Neuronal Nitric Oxide Synthase mRNA Upregulation in Rat Sensory Neurons after Spinal Nerve Ligation: Lack of a Role in Allodynia Development

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The Journal of Neuroscience, November 1, 1999, 19(21):9201-9208

Neuronal Nitric Oxide Synthase mRNA Upregulation in Rat Sensory Neurons after Spinal Nerve Ligation: Lack of a Role in Allodynia Development
Z. David Luo¹, S. R. Chaplan¹, B. P. Scott¹, D. Cizkova¹, N. A. Calcutt², and T. L. Yaksh¹
Departments of ¹ Anesthesiology-0818 and ² Pathology-0612, University of California, San Diego, La Jolla, California 92093

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Pharmacological evidence suggests a functional role for spinal nitric oxide (NO) in the modulation of thermal and/or inflammatoryhyperalgesia. To assess the role of NO in nerve injury-inducedtactile allodynia, we examined neuronal NO synthase (nNOS) expressionin the spinal cord and dorsal root ganglia (DRG) of rats withtactile allodynia because of either tight ligation of the leftfifth and sixth lumbar spinal nerves or streptozotocin-induceddiabetic neuropathy. RNase protection assays indicated that nNOSmRNA (1) was upregulated in DRG, but not spinal cord, neuronson the injury side beginning 1 d after nerve ligation, (2) peaked(~10-fold increase) at 2 d, and (3) remained elevated for at least13 weeks. A corresponding increase in DRG nNOS protein was alsoobserved and localized principally to small and occasionally medium-sizesensory neurons. In rats with diabetic neuropathy, there was nosignificant change in DRG nNOS mRNA. However, similar increasesin DRG nNOS mRNA were observed in rats that did not develop allodyniaafter nerve ligation and in rats fully recovered from allodynia3 months after the nerve ligation. Systemic treatment with a specificpharmacological inhibitor of nNOS failed to prevent or reverseallodynia in nerve-injured rats. Thus, regulation of nNOS maycontribute to the development of neuronal plasticity after specifictypes of peripheral nerve injury. However, upregulation of nNOSis not responsible for the development and/or maintenance of allodyniaafter nerveinjury.

Key words: neuronal nitric oxide synthase; nerve injury; spinal cord; dorsal root ganglia; sensory neurons; mRNA regulation; diabetic neuropathy; allodynia

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Nerve injury of varying etiologies may produce chronic pain states characterized by allodynia, in which innocuous tactilestimuli become frankly aversive. Experimental models of nerveinjury-evoked allodynia include traumatic and metabolic etiologies,such as nerve ligation and streptozotocin-induced diabetes. Oneconsequence of such nerve injuries is the appearance of adaptivechanges in the expression of a variety of receptors, channels,and enzymes in the dorsal root ganglion (DRG) of the injured nerveand in spinal neurons postsynaptic to the injuredafferents.

Changes in spinal nitric oxide (NO) production may contribute to allodynia after nerve injury. Spinal NO release is evokedby NMDA receptor activation (Snyder, 1992; Luo and Vincent, 1994;Montague et al., 1994; Sakai et al., 1998). NO has been shownto enhance the release of excitatory amino acids (Akira et al.,1994; Montague et al., 1994; Mollace et al., 1995; Ohno et al.,1995; Sandor et al., 1995; Ientile et al., 1996; Nei et al., 1996;Bogdanov and Wurtman, 1997). Spinal delivery of NMDA receptorantagonists has been shown to attenuate allodynia (Calcutt andChaplan, 1997; Chaplan et al., 1997; Siegan et al., 1997). Theseobservations suggest an important role of spinal neuronal nitricoxide synthase (nNOS) in allodynic states observed after nerveinjuries. Pharmacological evidence regarding the role of spinalNO in the development of nerve injury-evoked allodynia has beenconflicting. Although some investigators observed allodynia inhibitionin nerve-injured rats after treatment with L-N^G-nitro-arginine methyl ester (L-NAME), a nonspecific NOS inhibitor(Yoon et al., 1998), others have found that L-NAME has no effecton diabetic- or nerve injury-evoked allodynia (Calcutt and Chaplan,1997) (S. R. Chaplan, unpublishedobservations).

