Comparison of the antinociceptive action of mu and delta opioid receptor ligands in the periaqueductal gray matter, medial and paramedial ventral medulla in the rat as studied by the microinjection technique

In rats stereotaxically implanted with microinjection cannula in either the periaqueductal gray matter (PAG) or the medial/paramedial medullary reticular formation (MRF), microinjection of morphine, sufentanil, D-Ala2-D-Leu5-enkephalin (DADL) or D-Ser2-Thr6-leucine enkephalin (DSTLE) produced dose-dependent elevations in the response latency on tail-flick and hot plate tests. These effects were reversed by naloxone administered by microinjection into the same intracerebral site. Both mu (morphine and sufentanil) and delta (DADL and DSTLE) opioid receptor ligands produced a maximal elevation in the supraspinally mediated hot plate response when administered into either the PAG or the MRF. Similarly, mu and delta receptor ligands produced maximum elevations in the spinally mediated tail-flick response when microinjected into the PAG. In contrast, delta, but not mu, receptor agonists produced a total blockade of the tail-flick response following administration into the MRF. Microinjection of mu (morphine) or delta (DADL) agonists into the PAG or the MRF also resulted in a naloxone-reversible inhibition of the visceral chemical evoked writhing response. These observations suggest that mu and delta opioid receptor linked systems within the MRF but not the PAG produce their antinociceptive effects by discriminable mechanisms with a differential action on spinopetal vs supraspinal modulatory systems.     

Studies on the opiate receptor-mediated inhibition of K-stimulated cholecystokinin and substance P release from cat hypothalamus in vitro

The addition of 50 mM K+ to the perfusate of cat hypothalamic slices results in a 3.4- and 5.5-fold increase in the levels of cholecystokinin (CCK) and substance P (sP) like immunoreactivity, respectively. The addition of morphine (10(-11)-10(-8) M; a mu receptor agonist) and D-Ala2-D-Leu5-enkephalin (DADL: 10(-12)-10(-10) M; a delta receptor agonist) resulted in a dose-dependent suppression of the K+-evoked release. SKF10047 (a sigma receptor ligand) and U50488H (a kappa receptor ligand) had no effect in doses up to 10(-6) M. Naloxone added with the lowest dose of agonist producing a maximal inhibition produced a dose-dependent reversal of the anti-release effects of morphine and DADL. The IC50 of naloxone for the antagonism by DADL and morphine of the release of CCK were similar, whereas the naloxone IC50 was lower for morphine than DADL in the reversal of the effects of the agonist in sP release. Within the constraints of receptor selectivity of the several ligands, these data suggest that at least two populations of opioid receptors (mu and delta) may be discriminated which govern the release of hypothalamic sP.     

Opioid antagonists in the periaqueductal gray inhibit morphine and β-endorphin analgesia elicited from the amygdala of rats

In addition to brainstem sites of action, analgesia can be elicited following amygdala microinjections of morphine and μ-selective opioid agonists. The present study examined whether opioid analgesia elicited by either morphine or β-endorphin in the amygdala could be altered by either the general opioid antagonist, naltrexone, the μ-selective antagonist, β-funaltrexamine (BFNA) or theδ₂ antagonist, naltrindole isothiocyanate (Ntii) in the periaqueductal gray (PAG). Both morphine (2.5–5 μg) and β-endorphin (2.5–5 jig) microinjected into either the baso-lateral or central nuclei of the amygdala significantly increased tail-flick latencies and jump thresholds in rats. The increases were far more pronounced on the jump test than on the tail-flick test. Placements dorsal and medial to the amygdala were ineffective. Naltrexone (1–5 μg) in the PAG significantly reduced both morphine (tail-flick: 70–75%; jump: 60–81%) and β-endorphin (tail-flick: 100%; jump: 93%) analgesia elicited from the amygdala, indicating that an opioid synapse in the PAG was integral for the full expression of analgesia elicited from the amygdala by both agonists. Both BFNA (68%) and Ntii (100%) in the PAG significantly reduced morphine, but not β-endorphin analgesia in the amygdala on the tail-flick test. Ntii in the PAG was more effective in reducing morphine (60%) and β-endorphin (79%) analgesia in the amygdala on the jump test than BFNA (15–24%). Opioid agonist-induced analgesia in the amygdala was unaffected by opioid antagonists administered into control misplacements in the lateral mesencephalon, and the small hyperalgesia elicited by opioid antagonists in the PAG could not account for the reductions in opioid agonist effects in the amygdala. These data indicate that PAGδ₂ and to a lesser degree, μ opioid receptors are necessary for the full expression of morphine and β-endorphin analgesia elicited from the amygdala.     

