Molecular mechanism for analgesia involving specific antagonism of α9α10 nicotinic acetylcholine receptors
␣9␣10 nicotinic acetylcholine receptors (nAChRs) have been identified in a variety of tissues including lymphocytes and dorsal root ganglia; except in the case of the auditory system, the function of ␣9␣10 nAChRs is not known. Here we show that selective block (rather than stimulation) of ␣9␣10 nAChRs is analgesic in an animal model of nerve injury pain. In addition, blockade of this nAChR subtype reduces the number of choline acetyltransferase-positive cells, macrophages, and lymphocytes at the site of injury. Chronic neuropathic pain is estimated to affect up to 8% of the world's population; the numerous analgesic compounds currently available are largely ineffective and act through a small number of pharmacological mechanisms. Our findings not only suggest a molecular mechanism for the treatment of neuropathic pain but also demonstrate the involvement of ␣9␣10 nAChRs in the pathophysiology of peripheral nerve injury.N europathic pain is a prolonged, debilitating state characterized by allodynia (pain produced by previously innocuous stimuli), hyperalgesia (an increased or exaggerated response to painful stimuli), and spontaneous pain. Neuropathic pain is often refractory to conventional pain therapeutics such as opioids and nonsteroidal antiinflammatory agents and, therefore, represents a large, unmet clinical need. Neuropathic pain can be triggered in a variety of ways; injury to a peripheral nerve is one of the most common causes.The involvement of nicotinic acetylcholine receptors (nAChRs) in pain has been suggested by a number of experimental observations, and the administration of nAChR agonists reduces pain-related behaviors in several animal models (1-5). nAChRs are pentameric ligand-gated ion channels composed of ␣ (␣1-␣10) and non-␣ (1-4, , ␥, and ␦) subunits. The ␣2-␣6 and 2-4 subunits form heteromeric channels consisting of a combination of ␣ and  subunits (6). Homomeric channels can be formed by ␣7 or ␣9 subunits; the ␣10 subunit will only form functional receptors when it is expressed with the ␣9 subunit (6). Many of the nAChRs show widespread patterns of neuronal and nonneuronal distribution; ␣9 and/or ␣10 subunits have been reported within hair cells of the inner ear (7), sperm (8), dorsal root ganglion neurons (9), skin keratinocytes (10), the pars tuberalis of the pituitary (11), and lymphocytes (12). The function of ␣9␣10 nAChRs in the auditory system has been well characterized (13), but little is known regarding the function of ␣9␣10 nAChRs in other tissues. Here we demonstrate that the highly selective antagonist of ␣9␣10 nAChRs, RgIA, is analgesic and reduces migration of macrophages, lymphocytes, and acetylcholine (ACh)-producing cells into the area of nerve injury. ResultsRgIA Is Antinociceptive. Chronic constriction injury (CCI) produced mechanical hypersensitivity within 7 days of sciatic nerve ligation (Fig. 1). Paw withdrawal thresholds (PWTs) were reduced from 122 Ϯ 5 g to 26 Ϯ 5 g 7 days after CCI. The i.m. administration of the ␣9␣10-selective Conus peptide, RgIA, increased...
Peripheral nerve injury alters spinal nicotinic acetylcholine receptor pharmacology
Nicotinic acetylcholine receptors are widely expressed in the rat spinal cord and modulate innocuous and nociceptive transmission. The present studies were designed to investigate the plasticity of spinal nicotinic acetylcholine receptors modulating mechanosensitive information following spinal nerve ligation. A tonic inhibitory cholinergic tone mediated by dihydro-β-erythroidine-(DHβE) and methyllycaconitine-(MLA) sensitive nicotinic acetylcholine receptors was identified in the normal rat spinal cord and cholinergic tone at both populations of nicotinic acetylcholine receptors was lost ipsilateral to spinal nerve ligation. The administration of intrathecal nicotinic acetylcholine receptor agonists reduced mechanical paw pressure thresholds with a potency of epibatidine = A-85380 >> nicotine > choline in the normal rat. Following spinal nerve ligation, intrathecal epibatidine and nicotine produced an ipsilateral antinociception, but intrathecal A-85380 and choline did not. The antinociceptive response to intrathecal nicotine was blocked with the α7* and α9α10*-selective nicotinic acetylcholine receptor antagonist, MLA, and the αβ heteromeric nicotinic acetylcholine receptor antagonist, DHβE. The antinociceptive effects of both intrathecal nicotine and epibatidine were mediated by GABA A receptors. Spinal [ 3 H]epibatidine saturation binding was unchanged in spinal nerve-ligated rats, but spinal nerve ligation did increase the ability of nicotine to displace [ 3 H]epibatidine from spinal cord membranes. Spinal nerve ligation altered the expression of nicotinic acetylcholine receptor subunits ipsilaterally, with a large increase in the modulatory α5 subunit. Taken together these results suggest that pro-and antinociceptive populations of spinal nicotinic acetylcholine receptors modulate the transmission of mechanosensitive information and that spinal nerve ligation-induced changes in spinal nicotinic acetylcholine receptors likely result from a change in subunit composition rather than overt loss of nicotinic acetylcholine receptor subtypes.
