Nerve Growth Factor- and Neurotrophin-3-Induced Changes in Nociceptive Threshold and the Release of Substance P from the Rat Isolated Spinal Cord

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Volume 17, Number 21, Issue of November 1, 1997 pp. 8459-8467
Copyright ©1997 Society for Neuroscience

Nerve Growth Factor- and Neurotrophin-3-Induced Changes in Nociceptive Threshold and the Release of Substance P from the Rat Isolated Spinal Cord

Marzia Malcangio, Neil E. Garrett, Simon Cruwys, and David R. Tomlinson
Department of Pharmacology, St. Bartholomew's and the Royal London School of Medicine and Dentistry, Queen Mary and Westfield College, London E1 4NS, United Kingdom

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Acute superfusion of nerve growth factor (NGF; 1-100 ng/ml) through a naive rat spinal cord preparation did not alter basalor electrically evoked release of substance P-like immunoreactivity(SP-LI). In contrast, neurotrophin-3 (NT-3; 1-100 ng/ml), althoughnot modifying SP-LI basal outflow, dose-dependently inhibitedthe electrically evoked, but not capsaicin (10 nM)-induced, releaseof the peptide. This NT-3 (10 ng/ml)-induced inhibition persistedeven in the presence of 100 ng/ml NGF in the perfusion fluid andwas still significant when the evoked release of SP-LI was enhancedby a prolonged in vivo treatment with NGF. Co-superfusion withnaloxone (0.1 µM), but not CGP 36742 (100 µM), a GABA_B antagonist,prevented NT-3 (10 ng/ml) inhibition of SP-LI release. Basal andelectrically evoked release of SP-LI from the rat spinal cordin vitro was not modified 24 hr after single systemic injectionof either NGF (1 mg/kg) or NT-3 (10 mg/kg). At these time intervalsfrom administration, NGF had induced thermal and mechanical hyperalgesiain the rat hindpaw, and NT-3 had induced mechanical, but not thermal,hypoalgesia. NT-3 administered six times over a 2 week period(at 1 mg/kg) did not alter thermal threshold but significantlyreduced electrically evoked release of SP-LI from the spinal cord.An identical treatment regimen with 1 mg/kg NGF induced a significantincrease in evoked release of SP-LI. However, this was not associatedwith a significant hyperalgesia. Although finding that NGF-inducedhyperalgesia does not clearly correlate with changes in the releaseof SP-LI in the spinal cord, this study shows that NT-3 is aninhibitor of SP-LI release and suggests that this mechanism maybe responsible for NT-3-induced antinociception.
Key words: NGF; NT-3; hyperalgesia; hypoalgesia; substance P; spinal cord; adult rat; release

INTRODUCTION

Nerve growth factor (NGF) and neurotrophin-3 (NT-3) belong to a family of neurotrophic factors that also includes NT-4 and-5 and brain derived neurotrophic factor (BDNF) (for review, seeEbendal, 1992). In adult rats, NGF synthesized in peripheral tissuesis retrogradely transported by sensory neurons to the dorsal rootganglia (DRG) (Goedert et al., 1981). NGF binds to trkA receptorson the nerve terminals. Once in the DRG, NGF is responsible forthe maintenance of expression of the nociceptive peptide substanceP (SP) and calcitonin gene-related peptide (CGRP) (Lindsay etal., 1990). It has been recently established that the trkA receptoris expressed in unmyelinated axons derived from small cell bodies,which also express SP and CGRP (Kashiba et al., 1996). Furthermore,in the superficial dorsal horn of the rat spinal cord, trkA-likeimmunoreactivity has been found in lamina II (Molliver et al.,1995), which constitutes the first synapse in nociceptive pathways.

NT-3 is retrogradely transported by large, myelinated mechanoceptive and proprioceptive fibers to large-diameter cell bodiesof the DRG, which do not normally contain peptides and terminatein laminae III-VI of the spinal cord (DiStefano et al., 1992;Koliatsos et al., 1993). mRNA for NT-3 has been localized in ratmuscle and motor neurones (Ernfors and Persson, 1991). NT-3 bindingsites have been shown to be present throughout the rat spinalcord (Zhou and Rush, 1994), and immunoreactivity for the NT-3receptor, trkC, has also been reported in the superficial dorsalhorn of the monkey spinal cord (Ardvisson et al., 1994).

Systemic administration of a single dose of NGF induces mechanical and thermal hyperalgesia in adult rats, involving peripheraland central mechanisms (Lewin et al., 1993, 1994). The lattermay include an enhanced release of SP within the dorsal horn ofthe spinal cord, which we have recently demonstrated to occurafter prolonged treatment with NGF (Malcangio et al., 1997). Interestingly,it has also been shown that NT-3 infusion into the midbrain ofadult rats is antinociceptive (Siuciak et al., 1994). This effect,which started 24 hr after infusion and lasted for several days,was shown after continuous infusion of the neurotrophin into themidbrain. An involvement of the serotoninergic system has beensuggested (Siuciak et al., 1994).

The aim of this study was to identify any relationship between effects of NGF or NT-3 on sensitivity to noxious stimulationand the release of the nociceptive peptide SP from the isolatedspinal cord. For this purpose, the effects of single or prolongedsystemic treatment with NGF or NT-3 on the threshold to noxiousstimuli have been investigated. Subsequently, the spinal cordsfrom the same animals have been isolated in vitro for the measurementof basal outflow and electrically and/or capsaicin-evoked releaseof sensory neuropeptides, either in the absence or presence ofsuperfused NGF or NT-3. In a separate set of experiments the effectof acute superfusion of NGF or NT-3 on basal and electricallyevoked release of SP from naive rat spinal cords has also beeninvestigated.