PAG mu opioid receptor activation underlies sex differences in morphine antinociception

Given the findings that (1) systemic opioid antinociception varies by estrous stage in females and (2) the magnitude of sex differences in opioid antinociception is negatively correlated with opioid agonist efficacy, we hypothesized that sex differences in the function of the descending pain modulatory system are likely influenced by estrous stage in females and by the number of available opioid receptors therein. The present study tested these hypotheses by (1) comparing antinociception produced by morphine microinjection to the ventral periaqueductal gray (vPAG) in females at different stages of the estrous cycle and (2) examining systemic morphine antinociception in males versus females under conditions of reduced vPAG mu opioid receptor availability. When estrous stage of females was not controlled for (Experiment 1), there was no significant sex difference in tail withdrawal antinociception following morphine microinjection (0.3-10microg), although morphine was more potent in males than females in producing immobility. Experiment 2 showed that intra-vPAG morphine produced less antinociception and immobility in estrus than in diestrus females; that is, only estrus females' response to morphine was lower than that of males. Experiment 3 showed that microinjection of the irreversible mu opioid antagonist beta-funaltrexamine (beta-FNA) into the vPAG shifted the systemic morphine dose-effect curve farther to the right in females than in males. That is, a reduction in available vPAG mu opioid receptors had a greater impact on opioid antinociception in females than in males, suggesting that females have fewer vPAG mu opioid receptors than males. Overall, these data suggest that ovarian hormones and PAG mu opioid receptor density contribute to sex differences in antinociception produced by morphine.     

Analysis of opioid receptor subtype antagonist effects upon mu opioid agonist-induced feeding elicited from the ventral tegmental area of rats

The present study examined opioid receptor(s) mediation of feeding elicited by mu opioid agonists in the ventral tegmental area using general or selective opioid antagonist pretreatment. Naltrexone as well as equimolar doses of selective mu and kappa, but not delta opioid antagonists in the ventral tegmental area significantly reduced mu agonist-induced feeding, indicating a pivotal role for these receptor subtypes in the full expression of this response.     

Blockade effect of mu and kappa opioid antagonists on the anti-nociception induced by intra-periaqueductal grey injection of oxytocin in rats

Intra-periaqueductal grey (PAG) injection of 1 nmol of oxytocin induced significant increases in hindpaw withdrawal latency (HWL) to thermal and mechanical stimulation in rats. The anti-nociceptive effect of oxytocin was attenuated significantly by subsequent intra-PAG injection of the mu opioid antagonist beta-funaltrexamine (beta-FNA) and the kappa opioid antagonist nor-binaltorphimine (nor-BNI), but not by the delta antagonist naltrindole. The results demonstrated that mu and kappa opioid receptors, not delta receptors, were involved in the oxytocin-induced anti-nociception in PAG of rats.     