Immunological and enzymatic studies indicate the presence of nNOS-positive neurons and NOS activity in spinal cord and DRGneurons. Nerve injury after tight spinal nerve ligation has beenshown to evoke an increase of NOS expression and activity in DRGbut a reduction in spinal cord neurons (Steel et al., 1994; Choiet al., 1996), indicating a NOS-mediated neuronal response tothe nerve injury. However, the level of such regulation is notknown because nNOS mRNA levels after the nerve injury have notyet been examined. In addition, a direct correlation between nNOSexpression and the development and/or maintenance of allodyniahas not beenestablished.

This study characterized nNOS expression at the mRNA level and correlated it with the development of tactile allodynia afternerve injury. To do this we have used rats with different geneticbackgrounds, either susceptible or resistant to the developmentof allodynia after tight spinal nerve ligation (Kim and Chung,1992), nerve-ligated rats with allodynia or fully recovered fromallodynia, or diabetic rats with allodynia (Calcutt et al., 1996;Calcutt and Chaplan, 1997). In addition, the effects of 7-nitroindazole(7-NI), a nNOS-specific inhibitor, on the development and/or maintenanceof allodynia were evaluated. We established that nNOS expressionis upregulated dramatically at the mRNA level after mechanical,but not metabolic, nerve injury but that such regulation is notresponsible for the development and/or maintenance of nerve injury-inducedallodynia.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Materials. Rats were from Harlan Sprague Dawley (Indianapolis, IN), and [³²P]UTP (specific activity, 800 Ci/mmol) was from NEN Research Products(Wilmington, DE). Tris-acetate gels (NuPAGE) and buffers werefrom Novex (San Diego, CA). Monoclonal antibody against rat brainnNOS was from Sigma (St. Louis, MO). Secondary antibody labeledwith horseradish peroxidase, its substrate, and enhancer solutionswere from Pierce (Rockford, IL). Biotinylated anti-mouse secondaryantibody and avidin-biotin complex solution were from Vector Laboratories(Burlingame, CA). 7-Nitroindazole was from Research Biochemicals(Natick, MA). RNases were from Ambion (Austin, TX), and RNA polymerasesand restriction enzymes were from Life Technologies (Gaithersburg,MD). Other chemicals were fromSigma.

Animals. Rats (male Harlan or Holtzman Sprague Dawley; 100-150 gm) were housed in separate cages using soft bedding, maintainedon a 12:12 hr light/dark cycle, and fed food and water ad libitum.Diabetic studies used adult (230-250 gm) female Harlan SpragueDawley rats that were housed two per cage on wire grates to preventcontact with urine-soiled bedding. All animal care and experimentswere performed according to protocols approved by the InstitutionalAnimal Care Committee of the University of California, SanDiego.

Neuropathic lesions. The surgical procedure described by Kim and Chung (1992) was used to induce tactile allodynia in rats.Briefly, the left lumbar fifth and sixth spinal nerves (L5/6)of rats anesthetized with halothane were exposed and tightly ligatedwith 6.0 silk suture distal to their DRG and proximal to theirconjunction to form the sciatic nerve. Sham operations were performedin the same way except that spinal nerves were not ligated. Diabeticneuropathy was induced as described (Calcutt and Chaplan, 1997)by a single intraperitoneal injection of 50 mg/kg streptozotocin(freshly dissolved in 0.9% sterile saline) to ablate pancreatic $beta$ cells and induce insulin deficiency. Diabetes was confirmedin these rats 2 d later by measuring blood glucose concentrations,using a glucose oxidase-impregnated test strip and reflectancemeter (Ames Glucostix and Glucometer II; Miles, Elkhart, IN),in samples obtained by tail prick. Only animals with a blood glucoseconcentration >15 mmol/l were included as diabetic, and hyperglycemiawas reconfirmed at the time ofdeath.

Drug administration. 7-NI was suspended in peanut oil by sonication. For preemptive treatments, a subcutaneous injection of50 mg/kg in a volume of 1 ml was started 30 min before the surgeryand given daily for 6 d. For treatment of tactile allodynia, thesame daily dose of 7-NI was administered subcutaneously from day11 to 13 after the operation when tactile allodynia was fullydeveloped in the nerve-ligatedrats.

