Abstract
Nicotinic agonists, such as epibatidine (EPI) and A-85380, when administered systemically, elicit analgesia. Intrathecal EPI also produces analgesia accompanied by nociceptive and pressor responses. Since spinal administration of drugs offers a well defined pathway connecting the site of administration with behavioral and autonomic responses, we have compared the responses to intrathecal epibatidine and A-85380 to delineate the role of nicotinic acetylcholine receptors in spinal neurotransmission. Following implantation of intrathecal catheters in rats, we monitored cardiovascular, nociceptive, and antinociceptive responses after administration of various nicotinic receptor agonists. Consistent with A-85380 displacement of epibatidine from isolated spinal cord membranes, A-85380 elicited pressor, nociceptive, and antinociceptive responses similar to EPI. Antinociception was preceded by nociception. Both antinociception and nociception were blocked by mecamylamine, methyllycaconitine, and α-lobeline, but dihydro-β-erythroidine only blocked the antinociceptive response. Whereas prior administration of EPI desensitized the nociceptive and antinociceptive responses to EPI, A-85380 pretreatment only desensitized EPI-elicited nociception and not antinociception. 2-Amino-5-phosphopentanoic acid pretreatment blocked the nociceptive response to A-85380, indicating A-85380 stimulated release of glutamate ontoN-methyl-d-aspartate receptors to produce the irritant response of nociception. Intrathecal phentolamine virtually abolished A-85380 antinociception, but had no effect on EPI antinociception. Hence, analgesia can be produced by stimulation of distinct spinal preterminal nicotinic receptor subtypes, resulting in the release of neurotransmitters. In the case of A-85380, these sites primarily appear to be localized on adrenergic bulbospinal terminals. Our data suggest that A-85380 and EPI act at separate preterminal spinal sites as well as on distinct nicotinic receptor subtypes to elicit an antinociceptive response at the spinal level.
Studies examining the role of spinal cholinergic receptor systems have demonstrated that spinal nicotinic acetylcholine receptors appear to play a role in modulating the animal's response to noxious stimuli (Damaj et al., 1998; Khan et al., 1998; Lawand et al., 1999; Xu et al., 2000). Systemic administration of nicotinic receptor agonists, such as nicotine, cytisine, and epibatidine, can induce analgesia as measured by the escape indices in models of thermal, mechanical, and chemical nociception (Bannon et al., 1998; Damaj et al., 1998). The mechanisms underlying these responses to nicotinic receptor agonists are complex, but reflect in part actions at the spinal level. Thus, delivery of these agents to segmental regions of the spinal cord can also produce significant antinociception with its pharmacological response reflecting local stimulation of spinal nicotinic acetylcholine receptors (nAChRs) (Khan et al., 1998; Lawand et al., 1999). This antinociceptive or analgesic response, produced by either systemic or spinally delivered drug is, however, accompanied by significant cardiovascular responses and signs of behavioral agitation (Buccafusco, 1996; Khan et al., 1997, 1998). In recent studies, it has been hypothesized that these cardiovascular and nociceptive responses may be mediated, in part, by distinct populations of spinal nAChRs (Khan et al., 1994a,b,c, 1996b, 1997, 1998; Damaj et al., 1998).
Molecular cloning of nAChRs from rat brain indicates that neuronal nAChRs belong to a multigene family, which includes at least nine α-subunits and four β-subunits (non-α). Transfection of various combinations of these α- and β-subunit genes results in the assembly of functional surface receptors (Boulter et al., 1987;Bertrand et al., 1990). Ligand recognition is associated with an interface of the α-subunit, when associated with a juxtaposing β-subunit interface. In the heteromeric nAChRs, two α-subunits and three of the non-α- or β-subunits associate to form functional pentameric receptors in neuronal tissue (Lindstrom, 2000). Even though not all combinations of α- and β-subunits can form functional receptors, the number of permutations and thus the potential for assembly of various subtypes of neuronal nAChRs is very large.
