Effect of opioid antagonism on β-endorphin processing and proopiomelanocortin-peptide release in the hypothalamus

Previous studies have shown that chronic opioid receptor blockade has significant effects on POMC gene expression and peptide levels in the hypothalamus. We have now examined the effects of the opioid antagonist naltrexone on β-EP processing in the hypothalamus and on the release of 2 POMC-derived peptides, β-EP andγ₃-MSH, from the perifused hypothalamus in vitro. The β-EP immunoactivity in the medial basal hypothalamus (MBH) of 7 rats infused for 1 week with naltrexone by osmotic minipump, was individually analyzed by HPLC and compared to 7 control rats. The mean ratio of β-EP_1–31 compared to β-EP_1–27 plus β-EP_1–26 was 2.34 ± 0.41 in the naltrexone treated rats, significantly higher than the ratio of 1.26 ± 0.09 in the control rats (P < 0.02). Thus in the setting of chronic opioid antagonism although β-EP content decreases, there is relatively more β-EP_1–31, the biologically active opioid form of the peptide, compared to the C-terminally cleaved forms of β-EP which have reduced biological activity. To study the effects of naltrexone on β-EP andγ₃-MSH release, hypothalami were perfused in vitro with 10⁻⁶M naltrexone. Basal release ofγ₃-MSH was significantly higher from the naltrexone treated brains compared to the controls (221 ± 20pg/60min vs.161 ± 6.7pg/60 min) (P < 0.01); KCl stimulatedγ₃-MSH was also significantly higher in the naltrexone group (951 ± 94 vs.543 ± 85pg/60 min) (P < 0.005). Basal release of β-EP was136 ± 45pg/60 min in the naltrexone treated brains compared to 93 ± 15pg in the controls, but this difference was not significant; KCl stimulated release of β-EP, however was significantly higher in the naltrexone group (558 ± 103 vs. 275 ± 49pg/60 min (P < 0.02). To study the acute and chronic effects of naltrexone in vivo on β-EP andγ₃-MSH release, rats were either injected with naltrexone and sacrificed 40–60 min later or were infused with naltrexone for 7 days. Baselineγ₃-MSH release was significantly higher in rats treated with naltrexone 40–60 min prior to the perifusion (P < 0.01). Baseline β-EP release was below the limit of assay detection. No differences were noted in the responses ofγ₃-MSH or β-EP to KCl in either group. In contrast after chronic treatment with naltrexone for 1 week, baseline peptide release was not different from the control animals despite a more than 50% fall in peptide content. Theγ₃-MSH and β-EP responses to KCl stimulation, however, were significantly less in the naltrexone treated animals. Thus there is an increase in POMC peptide release acutely after treatment with naltrexone in vitro and in vivo. After 1 week of naltrexone, baseline POMC peptide release continues unchanged despite the fall in peptide content, however, the response to KCl is blunted possibly reflecting the decrease in peptide content after chronic stimulation with naltrexone. We conclude that naltrexone has significant effects on POMC peptide release and on β-EP processing in the hypothalamus. These results further demonstrate that the brain POMC system can respond to opioid blockade at several levels and are consistent with inhibitory feedback mechanisms for the autoregulation of the POMC system by endogenous β-EP.     

Stimulation of hypothalamic β-endorphin and dynorphin release by corticotropin-releasing factor (in vitro)

Corticotropin-releasing factor (CRF) at doses of 10⁻¹²–10⁻⁸ M significantly stimulated the release of β-endorphin and dynorphin from superfused rat hypothalamic slices. These effects were shown to be mediated by the CRF receptor since they were antagonized by the CRF receptor antagonist α-helical CRF_9–41 (10⁻⁶ M). The two opioid peptides showed different time courses of response and in the case of β-endorphin, an attenuation of the response upon continued exposure to CRF was observed.     

