Dynorphin-A-(1–13) antagonizes morphine analgesia in the brain and potentiates morphine analgesia in the spinal cord

Intrathecal injection of subanalgesic doses of morphine (7.5 nmol) and dynorphin-A-(1–13) (1.25 nmol) in combination resulted in a marked analgesic effect as assessed by tail flick latency in the rat. The analgesic effect of the composite dynorphin/morphine was dose-dependent in serial dilutions so that a composition of 1/8 of the analgesic dose of dynorphin and 1/3 that of morphine produced an analgesic effect equipotent to full dose of either drug applied separately. The analgesic effect induced by dynorphin/morphine mixture was not accompanied by motor dysfunction and was easily reversed by a small dose (0.5 mg/kg) of naloxone. Contrary to the augmentatory effect of dynorphin on morphine analgesia in the spinal cord, intracerevroventricular (ICV) injection of 20 nmol of dynorphin-A-(1–13) exhibited a marked antagonistic effect on the analgesia produced by morphine (120 nmol, ICV). The theoretical considerations and practical implications of the differential interactions between dynorphin-A-(1–13) and morphine in the brain versus spinal cord are discussed.     

Regional interactions of opioid peptides at μ and δ sites in rat brain

Opiate binding sites in five brain regions were labeled with the μ and δ markers, ³H-morphine and ³H-[D-Ala²,D-leu⁵]enkephalin, respectively. The highest densities of both ³H-morphine and ³H-DADLE labeled sites are found in striatum and frontal cortex. Hypothalamus and midbrain contain predominantly ³H-morphine labeled sites. The selectivity of the opioid peptides [D-Ala²,D-leu⁵]enkephalin, β-endorphin and dynorphin(1–13) for the two opiate sites was investigated by comparing the potency of these unlabeled compounds against the μ and δ markers in different brain regions. This determination has the effect of controlling for the breakdown of peptides within each region. While the enkephalin analogue shows a preference for the δ binding site and β-endorphin is more nearly equipotent towards the two binding sites, dynorphin(1–13) shows a high affinity and selective preference for the μ binding site over the δ site. The potency of the opioid peptides in displacing the μ and δ markers varies from region to region according to the relative densities of the two opiate binding site populations.     

Cardiovascular effects of dynorphin A (1–13) in conscious rats and its modulation of morphine bradycardia over time

The short-term cardiovascular effects of dynorphin A (1–13), as well as its effects upon morphine bradycardia were investigated. In unanesthetized, unrestrained rats, intracerebroventricular (ICV) dynorphin A (1–13) injections (10–20 μg) produced a dose-related pressor effect, whereas intravenous (IV) dynorphin A (1–13) (1.0 mg/kg) produced a depressor effect; these responses persisted less than five min. Heart rate was not significantly altered by these doses or routes of administration. Dynorphin A (1–13) also produced behavioral effects in the unanesthetized animals, such as wet dog shakes in response to IV administration and wet dog shakes accompanied by barrel rolling in response to ICV administration. To evaluate the effects of dynorphin A (1–13) pretreatment on the bradycardic response to IV morphine, rats were pretreated with 10 μg dynorphin A (1–13) ICV four, six or eight hours prior to challenge with morphine sulfate (0.1 mg/kg IV). Four hour pretreatment with dynorphin A (1–13) (tested at 14:00 hr) resulted in a potention of morphine bradycardia, with six hours pretreatment (tested at 16:00 hr) no effect was observed, and eight hours following dynorphin A (1–13) pretreatment (tested at 18:00 hr) morphine bradycardia was attenuated. Additionally, the bradycardic response to IV morphine alone became more exaggerated as rats approached their nocturnal activity cycle. These data further establish that dynorphin A (1–13) exerts a potent, long lasting modulatory effect on morphine bradycardia and emphasize the importance of circadian variables in altering the magnitude of cardiovascular responses to opioid agonists.     

