Abstract
The potential importance for nociception of P2X receptors, the ionotropic receptors activated by ATP, is underscored by the variety of pain states in which this endogenous ligand can be released. Several important findings have been made recently indicating that P2X receptors can be involved in pain mechanisms both centrally and in the periphery. The roles of ATP at these two sites and the P2X receptor subtypes involved appear to be different. In the periphery, ATP can be released as a result of tissue injury, visceral distension, or sympathetic activation and can excite nociceptive primary afferents by acting at homomeric P2X3 or heteromeric P2X2/3receptors. Centrally, ATP released from central afferent terminals or second order neurons can modulate neurotransmitter release or postsynaptically activate neurons involved in central nociceptive transmission, with P2X2, P2X4, P2X6, and some other receptors being potentially involved. Evidence from in vivo studies suggests that peripheral ATPergic mechanisms are most important under conditions of acute tissue injury and inflammation whereas the relevance of central mechanisms appears to be more limited. Furthermore, the release of ATP and P2X receptor-mediated afferent activation appear to have been implicated in visceral and neuropathic pain; the importance of the ATPergic component in these states needs to be investigated further. Thus, peripheral P2X receptors, and homomeric P2X3 and/or heteromeric P2X2/3 receptors in particular, constitute attractive targets for analgesic drugs. The development of selective antagonists of these receptors, suitable for a systemic in vivo use although apparently difficult, may prove a useful strategy to generate analgesics with a novel mechanism of action.
I. Introduction
P2X receptors are cation-permeable ion channels gated by ATP and some related nucleotides (Abbracchio and Burnstock, 1994; Fredholm et al., 1994; Khakh et al., 2001). During the last several years, a great body of evidence has been accumulated indicating that these receptors can be involved in pain mechanisms and thereby constitute possible targets for analgesic drugs. The potential importance of this target is emphasized by the ubiquitous presence of the endogenous ligand, ATP, in living cells, and the variety of states in which this ligand can be released activating its receptors. Unfortunately, development of selective antagonists suitable for in vivo use has been a challenge, and currently available compounds have limited selectivity, potency, or in vivo stability. Nevertheless, extensive work has been done to elucidate the role of P2X receptors in different pain states and to evaluate the potential of P2X receptor antagonists for the treatment of pain. Efforts using pharmacological tools have been recently substantiated by investigations of genetically modified animals with targeted deletion of P2X receptors in pain models. The aim of this review is, therefore, to analyze and to superimpose these various lines of evidence for the role of P2X receptors in different pain states and thus describe the profile of potential analgesics targeting these receptors.
Seminal work of Burnstock (1996) has attracted researchers' interest in the role of ATP and its receptors in peripheral tissues. There, large quantities of ATP may leave the intracellular space as a result of tissue trauma, tumor, inflammation, migraine, or visceral distension. The resulting P2X receptor activation is likely to contribute to the intense pain sensation occurring under these conditions. Furthermore, ATP is an important cotransmitter in peripheral and central noradrenergic neurons (von Kügelgen and Starke, 1985; Vizi and Burnstock, 1988; Poelchen et al., 2001). Its release from sympathetic postganglionic neurons could contribute to the condition of sympathetically maintained pain sometimes developing as a consequence of nerve injury. Interest in peripheral ATP mechanisms has been greatly intensified by findings that a subtype of ionotropic ATP receptors, the P2X3 receptor, is expressed with considerable selectivity by a subset of nociceptive sensory neurons in dorsal root ganglia (Chen et al., 1995; Lewis et al., 1995). In addition to such a universal role of ATP as a ‘pain molecule’ in the periphery, central release of ATP from terminals of primary afferent fibers has been demonstrated. There, in addition to the modulatory role of presynaptic P2X receptors controlling neurotransmitter release from primary afferents, postsynaptic P2X receptors on second order neurons, might be involved in pain transmission.
Several short reviews have recently appeared summarizing the status of understanding of the role of P2X receptors in pain (McCleskey and Gold, 1999; Bland-Ward and Humphrey, 2000; Ding et al., 2000; Hamilton and McMahon, 2000; Burnstock, 2001; Salter and Sollevi, 2001). However, given the great interest in this analgesic target, the rate at which new reports appear, and some inevitable discrepancies and controversies of the data, particularly from in vivo studies, there is a continuing need for a detailed analysis of the accumulated information. In this review, after a summary on the localization and pharmacology of pain-relevant P2X receptors, we shall consider the evidence from mechanistic studies regarding the relative roles of peripheral and central P2X receptors. Further on, in vivo evidence for the involvement of ATP and P2X receptors in acute, inflammatory, neuropathic, and visceral pain will be analyzed separately for each of these states. Finally, implications for the development of novel analgesics will be discussed.
II. P2X Receptor Subtypes, Localization, and Pharmacology
Extracellular ATP has been shown to act at two P2 receptors belonging either to the P2X (ligand-activated cationic channel) or P2Y (G protein-coupled receptor) types (Abbracchio and Burnstock, 1994;Ralevic and Burnstock, 1998). The classification of P2X receptors as well as their localization and pharmacological properties have been extensively discussed previously (Nörenberg and Illes, 2000;North and Surprenant, 2000; Khakh et al., 2001). Only a brief account will be given here on these issues, with the focus on aspects pertinent to nociception.
A. Subtypes of Ionotropic Receptors for ATP
Of the seven subtypes of cloned mammalian P2X receptors (P2X1–P2X7), the respective mRNAs or subunit proteins all have been found in the central and peripheral nervous system (Collo et al., 1996; Le et al., 1998b;Loesch and Burnstock, 1998; Kanjhan et al., 1999); measurements of changes in the intracellular free Ca2+concentration as well as recordings of membrane potential alterations or the underlying ionic currents evoked by P2X receptor activation confirmed the functional significance of these subunits (Edwards et al., 1992; Harms et al., 1992; Illes and Nörenberg 1993; Illes et al., 1996; Nörenberg and Illes, 2000). Studies on the localization of P2X receptors have confirmed the presence of at least six subtypes (P2X1–P2X6) in nervous structures involved in nociceptive transmission (seeSection II.B.). Although P2X7 receptor mRNA has been demonstrated in retinal ganglion cells and cochlear spiral ganglia of rats (Brändle et al., 1998, 1999), there is no functional evidence hitherto that these receptors could be involved in sensory transmission or nociception (Nörenberg and Illes, 2000). P2X7 receptors are situated at immune cells such as macrophages, lymphocytes, and microglia where they mediate the release of proinflammatory cytokines or the stimulation of transcription factors and are also regarded as being important for apoptosis (Burnstock, 2000; Illes et al., 2000; Di Virgilio et al., 2001). In this review, therefore, we shall focus on the first six members of the ionotropic ATP receptor family and their role in nociception.