We have been interested in characterizing the several behavioral and physiological actions of spinal nAChRs with respect to their binding properties, localization, and subunit composition. Recent studies reported that (+)-epibatidine is the most potent nicotinic receptor agonist in eliciting spinal systemic actions. Based on intrathecal delivery studies, epibatidine appears to exert its action through multiple spinal nAChRs systems (Khan et al., 1998). Moreover, specificities of nicotinic receptor antagonists indicate that different subtypes of neuronal nAChRs elicit antinociceptive and nociceptive responses to spinal epibatidine. This is consistent with the binding properties of [3H]epibatidine to spinal cord membranes where more than a single class of receptors with distinct affinities is revealed (Khan et al., 1997). Recently, a synthetic analog of epibatidine, so-called A-85380, has been shown to possess significant analgesic activity when administered systemically (Curzon et al., 1998). This nicotinic receptor agonist is thought to be specific for the α4β2 subtype of neuronal nicotinic receptor (Curzon et al., 1998). Given this subtype specificity and the reported selectivity of effects, we sought to characterize the pharmacology of the physiological and behavioral actions of spinally administered A-85380 in relation to other agonists. The well defined spinal pathways and defined pharmacological end points might enable us to distinguish the sites of action and receptor selectivity of these nicotinic receptor agonists.
Materials and Methods
Experimental Animals
Male Sprague-Dawley rats (300–350 g) were purchased from Harlan Co. (Indianapolis, IN). Animals were housed in the University of California, San Diego (UCSD) animal facility and were maintained on 12-h light/dark cycles. They received standard Purina Rat Chow and water ad libitum. All studies were carried out according to protocols approved by the UCSD Institutional Animal Care Committee.
For spinal drug delivery, intrathecal (i.t.) catheters were implanted as described previously (Khan et al., 1998). Briefly, rats were anesthetized with halothane (2–3%), placed in a stereotaxic frame, and the atlanto-occipital membrane was exposed. A 9-cm saline-filled polyethylene (PE-10) tubing was placed into the intrathecal space through the atlanto-occipital membrane and passed down to the rostral edge of the lumbar enlargement. The catheter was externalized on top of the skull and sealed with a piece of stainless steel wire. The incision was closed and the rats were allowed to recover for at least 5 days before further study. Only animals exhibiting normal motor behavior were used in the study. Animals with impaired motor function or an elevated sensory threshold were euthanized.
Measurement of Arterial Blood Pressure
Five to 6 days following i.t. catheter implantation, rats were reanesthetized with halothane (2–3%) and their tail arteries were catheterized with a PE-50 tube filled with heparin containing saline (1 U/ml). The wound was covered with gauze-tape, and the rats placed in a plastic cylindrical restraining cage. The cage was constructed to enable the animal to maintain a typical crouching posture. The tail artery was connected to a blood pressure transducer coupled to a Gould polygraph. Heart rates were measured using a cardiotachometer triggered from pressure pulses. Rats were allowed to recover for at least 30 min after placement in the cage for administration of drugs. Blood pressure and heart rate were monitored continuously for the duration of the experiment. The cardiovascular parameters were recorded with a Gould polygraph, and the data further analyzed with the aid of Ponemah Physiology Platform-3 (Gould Instruments Systems, Valley View, OH).
Drugs and Their Administration
The following chemicals were obtained from Sigma Chemical Co. (St. Louis, MO): A-85380, cytisine, mecamylamine, α-lobeline, (+)-epibatidine hydrochloride, dihydro-β-erythroidine, methyllycaconitine (MLA), and 2-amino-5-phosphopentanoic acid (AP-5). Sterile saline was used as the vehicle to dissolve the drugs for i.t. administration. Before all testing, an intrathecal catheter was connected to a motor-driven microinjection pump via a length of calibrated PE-50 tubing with each 10-μl compartment separated from the other by a small air bubble to avoid mixture of drugs. For i.t. delivery, drugs were injected in a volume of 10 μl followed by 10 μl of normal saline to flush the catheter over a 10-s interval (pump delivery rate of 60 μl/min.).