Studies on bombesin-induced grooming in rats

The gross behavior induced by centrally administered bombesin in rats was compared to that elicited by ACTH-(1–24) and the somatostatin analog, des AA^{1,2,4,5,12,13}[D-Trp⁸]-somatostatin (ODT8-SS). Bombesin (0.001–1 μg, ICV) caused dose-related excessive scratching which was qualitatively different from that associated with the other two groom-inducing agents. Bombesin-induced grooming was not markedly affected by behaviorally nondepressant doses of haloperidol, morphine, naloxone or neurotensin. Bombesin was active in genetically hypotrichotic (essentially furless) rats; and, again in such animals, even after numbing the area caudal to the shoulders with lidocaine. Tolerance and cross-tolerance studies with bombesin and ODT8-SS indicated that they produce scratching through different mechanisms. Bombesin caused scratching when injected directly into the periaqueductal gray, but not when administered intravenously. Neither hypophysectomy nor adrenalectomy markedly affected bombesin-induced grooming. This behavior appears to be initiated in the central nervous system and is produced independently of the pituitary-adrenal axis.     

Comparative effects on blood pressure and heart rate of dynorphin A(1–13) in anterior hypothalamic area, posterior hypothalamic area, nucleus tractus solitarius, and lateral cerebral ventricle in the rat

The objective of this study was to explore the effects of the endogenous opioid peptide dynorphin A(1–13) on the CNS regulation of blood pressure and heart rate. Wistar rats, anesthetized with pentobarbital and halothane, received dynorphin A(1–13) microinjected into the anterior hypothalamus area (AHA), the posterior hypothalamic area (PHA), the nucleus tractus solitarius (NTS), or the lateral cerebral ventricle (ICV). Dynorphin A(1–13), 20 (12 nmol) or 30 μg ICV, produced significant (p < 0.05) reductions in blood pressure and heart rate. Naloxone, 50 μg/kg ICV, completely prevented the blood pressure response and significantly (p < 0.05) blunted the heart rate response to the highest dynorphin concentration, 30 μg ICV (18 nmol). Dynorphin A(1–13), 5 μg, in the NTS significantly (p < 0.05) decreased systolic and diastolic blood pressure and heart rate with the response being evident 10 min and persisting for 30 min after injection. In contrast, the same dose of dynorphin A(1–13) in the AHA produced an immediate, marked, and significant (p < 0.05) decrease in systolic and diastolic blood pressure and heart rate that attained its maximum 1–3 min and returned rapidly towards baseline levels. Dynorphin A(1–13), 5 or 10 μg in the posterior hypothalamic area, was not associated with any change in blood pressure or heart rate. Injection of the diluent at any site was not associated with any changes in blood pressure or heart rate. The maximum change in blood pressure with dynorphin was greater in the AHA than NTS, and the maximum change in heart rate was greater in the NTS than AHA. These data indicate a potential role for dynorphin as a modulator of the CNS regulation of blood pressure and cardiac rate, and this is mediated in part through different areas in the brain that maybe localized to the anterior hypothalamic area and nucleus tractus solitarius but not the posterior hypothalamic area.     

Endogenous opioid peptide effects on the guinea-pig biliary tract

The effects of the endogenous opioid peptides, dynorphin (1-13), Met-enkephalin and beta-endorphin, on contraction induced by transmural stimulation of terminal bile duct preparations (terminal cavity and ampulla) and gallbladder were investigated in vitro. These peptides inhibited ampulla contraction, dose dependently. The potency order, indicated by ID50, was the same as in the guinea-pig ileum, but the absolute ID50 values in the ampulla were lower than in the ileum. In the terminal cavity, the dynorphin (1-13) ID50 was still less than in the ampulla, and beta-endorphin and Met-enkephalin did not reduce contraction by as much as 50%. In the gallbladder, the effects of these opioid peptides on contraction induced by transmural stimulation were not significant. The results suggest differences in the receptor populations of the ampulla and terminal cavity, and lack of opiate receptors (at least micro and k receptors) in the gallbladder.     

