Spinal morphine/clonidine antinociceptive synergism: involvement of G proteins and N-type voltage-dependent calcium channels

When morphine and clonidine are coadministered into the spinal cord (intrathecally) the resulting antinociception is greater than would be expected if the drug responses were additive; thus, a synergistic interaction. The mechanism for this synergistic interaction was investigated using agents which alter calcium channel function and G protein function. Drugs were administered intrathecally to mice and antinociception was measured using the tail flick test. The L-type calcium channel antagonists nifedipine (15 micrograms) and verapamil (15 micrograms) and the N-type antagonist omega-conotoxin GVIA (3 and 30 ng) decreased ED50 values for both morphine and clonidine three-to five-fold. The L-type calcium channel activator Bay K 8644 had a biphasic effect; 1.7 ng increased, although 170 ng decreased, morphine and clonidine ED50 values. None of the calcium channel modifiers affected the morphine/clonidine synergism. In mice pretreated with pertussis toxin (PTX, one, 10-ng dose 21 days previously), the morphine ED50 value increased two-fold, although the clonidine ED50 value was not changed. PTX pretreatment did not alter the morphine/clonidine synergism. Also, in PTX-pretreated mice, nifedipine and 1.7 ng Bay K 8644 did not alter the morphine/clonidine synergism. However, in PTX-pretreated animals omega-conotoxin GVIA (3 ng) changed the morphine/clonidine synergism to an additive interaction. Thus, both N-type calcium channels and PTX-sensitive G proteins are likely involved in spinal morphine/clonidine synergism.     

Positive and negative cis-acting elements are required for hematopoietic expression of zebrafish GATA-1

BACKGROUND: The Na+,K+-adenosine triphosphatase is a ubiquitous enzyme system that maintains the ion gradient across the plasma membrane of a variety of cell types, including cells in the central nervous system. We investigated the antinociceptive effect of intrathecally administered ouabain and examined its potential interaction with spinal morphine and lidocaine. METHODS: Using rats chronically implanted with lumbar intrathecal catheters, the ability of intrathecally administered ouabain, morphine, and lidocaine and of mixtures of ouabain-morphine and ouabain-lidocaine to alter tail-flick latency was examined. To characterize any interactions, isobolographic analysis was performed. The effects of pretreatment with intrathecally administered atropine or naloxone also were tested. RESULTS: Intrathecally administered ouabain (0.1-5.0 microg), morphine (0.2-10.0 microg), and lidocaine (25-300 microg) given alone produced significant dose- and time-dependent antinociception, but systemic administration of ouabain did not produce such an effect. The median effective dose (ED50) values for intrathecally administered ouabain, morphine, and lidocaine were 2.3, 5.0, and 227.0 microg, respectively. Isobolographic analysis exhibited a synergistic interaction after the coadministration of ouabain and morphine. With ouabain and lidocaine, there was no such evidence of synergism. Intrathecally administered atropine, but not naloxone, completely blocked the antinociceptive effect of ouabain and attenuated its interaction with spinally administered morphine. CONCLUSIONS: Intrathecally administered ouabain produces antinociception, at least in part, via an enhancement of cholinergic transmission in the spinal nociceptive processing system. The results of the interaction of ouabain with morphine and lidocaine suggest that modulation of Na+-,K+-electrochemical gradients and thus subsequent release of neurotransmitters in the spinal cord are likely to play important roles in the spinal antinociceptive effect of intrathecally administered ouabain.     

Pretreatment with protein kinase C activator phorbol 12,13-dibutyrate attenuates the antinociception induced by mu- but not epsilon-opioid receptor agonist in the mouse