Test Measurements
Antinociception.
Analgesia or antinociception was measured according to the experimental protocol described previously (Khan et al., 1998). Briefly, unanesthetized rats were placed in Plexiglas cages (9 × 22 × 25 cm) on top of a glass plate. A thermal stimulus was positioned under the glass to focus the projection bulb on the plantar surface. Initiation of the current to the bulb started a timer. Bulb current and time were automatically terminated when paw elevation was sensed by photodiodes or when an interval of 20 s (cut-off time) had passed. The surface under the glass was maintained at 30°C by a feedback-controlled heater fan. A focused stimulus (stimulus current = 4.8 amp with an escape latency of approximately 9 s) was reliably accomplished by a mirror attached to the stimulus, which permitted visualization of the undersurface of the paw. Light beam intensity was monitored by measurement of bulb current, and the stimulus intensity was calibrated daily by assessing the temperature change after 10 s sensed by an underglass thermocouple (t1/2 = 0.2 s). After placing the rat in the plastic cages for a 20-min adaptation period, the first measurement was conducted on both hind paws, and the response latencies averaged and counted as baseline score (time zero). Tests were then made at 3, 6, 9, 15, 20, 30, 40, 50, and 60 min after injection or for repeated intrathecal injections of drugs at 3, 6, 9, 15, 20, and 30 min after the first injection. After the second injection, testing was performed again at 3-, 6-, 9-, 15-, 20-, and 30-min intervals. Animals remained connected to the injection pump and were not handled during the test sequence.
Nociception and Agitation Behavior
Spontaneous agitation/spontaneous vocalization (SA/SV) was scored on a scale of 0 to 4.5. Scores were measured according to the following scale: 0.5, slight movement of the paws; 1, whole body movement; 1.5, slight twitching; 2, licking of the paws, moderate twitching; 2.5, moderate ambulation; 3, severe twitching, more pronounced ambulation; 3.5, hunchback posture, limited escape behavior; 4, rolling over, intense ambulation, and escape behavior; and 4.5, high-pitched squeaking, frantic ambulation, and escape behavior. Score rankings were directly proportional to the dose of the agonist, and each score represented the corresponding behavioral responses, including those from the lower scores.
Experimental Design
Each rat was used in one or two experiments with a minimum interval of 5 days between injections. Animals were randomly assigned to receive a single dose of the agonist, the antagonist followed by the agonist, or the antagonist or vehicle (normal saline) alone. The antagonist was injected 10 to 15 min before agonist (A-85380, 5 μg) administration followed by a 10-μl saline flush. The doses of the antagonists were selected from previously described studies (Khan et al., 1994b, 1996a, 1997, 1998).
Data Presentation
For thermal antinociception, data are represented as means ± S.E.M. For the time course, each time point represents the latency period in seconds after agonist or vehicle delivery. Thermal latencies were converted to the percentage of the maximum possible effect (%MPE) according to the following formula:
Results
Intrathecal A-85380-Elicited Responses
Similar to other nicotinic receptor agonists, i.t. A-85380 also elicited a dose-dependent nociceptive or agitation response (Fig.1B). Figure2B depicts the temporal agitation response following a 5-μg dose of A-85380. The SA/SV response was of rapid onset and it lasted for about 10 min (Fig. 2B). After this time period, only intermittent agitation responses were observed in the rats. In addition, to the nociceptive response, i.t. A-85380 also exhibited a transient antinociceptive response. This response was also dose-dependent (Fig. 1A). As shown in Fig. 2A, at a 5-μg dose, A-85380 elicited approximately 70% of the MPE. The peak response was observed within 3 min following agonist administration and had a duration of approximately 9 min. The ability of higher doses of A-85380 to elicit analgesia could not be examined, because they would produce unacceptable levels of irritation in the rats.