Butorphanol tartrate induces feeding in rats

Peripheral administration of butorphanol tartrate markedly enhanced feeding from 0800 to 1400 hours when compared with vehicle controls. Butorphanol tartrate feeding was not antagonized by doses of naloxone as high as 10 mg/kg. These data support the concept that the kappa or sigma opiate receptors are involved in feeding behavior.It is well recognized that the endogenous opiates play a role in the central regulation of appetite (1, 2, 3, 4). Numerous studies have shown that The endogenous opioid peptides and morphine can initiate feeding under various conditions (5–12) whereas the opiate antagonist, naloxine can reduce food consumption (13–20). Recently, the endogenous opiod peptide, dynorphin, has been reported to enhance food intake (12–25).Much evidence has been accumulated indicating that a number of opiate receptors are present in the brain, each one having a high affinity for a specific endogenous opioid peptide (26, 27). Both the cyclazocine related compounds (28) and the feeding enhancer, dynorphin (29–32), have been reported to be specific kappa receptor agonists. In the present study, we report on the effect of the morphinan congener, butorphanol tartrate (33), on ingestive behaviour.     

Involvement of dynorphin and the kappa opioid receptor in feeding

Dynorphin-(1–17) produces a highly specific increase in food ingestion. Similar enhancement of food ingestion is found with dynorphin fragments (1–10), (1–11), (1–13) and (3–13) but not with (1–8) and (1–9). Dynorphin B (rimorphin) also enhances food intake. The highly specific kappa agonist U-50,488 also enhances food intake as do a number of other kappa-opiate receptor agonists. These studies provided further support for the role of a highly specific dynorphin-kappa opioid receptor in the modulation of feeding.     

Oxytocin in the periaqueductal gray participates in pain modulation in the rat by influencing endogenous opiate peptides

Periaqueductal gray (PAG) plays a very important role in pain modulation through endogenous opiate peptides including leucine-enkephalin (L-Ek), methionine-enkephalin (M-Ek), β-endorphin (β-Ep) and dynorphin A_1-13 (DynA_1-13). Our pervious study has demonstrated that intra-PAG injection of oxytocin (OXT) increases the pain threshold, and local administration of OXT receptor antagonist decreases the pain threshold, in which the antinociceptive role of OXT can be reversed by pre-PAG administration of OXT receptor antagonist. The experiment was designed to investigate the effect of OXT on endogenous opiate peptides in the rat PAG during the pain process. The results showed that (1) the concentrations of OXT, L-Ek, M-Ek and β-Ep, not DynA_1-13 in the PAG perfusion liquid were increased after the pain stimulation; (2) the concentrations of L-Ek, M-Ek and β-Ep, not DynA_1-13 in the PAG perfusion liquid were decreased by the OXT receptor antagonist; (3) the increased pain threshold induced by the OXT was attenuated by naloxone, an opiate receptor antagonist; and (4) the concentrations of L-Ek, M-Ek and β-Ep, not DynA_1-13 in the PAG perfusion liquid were increased by exogenous OXT administration. The data suggested that OXT in the PAG could influence the L-Ek, M-Ek and β-Ep rather than DynA_1-13 to participate in pain modulation, i.e. OXT in the PAG participate in pain modulation by influencing the L-Ek, M-Ek and β-Ep rather than DynA_1-13.     

Dynorphin immunocytochemistry in the rat central nervous system

The distribution of dynorphin in the central nervous system was investigated in rats pretreated with relatively high doses (300–400 μg) of colchicine administered intracerebroventricularly. To circumvent the problems of antibody cross-reactivity, antisera were generated against different portions as well as the full dynorphin molecule (i.e., residues 1–13, 7–17, or 1–17). For comparison, antisera to [Leu]enkephalin (residues 1–5) were also utilized. Dynorphin was found to be widely distributed throughout the neuraxis. Immunoreactive neuronal perikarya exist in hypothalamic magnocellular nuclei, periaqueductal gray, scattered reticular formation sites, and other brain stem nuclei, as well as in spinal cord. Additionally, dynorphin-positive fibers or terminals occur in the cerebral cortex, olfactory bulb, nucleus accumbens, caudate-putamen, globus pallidus, hypothalamus, substantia nigra, periaqueductal gray, many brain stem sties, and the spinal cord. In many areas studied, dynorphin and enkephalin appeared to form parallel but probably separate anatomical systems. The results suggest that dynorphin occurs in neuronal systems that are immunocytochemically distinct from those containing other opioid peptides.     

