to be the predominant peptide, with tissue levels in striatum and thalamus almost 20 times higher than those of beta-neo-endorphin. These findings indicate that differential proteolytic processing of proenkephalin B occurs within different regions of brain and pituitary. Moreover, evidence is provided that, in addition to the paired basic amino acids -Lys-Arg- as the "typical" cleavage site for peptide hormone precursors, other cleavage signals also seem to exist for the processing of proenkephalin B.     

Detection of Met-enkephalin and Leu-enkephalin in the posterior pituitary of the holostean fish, Amia calva

Immunohistochemical analysis of the pituitary of the holostean fish, Amia calva, indicated that enkephalin-related immunoreactivity was restricted to the pars nervosa, and was not detected in other regions of the pituitary. Fractionation of acid extracts of posterior pituitaries by reverse phase HPLC followed by RIA analysis indicated the presence of immunoreactive Met-enkephalin and Leu-enkephalin. No immunoreactive forms were detected with RIAs specific for either Met-enkephalin-RF or Met-enkephalin-RGL. The molar ratio of Met- to Leu-enkephalin in this terminal field was 3:1 (n = 4). HPLC fractions were also digested with trypsin and carboxypeptidase B to test for C-terminally extended forms of Met-enkephalin. A novel modified form of Met-enkephalin was detected. Extracts of the posterior pituitary, forebrain, midbrain, hypothalamus and hindbrain were screened with RIAs specific for the Pro-dynorphin end products, alpha-neo-endorphin, dynorphin A(1-17), dynorphin A(1-8) and dynorphin B(1-13). The results of these analyses were negative. Collectively, these data suggest that a Pro-enkephalin-like molecule is present in holostean fish. The holostean enkephalin precursor contains at least Met-enkephalin and Leu-enkephalin. However, Pro-dynorphin-related end products with antigenic determinants similar to mammalian dynorphin A(1-17), dynorphin A(1-8), dynorphin B(1-13) and alpha-neo-endorphin could not be detected in the brain or pituitary of this species.     

Precursors of molecules related to mammalian opioid peptides in brain of a marine worm.

Total mRNA were extracted from brain of Nereis diversicolor (Annelida, Polychaeta) and were translated in vitro or in ovo. The newly synthesized polypeptides were analyzed through electrophoresis of immunoprecipitated products or the Western blotting technique using polyclonal antibodies raised against mammalian dynorphin 1-17 and mammalian alpha-neo-endorphin. Among the products translated in vitro, only one class of polypeptide of 70 kDa was recognized by anti-dynorphin 1-17 antibodies. Furthermore, some in ovo translated products as well as proteins extracted from brain of worms showed identical immunoreactivity. These polypeptides, 60-70 kDa, reacted with anti-dynorphin 1-17 and anti alpha-neo-endorphin antibodies. These results suggest the existence of epitopes common to in ovo and in vitro translated products, to polypeptides extracted from the brain and to some mammalian opioid peptides of the prodynorphin family. We postulate the presence, in the brain of N. diversicolor, of precursors of peptides related to mammalian dynorphin 1-17 and alpha-neo-endorphin. Data reported in this investigation do not allow us to propose or even postulate the presence, in the brain of the worm, of one precursor molecule common to polypeptides related to mammalian dynorphin 1-17 and alpha-neo-endorphin. Furthermore, the Nereis precursor molecules exhibit a clear-cut difference in molecular mass with the mammalian prodynorphin: 70 kDa versus 30 kDa.     

The degradation of dynorphin A in brain tissue in vivo and in vitro

The demonstration of analgesia following in vivo administration of dynorphin A (Dyn A) has been difficult. In contrast, a number of electrophysiological and behavioral effects reported with in vivo injection of Dyn A can be produced by des-tyrosine dynorphin A (Dyn A 2-17). This suggested the extremely rapid amino terminal degradation of dynorphin A. To test this hypothesis, we examined the degradation of dynorphin A following in vivo injection into the periaqueductal gray (PAG) as well as in vitro using rat brain membranes under receptor binding conditions. In vivo, we observed the rapid amino terminal cleavage of tyrosine to yield the relatively more stable destyrosine dynorphin A. This same cleavage after tyrosine was observed in vitro. Inhibition of this aminopeptidase activity in vitro was observed by the addition of dynorphin A 2-17 or dynorphin A 7-17 but not after the addition of dynorphin A 1-13, dynorphin A 1-8, dynorphin B or alpha-neo-endorphin suggesting a specific enzyme may be responsible. The detection of the behaviorally active des-tyrosine dynorphin A following in vivo injection of dynorphin A suggests that this peptide may play an important physiological role.     

