Opioids inhibit visceral afferent activation of catecholamine neurons in the solitary tract nucleus

Brainstem A2/C2 catecholamine (CA) neurons within the solitary tract nucleus (NTS) influence many homeostatic functions, including food intake, stress, respiratory and cardiovascular reflexes. They also play a role in both opioid reward and withdrawal. Injections of opioids into the NTS modulate many autonomic functions influenced by catecholamine neurons including food intake and cardiac function. We recently showed that NTS-CA neurons are directly activated by incoming visceral afferent inputs. Here we determined whether opioid agonists modulate afferent activation of NTS-CA neurons using transgenic mice with EGFP expressed under the control of the tyrosine hydroxylase promoter (TH-EGFP) to identify catecholamine neurons. The opioid agonist Met-enkephalin (Met-Enk) significantly attenuated solitary tract-evoked excitatory postsynaptic currents (ST-EPSCs) in NTS TH-EGFP neurons by 80%, an effect reversed by wash or the mu opioid receptor-specific antagonist D-Phe-Cys-Tyr-D-Trp-Orn-Thr-Pen-Thr-NH(2) (CTOP). Met-Enk had a significantly greater effect to inhibit afferent inputs onto TH-EGFP-positive neurons than EGFP-negative neurons, which were only inhibited by 50%. The mu agonist, DAMGO, also inhibited the ST-EPSC in TH-EGFP neurons in a dose-dependent manner. In contrast, neither the delta agonist DPDPE, nor the kappa agonist, U69,593, consistently inhibited the ST-EPSC amplitude. Met-Enk and DAMGO increased the paired pulse ratio, decreased the frequency, but not amplitude, of mini-EPSCs and had no effect on holding current, input resistance or current-voltage relationships in TH-EGFP neurons, suggesting a presynaptic mechanism of action on afferent terminals. Met-Enk significantly reduced both the basal firing rate of NTS TH-EGFP neurons and the ability of afferent stimulation to evoke an action potential. These results suggest that opioids inhibit NTS-CA neurons by reducing an excitatory afferent drive onto these neurons through presynaptic inhibition of glutamate release and elucidate one potential mechanism by which opioids could control autonomic functions and modulate reward and opioid withdrawal symptoms at the level of the NTS.

Tyrosine phosphorylation of the kappa -opioid receptor regulates agonist efficacy

To explore the role of highly conserved tyrosine residues in the putative cytoplasmic domains of the seven-transmembrane G protein-coupled opioid receptors, we expressed the rat kappa-opioid receptor (KOR) in Xenopus oocytes and then activated the intrinsic insulin receptor tyrosine kinase. KOR activation by the agonist produced a strong increase in potassium current through coexpressed G protein-gated inwardly rectifying potassium channels (K(IR)3). Brief pretreatment with insulin caused a 60% potentiation of the KOR-activated response. The insulin-induced increase in kappa-opioid response was blocked by the tyrosine kinase inhibitor genistein. In contrast, insulin had no effect on the basal activity of K(IR)3, suggesting that KOR is the target of the tyrosine kinase cascade. Mutation of tyrosine residues to phenylalanines in either the first or second intracellular loop of KOR to produce KOR(Y87F) and KOR(Y157F) had no effect on either the potency or maximal effect of. However, neither KOR(Y87F)- nor KOR(Y157F)-mediated responses were potentiated by insulin treatment. Insulin pretreatment shifted the dose-response curve for activation of KOR by increasing the maximal response without changing the EC(50) value for. These results suggest that insulin increases the efficacy of KOR activation by phosphorylating two tyrosine residues in the first and second intracellular loops of the receptor. Thus, tyrosine phosphorylation may provide an important mechanism for modulation of G protein-coupled receptor signaling.

Agonist-dependent desensitization of the kappa opioid receptor by G protein receptor kinase and beta-arrestin