The F1-ATPase beta-subunit is the putative enterostatin receptor

It has been suggested that the F₁-ATPase β-subunit is the enterostatin receptor. We investigated the binding activity of the purified protein with a labeled antagonist, β-casomorphin_1–7, in the absence and presence of cold enterostatin. ¹²⁵I-β-casomorphin_1–7 weakly binds to the rat F₁-ATPase β-subunit. Binding was promoted by low concentrations of cold enterostatin but displaced by higher concentrations. To study the relationship between binding activity and feeding behavior, we examined the ability of a number of enterostatin analogs to affect β-casomorphin_1–7 binding to the F₁-ATPase β-subunit. Peptides that suppressed food intake promoted β-casomorphin_1–7 binding whereas peptides that stimulated food intake or did not affect the food intake displaced β-casomorphin_1–7 binding. Surface plasmon resonance measurements show that the β-subunit of F₁-ATPase binds immobilized enterostatin with a dissociation constant of 150 nM, where no binding could be detected for the assembled F₁-ATPase complex. Western blot analysis showed the F₁-ATPase β-subunit was present on plasma and mitochondrial membranes of rat liver and amygdala. The data provides evidence that the F₁-ATPase β-subunit is the enterostatin receptor and suggests that enterostatin and β-casomorphin_1–7 bind to distinct sites on the protein.     

Dynorphin(1–13) impairs memory formation for aversive and appetitive learning in chicks

The opioid peptide dynorphin(1–13) impairs memory formation in chicks (5). We examined whether this occurs for both aversively and appetitively motivated learning. Four-day-old chicks were injected with dynorphin(1–13) into the intermediate medial hyperstriatum ventrale and trained on either a peck avoidance (PA) or an appetitive discrimination (AD) task; 2-day-old chicks were trained on PA. In 2-day-old chicks, dynorphin was amnestic for PA at 0.01, 0.03, or 0.1 mM. In 4-day-old chicks, dynorphin impaired memory formation for PA at 0.1 mM, and for AD training at 0.03 mM. Thus, similar doses of dynorphin impair memory formation for both appetitive and aversive conditioning.     

Angiotensin II and angiotensin-(1-7) inhibit the inner cortex Na+ -ATPase activity through AT2 receptor

In the present paper, the modulation of the basolateral membrane (BLM) Na⁺-ATPase activity of inner cortex from pig kidney by angiotensin II (Ang II) and angiotensin-(1–7) (Ang-(1–7)) was evaluated. Ang II and Ang-(1–7) inhibit the Na⁺-ATPase activity in a dose-dependent manner (from 10⁻¹¹ to 10⁻⁵ M), with maximal effect obtained at 10⁻⁷ M for both peptides. Pharmacological evidences demonstrate that the inhibitory effects of Ang II and Ang-(1–7) are mediated by AT₂ receptor: The effect of both polypeptides is completely reversed by 10⁻⁸ M PD 123319, a selective AT₂ receptor antagonist, but is not affected by either (10⁻¹²–10⁻⁵ M) losartan or (10⁻¹⁰–10⁻⁷ M) A779, selective antagonists for AT₁ and AT_(1–7) receptors, respectively. The following results suggest that a PTX-insensitive, cholera toxin (CTX)-sensitive G protein/adenosine 3′,5′-cyclic monophosphate (cAMP)/PKA pathway is involved in this process: (1) the inhibitory effect of both peptides is completely reversed by 10⁻⁹ M guanosine 5′-O-(2-thiodiphosphate) (GDPβS; an inhibitor of the G protein activity), and mimicked by 10⁻¹⁰ M guanosine 5′-O-(3-thiotriphosphate) (GTPγS; an activator of the G protein activity); (2) the effects of both peptides are mimicked by CTX but are not affected by PTX; (3) Western blot analysis reveals the presence of the G_s protein in the isolated basolateral membrane fraction; (4) (10⁻¹⁰–10⁻⁶ M) cAMP has a similar and non-additive effect to Ang II and Ang-(1–7); (5) PKA inhibitory peptide abolishes the effects of Ang II and Ang-(1–7); and (6) both angiotensins stimulate PKA activity.     