Changes in the processing of pro-dynorphin end products in the substantia nigra during neonatal development

The steady-state levels of pro-dynorphin-related end products were measured in the substantia nigra of the rat at neonatal day 0, 7, 14 and in the adult. At neonatal day 0 there was evidence that pro-dynorphin had undergone posttranslational processing to yield dynorphin A-related products, dynorphin B(1-13) and alpha-neo-endorphin. At this stage the molar ratio of dynorphin A(1-17) to dynorphin A(1-8) was 1:1 and a peak of 4 kilodalton dynorphin A-related immunoreactivity was detected. By neonatal day 7 the molar ratio of dynorphin A(1-17) to dynorphin A(1-8) resembled the adult processing pattern for the substantia nigra. The rapid maturation of the pro-dynorphin system in the substantia nigra is in contrast to the development of the pro-dynorphin system in the posterior pituitary where adult-like processing patterns are not observed until neonatal day 21 (11). Pro-enkephalin products have also been detected in the substantia nigra of the rat (15). At neonatal day 0 and neonatal day 7 the molar ratio of Met-enkephalin to Leu-enkephalin was 4:1. However, in the adult the molar ratio of Met-enkephalin to Leu-enkephalin was 1.4:1 in this terminal field. These results suggest that in the adult or perhaps late in neonatal development some pro-dynorphin end products undergo further proteolytic cleavage to yield Leu-enkephalin.     

Presence of dynorphin-like immunoreactivity in rat pituitary gland and hypothalamus

Using a highly specific and sensitive radioimmunoassay for dynorphin(1-13), dynorphin-like immunoreactivity (dynorphin-LI) was detected in rat pituitary and hypothalamus. Gel chromatographic studies on Sephadex G-50 revealed three components of dynorphin-LI with molecular weights of approximately 7500-9500 (big dynorphin), 3500-5500 (intermediate dynorphin) and 1600-1900 (small dynorphin), the latter of which eluted at the same position as authentic dynorphin contamination in porcine ACTH extracts (Sigma). Dynorphin-LI in rat anterior pituitary existed mainly as big dynorphin, whereas dynorphin-LI in rat intermediate-posterior pituitary and hypothalamus eluted mainly at the position of authentic small dynorphin.     

小鼠神经系统内强啡肽B免疫活性物质及其高压液相层析(HPLC)分析

强啡肽B是一种新发现的阿片肽。本工作以自制的兔抗强啡肽 B血清建立灵敏的放射免疫测定法,测定了小鼠神经系统与垂体内强啡肽 B免疫活性物质的含量,其中以垂体、下丘脑含量最高。 放射免疫测定结合 Sephadex C-50 层析和HPLC分析的结果表明,小鼠脑内强啡肽B免疫活性物质的主要成分是强啡肽 B,另外也包括了一定量的强啡肽-32和另一未知的分子量更大的成分,但不像大鼠还含有强啡肽 B-29。这种种属特异性的意义有待进一步研究。     

Detection of Met-enkephalin in the CNS of the teleosts, Anguilla rostrata and Oncorhynchus kisutch

Acid extracts of the brains of the American eel, Anguilla rostrata, and the coho salmon, Oncorhynchus kisutch, were screened for enkephalin-related products and dynorphin-related products. Following Sephadex G-50 column chromatography, a peak of Met-enkephalin-related immunoreactivity was detected near the total volume of the column for both species. No higher molecular weight forms of Met-enkephalin-related material were detected, nor were any immunoreactive forms with antigenic determinants similar to mammalian dynorphin A(1-17), dynorphin A(1-8), dynorphin B(1-13) or alpha-neo-endorphin detected for either species. The enkephalin-sized immunoreactivity was further analyzed by reverse phase HPLC. For both species, a peak of authentic Met-enkephalin was detected. However, Leu-enkephalin, Met-enkephalin-RGL and Met-enkephalin-RF were not detected by RIA in either species. In addition, no novel C-terminally extended forms of Met-enkephalin were detected in either species. Finally, opiate receptor binding activity was only found associated with the peak of immunoreactive Met-enkephalin.     

Expression in Escherichia coli of chemically synthesized gene for a novel opiate peptide alpha-neo-endorphin

Chemically synthesized alpha-neo-endorphin gene was fused to the Escherichia coli beta-galactosidase gene on the plasmid pKO13. The resulting recombinant DNA was used to transform E. coli cells. Radioimmunoassay for alpha-neo-endorphin in CNBr-treated bacterial cells showed that alpha-neo-endorphin was synthesized at approximately 5 x 10(5) molecules per single E. coli cell. One of the transformants, WA802/p alpha NE2, was used for alpha-neo-endorphin purification. From 10.9 g of wet cells, we isolated 4 mg of chemically pure and biologically active alpha-neo-endorphin.     

