Chronic exposure to antibodies directed against anti-opiate peptides alter delta-opioid receptor levels

The development of addictive states in response to chronic opioid use may be regulated partially by the release of endogenous peptides. These anti-opiate peptides (AOP) are secreted or released into the CNS and produce diverse actions that counterbalance the effects of prolonged opiate exposure. Though the mechanism(s) by which these peptides exert their physiological properties remain largely unknown, there is some indication that AOP's modulate opioid receptor levels. In this study, we investigated the effects of chronically infused alpha-melanocyte stimulating hormone (alpha-MSH), dynorphin(1-8) (DYN(1-8)), dynorphin A (DYNA), and NPFF antibodies on delta-opioid receptor expression in rat brains. Quantitative autoradiographic experiments revealed that antibodies directed against alpha-MSH and DYNA produced significant increases in delta receptor levels in the caudate, claustrum, and cingulate cortex of the rat brain. Conversely, NPFF monoclonal antibodies caused significant decreases in the caudate, nucleus accumbens, olfactory tubercle, and cingulate cortex. These results suggest that the density of delta-opioid receptors is affected by changes in the levels of the anti-opioid peptides in the extracelluar fluid in the rat brain.     

Comparison of structural requirements of α-MSH and ACTH for inducing excessive grooming and pigment dispersion

α-MSH and ACTH-like peptides are known to play an important role in the adaptation of many vertebrates to a new environment. These peptides induce pigment dispersion in amphibian melanophores through a receptor-mediated mechanism. In this study we compared the structural requirements of these peptides for melanotropic activity on Xenopus laevis melanophores with those for inducing excessive grooming in the rat. With the exception of ACTH_1–24 there is a close resemblance in structure-activity relationships of the fragments and analogs tested in the two bioassays. [Nle⁴,-D-Phe⁷]-α-MSH is extremely active in both assays. Weak agonists such as [Leu⁹]-α-MSH did not possess antagonistic properties either in the melanophore assay or in the excessive grooming test. The data suggest that the mechanism of action of α-MSH-like peptides in rat brain is receptor-mediated like their action on melanophores.     

Characterization of β-endorphin- and α-MSH-related peptides in rat heart

POMC-derived peptides and mRNA have been identified in heart tissue, although POMC processing has not been fully characterized. In the present study, we found that β-lipotropin and ACTH were localized in rat heart, although they were almost entirely converted to β-endorphin- and α-MSH-related peptides. Ion exchange HPLC analysis revealed that β-endorphin(1–31) was further processed to α-N-acetyl-β-endorphin(1–31), which comprised 35.9 ± 0.1% of total immunoreactivity, and smaller amounts of β-endorphin(1–27), β-endorphin(1–26), and their α-N-acetylated derivatives. The predominant α-MSH immunoreactive peptides coeluted with α-MSH and N,O-diacetyl-α-MSH by reverse-phase HPLC, although small amounts of ACTH(1–13)-NH₂ were also present. Thus, multiple forms of β-endorphin and α-MSH are localized in rat heart. β-Endorphin(1–31) is a minor constituent, however, indicating that nonopioid β-endorphin peptides predominate.     

Structural and conformational modifications of α-MSH/ACTH4–10 provide melanotropin analogues with highly potent behavioral activities

Previous studies have identified the (4–10) heptapeptide sequence as the central core of α-MSH/ACTH peptides required for mediation of important biological activities. In the present study, the structure-activity relationships of Nle⁴-substituted and -bridged cyclic α-MSH analogues, which were previously shown to exhibit a wide range of melanotropic potencies from weak agonism to super potency, were examined for grooming behavioral activity in the rat following intracerebroventricular injections. The results showed that stepwise C-terminal elongation of the linear Nle⁴-substituted Ac-α-MSH_4–10-NH₂ increased grooming potencies of the peptides in a manner similar to their actions on melanocytes. The most interesting finding was the observation that cyclization of the inactive linear “central (4–10) core” of α-MSH (Ac-α-MSH_4–10) to form Ac-[ ]-α-MSH_4–10-NH₂ resulted in a super potent agonist in the grooming assay. However, while cyclization of the (4–10) heptapeptide produced potent agonists on grooming behavior, the structure-activity relationships were different than the frog skin bioassay. These findings support the hypothesis that appropriate structural and confirmational modifications of α-MSH-related peptides can produce profound effects on the bioactivities of the peptides, and suggest that different structural-conformational requirements exist for α-MSH interactions with its various receptors.     