MATERIALS AND METHODS
Neurotrophin administration. Adult male Wistar rats (starting weight, 250-300 gm; Charles River) were used throughout thestudy. For single injection studies rats received either humanrecombinant NGF (Genentech, South San Francisco, CA) dissolvedin saline at a dose of 1 mg/kg intraperitoneally or NT-3 (Regeneron)dissolved in 0.01 M PBS, pH 7.4 (to improve stability) at dosesof 1, 10, and 20 mg/kg intraperitoneally. Control rats receiveda single injection of saline intraperitoneally. For chronic dosingstudies rats were injected subcutaneously at the back of the neckwith either NGF or NT-3 at 1 mg/kg three times a week for 2 weeks.Control rats received subcutaneous saline. Animals were kept insawdust-lined cages (three or four per cage) at an ambient temperatureof 20-25°C under a 12 hr light/dark cycle. Food and water wereavailable ad libitum. Animals were quarantined for 7 d beforeany experiments were performed.

Nociceptive testing. All experiments were performed in a blind manner in which the investigator (M.M. for the plantar testand S.C. for the paw pressure test) was not aware of the injectedagent. The thermal nociceptive threshold to radiant heat was quantifiedusing the paw withdrawal test (Hargreaves et al., 1988). Briefly,rats were placed in a Perspex enclosure without restraint, anda movable infrared radiant heat source was placed directly underthe plantar surface of the hindpaw (Ugo Basile). The paw withdrawallatency (PWL) to radiant heat was defined as the time from onsetof the radiant heat to the withdrawal of the rat hindpaw. Theradiant heat source was adjusted to result in preinjection latenciesof 12-14 sec. Testing was performed at 30 min and 2, 4, 6, and24 hr after injection in acute studies and 1, 24, 48, and 72 hrafter each injection in chronic studies. Testing was alternatedbetween hindpaws and performed at 3 min intervals. The averageof three estimations was taken to yield a mean PWL. Before anytesting was performed, rats were allowed to adjust to their environmentsfor at least 10 min. The mechanical nociceptive threshold wasquantified using an Analgesy meter (Ugo Basile). This instrumentgenerates a mechanical force that increases linearly with time.The force is applied directly to the dorsal surface of the rathindpaw via a cone-shaped plunger. The nociceptive threshold isdefined as the force, in grams, at which the rat attempts to withdrawits paw (cutoff force, 150 gm). Rats were trained by using repeatedpaw withdrawal tests on the previous day before experimentation.A single estimation was made for each rat at each time point.Testing was performed at 1, 3, 6, 24, and 48 after injection.In all cases preinjection values were subtracted from values obtainedat the specified time points after NGF, NT-3, or saline administration.These differences were used for subsequent statistical analysis.

Release of endogenous substance P from the dorsal horn of the rat spinal cord. Horizontal spinal cord slices were obtainedfrom naive and saline-, NGF-, or NT-3-treated rats, as describedpreviously (Malcangio and Bowery, 1993, 1994, 1996b). Hemisecteddorsal lumbosacral slices (350-400 µm thick to ensure adequateoxygenation) with L4 and L5 dorsal roots attached were isolatedand mounted in a three-compartment bath. The slice (0.5 cm long)was continuously superfused with oxygenated (95%O₂ and 5% CO₂)Krebs' solution (in mM: NaCl, 118; KCl, 4; MgSO₄, 1.2; KH₂PO₄,1.2; NaHCO₃, 25; CaCl₂, 2.5; and glucose, 11) at 1 ml/min at roomtemperature. Although spinal cord slices have been kept alivefor as long as 50 hr at 18-20°C (Kerkut and Bagust, 1995), ithas been recently reported that CGRP release from spinal cordprisms induced by either capsaicin or potassium ions was higherat 40°C than at 20°C (Dirig et al., 1997). However, our conditions(room temperature) were chosen to obtain a submaximal increasein peptide content in the stimulated fraction, which could bepharmacologically manipulated. The flow rate of superfusing solutionis crucial to avoid any risk of hypoxic damage for the nerve cellsin the inner region of the slice. Rates of 0.5-2 ml/min have beensuccessfully used for release experiments (Kangrga and Randic,1990; Andreeva and Rang, 1993; Malcangio and Bowery, 1993). Thedorsal roots were sealed across a leak-proof partition of high-vacuumgrease (Dow Corning Corp., Midland, MI) into the lateral compartments.On each side two lumbar roots were draped on pairs of bipolarplatinum electrodes and compartments filled with mineral oil toavoid dehydration (Aldrich, Milwaukee, WI). After 1 hr equilibration,normal Krebs' solution was substituted with modified Krebs' solutioncontaining 0.1% bovine serum albumin (BSA; Sigma, Poole, UK),100 µM captopril (Sigma), 1 µM phosphoramidon (Sigma), 20 µg/mlbacitracin (Sigma), and 6 µM dithiothreitol (Sigma). The presenceof protease inhibitors and antioxidant was essential for determiningbasal outflow of substance P-like immunoreactivity (SP-LI), whichappears to vary between preparations. After 16 min, samples ofsuperfusates were collected (8 min collection time) in aceticacid (0.1N) before, during, and after stimulation of the dorsalroots and/or superfusion of drugs. The stimulation parametersused to examine the electrically evoked release of SP-LI were20 V, 0.5 msec at 1 Hz for 8 min, and the stimulating currentwas 12.3 ± 1.3 mA. The voltage dependency of SP-LI release inthis preparation has been established previously, and, as expected,at voltages of <10 V at which C fibers are not likely to be activated(Kangrga and Randic, 1991), no significant release of SP-LI wasobserved (Malcangio and Bowery, 1993). Furthermore, the 80% reductionin evoked release of SP-LI from spinal cord of rats neonatallytreated with capsaicin suggested that unmyelinated fibers werethe major source of this peptide in this preparation (Teoh etal., 1996).

