Mechanism of Attenuation of Morphine Antinociception by Chronic Treatment with L-Arginine

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Vol. 281, Issue 2, 707-712, 1997

Mechanism of Attenuation of Morphine Antinociception by Chronic Treatment with L-Arginine¹

Hemendra N. Bhargava, Jing-Tan Bian and Shailendra Kumar

Department of Pharmaceutics and Pharmacodynamics, The University of Illinois at Chicago Health Sciences Center, Chicago, Illinois

	Abstract

Top Abstract Introduction Methods Results Discussion References

The effects of twice-daily injections of L-arginine or D-arginine (200 mg/kg i.p.) for 4 days on morphine-induced antinociception,brain nitric oxide synthase activity and brain and serum distributionof morphine and brain µ-opioid receptors labeled with [³H][D-Ala²,MePhe⁴,Gly⁵-ol]enkephalin were determined in male Swiss-Webster mice. Chronictreatment with L-arginine, but not D-arginine, decreased the antinociceptiveresponse to morphine in mice, increased the activity of nitricoxide synthase in the midbrain and decreased brain levels of morphine,compared with vehicle-injected controls. Significant decreasesin morphine levels were observed in midbrain, pons and medulla,hippocampus, striatum and spinal cord of L-arginine-treated mice,in comparison with vehicle-injected mice. However, the levelsof morphine in cortex, amygdala and hypothalamus of L-arginine-or D-arginine-treated mice did not differ from those of vehicle-injectedcontrols. Acute treatment with L-arginine (200 mg/kg i.p.) orD-arginine (200 mg/kg i.p.) did not modify either morphine antinociceptionor morphine distribution in brain regions or the spinal cord.Chronic administration of L-arginine or D-arginine did not alterthe B_max or K_d values of [³H][D-Ala²,MePhe⁴,Gly⁵-ol]enkephalin binding to the mouse brain membranes. These resultssuggest that chronic treatment with L-arginine reduces the antinociceptiveeffect of morphine by increasing brain nitric oxide synthase activityand by decreasing the concentration of morphine in certain brainregions and spinal cord.

	Introduction

Top Abstract Introduction Methods Results Discussion References

Considerable evidence suggests that NMDA/NO pathways may be involved in the acute and chronic actions of opioid drugs thatare used primarily for the relief of moderate- to severe-intensitypain. Opioid drugs produce their actions by interacting with threemajor types of opioid receptors, namely µ, $delta$ and $kappa$ , with morphineor DAMGO, [D-Pen²,D-Pen⁵]enkephalin and U-50,488H, respectively, being the prototypicalagonists. NO, a second messenger involved in the regulation ofcell function, is formed enzymatically from L-arginine by NOSafter the activation of the NMDA receptor (Moncada et al., 1991).NOS is inhibited by several L-arginine derivatives, such as N^G-nitro-L-arginine and L-NMMA (Rees et al., 1990; Thorat et al.,1994). Drugs that modify the concentration of NO in the centralnervous system appear to modify opioid-induced antinociception.Furthermore, NO is involved in nociceptive processes, particularlyin the spinal cord (Haley et al., 1992). Synaptic transmissionin the central and peripheral nervous system seems to be modulatedby NO (Meller and Gebhart, 1993). NO donors such as 3-morpholino-sydnonimine,sodium nitroprusside and hydroxylamine given i.t. induced hyperalgesiain rats, as measured by the tail-flick test, whereas NOS inhibitorssuch as L-NAME given i.t. or i.c.v. elicited a slight antinociception.However, the effects of other routes of administration of NO donorsor NOS inhibitors were not determined (Przewlocka et al., 1994).In the abdominal constriction test, L-arginine had no effect butL-NAME and L-NMMA by themselves produced marked antinociception,as evidenced by inhibition of the abdominal constriction responsein mice (Moore et al., 1991; Mustafa, 1992). In the tail-flicktest, L-NAME, L-NMMA and L-arginine had no effect (Dambisya andLee, 1995). In another study, i.c.v. administration of L-arginine(30 ng/mouse) elicited antinociception in mice, as assessed bythe tail-flick test. The antinociceptive action of L-argininewas attributed to the formation of kyotorphin (L-Tyr-L-Arg) inthe brain (Kawabata et al., 1994, 1996). In another study, L-argininewas also shown to produce antinociception by itself and to antagonizei.c.v. administered bradykinin-induced antinociception in mice(Germany et al., 1996). Thus, L-arginine appears to produce nociceptionand antinociception in tests that are sensitive to weak analgesicagents. On the other hand, acute administration of L-arginine,the precursor of NO, p.o. or i.p. but not i.c.v. reduced morphineantinociception in mice. These effects were observed at 300 and1000 mg/kg doses of L-arginine and were reversed by the NOS inhibitorsL-NAME and L-NMMA (Brignola et al., 1994). Intrathecal administrationof L-NAME has been shown to enhance morphine antinociception inrats (Przewlocki et al., 1993), suggesting involvement of thespinal NO system.