Pharmacological profiles of selective non-peptidic delta opioid receptor ligands

Several non-peptidic opioids have been synthesized recently as part of a program to develop selective delta receptor agonists. In this study, the affinities of a set of compounds for cloned delta and mu opioid receptors expressed in HEK 293 cell lines were determined by competition analysis of [3H]bremazocine binding to membrane preparations. All compounds studied exhibited high affinity and selectivity, with apparent dissociation constants in the range of 0.6-1.7 nM for the delta opioid receptor and 240-1165 nM for the mu opioid receptor. We next sought to determine which domain of the delta receptor was critical for mediating the highly selective binding by analysis of ligand affinities for mu/delta receptor chimeras. Receptor binding profiles suggested that a critical site of receptor/ligand interaction was located between transmembrane domain 5 (TM5) and TM7 of the delta receptor. Substitution of tryptophan 284, located at the extracellular surface of TM6, with lysine, which is found at the equivalent position in the mu opioid receptor, led to a spectrum of effects on affinities, depending on the ligand tested. Affinities of SB 219825 and SB 222941 were particularly sensitive to the substitution, displaying a 50-fold and 70-fold decrease in affinity, respectively. Activities of the delta receptor-selective agonists were tested in two functional assays. Brief exposure of HEK 293 cells expressing delta opioid receptors with selective ligands induced phosphorylation of MAP kinase, although the non-peptidic ligands were less efficacious than the enkephalin derivative DADL (Tyr-D-Ala-Gly-Phe-D-Leu). Similarly, chronic exposure of HEK 293 cells expressing delta opioid receptors with selective, non-peptidic ligands, with the exception of SB 206848, caused receptor down-regulation, however, the SB compounds were less efficacious than DADL.     

Effects of focal electrical stimulation and morphine microinjection in the periaqueductal gray of the rat mesencephalon on neuronal activity in the medullary reticular formation

Neurons in the medullary reticular formation (MRF; nucleus reticularis gigantocellularis and nucleus reticularis paragigantocellularis) were evaluated for their involvement in the analgesia produced by focal electrical stimulation and microinjection of morphine into the periaqueductal gray region (PAG) of the rat mesencephalon. Analgesia-producing PAG stimulation altered the spontaneous activity of 80% of the neurons in the MRF (both excitation and inhibition were observed) and inhibited the noxious-evoked excitation of 75% of MRF neurons. Microinjection of morphine into the PAG also increased (50%) and decreased (17%) the spontaneous activity of MRF units and inhibited the noxious-evoked excitation of 47% of MRF neurons. These effects were specific for analgesia produced by the PAG manipulations and were partially reversed by naloxone. The role of the MRF in PAG-induced analgesias and the degree of overlap in neuronal systems influenced by intracranial morphine and electrical stimulation is discussed.     

Stimulation-produced spinal inhibition from the midbrain in the rat is mediated by an excitatory amino acid neurotransmitter in the medial medulla

It has been previously established that a bulbar relay plays an important role in descending inhibition of spinal dorsal horn nociceptive neurons and nociceptive reflexes produced by stimulation in the midbrain periaqueductal gray (PAG). In the present study, selected receptor antagonists were microinjected into the medial medullary nucleus raphe magnus (NRM) to determine whether descending inhibition of the tail flick (TF) reflex in the rat produced by focal electrical stimulation in the midbrain PAG was mediated by serotonin, opioid, or glutamate receptors on bulbospinal neurons in the NRM. It was determined in initial experiments that the serotonin receptor antagonist methysergide, the opioid receptor antagonist naloxone, the local anesthetic lidocaine, and the glutamate receptor antagonists gamma-D-glutamylglycine (DGG) and DL-2-amino-5-phosphonovalerate (APV) microinjected into the medulla all significantly increased the threshold of focal electrical stimulation in the medulla required to inhibit the TF reflex. The antinociceptive efficacy of agonists at opioid, serotonin, and glutamate receptors was also tested in other experiments. The microinjection of morphine (2.5-10 micrograms) into the NRM increased significantly TF latencies in a dose-dependent manner in rats in the awake or lightly anesthetized state; morphine was more potent in awake rats. Inhibition of the TF reflex produced by the microinjection of morphine was reversed by a subsequent microinjection of naloxone into the same site in the medulla. The microinjection of serotonin (5 and 10 micrograms), however, did not affect the latency of the TF reflex in either awake or lightly anesthetized rats. Glutamate (100 microM, 0.5 microliter) microinjected into the rostral ventral medulla produced an inhibition of the TF reflex of short duration that could be blocked or attenuated significantly by the glutamate receptor antagonists DGG or APV microinjected into the same site. In subsequent experiments, a nonspecific functional block was introduced adjacent to the NRM bilaterally in the medullary reticular formations (MRFs) by the microinjection of the local anesthetic lidocaine; receptor antagonists were then microinjected into the NRM and their effect on the threshold of focal electrical stimulation in the PAG to inhibit the TF reflex determined. No increase was seen in stimulation thresholds in the PAG following the microinjection of either methysergide or naloxone into the NRM. Following the microinjection of lidocaine, DGG or APV into the NRM, the stimulation threshold in the PAG for inhibition of the TF reflex was increased significantly.(ABSTRACT TRUNCATED AT 400 WORDS)     

