Antagonism of the Melanocortin System Reduces Cold and Mechanical Allodynia in Mononeuropathic Rats

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The Journal of Neuroscience, November 1, 2000, 20(21):8131-8137

Antagonism of the Melanocortin System Reduces Cold and Mechanical Allodynia in Mononeuropathic Rats
Dorien H. Vrinten¹^,², Willem Hendrik Gispen¹, Gerbrand J. Groen², and Roger A. H. Adan¹
Departments of ¹ Medical Pharmacology and ² Anesthesiology, Rudolf Magnus Institute for Neurosciences, University Medical Centre Utrecht, 3584 CG Utrecht, The Netherlands

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The presence of both pro-opiomelanocortin-derived peptides and melanocortin (MC) receptors in nociception-associated areasin the spinal cord suggests that, at the spinal level, the MCsystem might be involved in nociceptive transmission. In the presentstudy, we demonstrate that a chronic constriction injury (CCI)to the rat sciatic nerve, a lesion that produces neuropathic pain,results in changes in the spinal cord MC system, as shown by anincreased binding of ¹²⁵I-NDP-MSH to the dorsal horn. Furthermore, we investigated whetherintrathecal administration (in the cisterna magna) of selectiveMC receptor ligands can affect the mechanical and cold allodyniaassociated with the CCI. Mechanical and cold allodynia were assessedby measuring withdrawal responses of the affected limb to vonFrey filaments and withdrawal latencies upon immersion in a 4.5°Cwater bath, respectively. We show that treatment with the MC receptorantagonist SHU9119 has a profound anti-allodynic effect, suggestingthat the endogenous MC system has a tonic effect on nociception.In contrast, administration of the MC4 receptor agonists MTIIand D-Tyr-MTII primarily increases the sensitivity to mechanicaland cold stimulation. No antinociceptive action was observed afteradministration of the selective MC3 receptor agonist Nle- $gamma$ -MSH.Together, our data suggest that the spinal cord MC system is involvedin neuropathic pain and that the effects of MC receptor ligandson the responses to painful stimuli are exerted through the MC4receptor. In conclusion, antagonism of the spinal melanocortinsystem might provide a new approach in the treatment of neuropathicpain.

Key words: neuropathic pain; chronic constriction injury; allodynia; melanocortins; melanocortin-4 receptor; spinal cord; dorsal horn; in situ ¹²⁵I-NDP-MSH binding

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In humans, damage to the nervous system (a peripheral nerve, dorsal root ganglion, dorsal root, or the CNS) can lead to apain state referred to as neuropathic pain. This syndrome is characterizedby spontaneous pain in combination with allodynia (pain evokedby normally nonpainful stimuli) and hyperalgesia (an increasedresponse to painful stimuli). In current clinical practice, severaldrugs are used to control neuropathic pain, including tricyclicantidepressants (for review, see Ollat and Cesaro, 1995; Kingery,1997), anticonvulsants (Rosenberg et al., 1997), systemic administrationof local anesthetics (Glazer and Portenoy, 1991; Rowbotham etal., 1991), and NMDA receptor antagonists (Backonja et al., 1994;Felsby et al., 1996). Despite this wide range of drugs, the treatmentof neuropathic pain is often unsatisfactory and limited by theoccurrence of adverse sideeffects.

Over the past decade, a number of animal models of neuropathic pain have become available, producing symptoms that closelyresemble those observed in human neuropathic pain. Research usingthese preclinical models has yielded an array of potential newanalgesics, including different enzyme inhibitors, ion channelblockers, and ligands for various receptors (for review, see Chizhet al., 1999; Yaksh, 1999). Another potential target in the controlof pain that has received very little attention is the melanocortin(MC) system. It has been reported previously that central administrationof the melanocortins adrenocorticotropic hormone (ACTH) and $alpha$ -melanocytestimulating hormone ( $alpha$ -MSH) cause hyperalgesia in various paintests (Bertolini et al., 1979; Sandman and Kastin, 1981; Williamset al., 1986). Furthermore, these peptides have also been shownto antagonize the analgesic effects of morphine and $beta$ -endorphin(Gispen et al., 1976; Wiegant et al., 1977; Smock and Fields,1981). The mechanisms through which these effects were exerted,however, remained unclear because no receptors for these peptideswere identified. Only in recent years, five MC receptors (MC-Rs)subtypes have been identified (for review, see Cone et al., 1996;Tatro, 1996), of which the MC3 and MC4 receptors are expressedin the nervous system. Compared with the MC3 receptor, the MC4receptor has a much more widespread distribution throughout thebrain. Moreover, it is the only subtype of which expression hasbeen demonstrated in the spinal cord (Mountjoy et al., 1994).Binding of ¹²⁵I-NDP-MSH, a synthetic $alpha$ -MSH analog, to rat spinal cord demonstratedthat the most abundant MC receptor expression is present in thesuperficial dorsal horn (lamina I and II) and in the gray mattersurrounding the central canal (lamina X), areas that are importantin nociceptive transmission (van der Kraan et al., 1999). Furthermore,pro-opiomelanocortin (POMC) mRNA was also demonstrated in spinalcord (van der Kraan et al., 1999), and immunoreactivity for thePOMC-derived peptides $beta$ -endorphin, ACTH, and $alpha$ -MSH has been describedin the dorsal horn and lamina X (Tsou et al., 1986; Plantingaet al., 1992). Together, these findings suggest the presence ofa functional MC system in the rat spinal cord. Considering thelocalization of ¹²⁵I-NDP-MSH binding in nociception-associated areas in the spinalcord and the fact that the MC4 receptor is the only MC receptorsubtype for which mRNA has been detected in the spinal cord, thespinal MC4 receptor might be a potential target in the ongoingsearch for newanalgesics.