Opposite Effects of Neuropeptide FF on Central Antinociception Induced by Endomorphin-1 and Endomorphin-2 in Mice

Neuropeptide FF (NPFF) is known to be an endogenous opioid-modulating peptide. Nevertheless, very few researches focused on the interaction between NPFF and endogenous opioid peptides. In the present study, we have investigated the effects of NPFF system on the supraspinal antinociceptive effects induced by the endogenous µ-opioid receptor agonists, endomorphin-1 (EM-1) and endomorphin-2 (EM-2). In the mouse tail-flick assay, intracerebroventricular injection of EM-1 induced antinociception via µ-opioid receptor while the antinociception of intracerebroventricular injected EM-2 was mediated by both µ- and κ-opioid receptors. In addition, central administration of NPFF significantly reduced EM-1-induced central antinociception, but enhanced EM-2-induced central antinociception. The results using the selective NPFF₁ and NPFF₂ receptor agonists indicated that the EM-1-modulating action of NPFF was mainly mediated by NPFF₂ receptor, while NPFF potentiated EM-2-induecd antinociception via both NPFF₁ and NPFF₂ receptors. To further investigate the roles of µ- and κ-opioid systems in the opposite effects of NPFF on central antinociception of endomprphins, the µ- and κ-opioid receptors selective agonists DAMGO and {"type":"entrez-nucleotide","attrs":{"text":"U69593","term_id":"4205069","term_text":"U69593"}}U69593, respectively, were used. Our results showed that NPFF could reduce the central antinociception of DAMGO via NPFF₂ receptor and enhance the central antinociception of {"type":"entrez-nucleotide","attrs":{"text":"U69593","term_id":"4205069","term_text":"U69593"}}U69593 via both NPFF₁ and NPFF₂ receptors. Taken together, our data demonstrate that NPFF exerts opposite effects on central antinociception of endomorphins and provide the first evidence that NPFF potentiate antinociception of EM-2, which might result from the interaction between NPFF and κ-opioid systems.     

α-MSH and coat color changes in the mouse

The effect of α-MSH on coat color was examined in viable yellow mice (C3H/He-A*^vy). These mice normally grow a coat of darkly pigmented hair at puberty. This darkening effect was also evident in hair that grew in a region that had been plucked at 13 days of age. Administration of α-MSH increased the darkness of this hair and the hair which grew naturally in an unplucked area. However, the natural coat darkening that occurred at puberty was not associated with an increase in plasma immunoreactive α-MSH levels. Moreover, although bromocryptine, a dopamine agonist that inhibits α-MSH release from the pituitary reduced the darkness of the coat that grew after plucking the reduction in coat darkening was unrelated to changes in plasma α-MSH. Nevertheless, this effect of bromocryptine was reversed when α-MSH was administered together with the drug. Apomorphine had no effect on coat darkening and produced only a slight decrease in plasma α-MSH. Melatonin reduced coat darkening slightly but, like apomorphine, had little effect on plasma α-MSH concentrations. Although α-MSH may have a physiological role in coat darkening in the C3H/He-A*^vy mouse at puberty the response seems to be unrelated to an increase in circulating α-MSH. Thus, other factors, such as changes in melanocyte sensitivity to α-MSH or inhibitory mechanisms that prevent coat darkening during prepubertal and adult life may be involved in regulation of coat color in the viable yellow mouse.     