The effects of pretreatment with a protein kinase C activator, phorbol 12,13-dibutyrate, on antinociception induced by i.c.v.-administered mu-opioid receptor agonist (D-Ala2, NMePhe4, Gly(ol)5) enkephalin (DAMGO) or morphine and epsilon-opioid receptor agonist beta-endorphin were studied in male ICR mice. The tail-flick responses were used for antinociceptive tests. I.c.v. pretreatment with phorbol 12,13-dibutyrate (50 pmol) for 30 or 60 but not 10 min attenuated antinociception induced by i.c.v.-administered DAMGO. I.c.v. pretreatment with phorbol 12,13-dibutyrate (10 and 50 pmol) for 60 min caused a dose-dependent attenuation of DAMGO (19.5 pmol)- or morphine (6.0 nmol)-induced antinociception. The dose-response curve for DAMGO-induced antinociception was shifted to the right by 7.3-fold by i.c.v. pretreatment with phorbol 12,13-dibutyrate (50 pmol) for 60 min. However, the i.c.v.-administered beta-endorphin-induced antinociception was not affected by the same pretreatment with phorbol 12,13-dibutyrate. The attenuation of i.c.v.-administered DAMGO- and morphine-induced antinociception by phorbol 12,13-dibutyrate was reversed by concomitant i.c.v. pretreatment with a selective protein kinase C inhibitor calphostin C. These results suggest that activation of protein kinase C by phorbol 12,13-dibutyrate leads to the desensitization of mu-, but not epsilon-opioid receptor-mediated antinociception. These findings also provide additional evidence for differential intracellular modulation on antinociceptive action of mu- and epsilon-opioid receptor agonists.     

Dynorphin A(1-17) mediates midazolam antagonism of morphine antinociception in mice

Studies have shown that midazolam acts in the brain to antagonize the antinociception produced by morphine. The purpose of this study was to determine if spinal dynorphin A(1-17) (Dyn) was involved in the antagonistic effects of midazolam. A number of drugs when administered intracerebroventricularly (ICV) to mice release Dyn in the spinal cord to antagonize morphine-induced antinociception. In the present study using the mouse tail-flick test, midazolam administered ICV produced a dose related reduction of the antinociception induced by morphine given intrathecally (IT). The antagonistic action of midazolam against morphine-induced antinociception involved the release of Dyn in the spinal cord, as evidenced by the following results. 1) Administration of naloxone, nor-binaltorphimine and dynorphin antiserum, IT, eliminated the antagonistic effect of midazolam, given ICV, against morphine. Treatment with these opioid antagonists and dynorphin antiserum is known to inhibit the action of spinally released Dyn. 2) Production of desensitization to the effect of spinal Dyn by pretreating with morphine, 10 mg/kg subcutaneously 3 h before the tail-flick test, abolished the antagonistic action of midazolam given ICV. A 3-h pretreatment with midazolam, ICV, also produced desensitization to the antianalgesic action of Dyn given IT. 3) Elimination of the Dyn component of action of midazolam by administration of naloxone, nor-binaltorphimine and dynorphin antiserum, IT, uncovered slight antinociceptive activity of midazolam, given ICV. Coadministration of flumazenil (a benzodiazepine antagonist), bicuculline (a GABA antagonist) and picrotoxin (a chloride ion channel blocker) inhibited the midazolam effect.(ABSTRACT TRUNCATED AT 250 WORDS)     

Isolation, characterization and synthesis of a novel paradaxin isoform

Recently our laboratory found that tolerance to morphine-induced antinociception could be completely reversed with intracerebroventricular (i.c.v.) administration of a protein kinase A inhibitor, whereas intrathecal (i.t.) administration of the inhibitor produced hyperalgesia in morphine-tolerant mice. In the experiments described here, we sought to characterize further the role of phosphorylation events in supraspinal versus spinal opioid-mediated pain pathways and how such events might be involved in the development of antinociceptive tolerance. Two phosphatase inhibitors were administered centrally to determine whether they affected morphine-induced antinociception in naive or chronically morphine-treated mice. By the i.c.v. route, okadaic acid enhanced morphine-induced antinociception in tolerant mice and produced toxicity by the i.t. route. The calcineurin inhibitor ascomycin had no effect on antinociception following acute or chronic morphine treatment. These results suggest that increased activity of protein phosphatase types 1 and/or 2A in the brain may contribute to the development of morphine tolerance.     