The effect of chronic administration of L-arginine on morphine antinociception has not been determined. Although, in the aforementionedstudies, NO was implicated in the acute and chronic actions ofopioid drugs, other factors, such as the activity of NOS and thedistribution of opioid agents in the central nervous system, havereceived little attention. In the present studies, the effectsof chronic administration of L-arginine or D-arginine on the antinociceptiveactivity of morphine have been determined. The effects of suchtreatments on NOS activity and the distribution of morphine incertain brain regions, spinal cord and serum were evaluated. Ascontrols, the effect of acute administration of L-arginine onmorphine antinociception and its distribution in brain regionsand spinal cord have also been determined. Finally, the effectof chronic administration of L-arginine or D-arginine on the bindingof [³H]DAMGO to brain membranes was also assessed.

	Methods

Top Abstract Introduction Methods Results Discussion References

Animals. Male Swiss-Webster mice weighing 25 to 30 g (Sasco King Animal Co., Oregon, WI) were acclimated to a room with controlledambient temperature (23 ± 1°C) and humidity (50 ± 10%) and a 12-hrdark/light cycle (6:00 A.M. to 6:00 P.M.). The animals were housedunder these conditions for at least 4 days before being used.The animals were given food and water continuously.

Chemicals. Morphine sulfate was purchased from Mallinckrodt Chemical Co. (St. Louis, MO). L-Arginine and D-arginine were purchased fromSigma Chemical Co. (St. Louis, MO). The drugs were dissolved inphysiological saline and injected i.p. or s.c. in a volume of10 ml/kg body weight. The RIA kit for morphine was obtained fromDiagnostic Products Corp. (Los Angeles, CA). [³H]Arginine (specific activity, 64.0 Ci/mmol) was purchased fromAmersham International (Arlington Heights, IL). [³H]DAMGO (specific activity, 50.0 Ci/mmol) was obtained from theNational Institute on Drug Abuse (Rockville, MD). Unlabeled levorphanolwas purchased from Research Biochemicals Inc. (Natick, MA).

Chronic treatment with L-arginine or D-arginine. Mice were injected i.p. with vehicle, L-arginine (200 mg/kg) or D-arginine (200 mg/kg) twice each day for 4 days. On day 5,the antinociceptive response to morphine (2.5, 5.0 or 10 mg/kgs.c.) was determined as described below.

Measurement of the antinociceptive response. The antinociceptive response to morphine was measured by the tail-flick test as described earlier (D'Amour and Smith, 1941;Bhargava and Zhao, 1996; Zhao and Bhargava, 1996). At the beginningof the study, the light intensity in the tail-flick apparatuswas adjusted so that the mean basal latencies for the tail-flickresponse were approximately 2 sec. To minimize tail skin tissuedamage, the cut-off time was set at 10 sec. The tail-flick latencieswere determined before and 30 min after the injection of morphine(2.5, 5.0 or 10 mg/kg s.c.). The basal tail-flick latencies weresubtracted from the effect induced by the drug for each mouse.The antinociceptive response for each mouse was converted intoAUC. Data were expressed as AUC (mean ± S.E.M.). Ten mice wereused for each treatment group. The differences in the antinociceptiveresponses in chronic vehicle- and chronic L-arginine- or D-arginine-treatedmice were determined by using Student's t test. A value of P <.05 was considered to be significant.