Relative stability of α-melanotropin and related analogues to rat brain homogenates

α-Melanotropin (α-MSH) retains less than 1% of its original activity after a 60 min incubation with 10% rat brain homogenate. [Nle⁴, D-Phe⁷]-α-MSH is nonbiodegradable in rat serum (240 min incubation) and still maintains 10% of its original activity in 10% rat brain homogenate (240 min incubation). The related fragment analogue, Ac-[Nle⁴, D-Phe⁷]-α-MSH_4–10-NH₂, retains 50% of its activity after a 240 min incubation in rat brain homogenate, whereas Ac-[Nle⁴, D-Phe⁷]-α-MSH_4–11-NH₂ is totally resistant to inactivation by rat brain homogenate. Both [Nle⁴, D-Phe⁷]-fragments are resistant to degradation by rat serum, but [Nle⁴]-α-MSH, Ac-[Nle⁴]-α-MSH_4–10-NH₂ and Ac-[Nle⁴]-α-MSH_4–11-NH₂ are rapidly inactivated under both conditions. The cyclic melanotropin, [ ]-α-MSH, is inactivated in rat brain homogenate as is the shorter Ac-[ ]-α-MSH_4–10-NH₂ analogue, but neither cyclic melanotropin is inactivated upon incubation in serum from rats. Ac-[ ]-α-MSH_4–10-NH₂ is resistant to inactivation by either rat serum or a brain homogenate. Some of these melanotropin analogues may provide useful probes for the localization and characterization of putative melanotropin receptors in both the central nervous system and peripheral tissues.     

In vitro antimicrobial activity of alpha-melanocyte stimulating hormone against major human pathogen Staphylococcus aureus

Alpha-melanocyte stimulating hormone (α-MSH) is an endogenous anti-inflammatory peptide reported to possess antimicrobial properties, however their role as antibacterial peptides is yet to be established. In the present study, we examined in vitro antibacterial activity of α-MSH against S. aureus strain ISP479C and several methicillin-sensitive (MSSA) and methicillin-resistant (MRSA) S. aureus strains. Antibacterial activity was examined by varying several parameters, viz., bacterial cell densities, growth phase, pH, salt concentration, and temperature. Antibacterial activity was also examined in complex biomatrices of rat whole blood, plasma and serum as well as in biofilm form of bacteria. Our results showed that α-MSH possessed significant and rapid antibacterial activity against all the studied strains including MRSA (84% strains were killed on exposure to 12 μM of α-MSH for 2 h). pH change from 7.4 to 4 increased α-MSH staphylocidal activity against ISP479C by 21%. Antibacterial activity of α-MSH was dependent on bacterial cell density and independent of growth phase. Moreover, antimicrobial activity was retained when α-MSH was placed into whole blood, plasma, and serum. Most importantly, α-MSH exhibited antibacterial activity against staphylococcal biofilms. Multiple membrane permeabilization assays suggested that membrane damage was, at least in part, a major mechanism of staphylocidal activity of α-MSH. Collectively the above findings suggest that α-MSH could be a promising candidate of a novel class of antimicrobial agents.     

Cloning of a neoteleost (Oreochromis mossambicus) pro-opiomelanocortin (POMC) cDNA reveals a deletion of the γ-melanotropin region and most of the joining peptide region: implications for POMC processing

A signature feature of tetrapod pro-opiomelanocortin (POMC) is the presence of three melantropin (MSH) coding regions (α-MSH, β-MSH, γ-MSH). The MSH duplication events occurred early during the radiation of the jawed vertebrates well over 400 million years ago. However, in at least one order of modern bony fish (subdivision Teleostei; order Salmoniformes; i.e. salmon and trout) the γ-MSH sequence has been deleted from POMC. To determine whether the γ-MSH deletion has occurred in other teleost orders, a POMC cDNA was cloned from the pituitary of the neoteleost Oreochromis mossambicus (order Perciformes). In O. mossambicus POMC, the deletion is more extensive and includes the γ-MSH sequence and most of the joining peptide region. Because the salmoniform and perciform teleosts do not share a direct common ancestor, the γ-MSH deletion event must have occurred early in the evolution of the neoteleost fishes. The post-translational processing of O. mossambicus POMC occurs despite the fact that the proteolytic recognition sequence, (R/K)-X_n-(R/K) where n can be 0, 2, 4, or 6, a common feature in mammalian neuropeptide and polypeptide hormone precursors, is not present at several cleavage sites in O. mossambicus POMC. These observations would indicate that either the prohormone convertases in teleost fish use distinct recognition sequences or vertebrate prohormone convertases are capable of recognizing a greater number of primary sequence motifs around proteolytic cleavage sites.     