P2X1 through P2X5 subunits form functional receptors when expressed in heterologous systems, whereas only small currents are seen with recombinant homomeric P2X5 receptors, and the functionality of homomeric P2X6 receptors still remains to be demonstrated (Collo et al., 1996; Le et al., 1998a; King et al., 2000). In addition, most subunits have been shown to form functional recombinant heteromeric receptors, e.g., P2X1/5, P2X2/3, P2X2/6, and P2X4/6 (Radford et al., 1997; Le et al., 1998a;Torres et al., 1998, 1999). The only subunit that was unable to form hetero-oligomeric assemblies was P2X7 (Torres et al., 1999). It has recently been suggested that trimeric complexes of identical subunits seem to constitute an essential structural element of the P2X receptors channel (P2X1 and P2X3, Nicke et al., 1998; P2X2, Stoop et al., 1999). However, the stoichiometry of the native receptor is at present unresolved. The comparative properties of recombinant and native P2X receptors are summarized in Section II.C.
B. Distribution of P2X Receptors in Pain Relevant Neuronal Structures
1. Dorsal Root Ganglia and Trigeminal Ganglia.
At least six (P2X1–P2X6) of the seven cloned mammalian P2X receptors are present in sensory ganglia, forming distinct distribution patterns in populations of sensory neurons (Nörenberg and Illes, 2000; Khakh et al., 2001). Neurons of dorsal root ganglia (DRG2), trigeminal, and nodose ganglia express P2X1, P2X2, P2X3, P2X4, and P2X6 mRNA, whereby the expression of the P2X3 mRNA appears selective for a subpopulation of small-diameter cells (Chen et al., 1995; Lewis et al., 1995; Collo et al., 1996; Barden and Bennett, 2000). A similar distribution pattern is seen at the protein level (Vulchanova et al., 1996, 1997; Xiang et al., 1998). The predominant expression of the P2X3 receptor compared with other P2X receptors in small-diameter neurons (Xiang et al., 1998) and the originally reported selectivity of this localization in the rat (Chen et al., 1995; Collo et al., 1996) have attracted interest in this receptor as a target for novel analgesics, although more recent data indicate that the distribution of this receptor both in rat (Xiang et al., 1998; Hansen et al., 1999; Zhong et al., 2000) and human tissues is less nociceptor-specific (Garcia-Guzman et al., 1997; Yiangou et al., 2000). In addition, the confinement of P2X3receptor immunoreactivity to brain structures involved in pain transmission (nucleus tractus solitarius, solitary tract, spinal trigeminal nucleus; Vulchanova et al., 1996, 1997) appears to be stringent in the adult rat bain in contrast to a more widespread distribution observed in the embryonic and neonatal rat brain (Kidd et al., 1998).
Immunocytochemistry studies on the localization of the P2X3 receptor indicate its presence on a subpopulation of small-diameter nonpeptidergic neurons specifically binding the isolectin B4; these neurons project to lamina II (inner) of the dorsal horn (Bradbury et al., 1998;Llewellyn-Smith and Burnstock, 1998; Vulchanova et al., 1998). Dorsal rhizotomy eliminates the P2X3 receptor immunoreactivity in the spinal cord, confirming presynaptic localization on primary afferents (Bradbury et al., 1998; Vulchanova et al., 1998). In the lumbar DRG, P2X3 receptor expressing sensory fibers innervate both skin and viscera, whereas muscle afferents have a very low expression level of these receptors (Bradbury et al., 1998). There is a relatively high level of colocalization of P2X3 receptor immunoreactivity with the vanilloid receptor VR1 (Guo et al., 1999); because the latter confers sensitivity to noxious heat (Caterina et al., 1997; Tominaga et al., 1998; Caterina and Julius, 2001), the P2X3receptor might be expected to play a role in thermal nociception. Functional data on the existence and subtypes of P2X receptors on primary afferents are reviewed below (see Section III.).
2. Spinal Cord and Other Central Nervous System Areas.
In the dorsal horn of the spinal cord, in addition to P2X receptors localized on primary afferent terminals (particularly P2X3, P2X2, and P2X1, see above), both mRNA and the receptor protein for some P2X receptors have been found, indicating their presence on second order neurons. Here, as well as in other central nervous system regions, the P2X2, P2X4, and P2X6 receptors appear to have the highest expression levels (Collo et al., 1996; Vulchanova et al., 1996; Le et al., 1998b) although P2X3 receptors are also present (Vulchanova et al., 1997; Llewellyn-Smith and Burnstock, 1998). Functional evidence for the presence of P2X receptors and their role in synaptic transmission in the spinal cord is discussed below (seeSection IV.).
C. Functional Properties of Different P2X Receptor Subtypes
A detailed account on the functional differences between individual P2X receptor subtypes in the desensitization rate and sensitivity to protons and other ions, as well as to agonists and antagonists, can be found in several recent reviews (Lambrecht, 2000;North and Surprenant, 2000; Khakh et al., 2001) (Table1). These functional properties are frequently used to identify the subtype composition of native receptors in dissociated neuron or tissue preparations (e.g., see Section III.).
Inherent properties of recombinant and native P2X receptors are their different rates of desensitization in the continuous presence of ATP. P2X1 (Valera et al., 1994) and P2X3 homomers (Lewis et al., 1995) in contrast to all other P2X receptors rapidly desensitize within tens or hundreds of milliseconds (Buell et al., 1996; Ralevic and Burnstock, 1998). There is disagreement on the mechanism of P2X3 receptor desensitization, since on the one hand intracellular N-terminal (King et al., 1997a) or C-terminal domains (Koshimizu et al., 1999) were defined as possible sites of phosphorylation, and on the other hand the membrane-spanning hydrophobic segments were considered to be of primary significance (Werner et al., 1996). The P2X2/3heteromeric receptor exhibited a sustained response during a longer lasting exposure to ATP (Lewis et al., 1995).
The measurement of reversal potentials by the patch-clamp method indicated that recombinant homomeric P2X3 and heteromeric P2X2/3 receptors exhibit a considerably lower permeability for Ca2+ ions (Virginio et al., 1998a) than P2X1 (Evans et al., 1996) or P2X4 receptors (Buell et al., 1996). A direct determination of intracellular Ca2+ by fura-2 microfluorimetry also proved a lower peak response to P2X3 than P2X1 receptor activation in an expression system (gonadotropin-releasing hormone-secreting neurons; Koshimizu et al., 2000). Finally, extracellular Ca2+ has been reported to inhibit currents via P2X3 and P2X2/3 receptors with a lower affinity than via P2X2 receptors (Virginio et al., 1998a). In contrast, Cook et al. (1998) described a marked potentiation of P2X3 but not P2X2/3receptor currents in rat DRG neurons at higher external Ca2+ concentrations. It was suggested that Ca2+ binds to an extracellular site at the P2X3 receptor causing a faster recovery from desensitization, which in turn leads to a larger availability of an agonist-sensitive receptor pool (Cook et al., 1998).