As recently selective ligands for the MC receptors became available, it is now possible to study a putative role for the MC4receptor in the control of neuropathic pain. The aim of the presentstudy was to investigate whether changes in the spinal cord MCsystem play a role in neuropathic pain. Therefore, in situ bindingof ¹²⁵I-NDP-MSH to rat lumbar spinal cord sections was quantified. Thechronic constriction injury (CCI) (Bennett and Xie, 1988) waschosen because of its wide acceptance as a reliable and reproduciblemodel for neuropathic pain. In addition, we investigated whetherselective MC receptor ligands can alter the response of controland mononeuropathic rats to painfulstimuli.

We demonstrate that a CCI results in an increase in ¹²⁵I-NDP-MSH binding to the spinal cord, suggesting an increase in MC receptorlevels. We also show that, in CCI rats, intrathecal administrationof the MC receptor antagonist SHU9119 induced a decreased sensitivityto cold and mechanical stimulation, whereas the strong MC receptoragonist MTII or the more selective MC4 receptor agonist D-TyrMTII had the opposite effect. In contrast, in control rats, theseligands had no effect on sensitivity. Furthermore, we show thattreatment with the selective MC3-R agonist Nle- $gamma$ -MSH had no effectonsensitivity.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Peptides
For in vivo administration, MTII [Melanotan-II or cyclo-[Nle⁴, Asp⁵, D-Phe⁷, Lys¹⁰] $alpha$ -MSH-(4-10)], SHU9119 [cyclo-[Nle⁴, Asp⁵, D-Nal(2)⁷, Lys¹⁰] $alpha$ -MSH-(4-10)], D-Tyr-MTII (cyclo-[Nle⁴, Asp⁵, D-Tyr⁷, Lys¹⁰] $alpha$ -MSH-(4-10)], and Nle- $gamma$ -MSH (Ac-[Nle³]- $gamma$ ₂-MSH-NH₂) were used. MTII was purchased from Bachem Feinchemicalien(Buberdorf, Switzerland), and SHU9119, Nle- $gamma$ -MSH, and D-Tyr-MTIIwere synthesized using g-fluorenyl methoxycarbonyl solid phasesynthesis as reported previously (Schaaper et al., 1998). Peptideswere purified using reverse-phase preparative HPLC to a purityof ±90%, estimated after analysis by analytical HPLC at 215 nm.Molecular weight was confirmed by mass spectrometry performedon a Micromass Quattro single quadrupole. Potencies and affinitiesof these four peptides for the rat MC3 and MC4 receptor are shownin Table 1.


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Table 1. Affinity (Ki) and potency (EC₅₀) of melanocortin receptor ligands for the rat MC3 and MC4 receptors

For in situ melanocortin binding to spinal cord cryosections, ¹²⁵I-NDP-MSH was used. NDP-MSH (Melanotan-I or [Nle⁴, D-Phe⁷] $alpha$ -MSH) was purchased from Bachem Feinchemicalien and iodinatedusing bovine lacto-peroxidase (Calbiochem, Lucerne, Switzerland)and ¹²⁵I-Na (ICN Biochemicals, Costa Mesa, CA) as described previously(Huang et al., 1997), followed by HPLC purification on a C18 column(µBondapak 3.9 × 300 mm; Waters, Milford,MA).

Animals
Fifty-nine male Wistar rats weighing 200-240 gm at the start of the study were used. Animals were housed in groups of twoto three in plastic cages on a sawdust bedding. They were keptat a 12 hr light/dark cycle, with food and water available adlibitum. All testing procedures in this study were performed accordingto the Ethical Guidelines of the International Association forthe Study of Pain (Zimmermann, 1983) and were approved of by theEthics Committee on Animal Experiments of the UtrechtUniversity.