Measurement of NOS activity. NOS activity was determined in the brain regions (cerebellum, midbrain, cortex and remainder of the brain) and spinal cordof mice treated chronically with vehicle, L-arginine or D-arginineas described above. NOS activity was determined as described earlier(Barjavel and Bhargava, 1994a,b), as the rate of conversion of[³H]arginine to [³H]citrulline. Briefly, the appropriate tissue was homogenizedin HEPES buffer (20 mM, pH 7.4) containing 0.5 mM EDTA and 2 mM $beta$ -mercaptoethanol, using an ultrasonic dismembrator, for 10 secat setting 8. The homogenate was centrifuged at 18,000 × g for30 min at 4°C. A 50-µl volume of supernatant sample (150-250 µgprotein) was added to the incubation medium containing 50 mM HEPESbuffer, pH 7.4, 0.5 mM $beta$ -mercaptoethanol, 1 mM dithiothreitol,2 mM NADPH, 0.5 mM CaCl₂ and 5 µM L-arginine plus 1 µCi/ml [³H]arginine. The incubation was carried out in duplicate for 15min at 37°C. The blanks were run similarly but without NADPH andCaCl₂. The reaction was stopped by the addition of 500 µl of stopbuffer (20 mM HEPES, pH 5.5, containing 2 mM EDTA). The contentsof the incubation tubes were transferred to 0.6 ml of Dowex AG50W- X8 (Na⁺ form) resin. [³H]Citrulline formed was eluted from the column using 2 ml of distilledwater. A 250-µl aliquot of the eluate was added to a scintillationvial containing 5 ml of Scint-AXF scintillation fluid (PackardInstrument Co., Meriden, CT). The radioactivity in the sampleswas determined in a Packard liquid scintillation counter with60% efficiency. The protein concentration in the samples was measuredby the method of Lowry et al. (1951). NOS activity was expressedas picomoles of [³H]citrulline formed per minute per milligram of protein. The differencein NOS activity in treated and control tissues was determinedby analysis of variance followed by unpaired Student's t test.A value of P < .05 was considered to be statistically significant.

Measurement of morphine concentrations in brain regions, spinal cord and serum of L-arginine- and D-arginine-treated mice. Mice were treated with L-arginine or D-arginine for 4 days, as described above. On day 5, mice from each treatment group wereinjected with morphine (10 mg/kg s.c.) and sacrificed 60 min later.The brain, spinal cord and trunk blood were collected. The brainwas dissected into seven regions, namely hypothalamus, pons andmedulla, amygdala, hippocampus, corpus striatum, midbrain andcortex. The blood samples were centrifuged at 3000 rpm for 10min at 4°C. Serum was separated and stored in deep freeze at $-$ 80°C.The concentration of morphine in serum was determined by RIA using25 µl of the sample in duplicate, as described previously (Bhargavaet al., 1991, 1992; Bhargava and Villar, 1991a,b, 1992). Thisdetection method used ¹²⁵I-labeled morphine that competed with morphine in the sample forantibody sites. The antibody adhered to the wall of a polypropylenetube. The reaction of morphine and antibody was terminated bydecanting the supernatant. The antibody-bound radiolabeled morphinewas counted in a gamma counter. The brain regions and spinal cordwere weighed and homogenized in water (3-10 times the tissue volume),using a Polytron homogenizer (PT 10, setting 6 for 15 sec). Thefinal homogenate contained approximately 60 mg of tissue/ml. Theconcentration of morphine in the homogenate was expressed as nanogramsper gram of tissue. The recovery of morphine from brain regionswas found to be quantitative. The limit of detection was 0.8 ng/mlof homogenate. The specificity and cross-reactivity of the antibodywith morphine metabolites and other analogs have been describedpreviously (Bhargava et al., 1991). The antibody showed cross-reactivitywith the two morphine glucuronides of only 0.2% and with normorphineof 10%. Eight mice were used for each treatment group.

The differences in the morphine concentrations in various tissues and serum from vehicle-, L-arginine- and D-arginine-treatedmice were determined by using analysis of variance followed bythe Newman-Keuls test. A value of P < .05 was considered to besignificant.

Determination of the effects of acute administration of L-arginine or D-arginine on the antinociceptive activity of morphine and the distribution of morphine in brain regions and spinal cord of mice. Mice were injected with L-arginine (200 mg/kg i.p.), D-arginine (200 mg/kg i.p.) or the vehicle. They were then injected withmorphine (10 mg/kg s.c.) 10 min later. The antinociceptive activitywas determined as described above, using the tail-flick test,and was expressed as AUC_0-210min (mean ± S.E.M.). Ten micewere used for each treatment group. Statistical comparisons weremade as described above.