The β-endorphin inhibition of mitogen-induced splenocytes proliferation is mediated by central and peripheral paracrine/autocrine effects of the opioid

In this study we show that the opioid peptide β-endorphin exerts a tonic inhibitory effect on the proliferative response of splenocytes to the polyclonal mitogen phytohemoagglutinin throughout two separate sites of action: one central and one peripheral. The intracerebroventricular administration of β-endorphin, in fact, induces a significant inhibition of splenocyte proliferation. In contrast, both the intracerebroventricular and the peripheral administration of anti-β-endorphin γ globulins induce a significant increase in proliferation. Moreover, an increase of splenocyte proliferation was observed also after the intravenous administration of γ globulins and intraperitoneal naloxone, and this effect was still present in hypophysectomized rats. The data reported suggest that β-endorphin exerts a tonic inhibitory effect on proliferation, acting centrally, and peripherally throughout a paracrine/autocrine mechanism. FACS experiments show that the effect observed is not the consequence of an alteration of lymphocyte trafficking induced by the opioid.     

Alzheimer's β-amyloid peptides induce inflammatory cascade in human vascular cells: the roles of cytokines and CD40

Accumulating evidence suggests that β-amyloid (Aβ)-induced inflammatory reactions may partially drive the pathogenesis of Alzheimer's disease (AD). Recent data also implicate similar inflammatory processes in cerebral amyloid angiopathy (CAA). To evaluate the roles of Aβ in the inflammatory processes in vascular tissues, we have tested the ability of Aβ to trigger inflammatory responses in cultured human vascular cells. We found that stimulation with Aβ dose-dependently increased the expression of CD40, and secretion of interferon-γ (IFN-γ) and interleukin-1β (IL-1β) in endothelial cells. Aβ also induced expression of IFN-γ receptor (IFN-γR) both in endothelial and smooth muscle cells. Characterization of the Aβ-induced inflammatory responses in the vascular cells showed that the ligation of CD40 further increased cytokine production and/or the expression of IFN-γR. Moreover, IL-1β and IFN-γ synergistically increased the Aβ-induced expression of CD40 and IFN-γR. We have recently found that Aβ induces expression of adhesion molecules, and that cytokine production and interaction of CD40–CD40 ligand (CD40L) further increase the Aβ-induced expression of adhesion molecules in these same cells. These results suggest that Aβ can function as an inflammatory stimulator to activate vascular cells and induces an auto-amplified inflammatory molecular cascade, through interactions among adhesion molecules, CD40–CD40L and cytokines. Additionally, Aβ_1–42, the more pathologic form of Aβ, induces much stronger effects in endothelial cells than in smooth muscle cells, while the reverse is true for Aβ_1–40. Collectively, these findings support the hypothesis that the Aβ-induced inflammatory responses in vascular cells may play a significant role in the pathogenesis of CAA and AD.     

Copper-induced release of immunoreactive α-melanotropin from isolated hypothalamic granules

Previously, we demonstrated that copper chelates stimulate the release of luteinizing hormone releasing hormone (LHRH) from isolated hypothalamic granules. To assess the generality of the copper-stimulated release process, we determined the effects of copper on the release of immunoreactive α-melanotropin (α-MSH₁) from isolated granules. When granules were incubated with various copper complexes, CuATP stimulated α-MSH₁ release by 54 ± 6% (mean ± S.E.), Cu tartarate by 56 ± 4%, CuBSA by 32 ± 5% and Cu histidine by 29 ± 2%. CuATP-stimulated α-MSH₁ release from granules incubated under N₂ was 57% of that incubated under air. Furthermore, the reducing agent dithiothreitol (DTT) inhibited CuATP-stimulated α-MSH₁ release (p < 0.01), whereas oxidized DTT did not do so. Pretreatment of granules with the thiol-blocking reagents iodoacetic acid or 5, 5'-dithiobis-(2-nitrobenzoic acid) inhibited CuATP-stimulated α-MSH₁ release by 52 ± 3 and 38 ± 4%, respectively. Thus, chelated copper, rather than ionic copper, is the active form of the metal and the action of copper involves the oxidation of thiols. These data are similar to those previously observed for the copper-stimulated release of LHRH. Hence, the effects of copper on the permeability of granule membranes may be a generalized phenomenon which underlies susceptibility of storage granules to the reduction-oxidation status of the cellular milieu.     