We used the Xenopus oocyte expression system to examine the regulation of rat kappa opioid receptor (rKOR) function by G protein receptor kinases (GRKs). kappa agonists increased the conductance of G protein-activated inwardly rectifying potassium channels in oocytes co-expressing KOR with Kir3.1 and Kir3.4. In the absence of added GRK and beta-arrestin 2, desensitization of the kappa agonist-induced potassium current was modest. Co-expression of either GRK3 or GRK5 along with beta-arrestin 2 significantly increased the rate of desensitization, whereas addition of either beta-arrestin 2, GRK3, or GRK5 alone had no effect on the KOR desensitization rate. The desensitization was homologous as co-expressed delta opioid receptor-evoked responses were not affected by KOR desensitization. The rate of GRK3/beta-arrestin 2-dependent desensitization was reduced by truncation of the C-terminal 26 amino acids, KOR(Q355Delta). In contrast, substitution of Ala for Ser within the third intracellular loop [KOR(S255A,S260A, S262A)] did not reduce the desensitization rate. Within the C-terminal region, KOR(S369A) substitution significantly attenuated desensitization, whereas the KOR(T363A) and KOR(S356A,T357A) point mutations did not. These results suggest that co-expression of GRK3 or GRK5 and beta-arrestin 2 produced homologous, agonist-induced desensitization of the kappa opioid receptor by a mechanism requiring the phosphorylation of the serine 369 of rKOR.

[125I-Tyr1]biphalin binding to opioid receptors of rat brain and NG108-15 cell membranes

Mono iodinated analogues of biphalin [(Tyr-D-Ala-Gly-Phe-NH-)2], both nonradioactive [I-Tyr1]biphalin and radioactive [125I-Tyr1]biphalin have been synthesized. The radioligand binding profiles of these compounds for two types of tissues, rat brain membranes, and NG108-15 cell membranes were identical to the parent biphalin. This is additional evidence for the hypothesis that biphalin behaves like a monomeric ligand and that only one intact tyrosine is necessary for high biological activity. The second tyrosine could be used for successful radioiodination which may greatly simplify biochemical and pharmacological studies of biphalin. The results of receptor binding studies show that the binding of both biphalin and [I-Tyr1]biphalin to the delta and mu opioid receptors are not independent. [125I-Tyr1]Biphalin binds to delta receptors as shown in NG108-15 cell membranes. Nevertheless, [125I]biphalin binding to delta receptors in rat brain membranes was hardly evident and mu receptor binding predominated or at least was much more readily detectable in this preparation.

Agonist-induced phosphorylation of the kappa-opioid receptor

Antipeptide antibodies against the kappa-opioid receptor were used to test whether acute or chronic exposure to kappa agonists altered the phosphorylation state of the kappa-opioid receptor. Immunoprecipitation of the kappa receptor from guinea pig hippocampal slices preincubated in [32P]orthophosphoric acid revealed a basal phosphorylation of the kappa-opioid receptor. The amount of 32P incorporation into the receptor was increased following a 75-min treatment with the kappa agonist U50,488H. This effect was blocked by the selective kappa receptor antagonist norbinaltorphimine. The time course of this change in the phosphorylation state of the receptor correlated with a desensitization of the electrophysiological response to kappa agonists measured in the dentate gyrus of hippocampal slices. The phosphorylation state of the kappa-opioid receptor was also elevated in brain slices from guinea pigs made tolerant to U50,488H by 5 days of continuous exposure and then maintained in kappa agonist to avoid acute opiate withdrawal. The results of this study show that the kappa-opioid receptor was phosphorylated in an agonist-dependent manner in brain slices taken from untreated and U50,488H-tolerant animals.

Immunocytochemical localization of delta opioid receptors in mouse brain

An affinity-purified anti-peptide antibody generated against the carboxy-terminal region of the delta opioid receptor was used to localize delta opioid receptors in mouse brain. delta Opioid receptor immunoreactivity was found in axons and nerve terminals in regions of the olfactory bulb, hippocampal formation, cerebral and cerebellar cortex, midbrain and hindbrain. The immunocytochemical distribution correlated well, though not completely with autoradiographic distribution of delta opioid receptors in mouse brain using either [3H][2-D-penicillamine, 5-D-penicillamine]-enkephalin (DPDPE) or [3H]naltrindole. Confocal microscopy of double-labeled tissue provided direct evidence that delta opioid receptors are principally expressed on GABAergic terminals in the hippocampus. These anatomical findings complement extensive physiological studies to provide a more detailed description of endogenous opioid circuitry.