Clonidine, but not morphine, delays the development of thermal hyperesthesia induced by sciatic nerve constriction injury in the rat

BACKGROUND: It has been shown that the spinal facilitation induced by the injury discharge evoked by a nerve constriction injury is crucial in the development of thermal hyperesthesia. Both opioids and alpha 2 agonists have been reported to prevent the development of spinal facilitation evoked by the small afferent input to the spinal cord. Moreover, it has been reported that the thermal hyperesthesia induced by a nerve constriction injury is sympathetically maintained and that spinally administered alpha 2 agonists can modulate the sympathetic outflow from the spinal cord. The current study investigated the effect of spinally administered morphine and clonidine, an alpha 2 agonist, on the development of thermal hyperesthesia induced by nerve constriction injury in the rat. METHODS: A model of thermal hyperesthesia induced by a constriction injury created by making four loose ligatures around the rat sciatic nerve was used to examine the development of thermal hyperesthesia. Morphine, clonidine, and idazoxan were administered intrathecally or intraperitoneally 20 min before (pretreatment study) or 20 min after (posttreatment study) the nerve injury. RESULTS: Pretreatment, but not posttreatment, with intrathecal clonidine significantly delayed the development of thermal hyperesthesia in a dose-dependent manner, and this delay in onset produced by clonidine was 3 days after the nerve injury. This effect of clonidine's was completely antagonized by the coadministration of idazoxan with clonidine. Intrathecal morphine had no effect on the development of thermal hyperesthesia in this study. CONCLUSIONS: Spinal alpha 2 receptors, but not opioid receptors, may play an important role in the development of thermal hyperesthesia induced by a nerve constriction injury. This suggested that the activation of spinal alpha 2 receptor may reduce the sympathetic outflow and this reduction of sympathetic outflow may be the key mechanism that delays the development of thermal hyperesthesia.     

The effects of digitalis-like compounds on rat lenses

We examined the effects of several opioids that vary in intrinsic efficacy at the mu-opioid receptor alone and in combination with morphine in a rat warm water tail withdrawal procedure using 50 degrees C and 52 degrees C water (i.e., low- and high-stimulus intensities). Morphine, levorphanol, dezocine, and buprenorphine produced dose-dependent increases in antinociception using both stimulus intensities. Butorphanol produced maximal levels of antinociception at the low, but not at the high, stimulus intensity, whereas nalbuphine failed to produce antinociception at either stimulus intensity. For cases in which butorphanol and nalbuphine failed to produce antinociception alone, these opioids dose-dependently antagonized the effects of morphine. When levorphanol, dezocine, and buprenorphine were combined with morphine, there was a dose-dependent enhancement of morphine's effects. Similar effects were obtained at the low-stimulus intensity when butorphanol was administered with morphine. In most cases, the effects of these combinations could be predicted by summating the effects of the drugs when administered alone. These results indicate that the level of antinociception produced by an opioid is dependent on the intrinsic efficacy of the drug and the stimulus intensity. Furthermore, the level of antinociception produced by the opioid, not necessarily the opioids' intrinsic efficacy, determines the type of interaction among opioids. Implications: Compared with high-efficacy opioids, lower efficacy opioids produce lower levels of pain relief, especially in situations of moderate to severe pain. When opioids are given in combination, the effects can only be predicted on the basis of the antinociception obtained when the drugs are administered alone.     

Majonoside-R2, a major constituent of Vietnamese ginseng, attenuates opioid-induced antinociception

The effects of majonoside-R2 on antinociceptive responses caused by the mu-opioid receptor agonist morphine and the selective kappa-opioid receptor agonist U-50, 488H were examined by the tail-pinch test in mice. Intraperitoneal (IP) or intracerebroventricular (ICV) injection of majonoside-R2 (3.1-6.2 mg/kg, IP or 5-10 micrograms/mouse, ICV) and diazepam (0.1-0.5 mg/kg, IP or 0.5-1.0 microgram/mouse, ICV), as well as an opioid receptor antagonist naloxone (2 mg/kg, IP or 5 micrograms/mouse, ICV), dose-dependently attenuated the antinociception caused by subcutaneously administered morphine and U-50,488H. Moreover, when co-administered ICV or intrathecally (IT) with morphine (4 micrograms/mouse) or U-50,488H (60 micrograms/mouse), majonoside-R2 (5-20 micrograms/mouse) also exhibited antagonism against the antinociceptive action of these opioid receptor agonists in the tail-pinch test. The inhibitory effects of majonoside-R2 (10 micrograms/mouse, ICV) and diazepam (1 microgram/mouse, ICV) were reversed by flumazenil (2.5 micrograms/mouse, ICV), a selective benzodiazepine receptor antagonist, and picrotoxin (0.25 microgram/mouse, ICV), a GABA-gated chloride channel blocker. These results suggest that majonoside-R2 attenuates the opioid-induced antinociception by acting at the spinal and supraspinal levels, and that the GABAA receptor complex at the supraspinal level is involved in the effect of ICV administered majonoside-R2.     