Acute superfusion of neurotrophins. Modified Krebs' solution was used to dilute NGF stock solution (4.69 mg/ml in saline)and to dissolve NT-3. Superfusates were collected in the followingorder to evaluate the effect of acute superfusion: two fractionsto measure basal outflow of SP-LI, one fraction in the absence(control) or presence of NGF and/or NT-3, one fraction in thepresence or absence (control) of neurotrophins to measure electricallyevoked release of SP-LI, and three fractions to measure the returnto basal levels. When spinal cords from rats treated chronicallywith either NGF or NT-3 were used, fractions were collected inthe following order; three fractions to measure basal outflow,one fraction to assess electrically evoked release of SP-LI, andthree fractions to assess recovery to basal values. In some experiments,two more fractions were collected to measure capsaicin-inducedrelease of SP-LI and CGRP-LI. Capsaicin (1 µM) was superfusedfor the initial 2 min of the first fraction. In previous studiesthis concentration of capsaicin was able to induce a sixfold increasein SP-LI content, although the dorsal roots had been electricallystimulated previously (Malcangio and Bowery, 1993), suggestingthat capsaicin-sensitive pools were still available for releasingSP-LI. In contrast, electrical stimulation of the dorsal rootswas not effective after capsaicin superfusion, indicating thatthese SP-LI pools were the same activated by capsaicin (M. Malcangio,unpublished data).

In another set of experiments SP-LI release from isolated spinal cords was induced by superfusing capsaicin (1 nM-1 µM) forthe initial 2 min of an 8 min fraction at 1 ml/min. The effectof co-superfusion of NT-3 (100 ng/ml) on capsaicin (10 nM)-inducedrelease of SP-LI was then evaluated. Eight min superfusates (8ml volume) were collected in the following order: two fractionsto measure basal outflow of SP-LI, one fraction in the absence(control) or presence of NT-3, one fraction with or without (control)NT-3 in the presence of capsaicin for the initial 2 min, and threefractions to measure the return to basal levels.

At the completion of some experiments the spinal cord slice was blotted and weighed, and SP-LI and CGRP-LI were extracted.The tissue was immersed in glacial acetic acid for 1 hr, heatedin a boiling water bath for 15 min, homogenized, and centrifuged(12,000 rpm for 20 min), and the supernatant was collected.

Extraction and assay of SP-LI and CGRP-LI. Samples were partially purified and desalted by using 100 mg Sep-Pak C₁₈ reverse-phasesilica gel cartridges (Waters Associates, Watford, UK). Cartridgeswere first washed with 5 ml of acetonitrile (100%; HPLC grade;BDH Chemicals, Poole, UK) followed by 2 ml of trifluoroaceticacid 0.1% (TFA; HPLC grade; BDH). Samples were then loaded intothe column followed by 3 ml of TFA. Peptides were eluted using2 ml of 80% acetonitrile in 0.1% TFA (recovery, 90%). The eluateswere dried by evaporation at 55°C under nitrogen and stored at $-$ 70°C until they could be assayed for SP-LI or CGRP-LI contentby radioimmunoassay (1 fmol/tube sensitivity for both peptides)using the scintillation proximity technique (Amersham, Buckinghamshire,UK) as described previously (Malcangio and Bowery, 1993, 1996b;Malcangio et al., 1997). Rabbit antiserum against SP was mostreactive with the whole SP undecapeptide but showed no reactionwith N-terminal fragments and neurokinin A or B (Amersham). Antiserumagainst CGRP was specific for rat, showing only 35% cross-reactivitywith human CGRP (Peninsula Laboratories, Belmont, CA).

Data calculation and statistical analysis. The data are presented as mean ± SEM. ANOVA, Mann-Whitney U test, and Student'st test were used when appropriate. In Figures 3 and 4, areas underthe curves were calculated, and means were compared by Student'st test.
Fig. 3. Effect of single administration of saline (n = 5), NGF (n = 3), or NT-3 (n = 4) on the release of SP-LI from the rat spinalcord in vitro. Spinal cords were isolated 24 hr after injections.SP-LI release was induced by electrical stimulation of the dorsalroots for 8 min. Stimulus-evoked release (area under the curve)was not significantly different for the three treatments.
[View Larger Version of this Image (21K GIF file)]

Fig. 4. Effect of prolonged administration of either saline (n = 5) or NT-3 (1 mg/kg, s.c., 3 times a week for 2 weeks; n = 7) onSP-LI release from the rat spinal cord in vitro. SP-LI releasewas evoked by electrical stimulation of the dorsal roots for 8min (horizontal black bar) of spinal cord preparation isolated24 hr after last injection of NT-3. *p < 0.05, Student's t testbetween femtomoles of SP-LI present in the stimulated fractionafter subtraction of the basal outflow of control and NT-3-treatedspinal cords (see Results). The areas under curves were not significantlydifferent.
[View Larger Version of this Image (16K GIF file)]

