Effect of genetic deletion and pharmacological antagonism of P2X7 receptors in a mouse animal model of migraine

Headache is a common pain disorder affecting an estimated 11% of the general population [1] and the global prevalence of chronic migraine is 0.5-1% [2]. Despite increasing knowledge regarding migraine pathophysiology, drug therapies used for prevention and treatment of symptoms remain unsatisfactory for many patients. Therefore, it is necessary to continue development of new drugs and to identify promising new cellular or molecular targets [3].

Migraine is a complex brain disorder, characterized by predominantly unilateral pulsating head pain, which can be aggravated by routine physical activity and accompanied by neurological symptoms including nausea, vomiting, hypersensitivity to light, sound and smell and visual disturbances as well as cognitive, emotional and motor disturbances. Before and during migraine attacks, headache is accompanied by increased skin sensitivity to touch, heat and cold (cutaneous allodynia) [4, 5] and normally innocuous stimuli can be unpleasant and painful.

Among the variety of experimental models of migraine attacks, nitroglycerin (NTG) is amongst the most widely used and accepted approaches, in both animals and human [6]. Several reports show that the clinical use of NTG induces delayed spontaneous headache in migraine patients [7‐9] coupled with accompanying symptoms. NTG-derived nitric oxide (NO) activates brainstem regions and neuronal populations which are involved in environmentally triggered migraine attacks [10] and prophylactic agents can block NTG-induced headaches in human [11, 12]. Furthermore, NTG can provoke cutaneous allodynia in migraine sufferers [13] including in non-cranial regions [4, 5]. Previous studies showed that systemic administration of NTG induces hyperalgesia of the hindpaws, which is inhibited by the antimigraine drug sumatriptan in mice [14]. These observations validate extrafacial thermal and mechanical hyperalgesia as a potential behavioural correlate of migraine in mice subjected to NTG. NTG administration also activates neuronal populations in selected areas of the brain that are primarily involved in the transmission of cephalic pain, including the trigeminal nucleus caudalis (TNC) in rodents [14‐16]. Chemical activation of the C-fibers of the trigeminal nerve - leading to transmission of nociceptive information into the brainstem - induces c-fos expression within specific areas of the TNC. This is inhibited by anti-migraine therapeutics, such as olcegepant [17]. These findings indicate that those drugs, which influence c-fos expression in the TNC might have relevance in the mediation of potential anti-migraine effects.

The purinergic signalling system consists of enzymes, transporters and receptors responsible for the action of extracellular nucleotides, particularly ATP and adenosine. The actions of extracellular nucleotides are mediated by various subtypes of ionotropic P2X (P2X1-7) and metabotropic P2Y (P2Y₁, P2Y₂, P2Y₄, P2Y₆, P2Y₁₁, P2Y₁₂, P2Y₁₃, P2Y₁₄) receptors. The potential involvement of the purinergic signalling system in the pathophysiology of migraine was recognized more than thirty years ago [18]. Since then, the role of different subtypes of P2 receptors has been elucidated in different pain modalities, amongst which, the role of P2X3, and various P2Y receptor subtypes have already been proposed and examined in cellular and animal models of migraine [19‐24]. ATP is released during spreading depression (SD), a phenomenon thought to underlie aura both in vitro [25] and in vivo [26], which raises the possibility that endogenous purines could act as potential triggers or mediators of migraine.

P2X7 receptors (P2X7) belong to the P2X family of receptors, which are ligand-gated, non-selective cation channels. P2X7 is widely expressed in various cell types involved in pain transmission, including neurons, microglia, satellite glial cells, astrocytes in dorsal root ganglia, trigeminal ganglia and the dorsal horn of the spinal cord e.g. [27‐29]. Several studies have demonstrated that P2X7 is involved in the modulation of pathological nociception. P2X7 knockout mice showed a lack of hypersensitivity to mechanical and thermal stimuli [30, 31] and P2X7-specific antagonists have consistently been shown to be protective in animal models of inflammatory [32‐34] and neuropathic pain [33, 35]. Moreover, recent studies have highlighted that variation within the gene encoding P2X7 can affect chronic pain sensitivity in both mouse and human [36]. The role of P2X7, however, has not examined in any whole animal model of migraine.

The objective of this study, therefore, was to examine how genetic deletion and pharmacological blockade of P2X7 affects NTG-induced thermal hypersensitivity and c-fos induction in migraine related CNS areas in mice. We report here that although genetic deletion of P2X7 (P2X7-/-) results in non-significant changes in the nociceptive threshold after NTG treatment, the selective P2X7 antagonist, BBG completely prevents the effect of NTG in wild-type, but not in P2X7-/- mice and also alleviates NTG-induced c-fos expression.