Surgery
Animals were anesthetized with a single subcutaneous injection of Hypnorm (Janssen Pharmaceutical Ltd., Grove, Oxford, UK)containing 0.315 mg/ml fentanyl citrate and 10 mg/ml fluanisone,at a dose of 0.3 ml/kgbodyweight.
In 33 animals, the right sciatic nerve was exposed at midthigh level by blunt dissection, and a CCI was made by placing fourloose ligatures of 4-0 chromic catgut (Ethicon, Norderstedt, Germany)around the nerve, as described previously by Bennett and Xie (1988).In four animals, the same procedure was performed except for placementof the ligatures (sham surgery). After this, the incision wasclosed with silk sutures, and the animals were allowed to recover.The remaining 22 animals only received a cisterna magna cannula(controlanimals).
Placement of the cannulas was performed 2 weeks after the sham or CCI lesion. Rats were again anesthetized and placed in astereotactic frame. The skull was exposed by a midline incision.A steel cisterna magna cannula was inserted through a burr holejust before the squama occipitalis, and two small screws wereplaced lateral to the midline for extra fixation. Cannula andscrews were fastened with dental acrylic. The animals were alloweda 4 d recovery period before testing wasinitiated.

In situ ¹²⁵I-NDP-MSH binding to spinal cord
Seven animals that remained naive to treatment (four sham and three CCI animals) were used for in situ ¹²⁵I-NDP-MSHbinding.
Tissue preparation. Four weeks after placement of the ligatures or sham surgery, the rats were killed by decapitation. Thelumbar spinal cord was rapidly removed and frozen by submersionin 2-methyl-butane (Fluka Chemika, Buchs, Switzerland) on dryice. Spinal cords were stored at $-$ 80°C until further processing.From lumbar segments L4-L6, cryostat sections (16 µm) were preparedand mounted on gelatin-coated slides (two sections from each segmentperslide).
In situ binding assay. From each animal, one slide was incubated with ¹²⁵I-NDP-MSH as described previously (Tatro, 1993). In short, thesections were prewashed, incubated with ¹²⁵I-NDP-MSH (10⁶ cpm/ml) in binding buffer for 1 hr, washed six times to stopbinding reactions, and rapid air dried. A second slide from eachanimal was incubated with ¹²⁵I-NDP-MSH in the presence of 3 µM non-iodinated NDP-MSH to determinethe specificity of tracer binding. All binding assays were doneon the same day, in one experimentalsession.
To visualize the neuroanatomy more clearly, an adjacent section was Nissl stained (Fig. 1A).

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Figure 1. ¹²⁵I-NDP-MSH binding to rat spinal cord sections. A, Nissl staining of a representative spinal cord section, demonstrating the neuroanatomy. B, Diagram representing the sampling template used for determining ¹²⁵I-NDP-MSH binding in x-ray film autoradiograms of rat spinal cord sections. a, Superficial dorsal horn (left and right); b, lamina X; c, dorsal white matter column used for determining background value. For each region, the mean value of three (superficial dorsal horn and background) or four (lamina X) samples was calculated. C, D, x-Ray film autoradiogram of ¹²⁵I-NDP-MSH binding to a representative rat spinal cord section. Sections were incubated with ¹²⁵I-NDP-MSH in the absence (C) or presence (D) of 3 µM non-iodinated NDP-MSH. Specificity of binding present in C is demonstrated by its inhibition in D.

Autoradiography and analysis. Autoradiography was performed by exposing an x-ray film (BioMax MR; Eastman Kodak, Rochester,NY) directly to the slides for 1 week. All slides were run onthe same, single film, with CCI and sham samples randomly dividedover the film. Autoradiograms were digitized and quantitativelyanalyzed using the MCID (Microcomputer Imaging Device; ImagingResearch Inc., St. Catharines, Ontario, Canada). For each section,binding was measured in three anatomic regions, using a samplingtemplate as depicted in Figure 1B. Within each region, three orfour samples were measured, and the mean value was calculated.Specific binding was calculated by subtraction of the mean backgroundvalue, determined within the dorsal white matter column of thesame section. Absorbance values were converted into counts perminute using a linear calibrationcurve.