RESULTS

Effect of in vitro spinal cord superfusion with NGF and NT-3 on SP-LI release
Because both trkA and trkC receptors have been reported to be present in the dorsal horn of the spinal cord (see the introductoryremarks), the effect of their activation on SP-LI release hasbeen investigated by slice superfusion with NGF and NT-3. Whencontrol slices were mounted, electrical stimulation of attacheddorsal roots caused a significant increase in SP-LI content inthe superfusates (fourth and fifth fractions) over the peptidebasal outflow (initial three fractions) (Fig. 1A). The presenceof NT-3 (100 ng/ml) in the superfusion fluid, one fraction beforeand during stimulation of the dorsal roots (third and fourth fractions)(Fig. 1A), significantly inhibited the evoked SP-LI release (fourthfraction) without changing the basal outflow (third vs first andsecond fractions) (Fig. 1A). The effect of NT-3 (1-100 ng/ml)was concentration-dependent (Fig. 1B). Addition of NT-3 (100 ng/ml)to the electrically stimulated fraction after collection did notmodify SP-LI content, excluding that specific binding of the neurotrophinto the released SP could be responsible for the observed inhibition(data not shown). Superfusion of spinal cord slices with NGF (1-100ng/ml) did not modify either electrically evoked release of SP-LI(Fig. 1C) or basal outflow of the peptide (see legend to Fig.1C).
Fig. 1. A, Effect of NT-3 superfusion on electrically evoked SP-LI release from the rat spinal cord in vitro. NT-3 (n = 6) was presentin the 8 min fraction before stimulation and during 8 min stimulationof dorsal roots (20 V, 0.5 msec at 1 Hz, horizontal black bar).Eight preparations were used as controls. B, NT-3 dose-responseeffect on the release of SP-LI. NT-3 (1-100 ng/ml) was superfusedin the 8 min fraction before and during 8 min stimulation. Valueswere obtained from at least five preparations and are expressedas femtomoles present in the stimulated fraction after subtractionof the basal outflow: 10.7 ± 0.86 fmol/8 ml fraction in controls(n = 8) (mean value of the first three collected fractions); 14.4± 2.0 fmol/8 ml fraction in the first two fractions collectedbefore NT-3; and 17.6 ± 2.4 fmol/8 ml fraction in the fractioncollected in the presence of NT-3 (100 ng/ml) (n = 6). *p < 0.05versus controls, Mann-Whitney U test. C, Effect of topical applicationof NGF on the release of SP-LI from the rat spinal cord in vitro.NGF (1-100 ng/ml) was superfused in the 8 min fraction beforestimulation and during 8 min stimulation of the dorsal roots.Values were obtained from at least three preparations and areexpressed as femtomoles present in the stimulated fraction aftersubtraction of the basal outflow: 13.8 ± 1.8 fmol/8 ml fractionin controls (n = 3); and 14.6 ± 4.5 fmol/8 ml fraction in NGF(100 ng/ml) (n = 6).
[View Larger Version of this Image (17K GIF file)]

To assess the selectivity of NT-3 effect on electrically evoked release of SP-LI, which is likely to be dependent on activationof voltage-sensitive calcium channels (VSCCs), SP-LI release wasalso induced by capsaicin superfusion through the isolated spinalcord. Capsaicin action seems not to be mediated by activationof VSCCs, and it is blocked by the inorganic dye ruthenium red(for review, see Maggi, 1991). After a 2 min capsaicin superfusion(1 nM-1 µM) the peptide content in the superfusate was increasedover basal content (7.3 ± 1.1 fmol/8 ml fraction; n = 22) by 62.5± 10.6 fmol/8 ml fraction at 1 µM (n = 6; p < 0.001), 44.2 ± 5.0fmol/8 ml fraction at 100 nM (n = 3; p < 0.001), 13.5 ± 2.6 fmol/8ml fraction at 10 nM (n = 4; p < 0.05), and 4.65 ± 1.0 fmol/8ml fraction at 1 nM (n = 3; n.s.). The presence of NT-3 (100 ng/ml)in one fraction before capsaicin and in the whole fraction inwhich capsaicin (10 nM) was only superfused for the initial 2min did not reduce SP-LI release (fmol/8 ml fraction; n = 10.4± 1.0; n = 6).

These data indicate that activation of trkC, but not trkA receptor in the dorsal horn of the spinal cord, can selectivelymodulate the electrically evoked release of SP-LI.