Zn2+ and Cd2+ failed to alter P2X3 receptor currents although the ionic permeability of the P2X4 receptor channels was slightly inhibited and that of the P2X2 receptor channels was markedly potentiated (Nakazawa and Ohno, 1997). Both Cu2+ and Zn2+ potently enhanced the ATP-induced current in rat nodose ganglion neurons endowed with P2X2/3 heteromers (Li et al., 1996b). Similarly, H+ enhanced the affinity of P2X2 receptors for ATP (King et al., 1996, 1997b;Stoop et al., 1997), whereas the affinity of P2X1, P2X3, and P2X4 receptors was decreased by acidification of the medium (Stoop et al., 1997; Wildman et al., 1999b). Most importantly, the P2X2 subunit dominated the reaction of P2X2/3 heteromeric receptors to changes of pH in that H+ caused facilitation (Stoop et al., 1997; Burgard et al., 1999). It is noteworthy that nodose ganglion neurons and DRG neurons possibly containing the P2X2/3 heteromers show a similar effect to pH (Li et al., 1996a; Burgard et al., 1999). Since inflamed tissue has relatively low pH, sustained ATP responses mediated by P2X2/3 heteromers (see Section III.B.) may manifest themselves preferentially in inflamed tissue (McCleskey and Gold, 1999). Substance P and bradykinin also potentiated currents via recombinant P2X3 and P2X2/3 channels in accordance with their known ability to modulate pain perception (Paukert et al., 2001). Eventually, cibacron blue, which has been reported to be an antagonist of ATP at recombinant P2X1 and P2X2receptors (Surprenant, 1996), appeared to be an allosteric modulator of recombinant P2X3 receptors (Alexander et al., 1999). Cibacron blue mediated a large increase in both the magnitude and the potency of the ATP-activated Ca2+ influx and transmembrane current. In contrast, ivermectin was a positive allosteric effector of the gating and kinetics of P2X4 and probably P2X4/6but not of P2X2, P2X3, or P2X2/3 channels (Khakh et al., 1999).
Ethanol has been shown to inhibit ATP-induced currents in DRG neurons of bullfrogs (Li et al., 1993). Further experiments suggested that the inhibitory action was due to an allosteric mechanism (Li et al., 1998a) and raised the possibility that it involves the extracellular domain of the ATP-gated ion channel (Weight et al., 1999). Since the receptors studied by Weight et al. (1999) did not show fast desensitization kinetics like P2X3 receptors, they may belong to the P2X2/3 type. Human recombinant P2X3 receptors failed to react to ethanol but were inhibited by the active metabolite of the hypnotic drug chloral hydrate, trichloroethanol (Köles et al., 2000). The reported analgesic effect of chloral hydrate (Field et al., 1993) was suggested to be due to the modulation of pain transmission in DRG neurons (Köles et al., 2000). In contrast to P2X3receptors, recombinant P2X4 receptors were sensitive to ethanol-induced inhibition (Xiong et al., 2000).
D. Available P2X Agonist and Antagonist Tools
The reader is referred to several recent reviews for more detailed information on the subtype selectivity profile of the available P2X receptor agonists and antagonists (e.g., Lambrecht, 2000;North and Surprenant, 2000; Khakh et al., 2001). The availability of pharmacological tools to study the role of P2X receptors in pain mechanisms is very limited. Most ligands that have been available so far have low affinity and/or selectivity. The agonist α,β-methylene-ATP (α,β-meATP) has been shown to act at homomeric P2X1 (Valera et al., 1994, 1995) and P2X3 receptors (Chen et al., 1995, Garcia-Guzman et al., 1997), as well as at hetero-oligomeric P2X4/6 receptors (Le et al., 1998a) but not at the other P2X receptor subtypes (Ralevic and Burnstock, 1998). The finding that β,γ-methylene-l-ATP evoked fast inward currents in P2X1 receptor-containing smooth muscle cells, but failed to do so in P2X2/3receptor-containing nodose ganglion neurons (see Section III.B.) supplies a further pharmacological tool for discrimination (Trezise et al., 1995). As far as antagonists are concerned, suramin (8-(3-benzamido-4-methylbenzamido)-naphthalene-1,3,5-trisulfonic acid) and pyridoxalphosphate-6-azophenyl-2′,4′-disulfonic acid (PPADS) are weak and nonselective for the various subtypes of P2X receptors and, in addition, have some other properties complicating the interpretation of the in vitro or in vivo data (e.g., inhibition of ectonucleotidases) (Ralevic and Burnstock, 1998). The heteromeric P2X4/6 receptors have been shown to have a higher sensitivity to PPADS and suramin then their respective homomeric assemblies (Le et al., 1998a). Some antagonists with submicromolar affinity have recently been developed, e.g., 2′,3′-O-(2,4,6-trinitrophenyl)-ATP (TNP-ATP; Thomas et al., 1998; Virginio et al., 1998b), and diinosine pentaphosphate (Ip5I; King et al., 1999; Wildman et al., 1999a;Dunn et al., 2000) that are potent and selective antagonists at P2X1 and P2X3 receptors; the former but not the latter compound also blocks the heteromeric P2X2/3 receptor. Unfortunately, the use of TNP-ATP in whole tissue preparations or under in vivo conditions may be limited by its instability probably due to breakdown by ectonucleotidases (Lewis et al., 1998). The agonistic compounds ATP and α,β-meATP have been used in some in vivo experiments to inactivate P2X receptors by desensitization (see below).
III. Peripheral P2X Receptors and Nociception
A. Sources of Extracellular ATP in Peripheral Tissues
The importance of ATP as a pain-relevant molecule in peripheral tissues has been highlighted by Burnstock (1996), who hypothesized that ATP released from different cell types is implicated in the initiation of pain by acting on purinoceptors on sensory nerve terminals. According to this hypothesis, tissue trauma, tumor, inflammation, vascular or visceral distension, or sympathetic activation by nerve injury may all lead to accumulation of ATP in the extracellular space and activation of P2X receptors on sensory afferents (Bland-Ward and Humphrey, 2000; Burnstock, 2000, 2001; Ding et al., 2000; Hamilton and McMahon, 2000; Salter and Sollevi, 2001). It is noteworthy that ATP may be rapidly degraded by surface-located ectonucleotidases to adenosine (Zimmermann and Braun, 1999; Zimmermann, 2000), which acts at neuronal P1 receptors of the A1- or A2-type (Fredholm et al., 1994, 2000), thereby modulating pain transmission in the periphery as well as at central sites (Salter and Sollevi, 2001). The neuronal effects of adenosine are usually the opposite of the effects of ATP. For example, ATP is known to depolarize DRG neurons via P2X3 and P2X2/3 receptor activation (see Section III.B.), whereas adenosine inhibits high voltage-gated Ca2+ channels of DRG neurons by stimulating its own receptors of the A1 type (Dolphin et al., 1986; Macdonald et al., 1986). In this review, data on the role of peripherally released ATP in different pain states will be discussed separately in sections dealing with the respective pain types (see Section V. and Table2).