For determination of the effect of acute treatment with L-arginine or D-arginine on tissue distribution of morphine, the drugswere injected at 200 mg/kg (i.p.). Ten minutes later, morphine(10 mg/kg s.c.) was injected. Mice were sacrificed 60 min afterthe injection of morphine. The brain regions and spinal cordswere isolated and the morphine concentrations in the tissues weredetermined by RIA as described above. The data were analyzed byanalysis of variance, followed by Student's t test.

Determination of binding of [³H]DAMGO to µ-opioid receptors in the brain of mice treated chronically with L-arginine or D-arginine. Mice were injected i.p. with vehicle, L-arginine (200 mg/kg) or D-arginine (200 mg/kg) twice each day (9:00 A.M. and 5:00P.M.) for 4 days. The animals were sacrificed at 9:00 A.M. onday 5. Brain was isolated, the cerebellum was removed and theremainder of the brain was stored at $-$ 70°C. To determine the bindingof [³H]DAMGO, the tissue was homogenized in 30 volumes of ice-coldTris-HCl buffer (0.05 M, pH 7.4), using a Polytron homogenizer(setting 5 for 20 sec). The homogenate was centrifuged at 49,000× g for 15 min, and the pellet was resuspended in the same bufferand incubated at 37°C for 45 min to remove the endogenous opioidsfrom their binding sites. After a second centrifugation at 49,000× g for 15 min, the pellet was resuspended in Tris-HCl bufferand used for the binding studies.

The binding was carried out in a total volume of 0.25 ml, which contained 0.05 M Tris-HCl buffer and 0.1 ml of the homogenate(200-250 µg of protein). The binding of [³H]DAMGO was performed according to the procedure of Magnan etal. (1982)

, using [³H]DAMGO in the concentration range of 1.25 to 40 nM. All bindingassays were carried out in duplicate at 25°C for 60 min. The specificbinding was defined as the difference in binding observed in theabsence and presence of 10 µM levorphanol. Binding was terminatedby rapidly filtering the contents of the incubation tubes underreduced pressure, using a Brandel M-24R cell harvester and WhatmanGF/B glass fiber filters. The filters were washed twice with 5ml of the same ice-cold buffer used for the assay. The filterswere transferred to liquid scintillation vials containing 5 mlof Scint-A XF scintillation fluid (Packard). After an overnightequilibration period, the radioactivity in the samples was determinedusing a Packard liquid scintillation counter (model 4640) with60% counting efficiency. The concentration of protein in the sampleswas determined by using the method of Lowry et al. (1951)

The receptor densities (B_max values) and apparent dissociation constants (K_d values) were determined from the saturation curvesand the Scatchard plots using the program LIGAND (Munson and Rodbard,1980

). The data were expressed as mean values ± S.E.M. Six micewere used for each treatment group. The data were analyzed byusing Student's t test. A value of P < .05 was considered to besignificant.

	Results

Top Abstract Introduction Methods Results Discussion References

Effects of chronic administration of L-arginine or D-arginine on the antinociceptive actions of morphine in mice. Administration of morphine produced dose-dependent antinociception in mice, as evidenced by the increasing AUC_0-300minvalues. Chronic administration of L-arginine (200 mg/kg i.p.)twice each day for 4 days decreased the antinociceptive actionof morphine. As shown in figure 1, the antinociceptive responseto morphine (2.5 mg/kg) was decreased by 51%, but this changewas not significant. However, the responses to 5.0 and 10.0 mg/kgdoses of morphine were decreased by 75 and 76% and were significantat the P < .05 and P < .001 levels, respectively. The same treatmentregimen with D-arginine did not affect morphine-induced antinociception.

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Fig. 1. Effect of chronic administration of L-arginine or D-arginine on the antinociceptive action of morphine in mice. Mice weretreated with L-arginine (200 mg/kg i.p.) ( $black-square$ ), D-arginine (200mg/kg i.p.) (

) or the vehicle ( $square$ ) twice each day for 4 days.The antinociceptive response to different doses of morphine wasdetermined on day 5. *P < .05; ***P < .001, vs. vehicle controls.