Effect of NGF on NT-3-induced inhibition of SP-LI release from the spinal cord
To ascertain whether activation of trkA receptor could modify NT-3-induced inhibition of evoked release of SP-LI, NGF (100ng/ml) was co-superfused with NT-3 (10 ng/ml) before and duringstimulation of the dorsal roots. The presence of NGF in the superfusionfluid did not prevent the NT-3 effect (Fig. 2A). To increase theamount of SP-LI, which could be released after electrical stimulationof the dorsal roots, rats were treated with six injections ofNGF (1 mg/kg) over 2 weeks, and 24 hr after the last injectiontheir spinal cords were isolated in vitro. SP-LI release was doubledin NGF-treated spinal cords compared with controls (Fig. 2B).Basal outflow of the peptide was also increased (see legend toFig. 2B). Interestingly, acute NT-3 (10 ng/ml) superfusion throughspinal cord slices obtained from NGF-treated rats inhibited theNGF-induced increase in evoked SP-LI (Fig. 2B).
Fig. 2. A, Effect of superfusion of NGF (100 ng/ml) and NT-3 (10 ng/ml) separately or in combination on SP-LI release from the spinalcord. NGF and NT-3 were present in the 8 min fraction before stimulationand during 8 min stimulation of the dorsal roots. Values wereobtained from three to six preparations and are expressed as femtomolesof SP-LI present in the stimulated fraction after subtractionof the basal outflow: 11.7 ± 0.8 fmol/8 ml fraction in controls(n = 4); 10.5 ± 2.1 fmol/8 ml fraction in NGF (100 ng/ml) (n =5); 11.3 ± 1.7 fmol/8 ml fraction after NT-3 (10 ng/ml) (n = 3);and 11.5 ± 1.3 fmol/8 ml fraction after NT-3 and NGF (n = 5).B, Effect of topical application of NT-3 (10 ng/ml) on electricallyevoked release of SP-LI from the spinal cord of rats previouslyinjected with either saline or NGF (1 mg/kg, s.c., 3 times a weekfor 2 weeks). Dorsal roots were electrically stimulated for 8min. Values were obtained from at least five preparations andare expressed as femtomoles of SP-LI present in the stimulatedfraction after subtraction of the basal outflow: 6.4 ± 0.5 fmol/8ml fraction in controls (n = 5); 10.3 ± 1.7 fmol/8 ml fractionin NGF-treated rats (n = 4); 6.6 ± 0.2 fmol/8 ml fraction (n =5) in NT-3 alone; 10.8 ± 1.5 fmol/8 ml fraction (n = 5) afterNGF and NT-3. *p < 0.05, Mann-Whitney U test versus each of threegroups. C, Effect of co-superfusion with NT-3 (10 ng/ml) of CGP36742 (100 µM) or naloxone (0.1 µM) on SP-LI release from thespinal cord. Drugs were present in the 8 min fraction before stimulationand during 8 min stimulation. Values were obtained from a totalof 22 preparations and are expressed as femtomoles present inthe stimulated fraction after subtraction of the basal outflowSP-LI, which was 11.2 ± 2.3 fmol/8 ml fraction (n = 22) and wasmodified by neither CGP 36742 nor naloxone. *p < 0.05 versus controls,Mann-Whitney U test.
[View Larger Version of this Image (16K GIF file)]

These data indicate that NT-3 is not likely to exert its effect on SP-LI release through an activation of the trkA receptor,which has been localized on SP-containing terminals (Kashiba etal., 1996).

Effect of CGP 36742 and naloxone on NT-3 induced inhibition of SP-LI from the spinal cord
To reverse NT-3 action, antagonists at receptors of two major inhibitory systems in the spinal cord, the GABA_Bergic and opioidsystems, which are known to modulate SP release negatively (Goand Yaksh, 1987; Malcangio and Bowey, 1993), have been used. TheGABA_B antagonist 3-aminopropyl-n-butyl phosphinic acid (100 µM)co-superfused with NT-3 (10 ng/ml) did not change NT-3-inducedinhibition of evoked SP-LI release from naive rat spinal cord(Fig. 2C). This concentration of the antagonist, which did notalter evoked SP-LI release, has been previously shown to be effectivein preventing the inhibition of evoked SP-LI release induced bythe GABA_B agonist baclofen (Malcangio and Bowery, 1993). However,the GABA_Bergic system appears to be activated in situations suchas chronic inflammatory pain to counteract the enhanced releaseof SP in the spinal cord (for review, see Malcangio and Bowery,1996a). Thus, it is not surprising that a GABA_B receptor antagonistdid not modify the effect of NT-3 in normal rat spinal cord. Incontrast, the opioid antagonist naloxone (0.1 µM), at a concentrationthat was without effect on evoked SP-LI release, prevented NT-3-inducedinhibition of the release of this peptide (Fig. 2C).

These data indicate that NT-3-induced inhibition of evoked release of SP-LI is reversible by naloxone but not by a GABA_B receptorantagonist.

The subsequent aim was to evaluate whether these in vitro observations could be confirmed by in vivo experiments in whichNT-3 was systemically injected and the spinal cords were isolated24 hr after either single or prolonged administration.

Effect of single systemic injection of NGF and NT-3 on SP-LI release from the spinal cord in vitro
Administration of a single systemic dose of NGF (1 mg/kg) or NT-3 (10 mg/kg) induced no change in either basal outflow orelectrically evoked release of SP-LI from the spinal cord removedand studied 24 hr after injection (Fig. 3). At this time intervalafter administration, NGF-treated rats had developed both thermaland mechanical hyperalgesia, and NT-3 rats had developed mechanical,but not thermal, hypoalgesia (see subsequent sections).

Effect of prolonged treatment with NT-3 on the release of SP-LI from isolated spinal cords
Prolonged treatment of rats with NT-3 (1 mg/kg, s.c., each dose; six doses over 2 weeks) inhibited the electrically evokedrelease of SP-LI (in fmol/8 ml fraction: controls, 18.2 ± 1.3;NT-3, 10.7 ± 1.9; p < 0.05; see Fig. 4) without changing the basaloutflow of the peptide. Capsaicin-induced release of SP-LI andCGRP-LI was not significantly changed in NT-3-treated spinal cordscompared with controls (Table 1). The total content of both peptidesin the dorsal horn slices was not significantly reduced in NT-3-treatedcompared with saline-treated rat spinal cords (Table 1).

Table 1. Effect of prolonged treatment with NT-3 (1 mg/kg, s.c., three times a week for 2 weeks) on capsaicin-induced SP-LI and CGRP-LIrelease and on peptide total content in the spinal cord preparation

Treatment n Capsaicin-induced release of SP-LI (fmol/ml) Capsaicin-induced release of CGRP-LI (fmol/ml) SP-LI total content (fmol/mg tissue) CGRP-LI total content (fmol/mg tissue)

Saline 5 10.0 ± 1.9 20.9 ± 4.7 94.3 ± 26.8 128.8 ± 28.4

NT-3 7 8.3 ± 2.6 15.8 ± 6.2 77.3 ± 18.5 100.0 ± 14.5

Capsaicin (1 µM) was superfused for 2 min of 16 min collection of 16 ml perfusates. To determine the peptide total contents,each slice was extracted in glacial acetic acid (see Materialsand Methods). The tissue weights were 30 ± 3.5 mg (n = 12).