Oocytes from Xenopus laevis contain an intrinsic sigma 2-like binding site

In preparation for expression studies for rat brain sigma-binding sites, Xenopus oocytes were tested for the presence of [3H]di-o-tolylguanidine (DTG)-binding sites. Native oocytes were found to contain two intrinsic [3H]DTG-binding sites, a high-affinity site (Kd = 32 +/- 6 nM, Bmax of 45.7 +/- 19 pmol/mg protein) and a low-affinity binding site (Kd = 1.3 +/- 0.7 microM, Bmax of 3.2 +/- 0.7 nmol/mg protein). In a series of radioligand-binding-displacement studies, the high-affinity binding sites were found to have a binding profile which has a similar Kd to that of the mammalian sigma 2-binding site (32 vs. 38 nM). Comparison of the IC50 values for inhibition of [3H]DTG binding in rat liver and oocytes for DTG, haloperidol (HAL), (-)-pentazocine, (+)-3-(3-hydroxyphenyl)-N-propylpiperidine hydrochloride ((+)-3-PPP), (+)-pentazocine and Zn2+, showed similarity in rank (r2 = 0.913) but a 7-fold lower potency in oocytes. These results suggest that the high-affinity [3H]DTG-binding site in oocytes represents a sigma 2-like binding site.

Differential phosphorylation of two size forms of the N-type calcium channel alpha 1 subunit which have different COOH termini

Two size forms of the class B N-type calcium channel alpha 1 subunit were recently identified with CNB1, an antipeptide antibody directed against an intracellular loop of this channel (Westenbroek, R.E., Hell, J.W., Warner, C., Dubel, S.J., Snutch, T.P., and Catterall, W.A. (1992) Neuron 9, 1099-1115). To investigate the biochemical differences between these two size forms, the antibodies CNB3 and CNB4 were raised against peptides with sequences corresponding to the COOH-terminal end of the full-length form. Immunoblot experiments demonstrated that both antibodies specifically recognize the longer form of 250 kDa, indicating that the COOH-terminal regions of the two size forms of the class B N-type channel alpha 1 subunit are different. Phosphorylation experiments with immunopurified calcium channels and different second messenger-activated protein kinases revealed that both the 220- and 250-kDa forms of the class B N-type calcium channel alpha 1 subunit are substrates for cAMP-dependent protein kinase, cGMP-dependent protein kinase, and protein kinase C. These three kinases incorporated approximately 1 mol of phosphate/mol of binding sites for omega-conotoxin (omega-CgTx) GVIA, a ligand specific for the N-type calcium channel, and may regulate the activity of both forms in vivo. In contrast, calcium- and calmodulin-dependent protein kinase II (CaM kinase II) phosphorylated only the long form of the class B N-type calcium channel alpha 1 subunit, with a stoichiometry of 0.5 mol of phosphate/mol of total omega-CgTx GVIA binding sites. Specific phosphorylation of the long form of the class B alpha 1 subunit by CaM kinase II may differentially regulate the function of N-type calcium channels containing different size forms of their alpha 1 subunits in vivo.

Antinociceptive profile of biphalin, a dimeric enkephalin analog

The dimeric enkephalin biphalin (Try-D-Ala-Gly-Phe-NH)2 was evaluated in mice using antinociceptive, gastrointestinal and physical dependence paradigms and compared with that of morphine (reference mu agonist) and etorphine (ultrapotent opioid agonist). Intracerebroventricular biphalin was 6.7- and 257-fold more potent than etorphine or morphine in eliciting antinociception. When administered i.t., biphalin produced only a 60% maximal antinociceptive effect in the tail-flick test even when given at doses up to 3 orders of magnitude higher than those effective i.c.v.; morphine was equipotent in this assay when given i.c.v. or i.t. Both morphine and biphalin were equipotent after i.p. administration. In spite of its antinociceptive effectiveness after i.p. administration. In spite of its antinociceptive effectiveness after i.p. administration, only a small fraction of [125I]biphalin was shown to penetrate to the brain (0.051 +/- 0.011%, at 20 min). After i.c.v. administration, biphalin antinociception was antagonized by receptor selective doses of beta-funaltrexamine (mu antagonist), naloxonazine (mu 1 antagonist), ICI 174,864 (delta antagonist) and [D-Ala2,Cys4]deltorphin (delta 2 antagonist), but not by [D-Ala2,Leu5,Cys6]enkephalin (delta 1 antagonist) or nor-binaltorphimine (kappa antagonist), whereas etorphine antinociception was significantly antagonized only by beta-funaltrexamine and naloxonazine. Intracerebroventricular biphalin inhibited gastrointestinal propulsion at doses 8-fold higher than those producing i.c.v. antinociception; i.c.v. morphine showed a similar antinociceptive and gastrointestinal propulsion A50. Intraperitoneal biphalin, but not i.p. morphine, showed little, if any, physical dependence, but both biphalin and morphine produced significant physical dependence when equiantinociceptive doses were infused i.c.v.(ABSTRACT TRUNCATED AT 250 WORDS)