B. Characteristics of P2X Receptors on Primary Afferents
The functionality of P2X receptors localized on peripheral nociceptive neurons is best demonstrated by electrophysiological studies on sensory ganglion cells. In such experiments, the kinetics and pharmacology of responses mediated by native receptors can be compared with those obtained in recombinant receptor systems, allowing the analysis of receptor subtypes involved. Numerous reports have documented that application of ATP or its analogs to the cell bodies of acutely dissociated or cultured sensory neurons results in depolarization or inward current, the effect being blocked by the P2X receptor antagonists suramin and PPADS (Jahr and Jessell, 1983;Krishtal et al., 1983, 1988a,b; Bean, 1990; Robertson et al., 1996; Rae et al., 1998; Ueno et al., 1999). The current is mediated by a cation channel with a relatively high calcium permeability (Krishtal et al., 1983; Bean et al., 1990; Virginio et al., 1998a), which leads to an increase in intracellular calcium concentration (Bouvier et al., 1991). These reports mention that a variable but generally high proportion of sensory neurons responds to ATP and its analogs. It must be noted, however, that the majority of such studies has been performed with acutely dissociated or cultured DRG cells. These results should be interpreted with some caution because one study has demonstrated that the relative number of cells responding to ATP and α,β-meATP in intact DRG preparations is substantially lower compared with acutely dissociated DRG neurons (Stebbing et al., 1998).
ATP-sensitive neurons of sensory ganglia are not homogeneous with respect to the presence of functional P2X receptor subtypes. Using retrogradely labeled tooth pulp nociceptors and muscle stretch receptors in culture, Cook et al. (1997) have characterized several types of sensory neurons on the basis of the kinetics of their responses and sensitivity to P2X receptor agonists and antagonists. In nociceptors, one group showed rapidly desensitizing and slowly recovering responses to ATP, which could be antagonized by suramin, and sensitivity to the P2X1/P2X3 receptor agonist α,β-meATP. The second group of nociceptors was also sensitive to both α,β-meATP and suramin, but the kinetics of their activation and desensitization was slow. Consistent with the predominant localization in small sensory neurons, the two populations of nociceptors were concluded to express functional homomeric P2X3 and heteromeric P2X2/3receptors, respectively, whereas receptors other than P2X3 (likely to be P2X5) were presumed to mediate ATP responses of the homogeneous group of proprioceptive afferents.
A similar pattern has been observed in DRG. Consistent with the localization pattern of P2X3 receptors (Burgard et al., 1999; Ueno et al., 1999), small-diameter, capsaicin-sensitive, isolectin B4-positive neurons most frequently display rapidly desensitizing agonist-evoked currents and sensitivity to α,β-meATP and to the P2X receptor antagonists suramin, PPADS, and TNP-ATP (Burgard et al., 1999; Ueno et al., 1999; Li et al., 1999;Petruska et al., 2000a,b), the characteristics most closely matching those of recombinant homomeric P2X3 receptors (Burgard et al., 1999; Liu et al., 2001; see also Section II.C.). Medium-sized capsaicin-insensitive neurons have response characteristics of P2X2/3 heteromers and express both P2X2 and P2X3 receptor mRNA (Li et al., 1999; Ueno et al., 1999; Petruska et al., 2000a,b). Some authors have also observed mixed kinetics of responses (Burgard et al., 1999; Grubb and Evans, 1999; Ueno et al., 1999; Petruska et al., 2000a), which would be in agreement with the reported variety of functional profiles of cells with different relative levels of the P2X2 and P2X3 receptor expression in P2X2/3 heteromultimers (Liu et al., 2001). Confirming the results of the pharmacological analysis, acutely isolated DRG neurons of P2X3 receptor null mice did not show any rapidly desensitizing responses to ATP or α,β-meATP, indicating that these responses are mediated by the P2X3 receptor (Cockayne et al., 2000, Souslova et al., 2000).
Vagal afferents appear to have a different profile of functional P2X receptors. Immunohistochemical studies have shown that peripheral terminals of these afferents, as well as neurons in nodose ganglia where their cell bodies are localized, express both P2X2 and P2X3 receptors (Vulchanova et al., 1997; Virginio et al., 1998b; Brouns et al., 2000). Electrophysiologically, however, the slow kinetics of response desensitization and relatively high sensitivity to inhibition by extracellular calcium indicate that homomeric P2X3 receptors are absent in these cells (Khakh et al., 1995; Virginio et al., 1998a). Nodose ganglion neurons are either sensitive or insensitive to the P2X1 and P2X3 receptor antagonist TNP-ATP and most likely to express heteromeric P2X2/3 or homomeric P2X2 receptors, respectively (Thomas et al., 1998). Consistent with that, nodose ganglion neurons isolated from the P2X3 receptor knock-out mouse did not respond to α,β-meATP, and the response to ATP was much reduced (Cockayne et al., 2000; Souslova et al., 2000).
Although the presence of functional P2X receptors on isolated nociceptors appears thus well established (see, however, Stebbing et al., 1998), one important question remains whether activation of these receptors can excite intact nociceptive afferents. To address this issue, direct recordings of primary afferent activity have been performed, yielding somewhat controversial results. In vivo, the P2X receptor agonist α,β-meATP was unable to excite corneal nociceptors (Dowd et al., 1997) or tooth pulp afferents in the cat (Matthews et al., 1997). In contrast, intra-arterial or intra-articular injections of either ATP or α,β-meATP into the knee joint in the anesthetized rat evoked a rapid and short-lasting excitation of C- and Aδ-fibers in afferent nerves innervating this joint (Dowd et al., 1998). These agonists were also able to evoke discharges in vitro in nociceptive afferents in the skin-nerve preparation (Hamilton and McMahon, 2000) and in capsaicin-sensitive fibers in a preparation of intra-arterially perfused rat tongue (Rong et al., 2000). Recordings from mesenteric nerves in the anesthetized rat have also shown that ATP and α,β-meATP can directly excite visceral afferents, confirming the presence of functional P2X receptors (Kirkup et al., 1999). The reasons for these discrepancies remain unclear; of those discussed, species differences and limited access of test compounds to relevant sites seem most plausible (Dowd et al., 1998).