Differential effects of opioid agonists on G protein expression in CHO cells expressing cloned human opioid receptors

Recent evidence indicates that agonist ligands of G protein coupled receptors (GPCR) can activate different signaling systems. Such “agonist-directed” signaling also occurs with opioid receptors. Previous work from our laboratory showed that chronic morphine, but not DAMGO, up-regulates the expression of Gα12 and that both morphine and DAMGO decreased Gαi3 expression in CHO cells expressing the cloned human mu opioid receptor. In this study, we tested the hypothesis that chronic opioid regulation of G protein expression is agonist-directed. Following a 20 h treatment of CHO cells expressing the cloned human mu (hMOR-CHO), delta (hDOR-CHO) or kappa (hKOR-CHO) opioid receptors with various opioid agonists, we determined the expression level of Gα12 and Gαi3 by Western blots. Among five mu agonists (morphine, etorphine, DADLE, DAMGO, herkinorin) tested with hMOR-CHO cells, only chronic morphine and etorphine up-regulated Gα12 expression. All five mu agonists decreased Gαi3 expression. Among six delta agonists (SNC80, DPDPE, deltorphin-1, morphine, DADLE, etorphine) tested with hDOR-CHO cells, all six agonists down-regulated Gαi3 expression or moderately up-regulated Gα12 expression. Among five kappa agonists, ((−)-ethylketocyclazocine, salvinorin A, U69,593, etorphine, (−)-U50,488) tested with hKOR-CHO cells, only chronic (−)-U50,488 and (−)-EKC up-regulated Gα12 expression. All kappa agonists decreased Gαi3 expression. These data demonstrate that chronic opioid agonist regulation of G protein expression depends not only on the agonist tested, but also on the type of opioid receptor expressed in a common cellular host, providing additional evidence for agonist-directed signaling.     

Antinociception produced by mu opioid receptor activation in the amygdala is partly dependent on activation of mu opioid and neurotensin receptors in the ventral periaqueductal gray

Exposure to stressful or fear-inducing environmental stimuli activates descending antinociceptive systems resulting in a decreased pain response to peripheral noxious stimuli. Stimulating mu opioid receptors in the basolateral nucleus of the amygdala (BLA) in anesthetized rats produces antinociception that is similar to environmentally induced antinociception in awake rats. Recent evidence suggests that both forms of antinociception are mediated via projections from the amygdala to the ventral periaqueductal gray (PAG). In the present study, we examined the types of neurochemicals released in the ventral PAG that may be important in the expression of antinociception produced by amygdala stimulation in anesthetized rats. Microinjection of a mu opioid receptor agonist into the BLA resulted in a time dependent increase in tail flick latency that was attenuated by preadministration of a mu opioid receptor or a neurotensin receptor antagonist into the ventral PAG. Microinjection of a delta(2) opioid receptor antagonist or an NMDA receptor antagonist into the ventral PAG was ineffective. These findings suggest that amygdala stimulation produces antinociception that is mediated in part by opioid and neurotensin release within the ventral PAG.     

Differential epileptogenic potentials of selectiveμ andδ opiate receptor agonists

By using electroencephalographic (EEG) and electromyographic recordings in anaesthetized and free-moving rats, two opioid peptides, known as selective agonists for mu and delta opiate receptors, respectively, were examined for their epileptogenic properties. The delta receptor peptide (DSTLE, 4.6-18.6 nmol, intraventricularly, ivt), a putative delta opiate agonist, produced a dose-related increase of myoclonic contractions (MC) with epileptic discharges in anaesthetized rats and severe wet dog shakes, with occasionally falling down, in free-moving animals. Morphiceptin, a specific mu opiate agonist, used in equimolar doses and under the same experimental conditions, had a significantly less pronounced effect on the number of MC and epileptiform EEG phenomena. Similarly, DSTLE (18.6 nmol) injected in the CA2 area of the hippocampus, a region with a nearly equal distribution of mu and delta opiate receptors, induced epileptic discharges in anaesthetized and free-moving rats, while an equimolar dose of morphiceptin had no significant effect. It is suggested that the epileptiform activity of opioid peptides is mainly due to an activation of delta opiate receptors in the central nervous system.     