Molecular forms of α-melanocyte-stimulating hormone in the canine pituitary anterior and intermediate lobe

Reverse-phase high pressure liquid chromatography (HPLC) and radioimmunoassay (RIA) were used to determine the distribution of naturally occurring forms of α-melanocyte-stimulating hormone (α-MSH) in acid extracts of pars intermedia (PI) and anterior lobe (AL) tissue from canine and rat pituitary. Similarly, intracellular and secreted forms of α-MSH were determined using cultured canine PI and AL cells. Rat PI tissue contained predominantly diacetyl-α-MSH, while monoacetyl-α-MSH was the most abundant form in canine PI. In both canine and rat AL tissue extracts desacetyl-α-MSH was the major form of α-MSH. The profile of α-MSH contained in and secreted into culture medium by canine PI cells was found to be very similar to that in PI tissue extracts. The proportion of monoacetyl-α-MSH and diacetyl-α-MSH secreted by cultured canine AL cells and contained in extracts of AL cells in culture, however, was much higher than that in tissue extracts. These results indicate that in the dog, as in all other mammalian species studied, acetylated forms of α-MSH predominate in PI tissue, while nonacetylated α-MSH is the major form in AL tissue. It appears, however, that acetylation of α-MSH may occur in cultured canine AL cells, possibly as a result of the absence of factors that normally inhibit acetyltransferase in vivo or as a consequence of culture conditions.     

Functional expression and sites of gene transcription of a novel α subunit of the GABAA receptor in rat brain

Two α subunits of the gabaa receptor in rat brain have been identified by molecular cloning. The deduced polypeptide sequences share major characteristics with other chemically gated ion channel proteins. One polypeptide represents the rat homologue of the α3 subunit previously cloned from bovine brain [14], while the other polypeptide is a yet unknown subunit, termed α5. When coexpressed with the β1 subunit in Xenopus oocytes the receptors containing the α5 subunit revealed a higher sensitivity to GABA than receptors expressed from α1 + β1 subunits or α3 + β1 subunits (K_a = 1 μM, 13 μM and 14 μM, respectively). The α5 subunit was expressed only in a few brain areas such as cerebral cortex, hippocampal formation and olfactory bulb granular layer as shown by in situ hybridization histochemistry. Since the mRNA of the α5 subunit was colocalized with the αl and α3 subunits only in cerebral cortex and in the hippocampal formation the α5 subunit may be part of distinct GABA_A receptors in neuronal populations within the olfactory bulb.     

The effects of melanocortin agonists and antagonists on leptin-induced fever in rats

1. Over three experiments, separate groups of adult male Sprague–Dawley rats received intracerebroventricular (ICV) injections of either vehicle, recombinant rat leptin (1 μg), or leptin (4 μg), then two ICV injections, 30 min apart of vehicle/vehicle, leptin (4 μg)/vehicle, vehicle/α-MSH (300 ng), or leptin/α-MSH, and then vehicle/vehicle, leptin (4 μg)/vehicle, vehicle/ SHU-9119 (200 ng; a MC 3/4 receptor antagonist), or leptin/SHU-9119. Core temperatures (T_c), food intake and body weights were monitored.

2. Four microgram leptin resulted in the induction of fever, an effect blocked by injection of α-MSH. Antagonism of MC 3/4 receptors with SHU-9119 did not augment leptin-induced fever, but did block the inhibitory actions of leptin on food intake.

3. These data demonstrate the inhibitory effects of exogenous α-MSH on leptin-induced fever, but suggest that endogenous melanocortin action at MC 3/4 receptors does not tonically inhibit febrigenesis caused by leptin administration.

The effect of α-melanocyte stimulating hormone on endotoxin-induced intestinal injury

We investigated the effect of α-melanocyte stimulating hormone (α-MSH) on endotoxin-induced intestinal inflammation and the role of nitric oxide and prostaglandins in this response. α-MSH treatment (25 μg/rat, intraperitoneally (i.p.); twice daily) reduced the severity of the lesions macroscopically and microscopically. This protective effect was found to be confined mainly to the distal ileum. These lesions were reversed by pretreatment with the non-selective COX inhibitor indomethacin (10 mg/kg, subcutaneously (s.c.)) but not by the selective COX-2 inhibitor nimesulide (3 mg/kg, s.c.), the NO donor sodium nitroprusside (4 mg/kg, i.v.) or the iNOS inhibitor dexamethasone (3 mg./kg, i.p.) at macroscopic level and reversed by Indo or Dex at microscopic level. Increased peroxidase activity -index of tissue neutrophil infiltration- in the distal ileum of LPS-treated rats was decreased by α-MSH and this effect was reversed by pretreatment with Indo. In conclusion, the neuropeptide α-MSH has a beneficial effect on endotoxin-induced distal intestinal lesions by a mechanism which probably involves nitric oxide and COX-1 derived prostaglandins.     