Release of immunoreactive met-enkephalin from the spinal cord by intraventricular β-endorphin but not morphine in anesthetized rats

Effect of β-endorphin and morphine injected intraventricularly on the release of immunoreactive Met-enkephalin, Leu-enkephalin and dynorphin_1–13 from the spinal cord was studied in anesthetized rats. Intraventricular β-endorphin, 16 μg, caused a marked spinal release of immunoreactive Met-enkephalin and to a much lesser extent, of immunoreactive Leu-enkephalin while intraventricular morphine, 40 μg, did not cause any significant release of immunoreactive enkephalins. The release of immunoreactive Met-enkephalin was not blocked by the pretreatment with 5 mg/kg naloxone, i.p. Immunoreactive dynorphin_1–13 was not released by either β-endorphin or morphine. High performance liquid chromatographic analysis indicated that immunoreactive Met-enkephalin released by β-endorphin had a retention time identical to [³H]Met-enkephalin. These findings in conjunction with previous pharmacological studies suggest different modes of pharmacological action for β-endorphin and morphine.     

Pro-opiocortin fragments in human and rat brain: β-endorphin and α-MSH are the predominant peptides

The ‘pro-opiocortin’ fragments, β-lipotropin, β-endorphin, ACTH and α-MSH, were estimated in discrete areas of rat and human brain and pituitaries by means of radioimmunoassay in combination with gelfiltration. These peptides exihibited parallel patterns of distribution, but with β-endorphin and α-MSH predominant in the brain of rat and man, and, in contrast, their respective precursors, β-LPH and ACTH predominant in the adenohypophysis of rat and man. These data may be indicative of important differences in post-translational processing of ‘pro-opiocortin’ between these contrasting tissues.     

α-Melanocyte stimulating hormone discloses a stimulatory effect of β-endorphin on somatostatin release

The influence of alpha-melanocyte stimulating hormone (alpha-MSH) and beta-endorphin (beta-END) on the secretion of somatostatin (SRIF) from the median eminence (ME) was studied using an in vitro incubation system. The MEs from adult male rats were first preincubated at 37 degrees C for 30 min with constant shaking in 0.4 ml of Krebs-Ringer bicarbonate-glucose buffer (pH 7.4) containing bacitracin in an atmosphere of 95% O2/5% CO2. Medium was discarded and replaced by medium containing different doses of alpha-MSH, beta-END, or a fixed dose of alpha-MSH (10(-7) M or 10(-9) M) plus beta-END at various concentrations. By themselves alpha-MSH and beta-END did not alter basal SRIF release, but in the presence of alpha-MSH (10(-7) M) beta-END stimulated somatostatin release. This effect was significant at concentrations of beta-END of 10(-8) M and higher. The permissive effect of alpha-MSH was observed at a concentration as low as 10(-9) M, but in this case the stimulatory effect of beta-END became evident only at higher doses tested (10(-7) M). It is suggested that alpha-MSH and beta-END participate in the modulation of SRIF release. By themselves beta-END and alpha-MSH did not affect basal release of SRIF but in the presence of alpha-MSH, beta-END had a stimulatory effect on SRIF release. The mechanism for this interaction is unknown. The results are consistent with the possibility that beta-END neurons have stimulatory and inhibitory effects on SRIF release and that alpha-MSH, by blocking the inhibitory components, discloses the stimulatory effect of beta-END on SRIF release.     

Effects of β-endorphin and its fragments on inhibitory avoidance behavior in rats

The effects on retrieval of a one-trial learning inhibitory avoidance response of β-endorphin, α-endorphin, and γ-endorphin, given prior to test have been studied in rats. β-Endorphin (β-LPH_61–91) in a relatively low dose (1.5 μg sc. or 50 ng icv.) facilitated inhibitory avoidance behavior, while a higher dose (10 μg sc. or 100 ng icv.) caused bimodal changes (facilitation in 50% of the animals and attenuation in another 40%. Peripheral injection of γ-endorphin attenuated inhibitory avoidance behaviour in a dose-dependent manner. The C-terminus of β-endorphin (β-LPH_78–91) was ineffective. α-Endorphin facilitated inhibitory avoidance behavior in a dose-dependent manner. Naltrexone pretreatment antagonized the bimodal effect of β-endorphin: following pretreatment with the opiate antagonist the low latency component disappeared, but the facilitatory effect of the neuropeptide remained the same.It is suggested that β-endorphin carries more than one bit of behavioral information. Inherent activities either related or unrelated to naltrexone-sensitive opiate receptors as well as biotransformation into α- and γ-endorphin may contribute to the multiple behavioral effects of this neuropeptide.     