Behavioral testing. Tactile allodynia was tested as described previously (Chaplan et al., 1994). Briefly, rats were transferredto a clear plastic, wire mesh-bottomed cage and allowed to acclimatizefor 15 min. Von Frey filaments (Stoelting, Wood Dale, IL) wereused to determine the 50% paw withdrawal threshold using the up-downmethod of Dixon (1980). A series of filaments, starting with onethat had a buckling weight of 2.0 gm, was applied in consecutivesequence to the plantar surface of the left (nerve-ligated) orright (diabetic) hindpaw with a pressure causing the filamentto buckle. Lifting of the paw indicated a positive response andprompted the use of the next weaker filament. Absence of a pawwithdrawal response after 5 sec prompted the use of the next filamentof increasing weight. This paradigm continued until four moremeasurements had been made after the initial change of the behavioralresponse or until five consecutive negative (assigned a scoreof 15 gm) or four consecutive positive (assigned a score of 0.25gm) responses had occurred. The resulting scores were used tocalculate the 50% response threshold by using the formula: 50%gm threshold = 10^(Xf + )/10,000, where Xf = the value (in log units) of the final vonFrey filament used, $kappa$ = the value [from table in Chaplan et al.(1994)] for the pattern of positive and/or negative responses,and $partial$ = the mean difference (in log units) between stimulus strengths.Behavioral tests were performed immediately before or 30 min to1 hr after drug administrations. Allodynia was considered to bepresent when paw withdrawal thresholds were <4gm.

RNA extraction and RNase protection assay. Total RNA was extracted from rat tissues with TRIzol reagent (Life Technologies)and stored at $-$ 20°C. nNOS mRNA species were quantified by RNaseprotection assays as described (Luo et al., 1994, 1996). A partialrat nNOS cDNA subcloned in a Bluescript SK II plasmid (kindlyprovided by Dr. B. C. Knoe at the University of Texas, HoustonHealth Science Center, Houston, TX) was linearized with EcoRI.After in vitro transcription with [³²P]UTP, a 623 bp labeled antisense cRNA probe was used for RNaseprotection. To normalize for sample loading, an antisense probeof rat cyclophilin (gift of Dr. J. N. Wood; University College,London) was included in each RNase protection assay. A tRNA lanewas included in each RNase protection assay to verify the completedigestion of the free probes. Molecular masses of the protectedprobes were estimated by electrophoresis on polyacrylamide gels,and protected bands were exposed to BioMax films (Eastman Kodak,Rochester, NY) and quantified by densitometry (UltroScan XL; Pharmacia,Piscataway,NJ).

Western blot. To examine the cellular levels of nNOS, spinal cord and DRG tissues were extracted in 50 mM Tris buffer, pH8.0, containing 0.5% Triton, 150 mM NaCl, 1 mM EDTA, and proteaseinhibitors, subjected to NuPAGE Tris-acetate gel electrophoresis,and then transferred to nitrocellulose membrane (Schleicher &Schuell, Keene, NH) electrophoretically. After nonspecific bindingsites were blocked with 5% low fat milk in PBS containing 0.1%Tween 20 (PBS-T), monoclonal antibodies against rat brain nNOS(anti-nNOS) were used to blot the membrane in PBS-T for 1 hr atroom temperature. After the nitrocellulose membrane was washedtwice with the same buffer and once with a buffer containing 150mM NaCl and 50 mM Tris-Cl, pH 7.5, the antibody-protein complexeswere blotted for 1 hr at room temperature with secondary antibodieslabeled with horseradish peroxidase. After extensive washing,the protein-antibody complexes were detected with chemiluminescentreagents.

Immunohistochemistry. nNOS immunostaining was performed as described by Dun et al. (1993). At the end of the survival periodanesthetized rats were perfused intracardially with heparinizedsaline followed by 4% paraformaldehyde in 0.1 M PBS, pH 7.4. Thespinal cord and DRGs were then removed, post-fixed in the samefixative for 12 hr, and then immersed in PBS containing 15-20%sucrose. Frozen transverse sections (25 µm) were cut 24 hr later.Free-floating tissue sections were then pretreated with 0.3% H₂O₂in PBS for 30 min, washed and blocked with 5% normal horse serumin PBS, and incubated with the monoclonal anti-nNOS antibody (1:1000)overnight at 4 °C with gentle agitation. After several washes,sections were incubated with biotinylated anti-mouse secondaryantibody (1:200) for 2 hr and then with avidin-biotin complexsolution (1:50) for 1 hr at 21°C. The protein-antibody complexeswere detected by a color reaction with diaminobenzidine-H₂O₂.In some sections, specific nNOS staining was intensified by a1 min incubation with nickel chloride-enhancing solution. Sectionswere then washed, mounted, air-dried, dehydrated with alcoholfollowed by xylene, and coverslipped with Permount. In parallelcontrol sections, the anti-nNOS antibody was omitted from thestaining procedures, and no positive staining wasobserved.