Effect of a single administration of NGF or NT-3 on rat thermal and mechanical thresholds
In an attempt to correlate the observed effects of NGF and NT-3 on the release of the nociceptive peptide SP, with potentialchanges in nociceptive sensitivity, the effect of single or prolongedadministration of the neurotrophins on thermal and mechanicalthresholds were evaluated. In the plantar test, the overall meanpreinjection PWL values to noxious heat stimuli were 12.9 ± 0.68sec (n = 32). For each rat, preinjection PWLs were subtractedfrom PWL values obtained at various intervals after the administrationof NGF or NT-3, and the differences are reported in Figure 5A.The injection of saline induced only minor numerical changes inPWL values, none of which were significant, at 30 min and 2, 4,6, and 24 hr time intervals (see Fig. 5A). A single systemic injectionof NGF (1 mg/kg) induced a significant decrease (p < 0.05) inPWL scores (compared with controls) as early as 30 min after injection.The effect was still significant (p < 0.05) 24 hr after injection(Fig. 5A). Systemic administration of NT-3 (1 mg/kg) significantlyreduced PWL 30 min after injection. Thereafter, no change in PWLwas observed at time intervals up to 24 hr after injection (Fig.5A). Administration of a higher dose of NT-3 (10 mg/kg) did notalter the rat thermal threshold (data not shown). Co-administrationof NGF and NT-3 reduced PWL scores to the same extent as NGF aloneat 30 min and 2, 4, and 24 hr after injection (Fig. 5A). However,at the 6 hr time point, co-administration of the two neurotrophinsreduced PWL scores significantly more than NGF alone (Fig. 5A).
Fig. 5. A, Effect of a single intraperitoneal administration of saline (n = 6), NGF (n = 8), or NT-3 separately (n = 9) or in combination(n = 9) on rat PWL in the plantar test. NGF and NT-3 were injectedimmediately after determination of preinjection latencies. Valuesare mean ± SEM of PWLs at various intervals after subtractionof preinjection PWLs. *p < 0.05 versus controls, Mann-WhitneyU test. B, Effect of single intraperitoneal administration ofNGF or NT-3 on the threshold to mechanical stimulation. Saline(n = 5), NGF (n = 5), and NT-3 at 1 mg/kg (n = 5), 10 mg/kg (n= 10), and 20 mg/kg (n = 5) were injected immediately after preinjectionthreshold values were obtained. Values are mean ± SEM of paw pressurethreshold at various intervals after subtraction of preinjectionvalues. *p < 0.05 versus controls, Mann-Whitney U test.
[View Larger Version of this Image (31K GIF file)]

In the paw pressure test, the overall mean preinjection thresholds to noxious mechanical stimuli were 74.0 ± 0.7 gm (n = 30).For each rat, preinjection paw pressure thresholds were subtractedfrom thresholds obtained at various intervals after the neurotrophininjections, and the differences are reported in Figure 5B. Singlesystemic administration of NGF (1 mg/kg) significantly reduced(p < 0.05) paw pressure threshold, but only 24 hr after injection.The effect was still significant (p < 0.05) 48 hr after injection(Fig. 5B). NT-3 injection at 1 mg/kg caused a decrease in pawpressure threshold 6 hr after injection; at 10 and 20 mg/kg NT-3caused a decrease in paw pressure threshold 1 and 6 hr after injection(Fig. 5B). Then a significant increase in mechanical thresholdwas detected 24 hr after injection of 10 and 20 mg/kg NT-3. Theseeffects were absent in tests made at 48 hr after injection.

Effect of prolonged treatment with NGF and NT-3 on rat threshold to thermal stimulation
The first of six injections of NGF to rats (1 mg/kg) induced a significant decrease (p < 0.05) in PWL compared with saline-treatedrats at 1 and 24 hr time intervals (see Fig. 6A,B, respectively).The hyperalgesia that developed 1 hr after the first injectionof NGF persisted at this 1 hr interval after each of the followingfour injections of NGF and disappeared after the sixth injection(Fig. 6A). A tendency to a decreased threshold compared with controlswas observed at the 24 hr intervals in rats repeatedly treatedwith NGF (Fig. 6B). However, this effect never reached statisticalsignificance until 24 hr after the last (sixth) injection, whena significant decrease (p < 0.05) in PWL compared with controlswas observed (Fig. 6B). It is worth noting that 30 min after thesecond injection of NGF, rats presented a typical immunologicalreaction, showing swollen noses and paws, red ears, and rednessat the tip of the tail. These effects were less marked after thethird injection and did not show afterward.
Fig. 6. Effect of prolonged administration of saline (n = 6) or NGF (1 mg/kg, s.c., 3 times a week for 2 weeks; n = 8) on PWL in theplantar test. A, The first dose was injected immediately afterpreinjection latencies were determined, and PWLs were subsequentlydetermined 1 hr after each of six injections. B, PWLs were determinedbefore (B) and 24 hr after (A) each of six injections. *p < 0.05versus controls, ANOVA.
[View Larger Version of this Image (29K GIF file)]

Prolonged administration of NT-3 to rats (1 mg/kg) did not modify the threshold to thermal noxious stimulation. In controls(n = 9) PWL was 13.3 ± 1.6 sec before injections began and 12.2± 0.8 sec after 2 weeks of saline injections; in the NT-3 group(n = 9) PWL was 11.7 ± 0.4 before treatment and 10.5 ± 0.6 secafter 2 weeks of NT-3 treatment. No effects on behavior and noimmunological responses were noted. After either single or prolongedadministration of NT-3 the body weight of the treated animalsincreased at the same rate as the controls over the course ofthe experiment. There was no apparent muscle tone weakness ormotor dysfunction assessed by general observation. The generalexploratory behavior of the rats on removal from the cages wasunchanged.