In addition to the antinociceptive and nociceptive responses, intrathecal A-85380 also resulted in dose-dependent increases in arterial blood pressure (Fig. 1C). The data presented in Fig. 1C are from a different group of rats than those presented in Fig. 1, A and B. As seen for other spinal nicotinic receptor agonists (Khan et al. 1994b, 1996a, 1998), spinal A-85380 also resulted in dose-dependent increases in heart rate (data not shown). The onset of the cardiovascular response was also rapid. It appeared within 1 min following injection and lasted for about 10 to 12 min.
The nociceptive and cardiovascular responses occurred at lower doses of A-85380 than the antinociceptive response. This rank order of responses was similar to that of epibatidine (Khan et al., 1998); however, A-85380 appears to be less potent than epibatidine.
Antagonism of Intrathecal A-85380-Elicited Responses
Nicotinic Antagonists.
To distinguish the receptor specificities of spinal A-85380-elicited responses, various nicotinic receptor antagonists were evaluated on A-85380-evoked responses. As reported previously, the nicotinic receptor antagonists, when administered alone, did not increase the thermal threshold (Khan et al., 1998). Intrathecal administration of the nicotinic receptor channel blocker mecamylamine (50 μg), 10 min before A-85380, completely blocked the antinociceptive and nociceptive responses to 5 μg of A-85380 (Fig. 3, A and B). The pressor (Fig. 3C) and heart rate (data not shown) responses to 0.5 μg of A-85380 were also significantly blocked by mecamylamine pretreatment.
The competitive antagonists α-lobeline, dihydro-β-erythroidine (DβE), and MLA exhibited different selectivities in blocking the antinociceptive and agitation responses to i.t. A-85380 (Figs. 3, A and B). The three antagonists significantly blocked the antinociceptive response to A-85380; however, unlike α-lobeline or MLA, DβE did not antagonize the nociceptive response to the agonist. DβE also did not antagonize the cardiovascular responses to spinal A-85380 (Fig. 3C).
Figure 4, A and B, shows the temporal responses to A-85380-elicited antinociceptive and SA/SV responses following DβE pretreatment. DβE, an α4β2-selective antagonist, not only antagonized the antinociceptive response to A-85380 but also the nociceptive response to A-85380 was enhanced and prolonged over a 20- to 30-min time interval compared with vehicle-pretreated rats. Although α-lobeline and MLA antagonized the antinociceptive response to A-85380, unlike DβE, prior treatment with these two antagonists did not result in hyperalgesia following administration of the nicotinic receptor agonist (data not shown).
Desensitization and Cross-Desensitization
Intrathecal pretreatment with 5 μg of A-85380 resulted in desensitization of antinociceptive, nociceptive, and cardiovascular responses to a subsequent 5-μg dose of A-85380 administered 30 min later (Fig. 5, A–C). Moreover, two consecutive doses of A-85380 significantly desensitized the nociceptive responses to epibatidine. In contrast, the antinociceptive response to epibatidine was marginally reduced by prior doses of A-85380 and not significantly different from saline-treated control rats (Fig.6, A and B). On the contrary, two consecutive doses of 0.5 μg of epibatidine 30 min apart significantly desensitized both the antinociceptive and nociceptive responses to a subsequent 5-μg dose of A-85380 30 min later (Fig. 6, C and D). Similar pretreatment with cytisine (5 μg each) only desensitized the nociceptive response to A-85380 (Fig. 6, E and F). The antinociceptive response to A-85380 appeared to be modestly attenuated following repeated dosing with cytisine, but it was not statistically significant. Analysis of analgesia over time revealed that the peak antinociceptive response to A-85380 (at 3 min) was significantly desensitized by cytisine pretreatment. However, the antinociceptive response, while modest, is sustained for a substantially longer period (Fig. 7). This presumably arises from desensitization of nociception and unmasking of analgesia.
Adrenergic Receptor Antagonists on Intrathecal Nicotinic Agonist Responses
Pretreatment with phentolamine (25 μg i.t.), an α-adrenergic receptor antagonist, significantly inhibited the antinociceptive and nociceptive responses to A-85380 (Fig. 8, A and B). In contrast, phentolamine pretreatment had no significant effects on epibatidine-elicited antinociceptive or nociceptive responses (Fig. 8, C and D). Phentolamine had no effect on the cardiovascular responses to A-85380 (data not shown).