Statistical analyses. Statistical analyses were performed using the unpaired Student's t test and the Mann-Whitney test wheresignificance was indicated by a two-tailed p value < 0.05.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Behavioral effects of nerve injury

As shown in Figure 1, tactile allodynia (reduction in the paw withdrawal threshold to mechanical stimulation) developed innerve-ligated rats by day 4 after the nerve injury. The allodyniapeaked at day 6 and lasted for at least 2 weeks. Comparable pawwithdrawal thresholds (<4 gm), indicative of tactile allodynia,also developed in diabetic rats (data not shown).

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Figure 1. Development of tactile allodynia after L5/6 spinal nerve ligation. Left L5/6 spinal nerve tight ligation was performed in Harlan Sprague Dawley rats, and the paw withdrawal threshold (PWT) to mechanical stimulation was tested daily starting 1 d after the surgery. Data are presented as the means ± SEM from 4 (second week) to 10 (first week) nerve-ligated rats and 10 sham rats.

nNOS mRNA

To elucidate the possible regulation of nNOS at the mRNA level in rat models of neuropathic pain, we examined nNOS mRNA levelsin the spinal cord and DRGs 2 weeks after tight ligation of theL5/6 spinal nerves or after 8 weeks of diabetes. As indicatedin Figure 2A, nNOS mRNA levels were higher in dorsal lumbar thanin ventral lumbar spinal cord, and L4-6 DRG neurons expresseda low level of nNOS mRNA. L1 DRG neurons expressed a high levelof nNOS mRNA, consistent with the high expression level of nNOSprotein in L1 DRG neurons (Steel et al., 1994). Interestingly,nNOS mRNA levels were upregulated ~10-fold in L5/6 DRG of theinjured side compared with those of the contralateral side, whereasnNOS mRNA levels in L4 DRG were slightly upregulated. In contrast,nNOS mRNA levels were not increased in L1 DRG or lumbar spinalcord after nerve ligation, nor was nNOS mRNA upregulated significantlyin L4/5 DRG of diabetic rats (Fig. 2).

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Figure 2. nNOS mRNA level in the spinal cord and DRG of allodynic rats after L5/6 spinal nerve ligation and diabetic neuropathy. Total RNA was extracted from the spinal cord and DRG of Harlan Sprague Dawley rats with allodynia resulting from tight ligation of the left L5/6 spinal nerves (2 weeks) or diabetes (8 weeks). nNOS mRNA was detected by RNase protection assays. A, Representative autoradiograms. Twenty micrograms of total RNA from the spinal cord or total RNA from two (L4, L5/6, and diabetic) or three (L1) DRGs were used for each lane. nNOS bands had a longer exposure time than did cyclophilin bands because of the low abundance of the nNOS mRNA, except for the separate RNase protection of diabetic samples in which lower specific activity of the cyclophilin probe was used. Lanes are labeled 1, for the contralateral side or nondiabetic rats, and 2, for the nerve-ligated side or diabetic neuropathy rats. B, Percentage change of nNOS mRNA in neuropathic tissues compared with control tissues. Data are presented as the means ± SEM from 6 to 10 rats except for the L5/6 DRG samples that are from 4 rats (*p < 0.05 by Student's t test or Mann-Whitney test). Cyclo., Cyclophilin; Diabet., diabetic; Dors., dorsal; Lumb.S.C., lumbar spinal cord; Vent., ventral.

The relationship between nNOS mRNA upregulation and the development of tactile allodynia was examined by comparing the timecourses of injury-induced nNOS mRNA expression in L5/6 DRGs andallodynia onset. Upregulation of nNOS mRNA after the nerve injurywas time dependent, starting 1 d but not 8 hr after the surgery,peaked at day 2, and remained elevated for at least 13 weeks (seeFigs. 3, 7B,C). There was no similar nNOS mRNA increase in DRGneurons from sham-operated rats (Fig. 3B). Thus, DRG nNOS mRNAupregulation precedes the tactile allodynia onset (compare Figs.3B, 1).