DISCUSSION

NGF-induced changes in pain threshold and release of SP-LI from the spinal cord
This study confirms that single systemic administration of NGF to the rat induces thermal and mechanical hyperalgesia (Lewinet al., 1993). Thermal hyperalgesia developed as soon as 30 minafter injection (early component) and persisted for up to 24 hr(late component), whereas mechanical hyperalgesia started 24 hrafter injection and persisted for up to 48 hr. After these acutechanges, prolonged administration of NGF is associated with areturn to normal thermal nociceptive sensitivity. We also showedthat, in contrast to NGF, a single systemic administration ofNT-3, although not affecting thermal threshold, induced significantmechanical hypoalgesia 24 hr after administration. Single co-administrationof NGF and NT-3 induced thermal hyperalgesia to the same extentas NGF alone.

The early component of NGF-induced thermal hyperalgesia may be attributed to both activation of the autonomic nervous system(Andreev et al., 1995) and sensitization of peripheral nociceptorterminals (Lewin et al., 1994; Apfel et al., 1995). Mechanismsresponsible for NGF-induced late thermal hyperalgesia appearedto involve the activation of central NMDA receptors for glutamateand peripheral bradykinin B₁, but not substance P-neurokinin (SP-NK₁)receptors (Lewin et al., 1994; Rueff et al., 1996). Thompson etal. (1995) showed that a single systemic injection of NGF in ratsinduces delayed changes in the nociceptive spinal reflexes, whichinvolve NK₁ receptor activation. This was attributed to a possibleincrease in centrally released SP within hours of NGF administration.However, this supposition is not supported by the present study,in which both thermal and mechanical hyperalgesia reached theirmaximum 24 hr after NGF administration, when the release of SP-LIfrom the isolated spinal cord was not different from that fromcords of saline-treated rats. Furthermore, prolonged administrationof NGF to rats has been reported to increase both basal outflowand electrically evoked release of SP-LI from the spinal cord(Malcangio et al., 1997). Surprisingly, this enhanced availabilityof SP within the spinal cord after NGF treatment did not correspondto a prolonged thermal hyperalgesic effect. By contrast, ratsdeveloped tolerance to both early and late components of NGF-inducedthermal hyperalgesia. Among the several systems that could accountfor tolerance to early NGF-induced hyperalgesia, depletion ofhistamine from mast cells may play a major role. Furthermore,a downregulation of central NK₁ receptors attributable to theincreased SP levels might have occurred and would explain ratreduced sensitivity to noxious stimulation during NGF treatment.A speculative explanation for NGF-induced tolerance to the latecomponent of its hyperalgesic effect could be that during thetreatment, an increase in BDNF expression occurs in the dorsalhorn (Priestley et al., 1996). Intrathecally administered BDNFhas been reported to induce antinociception (Siuciak et al., 1994)and thus may counteract the pronociceptive effect of NGF. In contrastwith our findings, it has been previously reported that dailyinjection of NGF for 4 d does not modify the mechanical hyperalgesiainduced by the first dose, thus suggesting that there were nocumulative effects, and tolerance did not develop (Lewin et al.,1993). An explanation for this discrepancy may stem from the differentprotocols used for the prolonged treatment, the administrationof human recombinant NGF rather that NGF extracted from mousesalivary glands and, possibly, the fact that thermal rather thanmechanical thresholds were monitored.

NT-3 effects on pain threshold and release of SP-LI from the spinal cord
In contrast to the hyperalgesic action of NGF, a single systemic administration of NT-3 (10 and 20 mg/kg) induced a hypoalgesiceffect 24 hr after injection after the induction of mechanicalhyperalgesia at earlier time points. However, as for NGF, theeffect of the nociceptive threshold was not concomitant with changesin evoked release of SP-LI from the spinal cord. The initial mechanicalhyperalgesia after NT-3 injection may be attributable to activationof the autonomic system through an action on trkA receptors bya transient high concentration. NT-3 has been recently shown tomediate sympathetic neuron survival through a regulation of trkAreceptors (Belliveau et al., 1997). NT-3-induced changes in mechanicalthreshold are in line with recent work suggesting that tactilesensation is a target for NT-3 (Airaksinen et al., 1996). Thedoses necessary to detect an antinociceptive effect in this studyseem reasonable in view of the finding that 20 mg/kg NT-3 wasnecessary to prevent pyridoxine-induced neuropathy (Helgren etal., 1997). The slow onset of the antinociceptive effect of NT-3may suggest a central effect, which could involve retrograde transportof NT-3 to the DRG after uptake at peripheral terminals. However,it is not yet known whether NT-3 is transported from DRG to thespinal cord.

Prolonged treatment of rats with NT-3, following a protocol identical to that for NGF, although not changing thermal sensitivity,decreased SP-LI release in the spinal cord. Thus, as is the casewith NGF, NT-3 effects on thermal nociceptive threshold did notcorrelate with SP-LI release. A reduction, although not statisticallysignificant, in capsaicin-induced release of SP-LI and CGRP-LIafter NT-3 treatment was also observed. However, the total contentof both peptides in the spinal cord was not changed. These dataindicate that exogenous NT-3 can influence the release of neurotransmitterscontained in sensory neurons evoked by electrical stimulationof the dorsal roots but not that evoked by capsaicin. This conclusionis substantiated by the lack of effect of acutely superfused NT-3on capsaicin-induced release of SP-LI from the spinal cord.