Effects of acute administration of L-arginine or D-arginine on the antinociceptive activity of morphine in mice. Acute administration of a 200 mg/kg dose of L-arginine or D-arginine did not modify either the basal tail-flick latency (table1) or the antinociception induced by morphine (10 mg/kg). Asshown in figure 2, the AUC_0-210min values for morphine invehicle-, L-arginine- or D-arginine-treated mice were virtuallyidentical.

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TABLE 1
Effects of chronic treatment with vehicle, L-arginine or D-arginine on the tail-flick latency in mice

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Fig. 2. Effect of acute administration of L-arginine or D-arginine on the antinociceptive action of morphine in mice. Mice were injectedwith L-arginine (200 mg/kg i.p.), D-arginine (200 mg/kg i.p.)or the vehicle. Morphine (10 mg/kg s.c.) was injected 10 min later.The antinociceptive response was determined as described in thetext.

Effects of chronic administration of L-arginine or D-arginine on the activity of NOS in brain regions and spinal cord of mice. The activity of NOS was found to be the highest in cerebellum, followed in decreasing order by midbrain, cortex, remainderof the brain and spinal cord. Chronic administration of L-arginine(200 mg/kg i.p.) twice each day for 4 days increased the NOS activityin midbrain by 15.2% (P < .05), but in other brain regions andspinal cord the NOS activity remained unchanged. A similar treatmentregimen with D-arginine, on the other hand, did not modify NOSactivity in any brain region or the spinal cord of the mouse (fig.3).

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Fig. 3. Effect of chronic administration of L-arginine or D-arginine on the NOS activity in brain regions and spinal cord of mice.Mice were treated with L-arginine ( $black-square$ ), D-arginine (

) or the vehicle( $square$ ) for 4 days, as described in the legend for figure 1. NOS activitywas determined on day 5. *P < .05, vs. vehicle controls.

Effects of chronic administration of L-arginine or D-arginine on the distribution of morphine in brain regions, spinal cord and serum of mice. The distribution of morphine in brain regions and spinal cord of mice given vehicle, L-arginine (200 mg/kg i.p.) or D-arginine(200 mg/kg i.p.) for 4 days and then given morphine (10 mg/kgs.c.) is shown in figure 4. Chronic administration of L-argininedecreased the concentration of morphine in midbrain (40%, P <.01), pons and medulla (34%, P < .05), hippocampus (28%, P < .05),corpus striatum (33%, P < .05) and spinal cord (38%, P < .05),in comparison with vehicle-injected controls. The concentrationof morphine in cortex, amygdala and hypothalamus of L-arginine-and vehicle-injected controls did not differ. Chronic treatmentwith D-arginine, however, did not alter the concentration of morphinein any brain regions or spinal cord of the mice (fig. 4). Chronicadministration of L-arginine or D-arginine treatment did not affectserum concentration of morphine (table 2).

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Fig. 4. Effect of chronic administration of L-arginine or D-arginine on the distribution of morphine in brain regions and spinal cordof mice given morphine. Mice were treated with L-arginine ( $black-square$ ),D-arginine (

) or the vehicle ( $square$ ) for 4 days, as described inthe text. On day 5, mice from all treatment groups were injectedwith morphine (10 mg/kg s.c.) and sacrificed 60 min later. *P< .05, vs. vehicle controls.

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TABLE 2
Effects of acute and chronic administration of L-arginine or D-arginine on the morphine concentration in serum of mice injectedwith morphine

Effects of acute administration of L-arginine or D-arginine on the distribution of morphine in brain regions and spinal cord of mice. Acute administration of a 200 mg/kg dose of L-arginine or D-arginine did not alter the concentration of morphine determined60 min after the administration of a 10 mg/kg dose of morphine.As can be seen in figure 5, the morphine concentrations in specificbrain regions or the spinal cords of mice treated acutely withL-arginine or D-arginine did not differ from those in animalstreated with the vehicle. Similarly, the serum concentration ofmorphine was not modified by acute treatment with L-arginine orD-arginine (table 2).

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Fig. 5. Effect of acute administration of L-arginine or D-arginine on the distribution of morphine in brain regions and spinal cordof mice given morphine. Mice were treated with L-arginine ( $black-square$ ),D-arginine (

) or the vehicle ( $square$ ), as described in the legendfor figure 2. Mice were injected with morphine (10 mg/kg s.c.)10 min later and were sacrificed 60 min later.