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Figure 3. Time-dependent increase of DRG nNOS mRNA in nerve-ligated rats. Total RNA was extracted from two pooled L5/6 DRGs at the designated time after nerve ligation, and nNOS mRNA levels were examined by RNase protection assays as described. A, Representative autoradiography showing nNOS and cyclophilin probes protected by their corresponding mRNAs. nNOS bands had a longer exposure time than did cyclophilin bands because of the low abundance of the nNOS mRNA. Each pair of samples was taken from the same animal on the contralateral side (lane labeled 1) or the nerve-ligated side (lane labeled 2). B, Summarized time-dependent increase of nNOS mRNA after nerve ligation. The fold increase in nNOS mRNA was defined by comparing nNOS band densities in the injury side with those in the contralateral side after taking the ratio of the nNOS band over the cyclophilin band to correct differences in RNA loading. Data are presented as the means ± SEM from four independent experiments. Values at all time points except for that of the sham control are significantly (p < 0.05) different from the value at time 0 as measured by the Student's t test or the Mann-Whitney test.

nNOS protein expression and localization after spinal nerve ligation

The nNOS protein levels after the nerve injury were examined by Western blot analyses 1 week after the nerve ligation. Therewas a 20-fold increase of nNOS in L5/6 DRG neurons on the injuryside compared with that on the contralateral side. No such increasewas observed in dorsal lumbar spinal cord (108 ± 12% on the injuryside compared with that on the contralateral side; n = 9) or inL5/6 DRGs from sham-operated rats (Fig. 4A). Data from immunohistochemicalexperiments indicated that increased nNOS-positive staining ismainly in the small and occasionally medium-size neurons (Fig.5). Quantitative analyses of the immunohistostaining data revealedthat L5/6 DRGs ipsilateral to the nerve injury contain significantly(p < 0.0001) more nNOS-positive cells (11.3 ± 1.4%; three sectionseach from four rats; 2282 cells were counted) than do L5/6 DRGsfrom sham-operated rats (2.2 ± 0.3%; three sections each fromfour rats; 2759 cells were counted).

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Figure 4. Upregulation of nNOS protein in L5/6 DRGs, but not spinal cord, of nerve-ligated animals. Total protein was extracted from two pooled L5/6 DRGs or the dorsal lumbar spinal cord from each side of the animals, and nNOS protein was identified using monoclonal antibodies against rat brain nNOS. A, Representative Western blots. Purified rat brain nNOS was used as a positive control. B, Fold increase of nNOS in neuropathic DRGs compared with contralateral DRGs. Data are presented as the means ± SEM from eight independent experiments (*p < 0.05 by Student's t test or Mann-Whitney test). S.C., Spinal cord.

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Figure 5. Immunohistological staining of nNOS-positive neurons in L5 DRG. Rat left L5 DRGs from 1 week sham-operated (A) or nerve-ligated (B) rats were sectioned and stained for nNOS-positive cells as described. Data shown are representative staining from four rats, and photos were taken using a 40× phase-contrast objective. Immunohistostaining of nNOS-positive neurons in L6 DRGs was similar to that in L5 DRG neurons (data not shown). Arrows indicate nNOS-positive neurons.

Effect of nerve ligation on nNOS mRNA in a rat strain resistant to allodynia development

To examine the linkage between nNOS mRNA upregulation and allodynia development, we examined nNOS mRNA levels 1 week afterthe nerve injury in Holtzman rats, a strain that does not developtactile allodynia (Fig. 6A). Data from RNase protection experimentsindicated an increase of nNOS mRNA in L5/6 DRGs ipsilateral tothe nerve ligation comparable with that seen in the Harlan strain(Fig. 6B,C). The similarity of nNOS mRNA upregulation despitegenetically based differences in the behavioral response indicatesa dissociation between the nNOS mRNA upregulation and the tactileallodynia development after nerve injury.

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Figure 6. Upregulation of nNOS mRNA in L5/6 DRGs after nerve ligation in Holtzman rats, which do not develop allodynia. Total RNA was extracted from two pooled L5/6 DRGs in Holtzman rats 1 week after the nerve ligation, and nNOS mRNA levels were examined by RNase protection assays. A, The paw withdrawal thresholds to mechanical stimulation in the nerve-ligated animals' paws were not significantly different from those in the sham-operated animals' paws (Mann-Whitney test; 4 rats in each group). B, Representative autoradiography shows nNOS and cyclophilin probes protected by the corresponding mRNAs from DRGs of two individual rats. Lanes are labeled 1, for the contralateral side, and 2, for the nerve-ligated side. nNOS bands had a longer exposure time because of the low abundance of the mRNA. Numbers on the left indicate the positions of DNA markers in base pairs. C, Summarized data are from RNase protections shown in B. The fold increase of nNOS mRNA was defined by comparing nNOS band densities in the injury side with those in the contralateral side after taking the ratio of nNOS bands over the cyclophilin bands to correct differences in RNA loading. Data are presented as the means ± SEM from four independent experiments (*p < 0.05 by Student's t test or Mann-Whitney test). Contral., Contralateral.