There is evidence in the rat that myelinated fibers, which do not normally contain peptides, retrogradely transport NT-3 (DiStefanoet al., 1992). Thus a direct effect of NT-3 on SP-containing terminalsis unlikely unless NT-3 interacts with the trkA receptor on nociceptorterminals (Kashiba et al., 1996).

Effect of spinal cord superfusion with NGF and NT-3 on SP-LI release
In contrast to NGF, which was ineffective in vitro, NT-3 acutely superfused through spinal cord slices dose-dependently inhibitedthe evoked release of SP-LI without changing the basal outflow.NT-3-induced inhibition of evoked SP-LI release was not preventedby co-superfusion of NGF. Furthermore, even when evoked SP-LIrelease was enhanced by 2 weeks of in vivo treatment with NGF,NT-3 was still able to depress significantly the evoked releaseof the peptide from central terminals of primary afferents. Thesedata indicate that NT-3 can modulate the release of SP-LI undernormal conditions as well as under conditions of enhanced releasesuch as after treatment in vivo with NGF. If this treatment withNGF mimicked inflammatory conditions, in which mechanical andthermal hypersensitivity are NGF-dependent, it may have inducedexpression of SP in myelinated fibers, which do not normally containthis peptide (Neumann et al., 1996). The release of this extraSP would have occurred under our experimental conditions (in whichelectrical stimulation also recruits myelinated, fast-conductingfibers) and appeared to be inhibited by NT-3. NT-3 has been recentlysuggested to behave as a rapid modulator of synaptic activityin the CNS (Lohof et al., 1993; Kim et al., 1994), and the presentstudy substantiates this possibility. The observation that theeffect of NT-3 was not prevented by an activation of spinal cordtrkA receptors by NGF suggests that an activation of the trkCreceptor may be responsible for the NT-3 effect, and, indeed,these receptor binding sites have been found in the dorsal hornof the monkey (Ardvisson et al., 1994) and rat (J. V. Priestley,personal communication), although their exact localization stillhas to be shown. Unfortunately a direct block of trkC receptorsis not yet feasible because of lack of pharmacological tools.Thus, in an attempt to functionally block NT-3-induced inhibitionof the evoked release of SP-LI, two major systems that inhibitthis release have been considered as potential intermediates:GABA_Bergic and opioid. In this study, naloxone but not CGP 36742superfusion prevented the effect of NT-3, suggesting that enkephalinscontained in dorsal horn neurons may be mediating NT-3-inducedinhibition of SP release.

This study suggests that NGF-induced hyperalgesia may be partly attributable to an increased SP synthesis and consequent releasein the spinal cord, and that NT-3, either systemically injectedor acutely applied to the spinal cord, exerts a direct inhibitoryaction on SP-LI release from primary afferent central terminals(Table 2). In addition, NT-3 induces antinociception 24 hr aftersingle systemic administration. Assuming that the mechanism foran NT-3 antinociceptive effect is the inhibition of SP release,the neurotrophin would have reached the spinal cord only if retrogradelytransported by large fibers. These fibers, once electrically stimulated,could have delivered NT-3 in the vicinity of SP-containing, unmyelinatedfiber terminals in the dorsal horn. A possible target for NT-3appeared the enkephalinergic neurons, the activation of whichwould have in turn reduced the release of SP. However, althoughretrograde transport of peripherally derived NT-3 from targettissue to the cell bodies of primary afferent fibers in the DRGis likely to occur, anterograde transport of the neurotrophinfrom the cell bodies to the central terminals in the spinal cordremains to be shown. Interestingly, anterograde transport of exogenousneurotrophins has been reported in the developing visual system(von Bartheld et al., 1996).

Table 2. Summary of the effects of NGF and NT-3 on rat nociceptive threshold and the release of SP-LI from the isolated spinal cord

Neurotrophin Treatment Thermal threshold Mechanical threshold Electrically-evoked release of SP-LI

In vivo

  NGF Single injection $down-arrow$ $down-arrow$ No effect

  NT-3 Single injection No effect $down-arrow$ , $up-arrow$ No effect

  NGF Prolonged No effect $down-arrow$ ^* $up-arrow$

  NT-3 Prolonged No effect - $down-arrow$

In vitro

  NGF 1-100 ng/ml - - No effect

  NT-3 1-100 ng/ml - - $down-arrow$

  NT-3 + naloxone 10 ng/ml + 0.1 µM - - No effect

  NT-3 + CGP 36742 10 ng/ml + 100 µM - - $down-arrow$

$down-arrow$ , Decrease; $up-arrow$ , increase; -, not measured; $down-arrow$ *, Lewin et al. (1993).

FOOTNOTES

Received April 25, 1997; revised July 30, 1997; accepted Aug. 11, 1997.

N.E.G. is supported by a grant from the British Diabetic Association to D.R.T. We thank Drs Maria de Ceballos and Paul Fernyhoughfor critical reading of this manuscript, Karin Fernandes and LukeHounsom for technical assistance, Novartis (Basel, Switzerland)for the gift of CGP 36742, Genentech (South San Francisco, CA)for the gift of NGF, and Regeneron for the gift of NT-3.

Correspondence should be addressed to Dr. Marzia Malcangio, Department of Pharmacology, Queen Mary and Westfield College,Mile End Road, London E1 4NS, UK.

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