Acetyl-RYYRIK-NH(2) is a highly efficacious OP(4) receptor agonist in the cardiovascular system of anesthetized rats

Nociceptin, the endogenous ligand of the OP₄ or ORL₁ (opioid receptor-like₁) receptor, decreases blood pressure and heart rate in anesthetized rats. Since the OP₄ receptor antagonist [Phe¹Ψ(CH₂-NH)Gly²]-nociceptin(1–13)NH₂ possesses an agonistic effect in this model, we examined whether other purported OP₄ receptor antagonists, acetyl-RYYRIK-NH₂ and naloxone benzoylhydrazone, antagonize the depressant effects of nociceptin. Acetyl-RYYRIK-NH₂, like nociceptin and [Phe¹Ψ(CH₂-NH)Gly²]-nociceptin(1–13)NH₂ and unlike naloxone benzoylhydrazone, decreased diastolic blood pressure and heart rate (rank order of potencies: nociceptin ≈ acetyl-RYYRIK-NH₂ [Phe¹Ψ(CH₂-NH)Gly²]-nociceptin(1–13)NH₂). The depressant effects were insensitive to the OP_1–3 receptor antagonist naloxone but diminished by naloxone benzoylhydrazone. In conclusion, the hypotensive and bradycardic effects of nociceptin in the anesthetized rat are mediated via OP₄ receptors, at which acetyl-RYYRIK-NH₂ is a highly potent and efficacious agonist.     

Decreased dynorphin levels and increased kappa opioid receptor binding in male rats with isolation-induced hypertension

The role of hippocampal dynorphin A (1–8) (Dyn A (1–8)) and kappa opioid receptors was investigated in the isolation-induced hypertensive rat (IHR). Male Sprague Dawley rats were either isolated (1 per cage) or grouped (3 per cage) for 7 days. Isolated rats exhibited increased blood pressure (systolic blood pressure 159.7 ± 6.6 mmHg) whereas the grouped rats remained normotensive (systolic blood pressure 137 ± 6.3 mmHg). Using radioligand binding techniques we observed a significant increase in kappa opioid receptor binding in the hippocampus of isolated rats (56% increase) and this further increased when the length of isolation was increased to 2 weeks (72% increase). Radioimmunoassay showed that isolation decreased the hippocampal content of Dyn A (1–8) from 12.7 ± 0.4 to 11.6 ± 0.2 pg Dyn A (1–8) per 10 mg tissue (rats weighing approximately 100 g) and from 13.3 ± 0.8 to 9.7 ± 1 pg Dyn A (1–8) per 10 mg tissue (approximately 200 g rats). These data suggest that functional alterations in the hippocampal dynorphin system may be involved in the maintenance of isolation induced hypertension.     

Solubilization of active GLP-1 (7–36)amide receptors from RINm5F plasma membranes

Glucagon-like peptide-1 (7–36)amide (GLP-1 (7–36)amide) represents a physiologically important incretin in mammals including man. Receptors for GLP-1 (7–36)amide have been described in RINm5F cells. We have solubilized active GLP-1 (7–36)amide receptors from RINm5F cell membranes utilizing the detergents octyl-β-glucoside and CHAPS; Triton X-100 and Lubrol PX were ineffective. Binding of radiolabeled GLP-1(7–36)amide to the solubilized receptor was inhibited conentration-dependently by addition of unlabeled peptide. Scatchard analysis of binding data revealed a single class of binding sites with K_a= 0.26 ± 0.03 nM and B_max= 65.4 ± 21.24 fmol/mg of protein for the membrane-bound receptor and K_a= 22.54 ± 4.42 μM and B_max= 3.9 ± 0.79 pmol/mg of protein for the solubilized receptor. The binding of the radiolabel to the solubilized receptor was dependent both on the concentrations of mono- and divalent cations and the protein/detergent ratio in the incubation buffer. The membrane bound receptor is sensitive to guanine-nucleotides, however neither GTP-γ-S nor GDP-β-S affected binding or labeled peptide to solubilized receptor. These data indicate that the solubilized receptor may have lost association with its G-protein. In conclusion, the here presented protocol allows solubilization of the GLP-1(7–36)amide receptor in a functional state and opens up the possibility for further molecular characterization of the receptor protein.     