nNOS mRNA in nerve-ligated rats fully recovered from allodynia

The relationship between nNOS mRNA upregulation and the development and/or maintenance of tactile allodynia was further examinedin nerve-ligated rats fully recovered from the neuropathic painstate. As indicated in Figure 7A, rats developed tactile allodynia1 week after the nerve ligation, recovered gradually in 7 weeks,and achieved a full recovery 9 weeks after the surgery. However,nNOS mRNA levels in L5/6 DRGs ipsilateral to the nerve ligationremained elevated even when the rats were fully recovered fromtactile allodynia (Fig. 7B,C), indicating a dissociation betweennNOS mRNA upregulation and the maintenance of tactile allodyniaafter nerve injury.

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Figure 7. Upregulation of nNOS mRNA in L5/6 DRGs of nerve-ligated rats fully recovered from tactile allodynia. Tight ligation of the left L5/6 spinal nerves was performed in Harlan Sprague Dawley rats, and the paw withdrawal threshold to mechanical stimulation was tested from 1 to 13 weeks after the nerve ligation. Total RNA was extracted from two pooled left L5/6 DRGs from each rat at week 13, and nNOS mRNA levels were examined by RNase protection assays as described. A, Full recovery from tactile allodynia in nerve-ligated rats 9 weeks after the spinal nerve ligation. Data presented are the means ± SEM from four sham control rats and six nerve-ligated rats. B, Representative autoradiography showing nNOS and cyclophilin probes protected by corresponding mRNAs. nNOS bands had a longer exposure time because of the lower abundance of the nNOS mRNA than that of cyclophilin mRNA. Numbers on the left indicate the positions of DNA markers in base pairs. Lanes are labeled 1, for the contralateral side, and 2, for the surgery side. C, Summarized data of RNase protections shown in B. Data analysis was done as described in the legend for Figure 6C. Data are presented as the means ± SEM from four independent experiments (*p < 0.05 by Student's t test or Mann-Whitney test).

nNOS inhibition and allodynia

To examine whether nNOS inhibition could alter the expression of nerve injury-evoked allodynia, we treated nerve-ligated ratsonce daily (50 mg/kg, s.c.) with an nNOS-specific inhibitor, 7-NI,that was started 30 min before the surgery and continued for 6d. In addition, the role of nNOS inhibition on the maintenanceof allodynia was examined by treating allodynic rats with thesame treatment for 3 d, starting on day 11 after the operation.At this dose, 7-NI was shown to inhibit effectively rat brainNOS activity and the allodynia-like response induced by spinalcord ischemia in vivo (Babbedge et al., 1993; Hao and Xu, 1996).No motor deficit was observed in treated rats. As indicated inFigure 8, neither pre- nor postsurgery treatment of 7-NI affectedthe development and/or maintenance of tactile allodynia. Intraperitonealadministration of 7-NI (25-50 mg/kg) also failed to reverse allodyniain nerve-injured rats (data not shown).

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Figure 8. Effects of systemic administration of an nNOS specific inhibitor, 7-NI, on the development and/or maintenance of tactile allodynia in rats after spinal nerve ligation. Preemptive and treatment protocols are indicated, and the paw withdrawal threshold to mechanical stimulation was tested at the designated times. In both cases, control animals were injected with the same volume of peanut oil (vehicle) alone. Similar findings were observed when the drug was administered intraperitoneally. Data presented are the means ± SEM from five (treatment) and six (preemptive treatment) rats.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Our study provides the first evidence to indicate that nNOS expression is upregulated at the messenger RNA level in rat DRG,but not spinal cord, neurons after tight spinal nerve ligation,a model widely used to study neuropathic pain after peripheralnerve injury. This finding is similar to the increase of nNOSmRNA in DRG after sciatic nerve transection (Verge et al., 1992).However, the physiological abnormalities resulting from thesetwo nerve injury models are distinct. Although peripheral axotomyresults in motor deficit and a complete loss of sensation in thepaw ipsilateral to the nerve injury, rats with nerve ligationretain motor function and develop pain syndromes including hyperalgesia,tactile allodynia, and spontaneous pain (Kim and Chung, 1992).Thus, pathways controlling neuropathic pain states are functionaland activated in nerve-ligated animals, permitting us to studythe coupling of nNOS regulation and the development and/or maintenanceof allodynia after nerveinjury.

