Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P01189 (beta-endorphin)
 21,003 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The pulsatile release of gonadotropin-releasing hormone and the consequent secretion of gonadotropins are regulated by a complex interplay of steroids, neuropeptides, catecholamines, and environmental factors. Estrogen and progesterone influence the amplitude and frequency of luteinizing hormone pulsatile secretion. These effects lead to both a diurnal variation in pulse frequency, with a lower frequency at night, and variation during the menstrual cycle, with a lower frequency and increased amplitude during the luteal phase. Opioid peptides inhibit the pulsatile discharge of gonadotropin-releasing hormone and luteinizing hormone. The opioid antagonist, naloxone, causes an increase in luteinizing hormone secretion, particularly during the luteal phase. The administration of opioid receptor agonists, such as beta-endorphin, results in a decline in serum luteinizing hormone during the early follicular phase. Corticotropin-releasing factor, which is increased during stress, inhibits pulsatile luteinizing hormone secretion, and this effect can be blocked by the simultaneous administration of naloxone. These observations suggest that corticotropin-releasing factor exerts its effects on luteinizing hormone through an opioidergic intermediary. Endogenous catecholamines such as dopamine inhibit pulsatile luteinizing hormone release; however, the mechanism involved is not clear.
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PMID:Neuromodulatory regulation of gonadotropin-releasing hormone pulsatile discharge in women. 224 Jan 30

Endogenous opioids (EO) probably do not modulate endotoxin (LPS)- or interleukin 1 (IL1)-induced fever because naloxone does not prevent its development. Yet, increases in CSF and hypothalamic levels of beta-endorphin have been reported during LPS-and IL1-induced fevers. Since IL1 also reduces the specific binding of opioids to their receptors in guinea pig brain, the opioids could be involved in modulating nonfebrile effects of IL1. To determine whether EO might have a role in the IL1-induced acute-phase glycoprotein response of guinea pigs, (1) naloxone (5 and 10 mg/kg, SC) was injected prior to LPS (S. enteritidis 2 micrograms/kg, IV; N = 5), and (2) morphine (MOR, 10 micrograms/microliter), [D-ala2]-met-enkephalinamide (DAME, 5 micrograms/microliter), or dynorphin A (DYN, 5 micrograms/microliter) was injected into the preoptic area (1 microliter, bilaterally; N = 8/treatment) or into the 3rd ventricle (N = 4/treatment); pyrogen-free saline was the control injection. Measurements were: core temperature (Tco) and, as indices of acute-phase glycoproteins, plasma levels of copper (Cu) and N-acetylneuraminic acid (NANA). Naloxone did not prevent the fever or the increases in plasma Cu and NANA levels evoked by LPS. The intracerebral administration of opioid agonists by either route induced variable rises in Tco, each with a different pattern, but no increases in plasma Cu and NANA levels. Thus, EO do not participate in the central modulation of acute-phase glycoprotein synthesis, but may have a role in influencing other nonthermal IL1 effects in the CNS.
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PMID:Hypothalamic opioids and the acute-phase glycoprotein response in guinea pigs. 241 70

We have reported previously that i.v.t. beta-endorphin increases the release of immunoreactive Met-enkephalin but not Leuenkephalin or dynorphins from the spinal cord. To determine if the effect is specific to beta-endorphin, the present investigation tested i.v.t. beta-endorphin, its analogs and other opiate agonists with different opioid receptor activities for their ability to release Met-enkephalin using an intrathecal perfusion technique. Human beta-endorphin and its analogs, human beta-endorphin-(1-30), -(1-29) and -(1-28) which have an identical amino acid sequence in the NH2-terminus showed reduced stepwise potencies in releasing Met-enkephalin. The results correlated well with their analgesic potencies. Des-Met5-camel beta-endorphin (64 micrograms i.v.t.) which does not have a complete sequence of Met-enkephalin in its NH2-terminus but still retains 20% of camel beta-endorphin analgesic potency caused the spinal release of Met-enkephalin. Morphine (mu opioid receptor agonist, 40 micrograms), D-Ala2-D-Leu5-enkephalin (delta opioid receptor agonist, 80 micrograms) and U-50488H (kappa opioid receptor agonist, 160 micrograms) injected i.v.t. were unable to cause any release of Met-enkephalin. High-performance liquid chromatography after Sephadex G-50 gel chromatography indicated that the immunoreactive Met-enkephalin in the spinal perfusate released by i.v.t. beta-endorphin had a retention time identical to authentic Met-enkephalin. Intraventricular injection of Met-enkephalin, 4 nmol (2.3 micrograms), caused little increase of Met-enkephalin immunoreactivity in the spinal perfusate, whereas 4 nmol of i.v.t. beta-endorphin caused a marked increase of Met-enkephalin in the spinal perfusate. Inhibition of peptidase by i.v.t. aprotinin and bacitracin does not prevent the spinal release of Met-enkephalin induced by i.v.t. beta-endorphin. It is concluded that the release of Met-enkephalin was specific to beta-endorphin and the results were not due to cross-immunoreactivity of beta-endorphin or its metabolites.
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PMID:Spinal release of immunoreactive Met-enkephalin by intraventricular beta-endorphin and its analogs in anesthetized rats. 242 Sep 69