Central and peripheral actions of α-MSH in the thermoregulation of rats

The effect of α-MSH on thermoregulation in rats at room temperature was examined. α-MSH (1 μg ICV or 30 μg IP) alone did not alter temperature. However, this peptide was a potent antipyretic when administered centrally or peripherally in rats treated with pyrogen derived from Salmonella typhi.     

Design and synthesis of peptides that bind α-bungarotoxin with high affinity and mimic the three-dimensional structure of the binding-site of acetylcholine receptor

α-Bungarotoxin (α-BTX) is a highly toxic snake neurotoxin that binds to acetylcholine receptor (AChR) at the neuromuscular junction, and is a potent inhibitor of this receptor. In the following we review multi-phase research of the design, synthesis and structure analysis of peptides that bind α-BTX and inhibit its binding to AChR. Structure-based design concomitant with biological information of the α-BTX/AChR system yielded 13-mer peptides that bind to α-BTX with high affinity and are potent inhibitors of α-BTX binding to AChR (IC₅₀ of 2 nM). X-Ray and NMR spectroscopy reveal that the high-affinity peptides fold into an anti-parallel β-hairpin structure when bound to α-BTX. The structures of the bound peptides and the homologous loop of acetylcholine binding protein, a soluble analog of AChR, are remarkably similar. Their superposition indicates that the toxin wraps around the binding-site loop, and in addition, binds tightly at the interface of two of the receptor subunits and blocks access of acetylcholine to its binding site. The procedure described in this article may serve as a paradigm for obtaining high-affinity peptides in biochemical systems that contain a ligand and a receptor molecule.     

3D-Neuronavigation In Vivo Through a Patient's Brain During a Spontaneous Migraine Headache

A growing body of research, generated primarily from MRI-based studies, shows that migraine appears to occur, and possibly endure, due to the alteration of specific neural processes in the central nervous system. However, information is lacking on the molecular impact of these changes, especially on the endogenous opioid system during migraine headaches, and neuronavigation through these changes has never been done. This study aimed to investigate, using a novel 3D immersive and interactive neuronavigation (3D-IIN) approach, the endogenous µ-opioid transmission in the brain during a migraine headache attack in vivo. This is arguably one of the most central neuromechanisms associated with pain regulation, affecting multiple elements of the pain experience and analgesia. A 36 year-old female, who has been suffering with migraine for 10 years, was scanned in the typical headache (ictal) and nonheadache (interictal) migraine phases using Positron Emission Tomography (PET) with the selective radiotracer [¹¹C]carfentanil, which allowed us to measure µ-opioid receptor availability in the brain (non-displaceable binding potential - µOR BP_ND). The short-life radiotracer was produced by a cyclotron and chemical synthesis apparatus on campus located in close proximity to the imaging facility. Both PET scans, interictal and ictal, were scheduled during separate mid-late follicular phases of the patient''s menstrual cycle. During the ictal PET session her spontaneous headache attack reached severe intensity levels; progressing to nausea and vomiting at the end of the scan session. There were reductions in µOR BP_ND in the pain-modulatory regions of the endogenous µ-opioid system during the ictal phase, including the cingulate cortex, nucleus accumbens (NAcc), thalamus (Thal), and periaqueductal gray matter (PAG); indicating that µORs were already occupied by endogenous opioids released in response to the ongoing pain. To our knowledge, this is the first time that changes in µOR BP_ND during a migraine headache attack have been neuronavigated using a novel 3D approach. This method allows for interactive research and educational exploration of a migraine attack in an actual patient''s neuroimaging dataset.     