Medullary μ and δ opioid receptors modulate mesencephalic morphine analgesia in rats

Supraspinal opioid analgesia is mediated in part by connections between the midbrain periaqueductal gray (PAG) and rostral ventral medulla (RVM) which includes the nuclei raphe magnus and reticularis gigantocellularis. Serotonergic 5HT₂ and 5HT₃ receptor subtypes appear to participate in this pathway since general and selective serotonergic antagonists microinjected into the RVM significantly reduced morphine analgesia elicited from the PAG. Since both an enkephalinergic pathway between the PAG and RVM and intrinsic enkephalinergic cells in the RVM exist, the present study evaluated the abilities of general (naltrexone), μ-selective (β-funaltrexamine: B-FNA) andδ₂-selective (naltrindole) opioid receptor subtype antagonists microinjected into the RVM to alter morphine (2.5 μg) analgesia elicited from the PAG as measured by the tail-flick and jump tests. Mesencephalic morphine analgesia was significantly reduced after pretreatment in the RVM with naltrexone (1–10 μg), B-FNA (0.5–5 μg) or naltrindole (0.5–5 μg). Naltrexone in the RVM failed to alter basal nociceptive thresholds and none of the opioid antagonists were effective in reducing mesencephalic morphine analgesia when they were microinjected into placements lateral or dorsal to the RVM. These data indicate that μ andδ₂ opioid receptors in the RVM modulate the transmission of opioid pain-inhibitory signals from the PAG.     

Naloxone can act as an analgesic agent without measurable chronic side effects in mice with a mutant mu-opioid receptor expressed in different sites of pain pathway

Midbrain periaqueductal gray (PAG) and spinal cord dorsal horn are major action sites of opioid analgesics in the pain pathway. Our previous study has shown that opioid antagonists activate MORS196A-CSTA (a mutant of mu-opioid receptor) as full agonists in vitro cell models and naloxone showed antinociceptive effects after the expression of MORS196A-CSTA in the spinal cord in mice. The purpose of this study is to investigate the site-directed antinociceptive effects of naloxone in mice injected with dsAAV-MORS196A-CSTA-EGFP at spinal cord or at periaqueductal gray. MORS196A-CSTA-EGFP was administered to ICR mice using dsAAV as vector. We measured MORS196A-CSTA-EGFP expression by detecting the EGFP visualization with a fluorescence microscope. The antinociceptive effect of naloxone was determined by tail-flick test and hot plate test. Drug rewarding effect was evaluated by the conditioned place preference test. Naloxone (10 mg/kg, s.c.) elicited both supraspinal and spinal antinociceptive responses in mice injected with the virus at PAG while only spinal antinociceptive response was observed in mice injected with virus at dorsal horn region. Chronic naloxone treatment did not induce physical dependence or rewarding effect in mice injected with MORS196A-CSTA-EGFP in spinal cord or PAG. These data suggest that the observed naloxone-induced antinociceptive response is the consequence of the local expression of MORS196A-CSTA at specific sites of pain pathway. Injection of such MOR mutant and the systemic administration of naloxone can be a new strategy in the management of chronic pain without the various side effects associated with the use of morphine.     

The effects of bilateral intranigral microinjection of selective opioid agonists on behavioral responses to noxious thermal stimuli.