Behavioral studies also support the existence of functional P2X receptors on peripheral nociceptors. Intraplantar applications of ATP, as well as of the P2X1/P2X3agonist α,β-meATP, have been shown to evoke nocifensive behavior or to cause thermal or mechanical hypersensitivity in rats (seeSection V.A. and Table 2). These behavioral changes could be abolished by a local anesthetic or by nociceptor desensitization using topical application of capsaicin (Bland-Ward and Humphrey, 1997), indicating their primary afferent origin. Neonatal treatment with capsaicin, which is known to selectively destroy fine heat-sensitive nociceptor afferents, selectively abolished α,β-meATP-induced thermal hyperalgesia without affecting the mechanical allodynia (Tsuda et al., 2000). This treatment also decreased the proportion of DRG neurons showing rapid desensitization of responses to α,β-meATP, whereas the percentage of cells with slowly desensitizing responses was not changed. Together with electrophysiological evidence discussed above, these data confirm that functional P2X2/3receptors are localized on medium-caliber, mechanosensitive afferents, whereas homomeric P2X3 receptors are predominant on small-diameter heat-sensitive nociceptors, contributing to ATP-evoked mechanical allodynia and thermal hyperalgesia, respectively (Tsuda et al., 2000). Recent data from P2X3receptor null-mutant mice suggest that most of the nociceptive response to peripheral ATP is mediated by homo- or heteromeric P2X3 receptors, although some contribution of other PPADS-sensitive P2X receptors was also observed (Cockayne et al., 2000; Souslova et al., 2000).
Some behavioral evidence that P2X receptor function in the periphery can be increased under conditions of inflammation also indirectly points at the functional presence of proton-sensitive P2X receptors, such as P2X2/3 heteromeric assemblies (seeSection V.B. and Table 2).
IV. Central P2X Receptors and Nociceptive Transmission
A. ATP As Nociceptive Neuromodulator or Neurotransmitter
In addition to sensing ATP in the periphery, P2X receptors can also be involved in the processing of nociceptive stimuli in the spinal cord. The role of ATP as nociceptive neurotransmitter has been suggested by reports showing its release from the terminals of primary afferents in the spinal cord. Early reports demonstrated the release of ATP from peripheral endings of primary sensory neurons and hypothesized that the same may also occur centrally (Holton and Holton, 1954:Holton, 1959). This was later confirmed by findings that exposure to depolarising concentrations of potassium (White et al., 1985) or capsaicin (Sweeney et al., 1989) led to release ATP from dorsal spinal cord synaptosomes in a calcium-dependent manner. Prior dorsal rhizotomy greatly reduced, but did not fully abolish the release of ATP in this preparation, indicating that, although it was largely originating from central terminals of primary afferent neurons, a proportion of second order spinal neurons could also release ATP (Sawynok et al., 1993).
ATP released in the spinal cord upon peripheral noxious stimulation may act at presynaptic and/or postsynaptic P2X receptors. These different populations of spinal ATP receptors are functionally distinct and appear to have different subtype composition.
B. P2X Receptor Involvement in Spinal Nociceptive Transmission
Consistent with the predominant expression of P2X1, P2X2 and P2X3 receptors on small DRG neurons (seeSection II.B.), these receptors are localized on the central terminals of thin nociceptive fibers in the superficial dorsal horn (lamina II) of the spinal cord (Vulchanova et al., 1996, 1997, 1998). Their presynaptic localization suggests a role in controlling neurotransmitter release; indeed, there is some evidence that they may facilitate glutamate release onto second order neurons. Whole cell recordings from substantia gelatinosa neurons in spinal cord slices showed that bath applied ATP can evoke a fast inward current and potentiate both glutamate- and synaptically-induced currents (Li and Perl, 1995). In a DRG-dorsal horn coculture system, focal applications of ATP to DRG neurons were found to induce glutamate release onto dorsal horn neurons (Gu and MacDermott, 1997; Labrakakis et al., 2000). The time-courses of ATP-gated currents recorded at the cell bodies were mirrored by the time-courses of transmitter release from the DRG nerve terminals, indicating similar P2X receptor properties on the soma and their associated terminals (Labrakakis et al., 2000). Another study in spinal cord slices demonstrated that the P2X receptor antagonist PPADS can inhibit glutamatergic excitatory postsynaptic currents (EPSCs) in superficial dorsal horn neurons evoked by primary afferent stimulation (Li et al., 1998b). The alteration of responses to paired-pulse stimulation reported in this work suggested the involvement of a presynaptic PPADS-sensitive facilitatory mechanism. Consistent with these in vitro data, in the mouse spinal cord in vivo, the hyperalgesia evoked by intrathecally applied α,β-meATP could be antagonized by the exocytosis inhibitor botulinum neurotoxin B and NMDA receptor antagonists (Tsuda et al., 1999b).
All these findings are consistent with the role of synaptically released ATP as a positive modulator of glutamatergic nociceptive transmission in the spinal cord via presynaptic P2X receptors. However, the involvement of this mechanism in segmental nociceptive transmission appears to be variable and probably limited to some populations of lamina II neurons. Some authors saw little effect of PPADS on evoked or miniature glutamatergic EPSCs in dorsal horn lamina II neurons in spinal cord slices (Gu et al., 1998). In our hands, the selective P2X1/P2X2/3/P2X3receptor antagonist TNP-ATP (up to 10 μM) did not alter the population motoneuron EPSP evoked by high intensity dorsal root stimulation in the hemisected spinal cord preparation of the immature rat in vitro (Chizh, unpublished observations). Thus, the overall contribution of these receptors in acute segmental nociceptive transmission in the spinal cord appears to be limited.
In addition to presynaptic receptors, the existence of postsynaptic P2X receptors on second order spinal cord neurons has been shown (seeSection II.B.). Neurons in the spinal trigeminal nucleus and dorsal horn of the spinal cord showed excitation in response to iontophoretic ATP administration in vivo (Salt and Hill, 1983; Fyffe and Perl, 1984; Salter and Henry, 1985). An inward current was observed in cultured (Jahr and Jessell, 1983; Hugel and Schlichter, 2000) or acutely dissociated (Bardoni et al., 1997; Rhee et al., 2000) dorsal horn neurons exposed to ATP. At the mRNA level, the most abundant P2X receptors in the spinal dorsal horn are of P2X2, P2X4 and P2X6 subtypes (Collo et al., 1996), suggesting their role in fast purinergic transmission in the spinal cord. Consistent with that, acutely dissociated dorsal horn neurons showed nondesensitizing responses to ATP that were variably inhibited by the P2X receptor antagonists suramin and PPADS, and were largely insensitive to the P2X1/P2X3 receptor agonist α,β-meATP (Bardoni et al., 1997). These properties of the native receptors would be generally compatible with those of homomeric P2X2 and heteromeric P2X4/6receptors, as well as homomeric assemblies of P2X4 and P2X6 receptor (seeSection II.C.); the variability of the antagonist sensitivity suggests that the population of dorsal horn neurons was not homogeneous (the homomeric P2X2 and heteromeric P2X4/6 receptors are sensitive, and the homomeric P2X4 and P2X6 are largely insensitive to suramin and PPADS, see Section II.C.).