Dissociation of antinociceptive and motor effects of supraspinal opioid agonists in the rat

This study compared the antinociceptive and motor effects produced by intracerebroventricular administration of selective mu- (DAMGO) and delta- (DPDPE) opioid receptor agonists in the rat. Changes in nociceptive thresholds were measured using the Randall-Selitto paw-withdrawal test and changes in motor coordination were evaluated using the rotarod treadmill test. Both DAMGO and DPDPE produced statistically significant, dose-dependent increases in mechanical nociceptive thresholds compared to vehicle controls. However, in the motor coordination studies, neither opioid agonist produced statistically significant changes in rotarod performance scores. The dissociation of antinociceptive and motor effects at this supraspinal site differs from the strong association between antinociceptive and motor effects produced by intrathecal administration of the same opioid agonists.     

Lack of effect of interleukins 1α and 1β, during in vitro perifusion,on anterior pituitary release of adrenocorticotropic hormone and β endorphin in the male rat

It has been demonstrated that interleukin 1 (IL1) injection provokes a great variety of biological effects, notably an activation of the corticotropic axis, increasing plasma adrenocorticotropic hormone (ACTH) and corticosterone. However, the primary site of action of IL1 is still controversial. In the present study, we first verified the in vivo capability of human interleukins 1α (hIL1α) and 1β (hIL1β) to release ACTH and β endorphin (β EP) in the normal male rat, before investigating, through an anterior pituitary (AP) perifusion system, the hIL1α and hIL1β effects on basal and corticotropin-releasing factor (CRF)-induced ACTH and β EP secretions. This system enabled the examination of a dynamic profile of hormones secretion, avoiding the possibility of feedback mechanisms, as is the case with the use of regular but very often longtime incubations. The results showed that in a perifusion system, with a short duration treatment (below 2 hr) compatible with the kinetics of action observed in vivo, basal and CRF-induced ACTH and β EP release were not modified in the presence of a broad range of concentrations (from 10^?12 to 10^?9 M) of hIL1α or hIL1β. Taken together, these results clearly show that in an in vitro situation close to physiological conditions, the primary site of action of hIL1α and hIL1β on ACTH and β EP release is not located at the AP level in the male rat. © 1993 Wiley-Liss, Inc.     

μ-, δ-, κ- and ε-Opioid receptor modulation of the hypothalamic-pituitary-adrenocortical (HPA) axis: subchronic tolerance studies of endogenous opioid peptides

In opiate-naive rats, the endogenous opioid peptides, β-endorphin, dynorphin(1–13) and Met---Enk---Arg---Phe (MEAP) and the synthetic enkephalin analogue -Ala²- -Leu⁵-Enk (DADLE) potently stimulated plasma corticosterone in a dose-dependent, naloxone-reversible manner. To characterize their in vivo affinities, the effects of these peptides on plasma corticosterone release were tested in rats made tolerant to morphine, U50488H, DADLE/morphine or β-endorphin. These cross-tolerance studies showed that dynorphin and MEAP exerted their action on plasma corticosterone release at κ-opioid receptors. The action of DADLE occurred at δ-opioid receptors, while the action of β-endorphin occurred principally at another receptor site. These results indicate that there is independent modulation of the hypothalamic-pituitary-adrenal axis by endogenous opioid peptides at μ-, δ- and κ-opioid receptors. In addition, there may be modulation by β-endorphin at a separate site that we suggest could be a central ε-receptor site. This cross-tolerance paradigm, using a neuroendocrine model, provides in vivo evidence for the action of centrally active endogenous opioid peptides at multiple and independent opioid receptors.     