Drug administration
Thirty CCI and 22 control animals were used to study the effects of the different peptides on nociception. Peptides were dissolvedin 10 µl of saline and injected through the cisterna magna cannulaby means of a Hamiltonsyringe.
On each testing day, CCI rats were randomly divided into three groups (n = 10 each), each group randomly and blindly receivingone of the following doses: vehicle, SHU9119, 0.15, 0.5, or 1.5µg (0.140, 0.466, or 1.40 nmol, respectively); MTII, 15, 30, 100,or 500 ng (14.6, 29.2, 97.6, or 488.2 pmol, respectively); D-Tyr-MTII,0.3, 1.0, or 3.0 µg (0.289, 0.962, or 2.885 nmol, respectively);Nle- $gamma$ -MSH, 5 µg (3.22 nmol) or a combination of 15 ng of MTIIand 0.5 µg of SHU9119. Thus, in total, 13 groups of 10 CCI animalsweretested.
Similarly, on each testing day, control rats were randomly divided in two groups (n = 11 each), each group randomly and blindlyreceiving one of the following doses: vehicle, 1.5 µg of SHU9119,500 ng of MTII, or 3 µg of D-Tyr-MTII (corresponding to the highestdoses tested in CCI animals). Thus, in total, four groups of 11control animals weretested.
Using this experimental setup, animals received only a single injection with a single dose on each testing day. The studywas continued until all doses of all drugs were tested. Animalswere given at least 2 d rest between drug injections to minimizeany possibility of drug interactions or development oftolerance.

Testing procedures
Temperature stimulation test. Withdrawal latency to a temperature stimulus was measured by immersing the right (experimental)hind paw into a 4.5 or 47.5°C water bath. Upon immersion of thepaw, an electronic circuit including a timer was closed. Withdrawalof the paw resulted in a discontinuation of the circuit, whichstopped the timer, thus allowing a precise registration of thewithdrawal latency time. Cutoff time for both temperatures wasset at 10 sec to avoid skindamage.
Mechanical stimulation test. Foot withdrawal threshold in response to a mechanical stimulus was determined using a seriesof von Frey filaments (Stoelting, Wood Dale, IL), ranging from1.08 to 21.09 gm. Animals were placed in a plastic cage with ametal mesh floor, allowing them to move freely. They were allowedto acclimatize to this environment before the experiment. Thefilaments were presented to the midplantar surface as describedby Chaplan et al. (1994), starting with the smallest filament.Each probe was applied to the foot until it just bent, and thesmallest filament eliciting a foot withdrawal response was consideredthe thresholdstimulus.
For both mechanical and temperature stimulation tests, baseline values were determined, and measurements were repeated 15,30, and 60 min after drug or vehicleadministration.

Grooming assay
In eight CCI animals, a grooming assay was performed as described by Gispen et al. (1975). In short, animals were placed ina plastic observation cage immediately after injection of 500ng of MTII (n = 4) or saline (n = 4) through the cisterna magnacannula. Starting 10 min after injection, grooming (face washing,genital grooming, body licking and grooming, and scratching andpaw licking) was scored every 15 sec. Observation was stopped50 min afterinjection.

Data analysis
All data are expressed as mean ± SEM for visualization purposesonly.
For in situ ¹²⁵I-NDP-MSH binding to spinal cord, the overall mean of levels L4-L6 and one to two sections per rat (thus renderingone data point per anatomic region per rat) were used to calculategroup means and SEM. Differences between sham and CCI groups wereanalyzed using an independent Student's ttest.
For the temperature stimulation test, the difference between baseline and postinjection withdrawal latency was calculatedfor each animal at each timepoint.
To obtain a linear scale of perceived intensity in the mechanical stimulation test, the logarithm of the withdrawal thresholdswas plotted. As for the temperature stimulation test, differencesbetween post-treatment and pretreatment withdrawal thresholdswerecalculated.
For mechanical and temperature stimulation, differences in baseline values between control and CCI groups and differencesbetween drug treatment groups were analyzed using the Kruskall-Wallistest because of the nonparametric nature of the data. When appropriate,post hoc analysis was performed using the Mann-Whitney U test,comparing each treatment dose with vehicle and for each treatmentcomparing the highest dose with the intermediate and lowest dose,respectively. A Bonferroni correction wasperformed.
Where possible, dose-response curves were generated. Therefore, postinjection values were expressed as a percentage of baselinevalue. Mean ± SEM of these percentages were plotted against theadministered dose. Dose-response curves are reported for the timeof peak effect (30 min after injection for MTII and D-Tyr-MTII,and 15 min after injection forSHU9119).
Differences in grooming scores were analyzed using an independent Student's t test. For all tests, a probability level ofp $<=$ 0.05 was the criterion for a significantdifference.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In situ ¹²⁵I-NDP-MSH binding to spinal cord

Specificity of the ¹²⁵I-NDP-MSH binding is indicated by its inhibition in the presence of 3 µM NDP-MSH, which reduced bindingto background level (Fig. 1C,D).

As demonstrated previously (van der Kraan et al., 1999), specific ¹²⁵I-NDP-MSH binding was highest in the superficial dorsal horn (correspondingto lamina I-II) and lamina X. In CCI animals, binding in laminaI-II on both the ipsilateral and contralateral sides was significantlyincreased compared with sham animals (125.5 and 118.7% of shamvalues, respectively). In contrast, binding to lamina X did notdiffer between groups (Fig. 2).