The biochemical and pharmacological properties of an endogenous anticonvulsant substance(s) found in rat cerebrospinal fluid (CSF) following seizures are described. CSF taken from donor rats following a single maximal electroshock (MES) seizure caused significant elevations in seizure thresholds in naive recipient rats when intracerebroventricularly injected 15 min prior to exposure to the volatile convulsant flurothyl. Anticonvulsant activity was antagonized by pre-injection in recipients of high doses of naloxone or the selective delta-opioid receptor antagonist ICI 174,864. The anticonvulsant activity was also lost when the CSF was exposed to heat (90 degrees C) or immobilized trypsin. Although unaffected by the peptidase inhibitors thiorphan and bestatin, the anticonvulsant activity was significantly potentiated by a combination of aprotinin and bacitracin. Ultrafiltration of CSF revealed that the anticonvulsant activity passed through membranes with a 10,000 molecular weight cut-off, but was retained by membranes with a 5000 molecular weight cut-off. CSF removed from rats following MES had significantly increased concentrations of beta-endorphin-like, but not dynorphin A, Leu- or Met-enkephalin-like immunoreactivities relative to CSF from sham-treated rats. However, significant increases in Met-enkephalin-like immunoreactivity were measured following exposure of the CSF to the proteolytic enzymes trypsin and carboxypeptidase B, suggesting the seizure-induced presence of a higher molecular weight form of Met-enkephalin not recognized immunologically prior to enzyme exposure. These data reconfirm the anticonvulsant actions of postseizure CSF, and indicate that these effects require mediation through delta-opioid receptors in the recipient rat. These data additionally argue against these effects being mediated by Met-enkephalin, Leu-enkephalin or dynorphin A in the CSF, and suggest instead that anticonvulsant effects are attributable to a heat- and trypsin-sensitive opioid peptide(s) with a molecular weight approximately in the range of 5000-10,000 Da.
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PMID:Characterization of opioid peptide-like anticonvulsant activity in rat cerebrospinal fluid. 245 10

An in vitro model system for analysis of presynaptic inhibitory actions of spinal opioids has been applied. Embryonic sensory neurons derived from chick dorsal root ganglia were grown in primary cell culture, and the release of substance P was evoked by electrical field stimulation during exposure to drugs with well-demonstrated affinity for opioid receptors. This allowed a pharmacologic characterization of the inhibitory actions of specific opioid agonists on the release of substance P as measured by radioimmunoassay (RIA). Sufentanil (0.5 microM), a high affinity mu receptor agonist, U-50,488H (25 microM), a selective kappa receptor agonist, and morphine (10 microM), an agonist with high affinity for mu and delta receptors, inhibited the evoked release of substance P by approximately 60%, 40%, and 50%, respectively. For sufentanil the response was demonstrated to be dose-dependent. As is the case for its analgesic action in vivo, morphine was approximately 50-fold less potent than sufentanil on a molar basis in this assay. The actions of sufentanil, U-50-488H and morphine were mimicked by the endogenous opioid peptide met-enkephalin, and its stable synthetic analog D-ala2-met5-enkephalinamide (DAME). Naloxone (25 microM), an opioid receptor antagonist, blocked the inhibitory action of sufentanil (0.5 microM), morphine (5 microM), and DAME (5 microM), but not U-50,488H (10 microM). The action of U-50,488H was partially blocked by the antagonist naltrexone (25 microM). Stereo-selectivity of agonist action was confirmed by the failure of dextrorphan (50 microM), an inactive opioid isomer, to inhibit the release of substance P.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Sufentanil, morphine, met-enkephalin, and kappa-agonist (U-50,488H) inhibit substance P release from primary sensory neurons: a model for presynaptic spinal opioid actions. 246 89

Intracerebroventricular injection of beta-endorphin stimulated the metabolism of dopamine in a dose-dependent, opiate antagonist-reversible manner. Local injections into the nucleus accumbens also caused similar increases, indicating that the actions of this peptide on mesolimbic dopaminergic projections were occurring at opioid receptor sites within the nucleus accumbens. Tolerance experiments suggested that epsilon opioid receptors may be involved in mediating these effects in the n. accumbens, unlike in the striatum.
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PMID:Modulation of mesolimbic dopaminergic projections by beta-endorphin in the rat. 252 13

A 30 sec swim in water at 30 degrees C reduced the writhing response produced in the female mice by i.p. acetic acid. Peripherally administered, naloxone and beta-endorphin1-27 antagonized this swim-induced antinociception. However, i.c.v. administration of these compounds had minimal effects on this phenomenon. beta-Endorphin1-27 was effective in antagonizing the antinociceptive effect of beta-endorphin, but not that of morphine. Furthermore, the doses of naloxone required to antagonize the swim-induced antinociception were similar to those required to antagonize beta-endorphin which produced the same degree of antinociceptive response, but were much higher than those required to block the effect of morphine. These results suggest the involvement of beta-endorphin in swim-induced antinociception in female mice and its interaction with some peripheral opioid receptor(s) other than the mu-receptor.
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PMID:The involvement of beta-endorphin in swim-induced antinociception in female mice. 253 77