Our study provides genetic, molecular, and pharmacological evidence indicating that nNOS regulation is not directly linkedto the development and/or maintenance of tactile allodynia. Eventhough upregulation of nNOS mRNA precedes the onset of allodyniaand persists for the duration of the neuropathic pain state innerve-ligated animals (Figs. 1, 3), our study indicates a clearseparation between nNOS upregulation and the development and maintenanceof tactile allodynia after nerve ligation. Nerve-ligated Holtzmanrats, which do not develop allodynia, show a remarkable nNOS upregulationin the DRG (Fig. 6), indicating that nNOS upregulation alone isnot a determining factor of allodynia susceptibility in this species.Rather, other intrinsic factors may underlie the genetic differences.In addition, Harlan Sprague Dawley rats that are fully recoveredfrom tactile allodynia continue to show levels of expression observedin the earlier period when allodynia was present (Fig. 7). Furthermore,our pharmacological data indicate that inhibition of nNOS doesnot prevent or block tactile allodynia (Fig. 8). Thus, our conclusionsare consistent with the hypothesis that there are NO cGMP-independentpathways that mediate nociception when nNOS is inhibited (Ichinoseet al., 1998).

Our findings differ with the conclusion drawn from a recent study showing that treatment with L-NAME partially blocks thedevelopment and/or maintenance of allodynia and suggesting thatNO may be involved in the neuropathic pain process (Yoon et al.,1998). The lack of specificity of drug action from available pharmacologicalagents may contribute to the controversial results of NOS inhibitionon tactile allodynia. In addition, NOS splice variant expression,as in the case of morphine analgesia and tolerance (Kolesnikovet al., 1997), may contribute to the complexity of NOS inhibitionexperiments. Finally, it is possible that NO produced by otherNOS isoforms such as inducible NOS (iNOS) contributes to the developmentand/or maintenance of tactile allodynia. This is supported bythe findings that iNOS mRNA expression was induced in conditionsproducing thermal hyperalgesia (Meller et al., 1994; Grzybickiet al., 1996). However, the slow onset of allodynia after nerveinjury seems inconsistent with the fast induction of iNOS mRNAthat occurs within hours of stimulation (Meller et al., 1994;Grzybicki et al., 1996). In addition, iNOS mRNA was not detectedin DRG neurons (data not shown), nor was its protein found inthe spinal cord (Goff et al., 1998) after spinal nerve ligation.The role of endothelial NOS in nerve injury-induced allodyniaremains to beinvestigated.

Several pathological conditions occur after nerve ligation that may drive nNOS gene expression in DRG. First, nerve ligationor section leads to an initial barrage of afferent activity inthe injured axons, and this is followed over a period of daysto weeks by the development of spontaneous afferent traffic arisingfrom the sprouting nerve terminal (neuroma) and from the DRG ofthe injured axon (Ambron and Walters, 1996). Second, such nerveinjuries result in a loss of materials undergoing retrograde axonaltransport from the normal target organ. Third, nerve injury leadsto the generation of active factors at the injury site that maybe retrogradely transported to DRG. These conditions may haveeither a negative or positive influence on DRG nNOSexpression.