Gabapentin enhances the antinociceptive effects of spinal morphine in the rat tail-flick test

The antinociceptive effects of the combination of spinal morphine and gabapentin were evaluated in the tail-flick test in rats. The intrathecal coadministration of a subantinociceptive dose of morphine at 0.2 microgram and gabapentin at 300 micrograms produced significant antinociception. Pretreatment with spinal gabapentin at 300 micrograms shifted the dose-response curve of spinal morphine to the left with a decrease in morphine ED50 value from 1.06 micrograms to 0.34 microgram. The antinociceptive effects produced by the combination of a subantinociceptive dose of morphine and gabapentin were reversed by spinal naloxone at 30 micrograms but were not reversed by spinal bicuculline at 0.3 microgram. Furthermore, the concurrent administration of spinal naloxone at 30 micrograms with the combination of morphine and gabapentin blocked antinociception, while the concurrent administration of spinal bicuculline at 0.3 microgram failed to prevent antinociception. These results indicate that the combination of spinal gabapentin and morphine produces an enhancement of antinociception that appears to involve the spinal mu opioid receptors. Furthermore, repeated administration of gabapentin for 3 days did not affect the enhancing effect of gabapentin on the antinociceptive effect of morphine, indicating that tolerance did not develop to gabapentin's ability to enhance morphine antinociception.     

Influence of incubation time, inoculum size, and glucose concentrations on spectrophotometric endpoint determinations for amphotericin B, fluconazole, and itraconazole

Antinociception can be produced at the spinal level by activation of opioidergic, noradrenergic, and serotonergic systems. We tested the antinociceptive effects of combined activation of all three systems. Antinociception was assessed in the rat tail-flick test, and drugs were administered via an intrathecal catheter. Morphine, the norepinephrine uptake inhibitor desipramine, and serotonin produced antinociception of their own. The combination of subthreshold doses of morphine 1 microg and of desipramine 3 microg produced pronounced antinociception that was antagonized by yohimbine. The combination of subthreshold morphine with serotonin 50 microg or desipramine with serotonin caused only small antinociceptive effects. When morphine combined with desipramine was decreased to a subthreshold dose, we observed pronounced antinociception when a subthreshold dose of serotonin was added. A complex interaction can be supposed by results obtained with antagonists. The activation of all three neurotransmitter systems with small doses of agonists may represent an effective principle for pain control at the spinal level. IMPLICATIONS: Pain sensations are modulated at the spinal level by opioids, noradrenergic drugs, and serotonin. Using a rat model, we showed that the concurrent use of drugs from each of these classes produces good pain control at doses that should avoid the side effects associated with larger doses of each individual drug.     

Continuous assay of proteases using a microtiter plate fluorescence reader

The present study was designed to determine if spinal calcium channels, calmodulin, and calcium/calmodulin-dependent protein kinase II were involved in the production of antinociception induced by cold water swimming stress (CWSS). The effects of intrathecal (i.t.) injection of nimodipine, omega-conotoxin GVIA, calmidazolium, or (S)-5-isoquinolinesulfonic acid, 4-[2-[(5-isoquinolinyl-sulfonyl)methylamino]-3-oxo-3-(4-phenyl-1-piperaz inyl)-propyl]phenyl ester (KN-62) on CWSS-induced antinociception were studied in ICR mice. The antinociception was assessed by the tail-flick test. CWSS produced inhibition of the tail-flick response. Various doses of nimodipine (10-40 ng), omega-conotoxin GVIA (5-40 ng), calmidazolium (10-40 ng), or KN-62 (5-40 ng) injected i.t. alone did not show any antinociceptive effect in the tail-flick test. I.t. pretreatment with omega-conotoxin GVIA, calmidazolium, or KN-62 dose dependently attenuated the CWSS-induced inhibition of the tail-flick response. However, i.t. pretreatment with nimodipine did not affect the inhibition of the tail-flick response induced by CWSS. Our results suggest that spinal N-type calcium channel, calmodulin and calcium/calmodulin-dependent protein kinase II may be involved in the production of antinociception induced by CWSS. On the other hand, CWSS-induced antinociception appears not to be mediated via the spinal L-type calcium channel.     