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Figure 2. ¹²⁵I-NDP-MSH binding levels in different anatomic regions in rat lumbar spinal cord (L4-L6) cryostat sections. Spinal cords were collected 4 weeks after CCI or sham surgery. Regions were analyzed by sampling the corresponding region of an x-ray film autoradiogram, using a template as depicted in Figure 1A. Values were converted to counts per minute using a linear calibration curve. Specific binding within each region was determined by subtracting the mean background value obtained from the dorsal white matter from the same section. For each region, the overall mean of levels L4-L6 from one or two sections was calculated per rat. Data are represented as mean ± SEM of four (sham) or three (CCI) rats. *p < 0.05 versus sham.

Baseline values for temperature and mechanical stimulation

In control animals, the mean baseline mechanical withdrawal threshold for all four groups at all time points was 21.09 ± 0gm (mean ± SEM). In CCI animals, the overall mean baseline wassignificantly lower (5.32 ± 0.21 gm, ranging from 4.83 ± 0.50to 6.67 ± 1.06 gm for the 13 different randomized groups), thusindicating a mechanicalallodynia.

At 4.5°C, overall mean baseline withdrawal latency in control animals was 9.86 ± 0.06 sec (ranging from 9.75 ± 0.19 to 10± 0 sec). In CCI animals, mean baseline withdrawal latency wassignificantly lower (6.05 ± 0.35 sec, ranging from 3.47 ± 0.41to 7.36 ± 1.07 sec), thus demonstrating a coldallodynia.

At 47.5°C, overall mean baseline withdrawal latency in control animals was 4.52 ± 0.22 sec (ranging from 3.57 ± 0.26 to 5.47± 0.45 sec). This value was not significantly different from thatin CCI animals (4.66 ± 0.22 sec, ranging from 3.47 ± 0.41 to 6.98± 1.26 sec). These data are shown in Figure 3.

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Figure 3. Baseline withdrawal thresholds to von Frey stimulation and baseline withdrawal latencies to cold stimulation (4.5°C) and heat stimulation (47.5°C) in control and neuropathic rats. Data are presented as mean ± SEM of 13 groups of 10 rats (CCI) or 4 groups of 11 rats each (control). *p < 0.05.

Although baseline values could differ between randomized groups, there was no correlation between these values and administrationof either an agonist or antagonist, nor were baseline values consistentlychanged by previous administration of either an agonist or antagonist(data notshown).

Vehicle injection

An injection of 10 µl of saline through the cisterna magna cannula had no effect on the responses to any of the tests performed,in neither CCI rats nor controlrats.

Administration of SHU9119

In CCI rats, treatment with SHU9119 (0.15, 0.5, and 1.5 µg) produced a tactile anti-allodynic effect, as shown by a dose-dependentincrease in withdrawal thresholds to von Frey stimulation (Fig.4A) compared with vehicle treatment. Peak effects were reached15 min after injection, resulting in a withdrawal threshold ofup to 170.5 ± 7.25% of baseline value (mean ± SEM) with 1.5 µgof SHU9119 (Fig. 5A).

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Figure 4. The effect of intrathecal SHU9119 (A), MTII (B), and D-Tyr-MTII (C) on withdrawal thresholds to von Frey stimulation in neuropathic rats. Thresholds are transformed to the logarithm of the applied force. Differences between postinjection and preinjection (baseline) values are plotted. Data are presented as mean ± SEM of 10 rats each, except 1.5 µg of SHU9119 (n = 4). *p < 0.05 versus vehicle; °p < 0.05 versus highest dose of MTII, D-Tyr-MTII, or SHU9119.

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Figure 5. Dose-response curves of the effect of intrathecal SHU9119 (A), MTII (B), and D-Tyr-MTII (B) on von Frey withdrawal thresholds in neuropathic rats. Values represent threshold at 30 min after injection as a percentage of baseline threshold. Data are presented as mean ± SEM of 10 rats each, except 1.5 µg of SHU9119 (n = 4).

As for the mechanical withdrawal thresholds, withdrawal latencies to cold stimulation also increased upon administration ofSHU9119 (Fig. 6A). The cold anti-allodynic effect of the two lowestdoses of SHU9119 showed a dose-dependency as observed for thetactile anti-allodynic effect. However, the highest dose tested(1.5 µg) only produced a small increase in withdrawal latencies.This group consisted of only four animals, and baseline withdrawallatencies of two of these four animals were already at cutoffvalue, leaving no room for a further increase in latency. In theremaining two animals latencies, however, did increase to cutoffvalue in one case and to 174% of baseline in the other case. Treatmentwith SHU9119 did not cause any changes in withdrawal latenciesat 47.5°C (data not shown).