The principal new finding of the present study is that antagonism of P2X7 by treatment with the specific P2X7 antagonist BBG leads to the alleviation of NTG-induced thermal hypersensitivity in mice. Moreover, as BBG treatment was ineffective in mice lacking P2X7, it is reasonable to assume that its effect is mediated by P2X7. The NTG-evoked c-fos expression in the TNC was also attenuated after subacute BBG treatment, which implicates a role for the TNC in mediating the effect of BBG on NTG-induced thermal hypersensitivity. All these findings implicate the therapeutic potential of P2X7 blockade in migraine.

We have used the NTG-induced migraine model described recently by Bates et al. [14] and reproduced findings showing that i.p. injection of NTG elicits thermal hypersensitivity in a time-dependent manner. We have also replicated the finding that NTG-induced thermal hypersensitivity is attenuated by the antimigraine drug, sumatriptan, and is followed by the expression of c-fos in the trigeminal nucleus of the brainstem and upper spinal cord [14]. Although the dose of NTG necessary to induce a significant drop in PWT (15 mg/kg), was somewhat higher than used by Bates et al. [14], this may be explained by differences in the source of NTG, or by the variation in the tests used to evaluate thermal nociception (Hargreaves test vs. ITHT). The interspecies variations in NTG sensitivity are well known and may be due to differences in the efficiency of hepatic bioactivation of NTG into the pharmacologically active NO [40]. This might also account for slight differences between NTG responsiveness observed in different rodent species [14‐16].

Following the study of Almási et al. [41], we have used the ITHT to measure thermal nociceptive threshold, in our experiments instead of the widely used latency measurements. As reported in this study, ITHT is a more accurate assay of thermal hyperalgesia although the changes in response to traditional analgesic drugs, such as diclofenac and paracetamol, are not more than 2.0-2.5°C in this test. Accordingly, similar changes were measured, in response to the antimigraine drug sumatriptan, indicating that the assay system reflects changes specific to antimigraine therapy.

Interestingly, no differences in NTG-induced thermal hypersensitivity in P2X7-/- mice were detected, when compared to their wild-type counterparts. The most likely explanation for this negative finding is the potential developmental upregulation of non-P2X7 P2X receptors in P2X7-/- mice, such as P2X3 or P2X4. In fact we have previously shown the upregulation of P2X4 mRNA in mice deficient of P2X7 [42].

When applied prophylactically, however, both acute and subacute BBG treatment was effective in the alleviation of NTG-induced thermal hypersensitivity in the P2X7+/+mice. BBG is known to permeate the blood brain barrier, and is thought to be specific to P2X7 in the applied dose. Although in vitro experiments revealed that BBG can inhibit Na⁺ channels in micromolar concentrations [43], in in vivo studies using a similar dose (45.5 mg/kg), BBG has not reached higher concentrations in the brain than 200 nM [44], which is selective for P2X7 [45]. The finding that its effect was completely lost in P2X7-/- mice also refutes the possibility of other target for BBG than P2X7 in these experiments.

Although further experiments are necessary to clarify this issue, there are several potential mechanisms, whereby endogenous P2X7 could participate in the sensitization of the trigeminovascular system. ATP is a well-known danger-signal, which is released in response to cell injury, inflammation, mechanical and metabolic distress, and is per se an algogenic substance [46, 47]. P2X7 is a ligand-gated cation channel with high Ca²⁺ permeability, which participates in pain transmission in various ways. In the dorsal root ganglia P2X7 is expressed on satellite glia and potentiate P2X3 receptor mediated signalling by the release of pro-inflammatory cytokine TNF-α [48]. An analogous mechanism might also play a part in migraine, as satellite glia of the trigeminal ganglion express P2X7 [49] and P2X3 receptors participate in craniofacial pain by interacting with NGF, substance P and CGRP [20, 22]. P2X3 receptors also display an enhanced activity in a genetic animal model of migraine [50]. Alternatively, P2X7 antagonists may act more centrally, at the level of the upper cervical spinal cord or trigeminal nucleus. P2X7 modulates the afferent nociceptive information processing within the dorsal horn of the spinal cord [35] and its activation participates in the central sensitization underlying hindpaw hyperalgesia [34]. Because moderate-high density of P2X7 receptor binding sites were found in the grey matter of the trigeminal nucleus [28] the detected alleviation of NTG induced c-fos expression in response to BBG indicates that the TNC is a potential target area for the action of P2X7 receptor antagonists. The activation of P2X7 releases excitatory amino acids in this area [27], the blockade of which might underlie the action of BBG.

Furthermore, P2X7 is also expressed in other areas of the brain [28]; therefore, a supraspinal action through diencephalic, brainstem or cortical regions cannot be excluded [51]. Finally, P2X7 is expressed on circulating and locally recruited immune cells and the best characterized action of P2X7 activation is its role in the posttranslational processing of pro-inflammatory cytokines, IL-1β and TNF-α [30, 37, 52], which are also known algogenic substances.

The data present here indicates that inhibition of P2X7 might be a potential target for the prophylaxis of migraine. Moreover, because BBG is a closed structural analogue of a US Food and Drug Administration (FDA)–approved non-toxic food dye [53, 54], our data argues for its evaluation in a human NTG-induced migraine model.