This study examined the effects of bilateral intranigral microinjection of selective opioid agonists on the tail-flick and hot-plate antinociception tests. The principal findings are: (1) the mu-selective agonist D-Ala2, N-Me-Phe4, Gly5-ol-enkephalin (DAGO) had antinociceptive effects on both tests which were reversible by beta-funaltrexamine (beta-FNA: a mu-selective antagonist) and naloxone (a non-selective opioid antagonist); (2) the antinociceptive potency of DAGO injected into the nigra is comparable to its potency in the periaqueductal gray; (3) intranigral D-Pen2, D-Pen5-enkephalin (a delta-selective agonist), U-50, 488H and dynorphin A-(1-13) (kappa-selective agonists) had no antinociceptive effects; (4) antinociceptive effects were produced by the mixed delta/mu agonists D-Thr2-leucine enkephalin-Thr (DTLET) and D-Ser2-leucine enkephalin-Thr (DSLET); (5) the effect of DTLET on the hot-plate but not the tail-flick test was reversed by Cys2, Tyr3, Orn5, Pen7-amide (CTOP; a mu-selective antagonist), beta-FNA, and naloxone, but not by the delta-selective antagonist naltrindole. Based on the potent antinociceptive effects of DAGO, the complete lack of such effects by the highly selective delta and kappa agonists, and the antagonism of DTLET by CTOP and beta-FNA, it is concluded that the antinociceptive effects of intranigral opioid agonists are mediated by mu receptors.     

The delta agonists DPDPE and deltorphin II recruit predominantly mu receptors to produce thermal analgesia: a parallel study of mu, delta and combinatorial opioid receptor knockout mice

Delta-selective agonists have been developed to produce potent analgesic compounds with limited side-effects. DPDPE and deltorphin II are considered prototypes, but their delta-selectivity in vivo and the true ability of delta receptors to produce analgesia remain to be demonstrated. Here we have performed a parallel analysis of mu, delta and combinatorial opioid receptor knockout mice, in which we found no obvious alteration of G-protein coupling for remaining opioid receptors. We compared behavioural responses in two models of acute thermal pain following DPDPE and deltorphin II administration by intracerebroventricular route. In the tail-immersion test, both compounds were fully analgesic in delta knockout mice and totally inactive in mu knockout mice. In the hotplate test, the two compounds again produced full analgesia in delta knockout mice. In mu knockout mice, there was significant, although much lower, analgesia. Furthermore, DPDPE analgesia in the delta knockout mice was fully reversed by the mu selective antagonist CTOP in both tests. Together, this suggests that mu rather than delta receptors are recruited by the two agonists for the tail withdrawal and the hotplate responses. Finally, deltorphin II slightly prolonged jump latencies in double mu/kappa knockout mice (delta receptors only) and this response was abolished in the triple knockout mice, demonstrating that the activation of delta receptors alone can produce weak but significant mu-independent thermal antinociception.     

Affective defense behavior elicited from the feline midbrain periqueductal gray is regulated by mu and delta opioid receptors.

The present study sought to identify specific opioid receptor subtypes involved in the modulation of affective defense behavior (AD) at the level of the midbrain periaqueductal gray (PAG). Cannula electrodes were utilized for eliciting AD from the PAG as well as for microinjecting mu, delta and kappa agonists and antagonists into these sites. Following microinjections of morphiceptin, D-Pen2,D-Pen5 enkephalin (DPDPE), or U-488H into sites from which AD was elicited, threshold values were determined. The results indicated that morphiceptin and DPDPE significantly suppressed AD in a dose- and time-dependent manner. Pretreatment with mu and delta opioid antagonists, B-FNA and ICI 174,864, completely blocked the suppressive effects of morphiceptin and DPDPE, respectively. Microinjections of morphiceptin and DPDPE failed to alter response thresholds for circling behavior also elicited from electrical stimulation of dorsal PAG. Administration of the selective kappa agonist, U-488H, or vehicle alone, did not alter the threshold for AD. The results of this study indicate that opioid peptides interact with mu and delta receptors within the midbrain PAG to powerfully suppress AD.     