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Figure 6. The effect of intrathecal SHU9119 (A), MTII (B), and D-Tyr-MTII (C) on withdrawal latencies to cold stimulation (4.5°C) in neuropathic rats. Differences between postinjection and preinjection (baseline) values are plotted. Data are presented as mean ± SEM of 10 rats each, except 1.5 µg of SHU9119 (n = 4). *p < 0.05 versus vehicle; °p < 0.05 versus highest dose of MTII, D-Tyr-MTII, or SHU9119.

In control rats, administration of 1.5 µg of SHU9119 had no effect on responses to mechanical, cold, or heat stimulation (datanotshown).

Administration of MTII and D-Tyr-MTII

In CCI rats, administration of the MC receptor agonist MTII (15, 30, 100, and 500 ng) produced a dose-dependent decrease inwithdrawal thresholds to mechanical stimulation (Fig. 4B). Thirtyminutes after injection, withdrawal thresholds were reduced to4.64 ± 0.52% of baseline (mean ± SEM) with the highest dose tested(Fig. 5B).

Similarly as for tactile thresholds, MTII dose-dependently decreased withdrawal latencies at 4.5°C (Fig. 6B). The most potenteffect was observed with the highest dose tested, which reducedlatencies to 9.68 ± 5.07% (mean ± SEM) of baseline value (Fig.7). As for SHU9119, treatment with MTII caused no significantchanges in withdrawal latency to a heat stimulus.

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Figure 7. Dose-response curves of the effect of intrathecal MTII and D-Tyr-MTII on withdrawal latencies to cold stimulation (4.5°C) in neuropathic rats. Values represent threshold at 30 min after injection as a percentage of baseline threshold. Data are presented as mean ± SEM of 10 rats each.

Administration of the more selective MC4 receptor agonist D-Tyr-MTII produced similar results as those observed with MTII,with ~10 times higher doses (0.3, 1, and 3 µg) resulting in adose-dependent decrease in withdrawal thresholds to von Frey stimulation(Fig. 4C) and in withdrawal latencies to cold stimulation (Fig.6C). Values were decreased to 14.73 ± 6.04 and 20.04 ± 5.14% (mean± SEM) of baseline values, respectively (Figs. 5B, 7). As forMTII, administration of D-Tyr-MTII had no effect on withdrawallatencies at 47.5°C.

In control rats, the highest dose of both ligands (500 ng of MTII or 3 µg of D-Tyr-MTII) did not cause any changes in responsesto mechanical, cold, or heat stimulation (data notshown).

Coadministration of MTII and SHU9119

Coadministration of 15 ng of MTII, a dose which by itself had no effect on sensory thresholds (Figs. 4B, 6B), and 0.5 µg ofSHU9119 in CCI rats resulted in a complete inhibition of the coldand mechanical anti-allodynic effect of SHU9119 (data notshown).

Administration of Nle- $gamma$ -MSH

In CCI rats, a single, high dose (5 µg) of the selective MC3 agonist Nle- $gamma$ -MSH was tested. No decreased or increased responsewas observed to either mechanical or thermal stimulation (datanotshown).

In Figure 8, a summary of the described effects of the different MC receptor ligands is presented.

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Figure 8. Summary of the effects of intrathecal. administration of the MC3-R-selective ligand Nle- $gamma$ -MSH (5 µg), the MC4-R-selective ligands MTII (500 ng) and D-Tyr-MTII (3 µg), and the MC-R antagonist SHU9119 (1.5 µg) on the responses of CCI and control rats to different stimuli (indicated on x-axis). Values represent thresholds at 30 min (MTII, D-Tyr-MTII, and Nle- $gamma$ -MSH) or 15 min (SHU9119) after injection as a percentage of baseline threshold. Data are presented as mean ± SEM of 11 (control) or 10 (CCI) rats each, except 1.5 µg of SHU9119 (n = 4 CCI rats).

Grooming behavior

Total grooming scores after injection of saline or 500 ng of MTII into the cisterna magna were 50.67 ± 6.39 and 54.5 ± 14.5,respectively (mean ± SEM). These values were not significantlydifferent (data notshown).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In the spinal cord, the expression of the MC4 receptor overlaps with that of the POMC-derived peptides $alpha$ -MSH and ACTH (Tsouet al., 1986; van der Kraan et al., 1999) in nociception-associatedareas. Therefore, we hypothesized that, at the spinal level, theMC system is involved in the processing of nociceptive information.Here we show for the first time that changes in the spinal cordMC system occur after a CCI to the rat sciatic nerve, a lesionthat causes neuropathic pain. As shown in Figure 2, in situ bindingof the synthetic MC receptor ligand ¹²⁵I-NDP-MSH is increased in lumbar (L4-L6, corresponding with sciaticnerve input) spinal cord sections of CCI rats compared with shamoperated animals, suggesting an upregulation of spinal cord MCreceptors. It is not likely that these changes are caused by theprofound deafferentation associated with a CCI lesion per se (Basbaumet al., 1991; Carlton et al., 1991), because van der Kraan etal. (1999) have shown that crushing the sciatic nerve, anotherlesion producing extensive nerve fiber loss, did not lead to significantdifferences in ¹²⁵I-NDP-MSH binding levels compared with shamsurgery.