Effects of a chronic inflammatory stress on levels of pro-opiomelanocortin-derived peptides in the rat spleen and thymus

Adjuvant-induced arthritis (AA) in specific strains of rats is an immunologically mediated inflammatory disease which is also characterised by activation of the endocrine system. To further investigate the effects of AA on processing of the pro-opiomelanocortin (POMC) precursor in rat immune tissues, we utilised radioimmunoassays for adrenocorticotropin (ACTH), β-endorphin and α-melanocyte-stimulating hormone (α-MSH) to measure these peptides in the spleen and thymus. 14 days following adjuvant injection, spleen levels of ACTH were elevated in the AA group (4.47 ± 1.04 ng/g tissue, n = 9) compared to controls 2.42±0.4 ng/g) and exacerbation of the disease by removal of circulating glucocorticoids through bilateral adrenalectomy (ADX) resulted in further elevation of spleen ACTH (5.11 ± 1.22 ng/g). β-Endorphin levels in both the AA (10.60 ± 1.61 ng/g) and AA/ADX (13.37 ± 2.36 ng/g) groups were higher than controls 5.57 ± 0.65 ng/g). Conversely, α-MSH spleen levels were decreased in the AA (2.89 ± 0.22 ng/g) and AA/ADX (2.22 ± 0.33 ng/g) groups compared to controls (4.62 ± 0.45 ng/g) and were also decreased following adrenalectomy. In the thymus, ACTH levels were elevated in the AA group (8.95 ± 1.41 ng/g) compared to controls (5.79 ± 0.63 ng/g), and the same pattern wasevident for thymic α-MSH (0.64 ± 0.08 ng/g in AA animals compared to control levels of 0.35 ± 0.03 ng/g). Following G50 gel filtration, ACTH and β-endorphin immunoreactivities (ir) were present in both spleen and thymus as two peaks, one which eluted near the void volume and one which eluted in a lower molecular mass position than the standards. However, ir-ACTH and ir-β-endorphin were present in multiple peaks in AA spleen extracts, indicating extensive processing. These data are the first evidence that ir-ACTH and ir-β-endorphin tissue content and POMC processing in the spleen and thymus can be influenced by a chronic stress.     

Binding and uptake of Aβ1‐42 by primary human astrocytes in vitro

Clearance of the amyloid‐β peptide (Aβ) as a remedy for Alzheimer's disease (AD) is a major target in on‐going clinical trials. In vitro studies confirmed that Aβ is taken up by rodent astrocytes, but knowledge on human astrocyte‐mediated Aβ clearance is sparse. Therefore, by means of flow cytometry and confocal laser scanning microscopy (CLSM), we evaluated the binding and internalization of Aβ1‐42 by primary human fetal astrocytes and adult astrocytes, isolated from nondemented subjects (n = 8) and AD subjects (n = 6). Furthermore, we analyzed whether α1‐antichymotrypsin (ACT), which is found in amyloid plaques and can influence Aβ fibrillogenesis, affects the Aβ uptake by human astrocytes. Upon over night exposure of astrocytes to FAM‐labeled Aβ1‐42 (10 μM) preparations, (80.7 ± 17.7)% fetal and (52.9 ± 20.9)% adult Aβ‐positive astrocytes (P = 0.018) were observed. No significant difference was found in Aβ1‐42 uptake between AD and non‐AD astrocytes, and no influence of ApoE genotype on Aβ1‐42 uptake was observed in any group. There was no difference in the percentage of Aβ‐positive cells upon exposure to Aβ1‐42 (10 μM) combined with ACT (1,000:1, 100:1, and 10:1 molar ratio), versus Aβ1‐42 alone. CLSM revealed binding of Aβ1‐42 to the cellular surfaces and cellular internalization of smaller Aβ1‐42 fragments. Under these conditions, there was no increase in cellular release of the proinflammatory chemokine monocyte‐chemoattractant protein 1, as compared with nontreated control astrocytes. Thus, primary human astrocytes derived from different sources can bind and internalize Aβ1‐42, and fetal astrocytes were more efficient in Aβ1‐42 uptake than adult astrocytes. © 2008 Wiley‐Liss, Inc.     