Although all these findings indicate a potential role of postsynaptic P2X receptors in spinal nociceptive transmission, studies directly addressing this issue have shown that only a small proportion of dorsal horn neurons have purinergic synaptic input. Bardoni et al. (1997) have found that only <5% of the tested lamina II neurons showed ATP-mediated EPSCs in response to dorsal root stimulation. Another group could not detect any residual current in superficial dorsal horn neurons in spinal cord slices after blocking the glutamatergic component of monosynaptic EPSCs evoked by afferent fiber stimulation (Li et al., 1998b).
Another potential source of synaptic ATP in the spinal cord is spinal interneurons. The presence of ATP-ergic neurons in the dorsal horn is suggested by the fact that prior dorsal rhizotomy did not completely abolish the release of ATP from dorsal spinal cord synaptosomes (Sawynok et al., 1993). Whole cell patch-clamp recordings from cultured neurons of superficial laminae of the dorsal horn have demonstrated that approximately half the cells utilize ATP as a fast excitatory transmitter acting at suramin- and PPADS-sensitive P2X receptors (Jo and Schlichter, 1999). All of these cells coreleased the inhibitory neurotransmitter GABA with ATP, and vice versa, the majority of neurons releasing GABA also released ATP, thus suggesting that GABAergic interneurons represent a major source of synaptic ATP in the spinal cord.
Both presynaptic action of ATP at P2X receptors enhancing glutamate release and its excitatory effects via postsynaptic P2X receptors on second order neurons would be generally consistent with its role in conveying nociceptive information in the spinal cord. However, ATP has also been shown to facilitate glycine- (Rhee et al., 2000) and GABAergic (Hugel and Schlichter, 2000) spontaneous inhibitory postsynaptic currents at dorsal horn neuron synapses; in both reports the effects were sensitive to the P2X receptor antagonists suramin and PPADS. Thus, P2X receptor-mediated activation of inhibitory interneurons by synaptically released ATP could inhibit nociceptive transmission. It is conceivable that a fine balance of excitatory and inhibitory components of ATPergic transmission may exist under normal conditions; it is also likely that this balance could shift under conditions of chronic pain, when major morphological changes in spinal cord organization, such as loss of inhibitory interneurons, take place. Thus, the role of P2X receptors in pain, and, respectively, the efficacy of the receptor antagonists may be expected to rise upon transition from acute to chronic states. The evidence for this comes largely from in vivo studies and will be discussed below (see also Table 3).
V. Role of ATP and P2X Receptors in Different Pain States
Generally, the progress in pharmacological characterization of the role of P2X receptors in pain in vivo has been greatly hampered by lack of selective, potent and stable tools that could be used systemically. For that reason, most of the studies in pain models have utilized topical (largely intraplantar and intrathecal) administration of agonists and antagonists. With this approach, high concentrations of compounds are used that cannot be directly compared with those active in vitro, which potentially confounds the results. This is at least one factor that may have contributed to the numerous discrepancies between the existing in vivo findings. On the other hand, topical peripheral and spinal administration of tool substances allows to unravel the roles in nociception of peripheral and spinal P2X receptors, respectively (see Tables 2 and 3). In some pain models this approach has proved successful in demonstrating the role of P2X receptors and endogenous ATP. The degree of this involvement, however, appears to vary depending on the painful condition investigated.
A. Acute Pain
Peripheral administration of P2X receptor agonists rapidly causes nocifensive behavior in experimental animals and pain sensation in humans. Thus, subcutaneous injection of the P2X receptor agonist α,β-meATP evoked hindpaw lifting and licking immediately after the administration (Bland-Ward and Humphrey, 1997). Benzoylbenzoyl-ATP, another P2X receptor agonist, has been shown to cause similar behavioral responses after injection into the rat paw; the effect was potentiated by a selective allosteric enhancer of P2X3 and P2X2/3 receptors, cibacron blue, and inhibited by the P2X1/P2X3/P2X2/3receptor antagonist TNP-ATP (Jarvis et al., 2001). In human volunteers, iontophoretic application of ATP onto skin evoked dose-related pain sensation (Hamilton et al., 2000). In addition to the ability to directly evoke pain or nociceptive behavior, both ATP and α,β-meATP have been demonstrated to cause a hypersensitivity to thermal or mechanical stimuli (Tsuda et al., 2000). Coadministration of ATP and α,β-meATP with formalin has also been shown to enhance the flinching response, especially in the second phase; the effect was antagonized by the P2X receptor antagonists suramin and PPADS (Sawynok and Reid, 1997).
Despite the apparent functionality of P2X receptors on nociceptors and the ability of the agonists to evoke nocifensive behavior or pain sensation, their role in physiological nociception seems to be limited. In studies using standard models of acute pain, such as tail-flick or hot-plate, little change in the latency of nociceptive responses was observed after intrathecal administration of the P2X receptor antagonist PPADS (Driessen et al., 1994; Li et al., 1998b). No inhibition of C-fiber-evoked responses of spinal dorsal horn neurons was observed in anesthetized rats after spinal administration of PPADS or suramin, the nonselective P2 receptor antagonist (Stanfa et al., 2000). These in vivo findings are in agreement with the limited involvement of P2X receptors in nociceptive synaptic transmission in the spinal cord in vitro (see Section IV.). Theoretically, the role of P2X receptors in acute pain should increase if extracellular levels of ATP are elevated, e.g., as a result of tissue damage. Lysates of human erythrocytes contain ATP and produce pain when applied to a human blister base (Bleehen et al., 1976). A direct activation of nociceptors via P2X receptors by endogenous ATP released by skin cell injury has recently been demonstrated in vitro (Cook and McCleskey, 2000). However, the importance of these mechanisms in vivo still needs to be demonstrated in experiments with selective antagonists.