Of the anatomic regions we investigated, which were the regions with the highest intensity of binding, the superficial dorsalhorn both ipsilateral and contralateral to the lesion showed thisincreased binding. Bilateral changes associated with CCI havebeen described for other systems as well, including opioid bindingsites (Stevens et al., 1991), calcitonin gene-related peptideand substance P immunoreactivity (Kajander and Xu, 1995), metabolicand nitric oxide synthase activity (Mao et al., 1992); (Choi etal., 1996), and transsynaptic degeneration (Hama et al., 1994).The contralateral changes might be explained by changes in primaryafferents that cross the midline, commissural connections betweenintrinsic spinal neurons (Sugimoto et al., 1990), or descendingcontrol systems affecting both sides of the spinal cord (Besseet al., 1992).

The superficial dorsal horn, the area that displayed an increased ¹²⁵I-NDP-MSH binding in our experiments, corresponds with the predominantentry zone of cutaneous fine diameter primary afferents of thesciatic nerve. In contrast, the gray matter surrounding the centralcanal, an area that receives mostly visceral input, showed nodifferences in binding. These findings suggest that changes inthe endogenous MC system in the spinal cord might be involvedin the increased pain state associated with the CCI lesion andprompted us to investigate whether tonic activity of the MC systemcontributed to this increased sensitivity. As shown in Figures4-6, administration of SHU9119, an antagonist at the MC4 receptor,induced a significant anti-allodynic effect in both the cold andmechanical stimulation tests, indicated by an increased withdrawallatency upon immersion in a 4.5°C water bath and a higher thresholdto von Frey stimulation, respectively. The observation that administrationof an MC receptor antagonist produced hypoalgesia by itself indeedsuggests a tonic influence of the MC system on nociceptivetransmission.

The increase in MC receptor level in the superficial dorsal horn in CCI rats suggests an increased sensitivity for MC receptoragonists in neurons in this area. Treatment with the MC receptoragonist MTII resulted in an opposite effect compared with SHU9119,producing an increased sensitivity to both cold and mechanicalstimulation. Similar results were obtained with D-Tyr-MTII, anMC receptor agonist that displays a higher affinity for the MC4receptor compared with the MC3 receptor. Coadministration of MTIIand SHU9119 demonstrated the specificity of the anti-allodyniceffect of SHU9119. Injection of 15 ng of MTII, a dose which byitself caused no significant changes in nociceptive thresholds,completely blocked the anti-allodynic effect of 0.5 µg of SHU9119when administered simultaneously, thereby demonstrating that theeffects of these compounds are indeed mediated through the samereceptor. Administration of the selective MC3 receptor agonistNle- $gamma$ -MSH had no effect on sensitivity. Because both MTII andD-Tyr-MTII altered the responses to cold and von Frey stimulationwhereas Nle- $gamma$ -MSH had no effect, we suggest that the observedchanges in nociception are mediated through the MC4receptor.

In the present study, we administered MC receptor ligands through a cannula placed in the cisterna magna, directly into thefluid surrounding the spinal cord. Adan et al. (1999) have demonstratedthat a dose of 4.5 pmol of MTII is already sufficient to inducegrooming when administered intracerebroventricularly. In contrast,we demonstrate that a >100-fold higher dose (500 ng, ~488 pmol)failed to induce grooming when injected into the cisterna magna.We cannot exclude the possibility that a small portion of thedrugs administered into the cisterna magna will retrogradely reachthe ventricular system and surrounding structures and that thesestructures play a role in the (anti-)nociceptive effects describedhere. However, because no grooming was observed after injectionof a high dose of agonist, we suggest that the effects we observedin the present study are predominantly exerted at the spinallevel.

In the dorsal horn, immunoreactivity has been demonstrated for the MC receptor agonists $alpha$ -MSH and ACTH, as well as for theopioid peptide $beta$ -endorphin (Tsou et al., 1986), all of which arederived from the POMC peptide. Furthermore, the µ- and $delta$ -opioidreceptor subtypes, for which $beta$ -endorphin displays a high affinity,has also been demonstrated in the same area by immunocytochemistry(Chaplan et al., 1994; Zerari et al., 1994). Therefore, we hypothesizethat the observed anti-allodynic effects of SHU9119 might be causedby blockade of a tonic influence of endogenous $alpha$ -MSH on nociceptionthrough the MC4 receptor in the spinal cord. This could tip thebalance in favor of the anti-nociceptive actions of $beta$ -endorphin,coreleased with $alpha$ -MSH in the same POMC projection areas, thusproducinganalgesia.