Effects of chronic administration of L-arginine or D-arginine on the binding of [³H]DAMGO to mouse brain µ-opioid receptors. [³H]DAMGO bound to mouse brain homogenate with a B_max value of 165.6 ± 10.3 fmol/mg protein and a K_d value of 3.06 ± 0.52 nM.Chronic administration of L-arginine or D-arginine to mice didnot alter the binding characteristics of [³H]DAMGO in the brain (table 3).

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TABLE 3
Effects of chronic administration of L-arginine or D-arginine on the parameters of [³H]DAMGO binding to mouse brain membranes

	Discussion

Top Abstract Introduction Methods Results Discussion References

The present studies clearly demonstrate that chronic administration of L-arginine but not of D-arginine causes a reductionin the antinociceptive action of morphine, a µ-opioid receptoragonist, in mice. Thus, the effect of arginine was stereospecific.To our knowledge, this is the first study on the effect of chronicadministration of L-arginine on morphine antinociception. In anearlier study, the effect of acute treatment with L-arginine orD-arginine on morphine antinociception was studied in mice. Thedoses of L-arginine that produced inhibition were 300 and 1000mg/kg and the degree of inhibition was rather small (Brignolaet al., 1994). However, in the present study, chronic treatmentwith L-arginine produced a robust decrease in the antinociceptiveaction of morphine in mice. Because in our studies chronic administrationof L-arginine (200 mg/kg) produced an 80% reduction in morphineantinociception, the effect of the same dose of L-arginine givenacutely on morphine antinociception was determined in mice. AcuteL-arginine treatment did not alter morphine antinociception inmice. It is clear that chronic L-arginine treatment induces changesthat result in decreased morphine antinociception.

Attempts were also made to determine the potential mechanisms by which L-arginine modified morphine antinociception. In anearlier study, where acute administration of high doses of L-argininep.o. or i.p. but not i.c.v. decreased morphine antinociception,the effect on NOS activity in brain or spinal cord was not determined.It was assumed that L-arginine affected the formation of NO (Brignolaet al., 1994). In the present study, chronic treatment with L-arginineproduced a 15% increase in the activity of NOS only in the midbrain.The midbrain is an important brain region involved in pain perceptionand contains the periaqueductal gray matter, with a high densityof endogenous opioid systems. The increase in NOS activity wouldenhance the production of NO. Previous studies have implicatedNO in nociceptive processes. Production of NO by i.t. administrationof L-arginine resulted in a rapid, transient and dose-dependentfacilitation of the nociceptive tail-flick reflex (Meller et al.,1992a). Similarly, NO of the spinal cord mediates the NMDA-inducedfacilitation of the tail-flick nociceptive reflex (Meller et al.,1992a; Kitto et al., 1992) and thermal hyperalgesia in a modelof neuropathic pain in rats (Meller et al., 1992b). As indicatedabove, the majority of studies show NO to have an algesic action.Therefore, increased production of NO as a result of chronic administrationof L-arginine would result in antagonism of the antinociceptiveresponse to morphine, as was observed in the present studies.NO in the spinal cord has been shown to modulate the descendingpain control system for antinociception activated by supraspinallyapplied morphine. Thus, activation of NO system in the spinalcord attenuates morphine antinociception (Xu and Tseng, 1995).However, the effect of i.t. administration of activators of NOon the antinociception induced by peripheral administration ofmorphine is not known. How L-arginine activates NO in the spinalcord and modifies morphine antinociception is not clear, becausein our studies the activity of NOS was modified by chronic treatmentwith L-arginine.

NO of the spinal cord has been reported to cause hyperalgesia. The evidence was based on the fact that i.t. injection of L-arginineor NO donors facilitated the tail-flick response and decreasedtail-flick latencies and this effect was reversed by N^G-nitro-L-arginine. However, the onset of such actions of L-argininewas rapid and the duration was short (2 min) (Kitto et al., 1992;Meller et al., 1992a). Other studies, however, failed to observehyperalgesia after i.t. injections of L-arginine, because thetail-flick latencies were not modified (Xu and Tseng, 1995). Ourstudies also did not find a change in the basal tail-flick latenciesafter chronic administration of L-arginine, and thus the attenuationof morphine antinociception cannot be explained on the basis ofany hyperalgesia of short duration (2 min) observed by Melleret al. (1992a). Thus, our results on the lack of an effect ontail-flick latency by L-arginine are in agreement with those ofXu and Tseng (1995) and in contrast to those of Kitto et al. (1992)and Meller et al. (1992a).