The central nucleus of the amygdala contributes to the production of morphine antinociception in the formalin test

The rat paw formalin test is a model of prolonged pain due to mild tissue injury. There is some evidence suggesting that morphine does not produce antinociception in the formalin test via the brain-stem and spinal cord circuitry normally associated with antinociception. Furthermore, morphine appears to require an intact forebrain in order to function as an analgesic for formalin pain. In the 2 experiments reported here, we investigated the possibility that the central nucleus of the amygdala (Ce) contributes to the production of morphine antinociception (MA) in the formalin test. Nociception in this test occurs in 2 phases, with the 1st phase occurring 0-5 min after formalin injection and the 2nd phase beginning 10-15 min after injection and continuing for approximately 1 h. In Exp. 1, bilateral neurotoxic lesions of the Ce, but not lesions of the adjacent basolateral nucleus (BL), reliably attenuated MA (7 mg/kg morphine sulfate) during the 2nd phase of the formalin test without affecting baseline nociception. These results were obtained regardless of whether the rating scale method or flinch-frequency method of nociceptive scoring was used. During the 1st phase, Ce lesions reliably attenuated MA as measured by the flinch-frequency method, but not as measured by the rating scale method. In Exp. 2, Ce lesions also reliably attenuated the antinociception produced by 12 mg/kg morphine sulfate during the 2nd phase of the formalin test. Antinociception appeared to be almost completely re-instated, however, if the dose of morphine was raised to 20 mg/kg. The results indicate that neurons originating from the Ce contribute to the production of MA during the 2nd phase, and possibly the 1st phase, of the formalin test, especially at relatively lower doses of morphine. This suggests that in addition to coordinating conditioned antinociceptive responses, the amygdala may be a component of endogenous antinociceptive circuitry. These and other issues are discussed with reference to the spino-ponto-amygdaloid nociceptive pathway, and the proposed role of the amygdala in the mediation of defense reactions.     

Caveolin interaction with protein kinase C. Isoenzyme-dependent regulation of kinase activity by the caveolin scaffolding domain peptide

Caveolar localization of protein kinase C and the regulation of caveolar function by protein kinase C are well known. This study was undertaken to examine whether caveolin subtypes interact with various protein kinase C isoenzymes using the caveolin scaffolding domain peptide. When protein kinase C-alpha, -epsilon, and -zeta were overexpressed in COS cells followed by subcellular fractionation using the sucrose gradient method, all the isoenzymes (alpha, epsilon, and zeta) were detected in the same fraction as caveolin. The scaffolding domain peptide of caveolin-1 and -3, but not -2, inhibited the kinase activity and autophosphorylation of protein kinase C-alpha and -zeta, but not of protein kinase C-epsilon, overexpressed in insect cells. Truncation mutation studies of the caveolin-1 and -3 peptides demonstrated that a minimum of 16 or 14 amino acid residues of the peptide were required for the inhibition or direct binding of protein kinase C. Thus, the caveolin peptide physically interacted with protein kinase C and regulated its function. Further, this regulation occurred in a protein kinase C isoenzyme-dependent manner. Our results may provide a new mechanism regarding the regulation of protein kinase C isoenzyme activity and the molecular interaction of protein kinase C with its putative binding proteins.     

Acute tolerance to spinally administered morphine compares mechanistically with chronically induced morphine tolerance