RANTES release contributes to the protective action of PACAP38 against sodium nitroprusside in cortical neurons

Pituitary adenylate cyclase activating polypeptide (PACAP), a promising neuroprotective peptide, plays an important role during development of the nervous system and in regeneration after injury. PACAP directly promotes survival via multiple signaling systems in neurons. This neuropeptide also has immuno-modulatory properties and can regulate the expression of various inflammatory mediators such as chemokines in nonneuronal cells. Chemokines and their G protein-coupled receptors are widely distributed in the brain, suggesting important functions for these inflammatory proteins in the CNS. The ability of brain endothelial cells and glia to release chemokines has been well documented, whether neurons are also a source for these mediators is unclear. The objective of this study is to determine whether PACAP38 affects expression of regulated on activation normal T expressed and secreted (RANTES) and macrophage inflammatory protein 1-alpha (MIP-1α) in cultured neurons and if these chemokines contribute to the neuroprotective effect of PACAP38. The data show that incubation of neuronal cultures with both PACAP38 and sodium nitroprusside (SNP) reduces the neuronal cell death evoked by SNP alone. PACAP38 dose-dependently increases immunodetectable levels of both RANTES and MIP-1α released in the media by cultured neurons. Co-treatment with a neutralizing antibody to RANTES decreases the PACAP38-mediated protection against SNP. Although RANTES treatment of neurons increased MIP-1α levels in the media and MIP-1α supports neuronal survival in unstressed cultures, MIP-1α does not protect neurons from SNP-induced toxicity. Furthermore, co-treatment with a MIP-1α neutralizing antibody did not affect PACAP38-induced protection against SNP. These results show that the protective effect of PACAP38 on cultured neurons is mediated, in part, by release of RANTES. The ability of PACAP to directly enhance neuronal survival through multiple intracellular signaling pathways as well as via the release of neuroprotective mediators such as RANTES highlights its utility as a potential therapeutic agent for the treatment of neurodegenerative diseases.     

Localization of neurons containing pro-opiomelanocortin-related peptides in the hypothalamus and midbrain of the lizard, Anolis carolinensis evidence for region-specific processing of β-endorphin

Immunohistochemical analyses of the lizard brain, following colchicine pretreatment, revealed two populations of POMC-producing cell bodies located in medial-basal hypothalamus and the mesencephalic tegmentum. Analyses of extracts of lizard brain regions by radioimmunoassay and gel filtration chromatography indicate that β-endorphin-sized and α-MSH-sized peptides are the major POMC-related end products. Evidence is presented for region-specific processing of β-endorphin in the lizard brain.     

Dopamine inhibits the release of immunoreactive β-endorphin from rat hypothalamus in vitro

Mediobasal hypothalamus tissue (MBH) from adult male rats was incubated in Krebs-Ringer bicarbonate medium (KRB). KRB was changed at 15 min intervals and the concentration of immunoreactive β-endorphin (β-ENDi) in the medium was measured by radioimmunoassay. Incubation of MBH tissue in normal KRB resulted in a constant release rate of β-ENDi of approximately 1% of the tissue content per h. KRB containing 45 mM K⁺ causes a two fold increase in the release rate of β-ENDi which was Ca²⁺ dependent. Dopamine (0.01–1.0 μM) inhibits both the spontaneous and the K⁺-stimulated release of β-ENDi in a dose related manner. The dopamine receptor blocking agent haloperidol prevents this inhibitory effect of dopamine. The selective D-1 receptor agonist SKF 38393 does not affect the release rate of β-ENDi; whereas the selective D-2 receptor agonist LY 141865 inhibits both the spontaneous and K⁺-stimulated release of β-ENDi. The effects of LY 141865 can be blocked by (−)-sulpiride, a selective D-2 receptor antagonist. Norepinephrine only weakly inhibits the K⁺-stimulated release of β-ENDi, and effect that can be blocked by haloperidol but not by the α-adrenoceptor blocker phentolamine. At concentrations tested (0.01–1.0 μM), isoproterenol, 5-hydroxytryptamine, carbachol and 8-Br-cAMP (1.0 μM) do not affect β-ENDi release. It is concluded that dopamine can inhibit the release of β-ENDi from hypothalamic neurons via a D-2 receptor mechanism.     

Release of β-lipotropin and β-endorphin from rat hypothalami in vitro

Hypothalamic tissue extracts of rats were chromatographed and β-endorphin immunoreactivity (β-End_i) was measured. The two major peaks of β-End_i co-eluted with β-lipotropin (β-LPH) and β-End respectively. Hypophysectomy caused a local decrease of β-LPH and β-End concentrations in the mediobasal hypothalamus. During superfusion of hypothalamic tissue blocks in vitro, membrane depolarization by electric stimulation or 45 mM K⁺ induced a Ca²⁺-dependent release of both β-LPH and β-End.