Our results also show that chronic administration of D-arginine, which is not a substrate for NOS, neither modified morphineantinociception nor altered the concentration of morphine in brainregions and spinal cord, further supporting the view that chronicadministration of L-arginine possibly modifies the transport ofmorphine across the blood-brain barrier.

Another possibility is that the decreased antinociceptive response to morphine with L-arginine may be related to alterationsin the distribution of morphine in the central nervous systemsites involved in the nociceptive response. The present studiesindicated that arginine, in a stereospecific manner, decreasedthe concentration of morphine in midbrain, pons and medulla, hippocampus,corpus striatum and spinal cord. Thus, L-arginine, but not D-arginine,decreased the levels of morphine in spinal and supraspinal structuresand could have been responsible for the decreased antinociceptiveactivity. Chronic treatment with L-arginine or D-arginine, however,did not affect the levels of morphine in serum. Acute treatmentwith L-arginine (200 mg/kg), which did not modify morphine antinociception,also failed to alter the concentration of morphine in brain regionsor the spinal cord of mice. It is, therefore, clear that chronicadministration of L-arginine induces certain changes in the brainand spinal cord, which result in decreased transport of morphinein the central nervous system. The decrease in morphine concentrationsin the brain after chronic treatment with L-arginine might bethe result of some change in the blood-brain barrier that decreasesthe movement of morphine to the brain. The fact that L-argininetreatment did not modify antinociception produced by i.c.v. administrationof morphine (Brignola et al., 1994; J.-T. Bian and H. N. Bhargara,unpublished observations) further supports the view that NO/NOSsystems may affect the blood-brain barrier to morphine. The exactmechanism by which L-arginine decreases the brain and spinal cordconcentrations of morphine is not clear at present.

In addition to the altered concentrations of morphine in the central sites after chronic administration of L-arginine, thecharacteristics of central µ-opioid receptors labeled with [³H]DAMGO were also determined, in an effort to further determinethe mechanism by which L-arginine decreases morphine antinociception.The present studies clearly demonstrated that the B_max and K_dvalues for [³H]DAMGO in the brains of mice treated chronically with L-arginineor D-arginine did not differ from those in mice treated chronicallywith the vehicle. Thus, the decreased analgesic response to morphineafter chronic L-arginine treatment is not related to changes inthe brain µ-opioid receptors. Administration of L-arginine (i.c.v.)also failed to modify the antinociception induced by i.c.v. injectionsof morphine or DAMGO (Xu and Tseng, 1993). These studies furthersupport the suggestion that L-arginine administered acutely orchronically does not modify the characteristics of the brain µ-opioidreceptors.

In summary, the present studies demonstrate that chronic treatment with arginine stereospecifically increases central NOSactivity and decreases morphine antinociception by decreasingthe levels of morphine in both the spinal and supraspinal structuresof the central nervous system. Further studies are warranted tounderstand the mechanisms involved in the attenuation of morphineantinociception by chronic treatment with L-arginine.

	Acknowledgments

The authors thank Celina Tejada for secretarial assistance.

	Footnotes

Accepted for publication January 13, 1997.

Received for publication September 20, 1996.

¹ These studies were supported by Research Scientist Development Award K02-DA00130 to H.N.B. from the National Institute onDrug Abuse, National Institutes of Health.

Send reprint requests to: Dr. Hemendra N. Bhargava, Department of Pharmaceutics and Pharmacodynamics (M/C 865), The University of Illinois at Chicago, 833 South Wood Street, Chicago, IL 60612.

	Abbreviations

AUC, area under the time-response curve; DAMGO, [d-Ala²,MePhe⁴,Gly⁵-ol]enkephalin; HEPES, 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid; i.t., intrathecal(ly); L-NAME, N^G-nitro-L-arginine methyl ester; NMDA, N-methyl-D-aspartate; L-NMMA, N^G-monomethyl-L-arginine; NO, nitric oxide; NOS, nitric oxide synthase; RIA, radioimmunoassay.

	References

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