Formalin-induced nociception can be considered as a model of chemically induced tissue injury. When the role of peripheral P2X receptors in this model was studied using intraplantar injections of α,β-meATP to produce their selective desensitization, no inhibition of nociception was observed, although this pre-emptive treatment was able to completely abolish the agonist-evoked nociception (Bland-Ward and Humphrey, 1997). Intrathecal administration of the P2X receptor-selective antagonists PPADS and TNP-ATP in mice caused a mild inhibition of the nociceptive behavior in the first “acute” phase of the formalin test (Tsuda et al., 1999a). Both the first and second phases of formalin-evoked nociceptive behavior in the rat were potentiated by peripheral administration of the selective allosteric P2X3 receptor enhancer Cibacron blue and inhibited by the P2X3 receptor antagonist TNP-ATP (Jarvis et al., 2001). Formalin-induced nociception, especially in the late phase, appears to involve tissue inflammation and nerve injury components (Tjølsen et al., 1992); the role of P2X receptors in inflammatory and neuropathic pain is discussed below (seeSections V.B. and V.C.).
Thus, both agonist and antagonist behavioral studies suggest that P2X receptors contribute to acute nociception, but only under conditions of tissue injury. The selectivity profile of the used ligands suggests a predominant role for homomeric P2X3 and/or heteromeric P2X2/3 receptors. Consistent with the pharmacological findings discussed above, analysis of P2X3 receptor knock-out mice did not reveal any role of this receptor subtype in responses to noxious mechanical or thermal stimuli (Cockayne et al., 2000; Souslova et al., 2000). The formalin-induced pain behavior in these mutants was, however, significantly attenuated in both the early and late phases compared with wild-type mice, thus confirming the involvement P2X3 receptors in pain induced by tissue injury. The role of P2X receptors in acute visceral pain is discussed below (see Section V.D.). P2X1 receptor knock-out mice have also been described (Mulryan et al., 2000); however, no nociception-related phenotypic difference from wild-type animals was mentioned in the report.
B. Inflammatory Pain
Tissue inflammation has been demonstrated to potentiate nociception evoked by peripherally applied P2X receptor agonists. In an in vitro skin-nerve preparation, nociceptor responses to α,β-meATP were greatly enhanced in the presence of carrageenan-induced skin inflammation (Hamilton and McMahon, 2000). Nociceptive responses and hyperalgesia induced by intraplantar injection of ATP or α,β-meATP were substantially potentiated in rats with skin inflammation caused by carrageenan or ultraviolet irradiation (Hamilton et al., 1999). In human volunteers, the original observations on the algogenic action of ATP were done using blister base applications, i.e., under conditions of inflammation (Bleehen et al., 1976; Bleehen and Keele, 1977). In a more recent human study, pain caused by electrophoretic application of ATP to the skin was markedly enhanced by ultraviolet irradiation (Hamilton et al., 2000). On the contrary, Dowd et al. (1998) did not find any change in the C- and Aδ-afferent fiber response to intra-articular α,β-meATP injection into the knee joint after the induction of chronic arthritis in the anesthetized rat. Thus, peripheral P2X receptors may play different roles in inflammatory pain of different origin.
P2X receptor antagonists appear to be antinociceptive in several models of inflammatory pain in vivo. Several studies have reported inhibition of nociceptive behavior in the formalin test after intrathecal administration of suramin, PPADS, or TNP-ATP (see Section V.A.). The nonselective P2 antagonist suramin reduced C-fiber-evoked activity of dorsal horn neurons after spinal administration in carrageenan-inflamed, but not normal rats; the P2X receptor antagonist PPADS produced a similar, although not statistically significant, inhibition (Stanfa et al., 2000).
One potential mechanism of inflammatory hyperalgesia is accumulation of ATP in the periphery (Burnstock, 1996; Burnstock and Wood, 1996). Elevated levels of ATP in inflamed tissues have been observed in experimental animals and in arthritic patients (Gordon, 1986; Ryan et al., 1991; Park et al., 1996). Additionally, a functional up-regulation of P2X receptors in inflammation may occur. This could be due to the proton sensitivity of some P2X subtypes, e.g., of the P2X2 and P2X2/3 receptors (see Section II.C.), whereby tissue acidosis could substantially potentiate nociceptor activity triggered by these receptors. The importance of this mechanism can be expected to be higher in the periphery, where tissue inflammation has been shown to be able to shift the pH to values as low as 5.5 (Reeh and Steen, 1996). Other endogenous agents that can be released during inflammation can also potentiate nociceptor responses to ATP. Thus, substance P and bradykinin have been shown to substantially enhance responses of small DRG neurons to ATP (Hu and Li, 1996). Behaviorally, responses to intraplantar injection of ATP or α,β-meATP in rats were substantially potentiated after pretreatment with prostaglandin E2 (Hamilton et al., 1999). Therefore, peripheral rather than central administration of P2X receptor antagonists could be expected to have a greater effect on inflammatory hypersensitivity; whether this is the case remains to be investigated.
A substantial attenuation of the nociceptive response to formalin has recently been reported in P2X3 receptor null-mutant mice (Cockayne et al., 2000; Souslova et al., 2000). Surprisingly, carrageenan inflammation evoked greater rather than lower hyperalgesic responses in the P2X3 receptor knock-out mice compared with their wild-type controls (Souslova et al., 2000). This raises the question of a possible up-regulation of other receptor or ion channel systems because of P2X3receptor genetic deletion. An up-regulation of, e.g., P2X2 receptors in these mice could manifest as an increased inflammatory hypersensitivity because of their proton sensitivity (see above).
C. Neuropathic Pain
There are several lines of evidence indicating that P2X receptors could contribute to neuropathic pain. Peripheral nerve injury has been shown to regulate the expression of peripheral P2X3 receptors, although the direction of the change appears to vary depending on the kind of injury. Thus, a profound (>50%) glial-derived neurotrophic factor-dependent down-regulation of P2X3 receptor expression in DRGs of the lumbar segments 4 and 5 was observed after sciatic nerve axotomy (Bradbury et al., 1998). Similarly, a significant decrease in numbers of P2X3 receptor-like immunoreactive neurons was observed in human DRG after central axotomy in patients with brachial plexus injuries (Yiangou et al., 2000). In contrast, an increase of the number of P2X3receptor-immunoreactive DRG neurons was demonstrated after a chronic constriction injury of the sciatic nerve (Novakovic et al., 1999). P2X receptor immunoreactivity was also increased in the spinal dorsal horn ipsilateral to the nerve injury, consistent with up-regulation of these receptors on intraspinal terminals of primary afferents. Chronic constriction injury of the inferior alveolar nerve has also been demonstrated to cause a substantial increase of the number of P2X3 receptor-immunoreactive neurons in trigeminal ganglia (Eriksson et al., 1998). Importantly, accumulation of P2X3 receptor immunoreactivity was observed in nerve endings at the site of injury. This local up-regulation of P2X receptors may be responsible for the development of ectopic purinergic sensitivity at the sites of nerve injury. Indeed, intravenous injection of ATP has been reported to excite afferents in the nerve with chronic constriction injury without affecting nerve fibers on the contralateral side; the effect was antagonized by the P2 receptor antagonist reactive blue 2 (Chen et al., 1999).