The mechanistic similarity between acutely and chronically induced morphine tolerance has been previously proposed but remains largely unexplored. Our experiments examined the modulation of acutely induced tolerance to spinally administered morphine by agonists that affect the N-methyl-D-aspartate receptor and nitric oxide synthase systems. Antinociception was detected via the hot water (52.5 degrees C) tail flick test in mice. Intrathecal pretreatment with morphine (40 nmol) produced a 9.6-fold rightward shift in the morphine dose-response curve. This shift confirmed the induction of acute spinal morphine tolerance. Intrathecal copretreatment with the receptor antagonists (competitive and noncompetitive, respectively) dizolcipine (MK801, 3 nmol) or LY235959 (4 pmol) and morphine [40 nmol, intrathecally (i.t.)] attenuated acute tolerance to morphine measured 8 hr later. A 60-min pretreatment of 7-nitroindazole (6 nmol, i.t.), a selective neuronal NOS inhibitor, followed by administration of morphine (40 nmol, i.t.) blocked the induction of morphine tolerance. Intrathecal copretreatment with morphine (40 nmol, i.t.) and agmatine (4 nmol, i.t.), an imidazoline, receptor agonist and putative nitric oxide synthase inhibitor, almost completely abolished acute spinal morphine tolerance. The results of these experiments agree with previous reports using models of chronically induced morphine tolerance. This evidence supports the proposal that the mechanisms responsible for acute morphine tolerance parallel those underlying chronic morphine tolerance. This study attests to the powerful predictive value of acute induction as a model for morphine tolerance.     

Norepinephrine stimulates mitogen-activated protein kinase activity in GT1-1 gonadotropin-releasing hormone neuronal cell lines

The GT1-1 GnRH neuronal cell lines exhibit highly differentiated properties of GnRH neurons. We have used GT1-1 cells to study the roles of norepinephrine (NE), membrane depolarization, calcium influx, and phorbol esters in the regulation of mitogen-activated protein (MAP) kinase. NE, which is known to stimulate the release of GnRH, induced MAP kinase activity, the tyrosine phosphorylation of MAP kinase, and MAP kinase kinase activity. Forskolin led to activation of MAP kinase comparable with that induced by NE, and a selective inhibitor of cAMP-dependent protein kinase, H8, attenuated the NE-induced activation of MAP kinase. On the other hand, elimination of extracellular calcium by EGTA completely blocked NE-induced tyrosine phosphorylation of MAP kinase, and a selective inhibitor of calcium/calmodulin-dependent protein kinase, KN-62, attenuated the NE-induced activation of MAP kinase. Furthermore, depolarization of GT1-1 cells with 75 mM KCl, 10 microM BayK 8644, or 1 microM calcium ionophore (A23187) induced rapid tyrosine phosphorylation of MAP kinase. The omission of calcium from the extracellular medium completely abolished these effects of tyrosine phosphorylation of MAP kinase. Phorbol 12-myristate 13-acetate (PMA) also induced MAP kinase activity, but pretreatment of the cultured cells with PMA to down-regulate protein kinase C did not abolish the activation of MAP kinase by NE. In addition, although phosphorylation of Raf-1 kinase was stimulated by PMA, this phosphorylation was not induced by either NE or A23187. These results demonstrate that NE activates MAP kinase directly in GT1-1 cells, and that the effect of NE is mediated by increase in the cAMP level and by calcium influx, but not by PMA-sensitive protein kinase C or Raf-1 kinase.     

Inhibition of morphine-induced tolerance and dependence by a benzodiazepine receptor agonist midazolam in the rat

We investigated whether midazolam administration influenced morphine-induced antinociception and tolerance and dependence in the rat. Antinociception was assessed by the tail-flick (TF) and the hot-plate test (HP 52 degrees C). Morphine tolerance developed after daily single injections of morphine for 11 days. The effect of midazolam on morphine-induced antinociception and tolerance was assessed by giving daily injections of various doses of midazolam for 11 days. The first injection of saline or midazolam was given intraperitoneally and 30 min later morphine (10 mg/kg body weight) was administered subcutaneously. Antinociception was monitored by measuring TF and HP latencies 60 min after the second injection. Midazolam was injected at four different concentrations: 0.03, 0.1, 0.3, and 3 mg/kg body weight. Chronic administration of morphine resulted in the development of tolerance to antinociception in both TF and HP tests, with rats exhibiting baseline antinociception on Day 9. Animals treated with midazolam alone showed little antinociception on Days 3-9. However, midazolam administration in morphine-treated animals attenuated morphine-induced tolerance to antinociception on Days 1-11 as measured by the tail-flick test. Midazolam also decreased the jumping behavior following naloxone injections in morphine-dependent rats. These results suggest that midazolam may prolong the effects of morphine by delaying morphine-induced development of tolerance to antinociception. Midazolam also attenuated a decrease in weight gain induced by chronic injections of morphine.     