Spinal α3β2* nicotinic acetylcholine receptors tonically inhibit the transmission of nociceptive mechanical stimuli
The presence of non-α4β2, non-α7 nicotinic acetylcholine receptors (nAChR) in the rat spinal cord has been suggested previously, but the identity of these nAChRs had not been shown. Intrathecal administration of the α3β2*/α6β2* selective α-conotoxin MII (α-CTX MII) dose-and timedependently reduced paw withdrawal thresholds to mechanical pressure in normal rats. The pronociceptive effect of α-CTX MII was partially blocked by NMDA receptor antagonism and lost completely following ablation of C-fibers. The effect of spinal nerve ligation on α-CTX MII-induced mechanical hypersensitivity was also assessed. Sensitivity was lost in the hind paw ipsilateral to spinal nerve ligation, but maintained in the contralateral hind paw at control levels.. Radioligand binding in spinal cord membranes revealed high and low affinity α-CTX MII binding sites. Spinal nerve ligation did not significantly alter α-CTX MII binding ipsilateral to ligation. Finally, no evidence for the presence of α6-containing nAChRs was identified. The results of these studies show the presence of 2 populations of α-CTX MII-sensitive nAChRs containing the α3 and β2, but not the α6, subunits in the rat spinal cord that function to inhibit the transmission of nociceptive mechanical stimuli via inhibiting the release of glutamate from C-fibers. Spinal nerve ligation produces a unilateral loss of α-CTX MII-induced mechanical hypersensitivity without altering α-CTX MII binding sites. Our data support a peripheral injury-induced loss of a cholinergic inhibitory tone at spinal α3β2* nAChRs, without the loss of the receptors themselves, which may contribute to mechanical hypersensitivity following spinal nerve ligation.
During development, the rescue of spinal motoneurons as well as sensory neurons in the dorsal root ganglion (DRG) from programmed cell death (PCD) depends on the integrity of peripheral target innervation. Following deletion of the pro-apoptotic gene Bax, both motoneurons and DRG neurons are rescued from PCD. In the present paper, we asked whether different cell types in the DRG exhibit distinct responses to Bax deletion. In 1 month-old Bax-deficient (Bax−/−) mice, distinct subsets of DRG neurons that were immunopositive for TrkA, CGRP, TRPV1 or TrkC, were all increased in number and exhibited cell atrophy compared to wild type DRG neurons. In addition there was hyperinnervation of the epidermis by CGRP immunopositive processes and a correlated functional hypersensitivity of mechanical nociception in Bax−/− mice. By contrast, the functional properties of populations of rescued thermoreceptor and mechanoreceptor DRG neurons were unchanged. These data indicate that although Bax deletion rescues all of the DRG cell types examined here from PCD, the functional consequences of having excess cells differ between sensory phenotypes.
Chronic nicotine exposure and the immune response to peripheral nerve injury has not been investigated thoroughly. Rats were exposed to chronic nicotine or saline followed by chronic constriction injury (CCI) of the sciatic nerve. Mechanical sensitivity was measured at various time points and the immune response was investigated at 21 days post-CCI. Chronic nicotine increased mechanical hypersensitivity, microglia activation, and the production of IL-1β, but not the number of immune cells at the site of injury. These results suggest that chronic nicotine increases mechanical hypersensitivity following peripheral nerve injury through a mechanism that may involve an increased production and release of central and peripheral cytokines.
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