N-Methyl-d-aspartate Antagonism and A-85380 Activity
AP-5 (5 μg i.t.) administered before A-85380 (5.0 μg) did not alter the antinociceptive response of the agonist, but did depress the nociceptive responses (Fig. 9, A–C). Although AP-5 has been demonstrated to block the cardiovascular responses to nicotine, cytisine, and epibatidine (Khan et al., 1996,1997, 1998), it did not have any significant effect on the A-85380-elicited pressor response (Fig. 9C).
Competitive Displacement of [3H]Epibatidine Binding by A-85380
Similar to other nicotinic receptor agonists, A-85380 displaces [3H]epibatidine binding from spinal cord membranes in a dose-dependent manner (Fig.10). The inhibitory dissociation constant of A-853380 for competitively displacing [3H]epibatidine binding from the high-affinity sites was 0.23 nM (the mean from two independentKi measurements of 0.19 and 0.28 nM). The competitive curve for A-85380 shows a shallower slope, suggesting two or more classes of binding sites whose relative affinities for epibatidine and A-85380 are not identical. When compared with theKi values of other nicotinic receptor agonists (Khan et al., 1994, 1997), A-85380 appears to be more potent than cytisine (Ki = 0.56 nM), but less potent than epibatidine (Ki = 0.05 nM) in binding to high-affinity sites of the spinal nAChR.
Discussion
Neuronal nAChRs and Analgesia.
As early as 1932, it was shown that systemic nicotine administration elicits analgesia (Davis et al., 1932). The low efficacy of nicotine in eliciting analgesia and the accompanying side effects precluded its utility as an analgesic agent. Recently, systemic delivery of epibatidine, a neurotoxin obtained from Ecuadorian frog skin, was reported to evoke a robust analgesic response (Badio and Daly, 1994). Importantly, epibatidine elicits significant analgesia after spinal delivery at doses that are not systemically active (Khan et al., 1998; Lawand et al., 1999). However, this antinociceptive response to spinal epibatidine is transient, and accompanied by cardiovascular and nociceptive responses (Khan et al., 1996a, 1997, 1998). The multiple responses produced by (+)-epibatidine appear to be mediated through distinct subpopulations of central nervous system neuronal nAChRs (Khan et al., 1997, 1998; Bannon et al., 1998; Donnelly-Roberts et al., 1998). The diverse responses arising from distinct sites are consistent with binding studies, which suggest nicotinic receptor agonists interact with multiple nicotinic sites.
Similar to the higher centers in the central nervous system, multiple nAChR subunits are expressed in various spinal regions. As noted previously, various α- and β-combinations, with a stoichiometry of 2α and 3β can form functional receptors (Lindstrom, 2000). α4 and β2 subunits are the predominant nAChR subunits expressed in the spinal cord (Wada et al., 1989). In the present studies, we examined the spinal action of a nicotinic receptor agonist, A-85380, reported to produce antinociception systemically through a single nAChR subtype characterized as α4β2 (Curzon et al., 1998).
Intrathecal A-85380-Elicited Responses in Rats.
Systemic A-85380 has been reported to be equally effective as, but less potent than, epibatidine in producing analgesia (Curzon et al., 1998). No other behavioral or cardiovascular responses were reported. Although direct evidence is lacking, it is suggested that systemic A-85380 elicits analgesia via stimulation of neurons in the region of the nucleus raphe magnus in the brain stem (Curzon et al., 1998).