The "Wallstent": a new stent for the treatment of urethral strictures

Morphine or morphine-6-glucuronide either alone or in combination with morphine-3-glucuronide was administered intrathecally to rats. Antinociceptive effects were evaluated with the tail flick and the hot plate tests. Motor function was tested using the rotarod test. Estimated ED50 from the dose-response curves for morphine and morphine-6-glucuronide showed about a 30 times more potent antinociceptive effect of morphine-6-glucuronide compared with morphine. Morphine-3-glucuronide had no antinociceptive effect. Simultaneous administration of morphine-3-glucuronide 5.0 micrograms did not show any significant effect on antinociception induced by morphine 1.0 microgram or morphine-6-glucuronide 0.05 microgram.     

Differential modulation of kappa and mu opioid antinociception by the glycine/NMDA receptor agonist D-serine

D-Serine, a selective agonist for the strychnine-insensitive glycine allosteric site associated with the NMDA receptor-ion channel complex, was found to modulate differentially the antinociception produced by kappa and mu-opioid receptor agonists in the rat formalin test. D-Serine (100 micrograms, i.c.v.) attenuated the antinociception produced by the selective kappa-opioid agonist, enadoline (0.003-0.1 mg kg-1, s.c.) against the tonic, but not acute, phase of the formalin response. Conversely, D-serine potentiated the antinociception produced by morphine (0.3-10 mg kg-1, s.c.) against both the acute and tonic phases. These results demonstrate an important interaction between the opioid and NMDA/glycine systems in the control of nociceptive information possibly at different levels of the neuraxis.     

Dietary protein deficiency induced changes in protein kinase C activity and phospholipid metabolism in rat hepatocytes

Dietary protein deficiency is known to alter the protein kinase C activity in various tissues of rats. Protein kinase C activity is influenced by the metabolism of membrane phosphoinositides and phosphatidyl choline (PC). For metabolic studies, hepatocytes have been the cells of choice of various workers. Therefore, studies on protein kinase C and these phospholipids were conducted in hepatocytes of rats maintained on three different diets viz. casein (20% protein) deficient (4% protein, rice flour as source of protein) and supplemented (deficient diet supplemented with L-lysine and DL-threonine) diet for 28 days. The protein deficiency in diet led to a decline in protein kinase C activity (P < 0.01) without effecting its translocation, an increase in phosphatidyl inositol 4,5-bisphosphate (P < 0.001) and a decrease in phosphatidyl inositol 4-monophosphate and phosphatidyl inositol (P < 0.01) but did not alter the PC contents, as compared to the casein group. Supplementation of deficient diet with L-lysine and DL-threonine could considerably reverse the effect of deficiency of protein in diet. The results suggest that quality of dietary protein is mainly relevant for maintaining phospholipid metabolism and physiology of hepatocytes and thus the signalling mechanism in these cells.     

Effect of modulators of protein tyrosine kinase activity on gender-related differences in vascular reactivity at reduced temperature

We used the isolated-muscle-bath technique to examine the effect of protein tyrosine kinase (PTK) and protein tyrosine phosphatase (PTP) inhibitors on the response of rings of tail artery from male and female rats to cooling and reduced temperature in the absence and presence of two PTK-dependent (clonidine and serotonin) and one PTK-independent (phenylephrine, PE) agonists. At 37 degrees C, reactivity to clonidine, serotonin, and PE was the same in tail artery from female and male rats. At 25 degrees C, reactivity to clonidine and serotonin, but not PE, was greater in tail artery from female rats compared with those from male rats. Sodium orthovanadate (SOV) eliminated the gender-related difference in the contractile effect of clonidine and serotonin at 25 degrees C. The sensitivity to relaxation by genistein was considerably greater for clonidine and serotonin at both temperatures as compared with PE. At 25 degrees C the sensitivity to genistein was greater for the clonidine and serotonin-contracted rings from female rats. In the presence of SOV, temperature reduction led to contraction of rat-tail artery. This effect was greater in rings from female rats. Our results strongly implicate differences in the activity of the PTK transduction pathway as the cause of the observed gender-related differences in agonist-mediated contraction at 25 degrees C and in cold-induced vasoconstriction.