Characterization, size estimation and solubilization of α-macroglobulin complex receptors in liver membranes

Receptors for α₂-macroglobulin-proteinase complexes have been characterized in rat and human liver membranes. The affinity for binding of ¹²⁵I-labelled α₂-macroglobulin · trypsin to rat liver membranes was markedly pH-dependent in the physiological range with maximum binding at pH 7.8–9.0. The half-time for association was about 5 min at 37°C in contrast to about 5 h at 4°C. The half-saturation constant was about 100 pM at 4°C and 1 nM at 37°C (pH 7.8). The binding capacity was approx. 300 pmol per g protein for rat liver membranes and about 100 pmol per g for human membranes. Radiation inactivation studies showed a target size of 466 ± 71 kDa (S.D., n = 7) for α₂-macroglobulin · trypsin binding activity. Affinity cross-linking to rat and human membranes of ¹²⁵I-labelled rat α₁-inhibitor-3 · chymotrypsin, a 210 kDa analogue which binds to the α₂-macroglobulin receptors in hepatocytes (Gliemann, J. and Sottrup-Jensen, L. (1987) FEBS Lett. 221, 55–60), followed by SDS-polyacrylamide gel electrophoresis, revealed radioactivity in a band not distinguishable from that of cross-linked α₂-macroglobulin (720 kDa). This radioactivity was absent when membranes with bound ¹²⁵I-α₁-inhibitor-3 complex were treated with EDTA before cross-linking and when incubation and cross-linking were carried out in the presence of a saturating concentration of unlabelled complex. The saturable binding activity was maintained when membranes were solubilized in the detergent 3-[(3-cholamidopropyl)dimethylammonio]profane sulfonate (CHAPS) and the size of the receptor as estimated by cross-linking experiments was shown to be similar to that determined in the membranes. It is concluded that liver membranes contain high concentrations of an approx. 400–500 kDa α₂-macroglobulin receptor soluble in CHAPS. The soluble preparation should provide a suitable material for purification and further characterization of the receptor.     

Bovine intermediate pituitary α-amidation enzyme: Preliminary characterization

A secretory granule-associated enzymatic activity that converts mono-[¹²⁵I]-D-Tyr-Val-Gly into mono-[¹²⁵I]-D-Tyr-Val-NH₂ has been studied. The activity is primarily soluble and shows optimal activity at pH 7 to pH 8. Amidation activity was stimulated 9-fold by addition of optimal amounts of copper (3 μM). In the presence of optimal copper, ascorbate stimulated the reaction 7-fold; none of the other reduced or oxidized cofactors tested was as effective. Taking into account the dependence of the reaction on ascorbate and molecular oxygen and the production of glyoxylate [2], it is suggested that the α-amidation enzyme is a monooxygenase. Lineweaver Burk plots with D-Tyr-Val-Gly as the varied substrate demonstrated Michelis-Menten type kinetics with the values of K_m and V_max increasing with the addition of ascorbate to the assay. A variety of peptides ending with a COOH-terminal Gly residue act as inhibitors of the reaction. Two synthetic peptides, γ₂MSH and ACTH(1–14), with carboxyl termini similar to the presumed physiological substrates for the enzyme, act as competitive inhibitors with similar K₁ values. It is likely that this secretory granule α-amidation activity is involved in the physiological biosynthetic α-amidation of a wide range of bioactive peptides.     

Regulation of μ binding sites after chronic administration of antibodies directed against specific anti-opiate peptides

There is some indication that anti-opiate peptides (AOP) modulate opioid receptor systems by altering μ-receptor density. To further characterize this phenomenon, we investigated the effects of continuous infusion of anti-AOP IgG on μ binding sites in the brains of rats. Specifically, male Sprague–Dawley rats received intracerebroventricular (ICV) infusions for 13 days of either control (rabbit) IgG or test IgGs: anti-dynorphin A IgG, anti-dynorphin A_1–8 IgG, anti-α-MSH IgG, or the monoclonal anti-NPFF IgG. Administration of anti-NPFF IgG or the anti-dynorphin_1–8 IgG significantly increased μ labeling by 40–70% in several brain regions at the caudate level. Contrary to these findings, anti-α-MSH IgG decreased (19–32%) [¹²⁵I]-DAMGO labeling in several thalamic nuclei. The results suggest that the density of μ-opioid receptors is regulated in part by anti-opiate peptides in the extracellular fluid of the brain.