Intrathecal A-85380 elicited the same constellation of behavioral and cardiovascular responses as other intrathecal nicotinic receptor agonists. Like epibatidine, it produced a transient antinociceptive response (Khan et al., 1997, 1998). However, A-85380 was less potent and efficacious than epibatidine in eliciting antinociception in rats. The responses to A-85830 were blocked by i.t. mecamylamine. Moreover, A-85380 displaced [3H]epibatidine binding from spinal cord membranes. The potencies of the various nicotinic receptor agonists in eliciting analgesia indicate epibatidine > A-85380 ≫ cytisine. For the nociceptive and cardiovascular responses the rank order of potencies of the nicotinic receptor agonists is epibatidine* > A-85380 ≥ cytisine* > nicotine* (*data from Khan et al., 1994b,c, 1997, 1998). This correlates well with the rank order of potencies of the various nicotinic receptor agonists in displacing [3H]epibatidine binding from spinal nAChRs, i.e., epibatidine* > A-85380 > cytisine* > nicotine*. Thus, A-85380 appears to bind to a specific complement of spinal nAChRs to elicit the multiple responses.
Recently, Rueter et al. (2000) found that intrathecal A-85380 caused a fall in the thermal escape latency (i.e., pronociception or hyperalgesia), but unlike epibatidine and A-85380 as in the present study (cf. Figs. 1 and 2), A-85380 did not have a subsequent antinociceptive action. Rueter et al. (2000) used a somewhat lower dose (10 nmol) of A-85380 and they administered the drugs into an initially restrained animal and tested 5 min later. In their studies, DβE at 1000 nmol partially blocked (50%) the pronociceptive effects of A-85380. In our hands, 140 nmol (50 μg) of DβE blocked the antinociceptive response produced by A-85380, but was ineffective in blocking its pressor and nociceptive response. Different doses and procedures for handling the animals for drug administration as well as different time points for measuring the antinociceptive response may account for the differences under Results.
Antagonism of A-85380-Elicited Responses.
The antinociceptive response to A-85380 was blocked by DβE, an α4β2-specific nAChR antagonist (McIntosh, 2000). Although this observation is consistent with the report that A-85380 is α4β2 subtype-specific nicotinic receptor agonist, DβE did not block the nociceptive or cardiovascular responses to i.t. A-85380. Thus, A-85380 also interacts with other spinal nAChR subtypes. Similar to mecamylamine, MLA significantly blocked all the responses to A-85380. As we indicated in earlier studies (Khan et al., 1994b,c, 1997, 1998), MLA behaves more like a channel blocker than a competitive antagonist in the spinal system.
Although DβE and MLA were effective in blocking the antinociceptive response to A-85380, neither antagonist blocked the antinociceptive response to epibatidine (Khan et al., 1998). This does suggest that epibatidine and A-85380 act differentially on distinct spinal nAChR subtypes to elicit the antinociceptive response. Our findings are consistent with the observation of Curzon et al. (1998), who demonstrated that epibatidine and A-85380 show different specificities for neuronal nAChRs in the brain. However, in the spinal cord, epibatidine binding is promiscuous and covers the same receptor subtypes as A-85380, since repeated i.t. administration of epibatidine desensitized both the nociceptive and antinociceptive responses to subsequent A-85380 treatment. In contrast, repeated administrations of A-85380 did not desensitize the antinociceptive response to epibatidine. However, it desensitized the nociceptive response to epibatidine.
Similar to epibatidine, prior cytisine treatment desensitized the nociceptive and antinociceptive responses to subsequent A-85380 administration. Pretreatment with both epibatidine and cytisine desensitizes the antinociceptive response to subsequent epibatidine administration (Khan et al., 1998). These observations indicate that both epibatidine and cytisine bind to the spinal α4β2 nAChR subtype, but have lower intrinsic agonist activities than A-85380 at this receptor subtype. This is consistent with cytisine being a poor agonist for α4β2-containing receptors (Picciotto et al., 1998; Zoli et al., 1998). It also appears that A-85380 has a lower intrinsic activity than epibatidine and a lower desensitization capacity than both epibatidine and cytisine for the nAChR subtype eliciting the antinociceptive response to i.t. epibatidine.