The role of the neuropeptide beta-endorphin on interleukin 1 (IL-1) production by murine bone marrow-derived macrophages was assessed. Beta-endorphin by itself did not induce IL-1 generation. However, over a wide range of concentrations (10(-6)-10(-14) M) beta-endorphin potentiated lipopolysaccharide (LPS)- or silica-induced production of intracellular and extracellular IL-1. This enhancement by beta-endorphin was most evident when using suboptimal doses of LPS. Naloxone, a competitive inhibitor of beta-endorphin opioid receptor interactions, abrogated the enhancing effects of beta-endorphin on LPS-induced IL-1 production. Furthermore, LPS-induced IL-1 production by macrophages (in the absence of added beta-endorphin) was also partially inhibited following treatment with naloxone, suggesting that opioids derived from activated macrophages may also modulate IL-1 generation and secretion. Thus, beta-endorphin-opioid receptor interactions result in enhanced production of immunomodulators such as IL-1.
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PMID:Beta-endorphin regulates interleukin 1 production and release by murine bone marrow macrophages. 253 39

Cell surface ligand-receptor interactions play a central role in the regulation and expression of macrophage function. Included among these macrophage membrane receptors are the beta-adrenergic and opioid receptors. We studied the abilities of epinephrine, met-enkephalin, forskolin, and adenosine 3':5' cyclic monophosphate (cAMP) analogues to affect macrophage morphology, spreading, and adherence. Cell spreading was quantitated by measuring the perimeters of adherent cell images recorded by videomicroscopy. Epinephrine induced a dose-dependent decrease in macrophage spreading; at 10(-5) M epinephrine the mean perimeter was 10.4 +/- 0.3 microns in comparison to 15.0 +/- 1.0 microns for controls. The inhibition of spreading can be blocked by the antagonist propranolol. On the other hand, met-enkephalin induced a dose-dependent increase in macrophage spreading, with a perimeter of 18.5 +/- 1.0 microns at 10(-8) M. Since catecholamines and opioids are simultaneously released from chromaffin cells of the adrenal, we examined the combinative effects due to treatment with both ligands. When macrophages were exposed to 10(-5) M epinephrine and 10(-8) M met-enkephalin, cell morphology and spreading were indistinguishable from that due to 10(-5) M epinephrine alone. The epinephrine dose-response curve in the presence of 10(-8) M met-enkephalin was similar to that of epinephrine alone. The beta-adrenergic receptor is apparently capable of diminishing or abrogating the opioid receptor signal(s). These combinative and epinephrine-mediated effects may be at least partially accounted for by the action of cAMP. Forskolin and the cAMP analogues N6-2'-O-dibutyryladenosine 3':5' cyclic monophosphate (dbcAMP) and 8-bromoadenosine 3':5' cyclic monophosphate (Br-cAMP) affected cell morphology and spreading in the same fashion as epinephrine. These differences in morphology and spreading behavior were accompanied by changes in the distribution of F-actin, as judged by phalladicin staining and fluorescence microscopy. We suggest that cAMP and microfilaments play important roles in receptor-mediated neuroregulation of macrophage function.
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PMID:Combinative ligand-receptor interactions: effects of cAMP, epinephrine, and met-enkephalin on RAW264 macrophage morphology, spreading, adherence, and microfilaments. 253 24

Beta-endorphin (beta-end) is a potent analgesic peptide which exhibits a variety of pharmacological activities in the central nervous system (CNS) following binding of its N-terminus to specific opioid receptors. Although C-terminal binding sites for this 31-amino-acid peptide have been characterized in CNS tissue, identification of their possible function has been facilitated by studies of beta-end effects on lymphocyte activities. In this communication, we report a detailed analysis of the opioid specificity of the ability of beta-end to enhance T cell mitogen-induced proliferation in unfractionated murine splenocytes. Intact 31-amino-acid beta-end peptides from several species, including human, camel and rat, enhanced concanavalin A-stimulated [3H]thymidine uptake 50-640% in a dose-dependent, naloxone-irreversible fashion. The presence of the C-terminal amino acids was required for the enhancement activity, since met-enkephalin, alpha- and gamma-endorphin, and human beta-end 1-27 were ineffective. Accordingly, the truncated peptides, human beta-end 6-31 and 18-31, were also able to enhance the Con A response. However, human beta-end 18-31 was consistently not as effective as beta-end 6-31 or the intact 31-residue peptide. These data suggest that although the C-terminus contains the primary active sequence, the N-terminus contributes to the overall potency of the effect. In support of this assertion, N-acetylation, which abolishes opioid binding activity, resulted in a reduced magnitude of enhancement. The data suggest that beta-end interacts with a non-opioid receptor which has specificity characteristics strikingly similar to non-opioid receptors characterized in CNS tissue.
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PMID:The opioid specificity of beta-endorphin enhancement of murine lymphocyte proliferation. 254 Jan 18


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