Contribution of spinal mu(1)-opioid receptors and dynorphin B to the antinociception induced by Tyr-d-Arg-Phe-Sar

The antinociceptive effect of Tyr-d-Arg-Phe-Sar (TAPS) at the spinal level was characterized with the mouse tail-flick test. Intrathecal (i.t.) administration of TAPS produced a dose-dependent antinociception. The antinociception induced by TAPS was completely blocked by i.t. pretreatment with the mu-opioid receptor antagonist beta-funaltrexamine, the mu(1)-opioid receptor antagonist naloxonazine or the kappa-opioid receptor antagonist nor-binaltorphimine, but not with the delta-opioid receptor antagonist naltrindole. Moreover, TAPS-induced antinociception was dose-dependently attenuated by i.t. pretreatment with an antiserum against dynorphin B, but not against dynorphin A, alpha-neo-endorphin, [Met(5)]enkephalin, or [Leu(5)]enkephalin. In mice lacking prodynorphin, TAPS-induced antinociception was significantly reduced compared to that in wild-type mice. These results suggest that TAPS mainly stimulates mu(1)-opioid receptors, which subsequently induce the release of dynorphin B, which then acts on kappa-opioid receptors to produce antinociception.     

Possible involvement of dynorphin A release via mu1-opioid receptor on supraspinal antinociception of endomorphin-2

It has been demonstrated that the antinociception induced by i.t. or i.c.v. administration of endomorphins is mediated through mu-opioid receptors. Moreover, though endomorphins do not have appreciable affinity for kappa-opioid receptors, pretreatment with the kappa-opioid receptor antagonist nor-binaltorphimine markedly blocks the antinociception induced by i.c.v.- or i.t.-injected endomorphin-2, but not endomorphin-1. These evidences propose the hypothesis that endomorphin-2 may initially stimulate the mu-opioid receptors, which subsequently induces the release of dynorphins acting on kappa-opioid receptors to produce antinociception. The present study was performed to determine whether the release of dynorphins by i.c.v.-administered endomorphin-2 is mediated through mu-opioid receptors for producing antinociception. Intracerebroventricular pretreatment with an antiserum against dynorphin A, but not dynorphin B or alpha-neo-endorphin, and s.c. pretreatment with kappa-opioid receptor antagonist nor-binaltorphimine dose-dependently attenuated the antinociception induced by i.c.v.-administered endomorphin-2, but not endomorphin-1 and DAMGO. The attenuation of endomorphin-2-induced antinociception by pretreatment with antiserum against dynorphin A or nor-binaltorphimine was dose-dependently eliminated by additional s.c. pretreatment with a selective mu-opioid receptor antagonist beta-funaltrexamine or a selective mu(1)-opioid receptor antagonist naloxonazine at ultra low doses, which are inactive against mu-opioid receptor agonists in antinociception, suggesting that endomorphin-2 stimulates distinct subclass of mu(1)-opioid receptor that induces the release of dynorphin A acting on kappa-opioid receptors in the brain. It concludes that the antinociception induced by supraspinally administered endomorphin-2 is in part mediated through the release of endogenous kappa-opioid peptide dynorphin A, which is caused by the stimulation of distinct subclass of mu(1)-opioid receptor.     

Dynorphin and the hypothalamo-pituitary-adrenal axis during fetal development

Although dynorphin has long been considered an endogenous opioid peptide with high affinity for the kappa-opioid receptor, its biological function remains uncertain. The high concentration of dynorphin peptides and kappa-opioid receptors in the hypothalamus suggest a possible role for dynorphin in neuroendocrine regulation. This review will summarize evidence that support a role for dynorphin in regulation of the developing hypothalamo-pituitary-adrenal (HPA) axis. Dynorphin can exert dual actions on adrenocorticotropin (ACTH) release: (i) via activation of hypothalamic kappa-opioid receptors leading to release of corticotropin-releasing hormone (CRH) and arginine vasopressin (AVP), and (ii) via a non-opioid mechanism that involves N-methyl-D-aspartate (NMDA) receptors and prostaglandins, and which is not dependent on CRH or AVP. The primary site of action of dynorphin and NMDA appears to be the fetal hypothalamus or a supra-hypothalamic site. The non-opioid mechanism does not mature until a few days prior to parturition and is active for only the brief perinatal period. In contrast, the opioid mechanism behaves as a constitutive system with sustained activity from prenatal to postnatal life. It is likely that the two mechanisms may respond to different stress stimuli and play a different role during development.     