Normal afferent activity and retrogradely transported factors may regulate nNOS expression via a negative feedback inhibitionmechanism. Nerve ligation may interrupt this feedback regulationand therefore result in increased nNOS expression. The slow onsetof nNOS mRNA upregulation after nerve injury seems inconsistentwith the interruption of afferent activity that would occur immediatelyafter the nerve ligation. It is possible that nNOS expressionis controlled by factors derived from peripheral nerves or innervatedtarget tissues. This is supported by three observations. (1) Theslow onset of nNOS upregulation after nerve injury falls in thetime frame of the early phase of nerve regeneration requiringsignals conveyed by retrograde transport after axon injury (Ambronet al., 1995; Ambron and Walters, 1996). (2) The upregulationof nNOS mRNA in our model is similar to that induced by sciaticnerve transection (Verge et al., 1992), and retrograde axonaltransport is interrupted in both models. (3) nNOS mRNA was mildly,but not significantly, upregulated in DRGs from diabetic ratsin which retrograde axonal transport of neurotrophic factors isdiminished but not abolished (Fernyhough et al., 1995, 1998).This hypothesis is in accord with the findings that nerve growthfactor (NGF) is required by peripheral sympathetic ganglion andsensory neurons to maintain their normal functions and is suppliedto ganglion neurons by retrograde axonal transport (Njå and Purves,1978; Verge et al., 1989, 1990; Anderson et al., 1998). Examplesof such feedback regulation include downregulation of the SNSsodium channel subtype in the DRG after axotomy, which is preventedby exogenous NGF administration (Dib-Hajj et al., 1998). Thus,upregulation of nNOS and the subsequent production of NO may serveas a compensatory mechanism for neuronal survival and/or regenerationafter DRG neurons sense the change in axonal transport or nerveinjury. However, the lack of retrograde control may lead to overexpressionof nNOS and subsequent overproduction of NO, which is known tobe neurotoxic, and may result in neurodegeneration (Dawson andDawson, 1996; Dawson et al., 1996).

Alternatively, upregulation of nNOS may result from positive signals derived from increased ongoing afferent activity or activefactors generated in the injured terminal as suggested in otherstudies (Curtis et al., 1993; Yamamoto and Yaksh, 1993; Gunstreamet al., 1995; Ambron et al., 1996). The slow onset of nNOS mRNAupregulation after nerve injury suggests that such change is notregulated directly by the initial injury-induced discharges thatwould reach the cell body immediately after axon injury (Ambronand Walters, 1996). However, it is possible that ongoing injurydischarges could indirectly induce nNOS expression requiring denovo protein synthesis. This hypothesis is supported by the findingsthat expression of transcription factors such as Jun, Fos, andKrox was upregulated and colocalized with the increased expressionof nitric oxide synthase within spinal cord neurons after noxiousstimulation of the rat hindpaw (Herdegen et al., 1994). Similarly,nNOS expression could be regulated by active factors generatedat the site of nerve injury. Examples of such retrograde activefactors include the ciliary neurotrophic factor (CNTF) that promotessurvival of sensory neurons (Barbin et al., 1984; Skaper and Varon,1986; Thoenen, 1991). This factor is released as a "lesion factor"by damage to Schwann cells in the sciatic nerve (Thoenen, 1991)and induces gene expression (Ip et al., 1992). Most interestingly,retrograde axonal transport of this factor by sensory neuronsis enhanced after peripheral nerve injury (Curtis et al., 1993).In fact, nerve CNTF levels are depleted in diabetic rats (Calcuttet al., 1992), perhaps explaining the minimal nNOS induction seenin the presentstudy.

The small but significant increase of nNOS mRNA in L4 DRG neurons after L5/6 spinal nerve ligation is interesting. The L4spinal nerve is the only remaining afferent connection to thespinal cord after L5/6 spinal nerve ligation. The increase ofnNOS mRNA in L4 DRG neurons may reflect adaptive changes, e.g.,peripheral neuronal sprouting leading to expended receptive fields.The lack of nNOS mRNA regulation in diabetic rats suggests thatDRG neurons respond specifically to certain types of pathologicalconditions and that the regulatory pathway for nNOS expressionmay not be markedly altered in diabetes. Taken together, our findingssuggest that nNOS regulation in DRG neurons may play an importantrole in neuroplasticity after nerve injury. However, regulationof nNOS expression is not responsible for the development and/ormaintenance of neuropathicallodynia.

  FOOTNOTES

Received Jan. 20, 1999; revised Aug. 9, 1999; accepted Aug. 12, 1999.

This work was supported by National Institutes of Health Grants F32HL09848 (Z.D.L.) and NS01769 (S.R.C.) and an institutionalgrant from the Howard Hughes Medical Institute, University ofCalifornia, San Diego (S.R.C. and Z.D.L.).
Correspondence should be addressed to Dr. Z. David Luo, Department of Anesthesiology-0818, University of California, San Diego,9500 Gilman Drive, La Jolla, CA 92093-0818. E-mail: zluo{at}ucsd.edu.

Dr. Cizkova's permanent address: Institute of Neurobiology SAS, Soltesovej 6, 040 01 Kosice,Slovakia.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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