Hindlimb paralytic effects of arginine vasopressin and related peptides following spinal subarachnoid injection in the rat

Intrathecal (IT) injection of arginine vasopressin (AVP) in rats caused a transient (<30 min), dose-related paralysis of the hindlimbs, loss of hindlimb and tail nociceptive responsiveness, and increased mean arterial pressure. Motor dysfunction was produced with comparable potency by lysine vasopressin (LVP) and arginine vasotocin (AVT); oxytocin (OXY) was approximately 1000 times less potent. Paralysis induced by these peptides was selectively blocked following IT pretreatment with 0.5 nmoles of the vasopressin V₁ receptor antagonist [1-(β-mercapto-β,β-cyclopentamethylene propioinic acid), 2-(O-methyl)tyrosine] Arg⁸-vasopressin (d(CH₂)₅[Tyr(Me²)]AVP). Pressor and antinociceptive responses to AVP were also blocked by this compound. However, at higher doses (2–5 nmoles, IT), d(CH₂)₅[Tyr(Me²)]AVP produced hindlimb paralysis, antinociception, and pressor responses by itself. In contrast to the fiber degeneration, cell loss, and necrosis found in lumbosacral cords of rats persistently paralyzed by other peptides (dynorphin A, somatostatin, and ICI 174864), neuropathological changes were not evident in spinal cords of rats transiently paralyzed by IT AVP. These results indicate that AVP-related peptides affected diverse spinal cord functions through interactions with a V₁-like receptor. The similar pattern of cardiovascular and antinociceptive responses to other peptides (dynorphin A, somatostatin, and ICI 174864), which also caused hindlimb paralysis, suggests that the former responses may actually reflect the nonselective consequences of a peptide-induced disruption of spinal cord function, rather than specific shared pharmacological effects.     

The effects of neurotensin, naloxone and haloperidol on elements of excessive grooming behavior induced by bombesin

The influence of naloxone, haloperidol and neurotensin was investigated on bombesin-induced excessive grooming in rats. All three drugs reduced the amount of bombesin-induced grooming. Haloperidol induced a general reduction in excessive grooming as induced by bombesin, without changing the composition of grooming behavior, whereas naloxone and neurotensin suppressed bombesin-induced grooming and caused a shift in the distribution of grooming elements. The main suppressive effect of these latter drugs appeared to be on the element scratching. From these data it is suggested that bombesin-induced scratching is mainly displayed by activation of opiate receptor systems, whereas the other elements of bombesin-induced excessive grooming are mainly regulated by dopaminergic systems.     

Kappa opioid receptor endocytosis by dynorphin peptides

Internalization and downregulation are important steps in the modulation of receptor function. Recent work with the beta2 adrenergic and opioid receptors have implicated these processes in receptor-mediated activation of mitogen-activated protein kinase (MAPK). We have used CHO cells expressing epitope-tagged rat kappa opioid receptors (rKORs) and prodynorphin-derived peptides to characterize the agonist-mediated endocytosis of rKORs and activation of MAPK. Kappa receptor-selective peptides induced receptor internalization and downregulation whereas nonpeptide agonists did not. An examination of the ability of dynorphin A-17-related peptides (lacking C-terminal amino acids) to promote KOR internalization, inhibition of adenylyl cyclase, and MAPK phosphorylation revealed that the N-terminal seven residues play an important role in eliciting these responses. Both dynorphin peptides and nonpeptide agonists induced rapid and robust phosphorylation of MAPKs. Taken together, these results point to a difference in the ability of dynorphin peptides and nonpeptide ligands to promote rKOR endocytosis and support the view that rKOR internalization is not required for MAPK activation.