The potential contribution of P2X receptors to neuropathic pain is frequently discussed in the context of sympathetically maintained pain (Burnstock and Wood, 1996; Burnstock, 2000). The involvement of the sympathetic nervous system in some patients with neuropathic pain has been documented (Roberts, 1986). Indeed, sympathectomy or sympathetic nerve block has been shown to alleviate pain in such patients (Richards, 1967; Bonica, 1990) and in some animals with spinal nerve injury (Kim and Chung, 1991; Kim et al., 1993; Kinnman and Levine, 1995). Adrenergic antagonists, however, showed more limited efficacy in reducing neuropathic pain in these models than sympathectomy (Kim et al., 1993, Lee et al., 1997), implying that the release of ATP from sympathetic postganglionic neurons sprouting into dorsal root ganglia may contribute to this process (Burnstock, 1990, 1996; Burnstock and Wood, 1996). One recent study analyzed the effects of sympathectomy and of block of adreno- and purinoreceptors in the spinal nerve ligation model of neuropathic pain in the rat (Park et al., 2000). Indeed, a clear division of neuropathic animals into “responders” and “nonresponders” to a combined systemic administration of the P2 antagonist suramin and the α-adrenoreceptor antagonist phentolamine was observed. In the responder subpopulation, consistent antiallodynic effects of the drug combination were observed after repeated treatments. Unfortunately, suramin is not a selective P2X receptor antagonist, and one cannot conclude from this study which P2X receptors are particularly involved in this sympathetically maintained allodynia. Other authors have failed to demonstrate any effect of suramin or a more selective P2X receptor antagonist PPADS in various models of neuropathic pain (Liu and Tracey, 2000; Stanfa et al., 2000). The known variability of the sympathetic component of neuropathic pain could be one explanation for these negative findings. Moreover, these other studies used intrathecal administration of antagonists; peripheral sites of ectopic purinergic sensitivity (see above) are unlikely to have been accessed by the antagonist given by this route. The reported lack of antiallodynic effect of intrathecally administered P2X receptor antagonists after peripheral nerve injury does imply that spinal P2X receptors play little role in the maintenance of this form of neuropathic pain. Nevertheless, given the limitations of the compounds used in these studies, this issue will need to be revisited when more potent, stable, and selective antagonists become available.
D. Visceral Pain
Burnstock (1996, 1999, 2001) has proposed that ATP plays an important role in visceral pain perception. According to his hypothesis, ATP can be released from epithelial cells upon distension of hollow visceral organs leading to activation of P2X3 and/or P2X2/3receptors on visceral afferents (Burnstock, 1999). Thus, excessive distensions would release ATP in amounts sufficient to reach the receptors on extrinsic sensory nerves that would convey this information to the central nervous system, with colic pain as a consequence, whereas moderate distensions would only activate P2X receptors on intrinsic sensory fibers and contribute to peristalsis (Barthó et al., 1999; Burnstock, 2001). Some evidence has been accumulated supporting this hypothesis. Thus, ATP-mediated synaptic potentials have been observed in enteric neurons (Galligan and Bertrand, 1994). ATP release from urothelial cells has been documented upon changing the hydrostatic pressure in the bladder (Ferguson et al., 1997; Grygorczyk and Hanrahan, 1997). In an in vitro rat bladder-pelvic nerve preparation, increases in the nerve discharge have been recorded in response to bladder distensions; this activity was inhibited by the P2 receptor antagonist suramin, indicating a possible involvement of ATP (Namasivayam et al., 1999). In this preparation, desensitization of P2X receptors by infusion of the P2X1/P2X3/P2X2/3receptor agonist α,β-meATP into the bladder also inhibited evoked afferent nerve discharges, confirming the involvement of functional P2X receptors on visceral afferents in this response. In an in vivo study in the anesthetized rat, ATP or α,β-meATP injections into the arteries supplying the gut evoked a biphasic increase of mesenteric afferent nerve activity (Kirkup et al., 1999). The second burst of activity was parallel to, and probably caused by, an increase in the intrajejunal pressure; both the early and the late phase of the afferent nerve response and the agonist-evoked rise in pressure were antagonized by systemic administration of the P2X receptor antagonists suramin or PPADS.
Of the P2X receptor subtypes, the homomeric P2X3and heteromeric P2X2/3 receptors seem to be the likely candidates to mediate the action of ATP in visceral pain. Immunohistochemical studies have shown the presence of P2X3 receptors on small-diameter DRG neurons with projections into the pelvic nerve (Bradbury et al., 1998) and on sensory neurons innervating the bladder (Elneil et al., 1999; Cockayne et al., 2000). Neurons in nodose ganglia, where the somata of vagal afferents are localized, express functional P2X2and P2X2/3 receptors (see Section III.B.). Recently, an important role of P2X3receptors in bladder sensitivity to distension has been demonstrated in the P2X3 receptor knock-out mice (Cockayne et al., 2000). The P2X3 receptor null mice showed a significant increase in bladder capacity and decrease in micturition frequency, as well as greatly reduced distension-evoked bladder contractions. The involvement of the P2X3receptor in the afferent control of physiological bladder regulation warrants further studies under painful conditions, e.g., cystitis.
VI. Conclusions
Activation of certain P2X receptor types by ATP appears to be an important factor in several pain states. P2X receptors, in particular P2X3 and P2X2/3 receptors, represent attractive targets for the treatment of inflammatory, visceral, and possibly also neuropathic pain. Further progress in this area is hampered by the lack of potent and selective antagonists sufficiently resistant to enzymatic degradation under in vivo conditions.
Acknowledgments
We are grateful to Dr. H. Himmel for critically reading the manuscript. The support of the Bundesministerium für Bildung, Forschung und Technologie, Leitprojekt “Molekulare Schmerzforschung” (01GG981/0) is acknowledged.
Footnotes
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↵1 Address for correspondence: Dr. Peter Illes, Rudolf-Boehm Institute of Pharmacology and Toxicology, University of Leipzig, Härtelstrasse 16-18, D-04107 Leipzig, Germany. E-mail:illp{at}medizin.uni-leipzig.de
Abbreviations
- DRG
- dorsal root ganglion
- α,β-meATP
- α,β-methylene-ATP
- PPADS
- pyridoxalphosphate-6-azophenyl-2′,4′-disulfonic acid
- TNP-ATP
- 2′,3′-O-trinitrophenyl-ATP
- IP5I
- diinosine pentaphosphate
- EPSC
- excitatory postsynaptic current
- The American Society for Pharmacology and Experimental Therapeutics
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