Gonadal steroids and anterior lobe dynorphin in the male rat

Immunoreactive (ir)-dynorphin levels were measured, and the species characterized by high performance liquid chromatography (HPLC), in the pituitary and hypothalamus of intact and castrate male rats. On HPLC, ir-dynorphin co-eluted with authentic dynorphin A 1-8, dynorphin A 1-17 and dynorphin 1-32 in the hypothalamus and intermediate lobe; in two different reversed phase (RP)-HPLC systems, anterior lobe ir-dynorphin co-eluted uniquely with dynorphin 32 (4K dynorphin). Anterior lobe levels of total ir-dynorphin were significantly lowered 7 days after castration, while HPLC profiles in all tissues remained unchanged. The change in anterior pituitary ir-dynorphin levels was reversed in a dose-related manner by dihydrotestosterone (15-500 micrograms/100 g b. wt/day); estradiol benzoate (3 micrograms/100 g/day) was without effect. The changes on castration and androgen administration suggest that gonadal steroids play a role in the regulation of dynorphin, as well as gonadotrophins and prolactin, within the anterior pituitary gland.     

alpha-Neo-endorphin: receptor binding properties of the tritiated ligand

Tritiated porcine alpha-neo-endorphin has been prepared from its corresponding iodinated analog. The iodinated analog (diiodotyrosine at position 1) was synthesized, along with its non-iodinated counterpart, by the solid-phase method. Catalytic exchange of this iodinated analog in the presence of tritium yielded tritiated porcine alpha-neo-endorphin having a specific activity of 45.5 Ci/mmole. Both the native, iodinated and tritiated alpha-neo-endorphin analogs were shown to be homogenous by chromatography on carboxymethylcellulose, paper chromatography, paper electrophoresis, high performance liquid chromatography and amino acid analysis. For the first time binding of alpha-neo-endorphin to rat membrane preparations is described using [3H2-Tyr1]alpha-neo-endorphin as the ligand. The binding is time-dependent and saturable with respect to alpha-neo-endorphin. Scatchard analysis was bi-phasic with KDs of 0.20 and 3.75 nM. Displacement binding studies indicate that the receptor for alpha-neo-endorphin has "kappa" and possibly "epsilon" binding characteristics.     

A general procedure for analysis of proenkephalin B derived opioid peptides

Tryptic digestion followed by radioimmunoassay for (Leu)enkephalin-Arg6 has been used in this study as a general method to detect the presence of all possible products containing the enkephalin sequence from the opioid peptide prohormone, proenkephalin B. Tissue extracts of human hypothalamus and pituitary were examined. Gel filtration was used to separate the different precursor products according to molecular weight. The elution profile was also monitored with highly sensitive radioimmunoassays for dynorphin A and dynorphin B, respectively. Immunoreactive dynorphin A appeared in three peaks with the approximate molecular weight of 1000, 2000 and 5000. Immunoreactive dynorphin B partly occurred in other peaks, 1500, 5000 and 10 000 dalton. Profiles obtained by measuring immunoreactive (Leu)enkephalin-Arg6 in all fractions from gel filtration after trypsin digestion showed a more complex pattern compared to the profiles of immunoreactive dynorphin A and dynorphin B. The major peaks coincided with dynorphin A and dynorphin B but high levels of immunoreactive (Leu)enkephalin-Arg6 were also generated from higher molecular weight regions (MW greater than 5000).     

Reaction of Opioid Peptides with Neutral Endopeptidase (''Enkephalinase")

The kinetics of the reactions of nine opioid peptides with the neutral endopeptidase ("enkephalinase") activities of human kidney, rat kidney, and rat brain have been determined. These opioid peptides can be divided into two classes, those that are good inhibitors of Leu5-enkephalin hydrolysis (Ki less than 75 microM) and good substrates for the enzyme, and those that are poor inhibitors (Ki greater than 500 microM) and are not substrates for the enzyme. The former group includes Leu5-enkephalin, Met5-enkephalin, Met5-enkephalin-Arg6-Phe7, beta-lipotropin, and gamma-endorphin, while the nonreactive opioid peptides include alpha-neo-endorphin, beta-neo-endorphin, dynorphin, and beta-endorphin. These results suggest that those peptides containing the Met5-enkephalin sequence are more reactive than those containing the Leu5-enkephalin sequence. The lack of specificity of this neutral endopeptidase indicates that it may function in the degradation of a variety of biologically active peptides.