DβE pretreatment not only antagonized the A-85380-elicited antinociceptive response but also induced greater hyperalgesia to subsequent A-85380 in the thermal escape pain model. This observation, coupled with the prolonged nociceptive response to A-85380 following DβE treatment, strongly suggests that the receptors eliciting the nociceptive response to spinal A-85380 are not the α4β2 subtype.
The blockade by i.t. phentolamine of the A-85380-elicited antinociceptive response, but not that of epibatidine, indicates that A-85380 and epibatidine work in part through different spinal mechanisms, and accordingly must recognize distinct neuronal sites of action to elicit antinociception. The effects of intrathecal phentolamine suggest a stimulatory action of A-85380 on bulbospinal adrenergic terminals. Neuronal projections from brain stem area extend to the dorsal lumbar spinal cord (Sandkuhler, 1996), and these bulbospinal pathways are known to play a role in inhibition of nociceptive transmission at the spinal level (Yaksh, 1979; Hammond and Yaksh, 1984). Their terminals are positive for adrenergic neurotransmitters (Peng et al., 1996). Moreover, intrathecal α-adrenergic receptor agonists will elicit profound analgesia (Reddy et al., 1980). Furthermore, reports indicate that nicotinic receptor agonists can elicit an antinociceptive response upon injection in the nucleus raphe magnus (Iwamoto, 1991; Bitner et al., 1998). Thus, presynaptic α4β2 nAChRs on the bulbospinal terminals may play a significant role in modulating sensory stimuli at a spinal level.
Xu et al. (2000) demonstrated that spinal nAChRs might be involved in mediating the antinociceptive response to spinal clonidine. Their data suggest that clonidine results in release of acetylcholine in the dorsal lumbar spinal cord, which then interacts with the nAChRs. Our data suggest that the site of action for A-85380 may be antecedent to the nAChR sites activated following clonidine-elicited acetylcholine release. Moreover, Xu et al. (2000) provide a plausible explanation for the decrease in nociceptive response to A-85380 following phentolamine pretreatment. Enhanced release of adrenergic neurotransmitters following A-85380 injection will result in release of acetylcholine (Klimscha et al., 1997), which in turn, may stimulate the spinal nociceptive nAChRs.
The antagonism profiles seen after DβE, MLA, and phentolamine administration indicate that epibatidine and A-85380 produce analgesia through separate sites of action or epibatidine analgesia may be mediated through more than one site. Previously, we proposed that epibatidine-elicited analgesia that follows nociception might, in part, be manifested by desensitization of the primary afferent terminals (Khan et al., 1998). Lawand et al. (1999) also made similar suggestions. They demonstrated an antinociceptive response to spinal epibatidine in neuropathic pain model. If epibatidine indeed results in primary afferent terminal desensitization, and the receptor mediating this terminal desensitization is different from the DβE-sensitive α4β2 subtype, then blockade of epibatidine action on the bulbospinal terminals would not be evident in our test system. Primary afferent terminal desensitization would be the critical step in the thermal escape model. Moreover, our data indicate that the response elicited by epibatidine at the DβE-insensitive site dominates that elicited by A-85308 at the bulbospinal adrenergic terminals.
Cross-Desensitization.
It appears that both A-85380 and epibatidine bind to a common receptor to elicit the nociceptive response since both of the agonists cross-desensitize each others' nociceptive response. Moreover, the nociceptive response to A-85380, like epibatidine, is significantly inhibited by intrathecal AP-5 treatment. This indicates that, similar to other nicotinic receptor agonists, a significant portion of the nociceptive response to A-85380 is mediated via spinal release of excitatory amino acids (Khan et al., 1996a, 1997, 1998).