The exact source of spinal POMC expression is not known; it might be intrinsic to the spinal cord (Plantinga et al., 1992;van der Kraan et al., 1999) but may also originate from a supraspinalsource, namely the nucleus tractus solitarius (Tsou et al., 1986)or the hypothalamus (Cechetto and Saper, 1988; Elias et al., 1998).Elias et al. (1998) have demonstrated that hypothalamic POMC-expressingneurons innervate the interomedial lateral cell column (IML) ata thoracic level in which sympathetic preganglionic cells arelocated. In this region, MC4-R mRNA is also expressed (Mountjoyand Wild, 1998).

The melanocortin system is suggested to play a role in the regulation of autonomic function, because centrally administeredmelanocortins can increase sympathetic nerve activity (Dunbarand Lu, 2000), possibly through activation of the MC4 receptor(Mountjoy et al., 1994; Mountjoy and Wild, 1998; Dunbar and Lu,1999). Although its exact role is still a matter of debate, thereare several lines of research indicating that the sympatheticnervous system is involved in neuropathic pain (Price et al.,1989; Kim and Chung, 1991; Shir and Seltzer, 1991; Ringkamp etal., 1999). One of the potential mechanisms by which sympatheticactivity influences nociception is through an increased norepinephrineresponsiveness in C fibers, the primary afferents activated bynoxious stimuli (for review, see Janig, 1985; Bennett, 1991; Janiget al., 1996).

In this present study, we only demonstrated changes in the MC system in areas of the spinal cord that correspond to sciaticnerve input. We cannot, however, exclude the possibility thatchanges also occur at other spinal levels or that the ligandswe used act through MC receptors located more rostrally. Thus,an alternative explanation for the observed effects of MC receptorligands on neuropathic pain might be a change in sympathetic activity,mediated at the level of theIML.

As shown in Figure 3, baseline values for von Frey and cold stimulation were significantly lower in CCI rats compared withcontrol rats, confirming the development of mechanical and coldallodynia associated with the CCI lesion (Bennett and Xie, 1988;Attal et al., 1990). However, in contrast to other groups (Bennettand Xie, 1988; Attal et al., 1990; Kupers et al., 1992), we observeno differences in sensitivity to noxious heat between controlrats and CCI rats. The reason for this discrepancy is not clearbut may result from genetic variability between various rat strains.As suggested previously, this may lead to differences in predispositionfor the development of neuropathic conditions (Wiesenfeld-Hallinet al., 1993) or in sensitivity to noxious stimuli because ofvariations in endogenous opiate systems or adrenergic sensitivity(Lee et al., 1997; Hoffmann et al., 1998).

Interestingly, we only observed effects of the MC receptor ligands in CCI rats and only in response to cold and mechanicalstimulation. From a clinical point of view, this is promisingbecause, in this study, the effects of melanocortins appear tobe specific for the allodynia associated with a neuropathic painstate, without altering normal pain sensation by inducing a moregeneral analgesia. This specificity for the hyperalgesia underlyingneuropathic pain without affecting baseline pain detection hasalso been reported for the $alpha$ 2-adrenergic agonist tizanidine (Leiphartet al., 1995).

In summary, in this present study, we show that intrathecally administered MC receptor ligands alter the sensitivity to coldand mechanical stimulation in a rat model for neuropathic pain,the CCI. Our data suggest that these effects are mediated throughthe MC4 receptor located in the spinal cord. SHU9119 producesprofound anti-allodynia, whereas MTII and D-Tyr-MTII increasesensitivity to cold and mechanical sensitivity. We therefore suggestthat selective MC4 receptor antagonists may be of value in thetreatment of neuropathic pain and that further research into themechanisms through which the effects of these ligands are exertedisneeded.

  FOOTNOTES

Received April 6, 2000; revised July 6, 2000; accepted Aug. 9, 2000.

We thank Simone Duis, Nienke Wanders, and Jan Brakkee for technical assistance on the in vivo experiments, and Keith Garnerfor performing the ¹²⁵I-NDP-MSH in situ bindingassay.
Correspondence should be addressed to Dr. Roger A. H. Adan, Department of Medical Pharmacology, Rudolf Magnus Institute forNeurosciences, University Medical Center Utrecht, Universiteitsweg100, 3584 CG Utrecht, The Netherlands. E-mail: adan{at}med.uu.nl.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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