Acute thermal hyperalgesia elicited by low-dose morphine in normal mice is blocked by ultra-low-dose naltrexone, unmasking potent opioid analgesia

Our previous electrophysiologic studies on nociceptive types of dorsal root ganglion (DRG) neurons in culture demonstrated that extremely low fM-nM concentrations of morphine and many other bimodally-acting mu, delta and kappa opioid agonists can elicit direct excitatory opioid receptor-mediated effects, whereas higher (microM) opioid concentrations evoked inhibitory effects. Cotreatment with pM naloxone or naltrexone (NTX) plus fM-nM morphine blocked the excitatory effects and unmasked potent inhibitory effects of these low opioid concentrations. In the present study, hot-water-immersion tail-flick antinociception assays at 52 degrees C on mice showed that extremely low doses of morphine (ca. 0.1 microg/kg) can, in fact, elicit acute hyperalgesic effects, manifested by rapid onset of decreases in tail-flick latency for periods >3 h after drug administration. Cotreatment with ultra-low-dose NTX (ca. 1-100 pg/kg) blocks this opioid-induced hyperalgesia and unmasks potent opioid analgesia. The consonance of our in vitro and in vivo evidence indicates that doses of morphine far below those currently required for clinical treatment of pain may become effective when opioid hyperalgesic effects are blocked by coadministration of appropriately low doses of opioid antagonists. This low-dose-morphine cotreatment procedure should markedly attenuate morphine tolerance, dependence and other aversive side-effects.     

Effect of morphine administered in the periaqueductal gray and at the recording locus on nociresponsive neurons in the medullary reticular formation

Neurons in the medullary reticular formation (MRF) contained within the nuclei reticularis gigantocellularis and reticularis paragigantocellularis were evaluated for their responses to morphine administered in the periaqueductal gray (PAG) and iontophoressed at the recording site. Morphine had a predominant excitatory effect on neurons in the MRF whether microinjected in the PAG or iontophoresed at the recording locus. Although morphine generally excited neurons in the MRF when administered at either site, examination ofindividual neurons for their responses to both modes of administration of morphine indicated that the effect produced by morphine administered in the PAG was rarely mimicked by morphine iontophoresed at the recording locus. Moreover, morphine administered in the PAG markedly attenuated the noxious evoked excitatory response of MRF neurons, an effect not reliably produced by morphine iontophoresed in the MRF. These results suggest that morphine's effect on neuronal activity in the MRF when microinjected in the PAG is not mediated by an enkephalinergic interneuron. The implications of these results on the role of the MRF in opiate-induced antinociception are discussed.     

Opioid supraspinal analgesic synergy between the amygdala and periaqueductal gray in rats

Analgesia can be elicited following microinjections of morphine, μ-selective agonists and β-endorphin into the amygdala. These analgesic responses are mediated by opioid synapses in the periaqueductal gray (PAG) since general (naltrexone), μ (β-funaltrexamine) and δ₂ (naltrindole isothiocyanate) opioid antagonists administered into the PAG significantly reduce both morphine and β-endorphin analgesia elicited from the amygdala. Supraspinal multiplicative opiate analgesic interactions have been observed between the PAG and rostroventromedial medulla (RVM), the PAG and locus coeruleus (LC), and the RVM and LC. The present study further examined the relationship between the amygdala and PAG in analgesic responsiveness by determining whether multiplicative analgesic interactions occur following paired administration of subthreshold doses of morphine into both structures, β-endorphin into both structures, morphine into one structure and β-endorphin into the other structure, or morphine and β-endorphin into one structure. Co-administration of subthreshold doses of morphine into both the amygdala and PAG results in a profound synergistic interaction on the jump test, but not the tail-flick test. Co-administration of subthreshold doses of β-endorphin into both structures also results in a profound test-specific synergistic interaction. In both cases, the magnitude of the interaction was similar regardless of the site receiving the fixed dose of the opioid, and the site receiving the variable dose of the opioid. Co-administration of β-endorphin (1 μg) into the amygdala and morphine (1 μg) into the PAG produced a potent interaction, but co-administration of morphine (1 μg) into the amygdala and β-endorphin (1 μg) into the PAG failed to produce interactive effects. Finally, co-administration of morphine (1 μg) and β-endorphin (1 μg) into either the amygdala alone or the PAG alone failed to produce an interaction, indicating the importance of regional opioid activation. These data are discussed in terms of the test-specificity of nociceptive processing in the amygdala, in terms of the multiple modulatory mechanisms mediating β-endorphin analgesia in the PAG, and in terms of whether the interactions are either mediated by anatomical connections between the amygdala and PAG or by mechanisms initiated by these two sites converging at another site or sites.