The different concentrations of A-85380 required to elicit the antinociceptive and nociceptive responses might be explained by A-85380 having greater affinity for the receptor eliciting the nociceptive response. Spinal nicotinic receptor agonists may elicit a nociceptive response by stimulating nAChRs on primary afferent terminals or postsynaptic neurons in dorsal lumbar spinal cord (Puttfarcken et al., 1997; Khan et al., 1994a, 1996a). Indeed, nicotinic binding sites have been localized histochemically on primary afferent terminals (Morita and Katamaya, 1984; Roberts et al., 1995; I. Khan, unpublished observations), and these nAChRs may be the higher affinity sites. Approximately 70% of the total binding sites in the dorsal spinal cord are the high-affinity subtype (Khan et al., 1997). In addition, α3 transcripts have been identified in the substantia gelatinosa layer of the spinal cord (Wada et al., 1989). Capsaicin treatment to eliminate the primary afferent terminals significantly, but not completely, ablates high-affinity nAChR sites in the superficial dorsal horn area (Roberts at al., 1995; I. Khan, unpublished observations). Moreover, capsaicin treatment does not completely block the nociceptive response to spinal nicotinic receptor agonists (I. Khan, unpublished observations). This leaves open the possibility that a significant portion of the spinal interneurons in the dorsal horn also express a non-α4β2 subtype of the high-affinity nAChR, which may also mediate the nociceptive response to nicotinic receptor agonists.
Subunit Composition.
Recently, binding studies with tissue from β2-deficient mice indicate that α4β2 is the primary nAChR subtype expressed in the brain (Zoli et al., 1998); however, α3β2, α3β4, and α4β4 subunit compositions appeared also to be present in the brain. α3 subunits can be detected in the trigeminal neurons, sympathetic ganglia, and the dorsal root ganglia (Wada et al., 1990;Boyd et al., 1991; Lukas, 1993; Flores et al., 1996) as α3β4 (Flores et al., 1996). Complementary to studies of Wada et al. (1990), our findings reveal that α5 transcripts and expressed subunits are present in the dorsal root ganglion as well as spinal interneurons (I. Khan, unpublished observations). Incorporation of α5 subunit into α3β2, α3β4, and α4β4 subunit compositions is known to modulate the activities, ligand binding affinities, and desensitization properties of these receptors in vitro (Ramirez-Lattore et al., 1996;Gerzanich et al., 1998). Therefore, it seems likely that more than one subtype of nAChR is expressed on afferent terminals. Such an expression pattern might confer selectivity of epibatidine over A-85380 for a particular subtype of nAChR to elicit afferent terminal desensitization.
Overall, our studies clearly demonstrate that spinal nAChRs can modulate the spinal processing of nociceptive stimuli through both facilitation and inhibition of the transmission. Thus, spinal nicotinic receptor agonists such as A-85380 and epibatidine elicit a profound but transient antinociceptive response. The DβE antagonism profiles suggesting that the nociceptive and antinociceptive responses are opposing each other, in part, explain the short duration of analgesia. Similarly, repeated cytisine pretreatment, which effectively desensitized the nociceptive response to subsequent A-85380, appeared to potentiate the antinociceptive response.
In conclusion, we demonstrate that A-85380 elicits an antinociceptive response after intrathecal administration, which appears to be mediated primarily by an α4β2-like nAChR. In addition to α4β2 receptor subtype, A-85380 also appears to associate with other receptor subtypes as indicated by the diversity of spinal responses it elicits and its ability to displace [3H]epibatidine binding from spinal cord membranes.
Footnotes
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Send reprint requests to: Dr. Imran M. Khan, Department of Pharmacology-0636, University of California San Diego, 9500 Gilman Dr., La Jolla, CA 92093-0636. E-mail: ikhan{at}ucsd.edu
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This study was supported by State of California, Tobacco Related Disease Research Program, and U.S. Public Health Service HL-35018 grants to P.T.
- Abbreviations:
- EPI
- epibatidine
- nAChR
- nicotinic acetylcholine receptor
- i.t.
- intrathecal
- PE
- polyethylene
- MLA
- methyllycaconitine
- AP-5
- 2-amino-5-phosphopentanoic acid
- SA/SV
- spontaneous agitation/spontaneous vocalization
- %MPE
- percentage of maximum effect
- DβE
- dihydro-β-erythroidine
- Received October 11, 2000.
- Accepted December 14, 2000.
- The American Society for Pharmacology and Experimental Therapeutics