Crosstalking interactions between P2X4 and 5-HT3A receptors.

Ionotropic receptors are ligand-gated ion channels triggering fast neurotransmitter responses. Among them, P2X and 5-HT3 receptors have been shown to physically interact each other and functionally inducing cross inhibitory responses. Nevertheless, despite the importance of P2X4 and 5-HT3A receptors that mediate for example neuropathic pain and psychosis respectively, complementary evidence has recently started to move forward in the understanding of this interaction. In this review, we discuss current evidence supporting the mechanism of crosstalking between both receptors, from the structural to the transduction pathway level. We expect this work may guide the design of further experiments to obtain a comprehensive view for the neuropharmacological role of these interacting receptors. This article is part of the Special Issue on "The receptor-receptor interaction as a new target for therapy".

New Insights of the Zn(II)-Induced P2 × 4R Positive Allosteric Modulation: Role of Head Receptor Domain SS2/SS3, E160 and D170.

P2 × 4R is allosterically modulated by Zn(II), and despite the efforts to understand the mechanism, there is not a consensus proposal; C132 is a critical amino acid for the Zn(II) modulation, and this residue is located in the receptor head domain, forming disulfide SS3. To ascertain the role of the SS2/SS3 microenvironment on the rP2 × 4R Zn(II)-induced allosteric modulation, we investigated the contribution of each individual SS2/SS3 cysteine plus carboxylic acid residues E118, E160, and D170, located in the immediate vicinity of the SS2/SS3 disulfide bonds. To this aim, we combined electrophysiological recordings with protein chemical alkylation using thiol reagents such as N-ethylmaleimide or iodoacetamide, and a mutation of key amino acid residues together with P2 × 4 receptor bioinformatics. P2 × 4R alkylation in the presence of the metal obliterated the allosteric modulation, a finding supported by the site-directed mutagenesis of C132 and C149 by a corresponding alanine. In addition, while E118Q was sensitive to Zn(II) modulation, the wild type receptor, mutants E160Q and D170N, were not, suggesting that these acid residues participate in the modulatory mechanism. Poisson-Boltzmann analysis indicated that the E160Q and D170N mutants showed a shift towards more positive electrostatic potential in the SS2/SS3 microenvironment. Present results highlight the role of C132 and C149 as putative Zn(II) ligands; in addition, we infer that acid residues E160 and D170 play a role attracting Zn(II) to the head receptor domain.

P2X4 Receptors on Muscle Macrophages Are Required for Development of Hyperalgesia in an Animal Model of Activity-Induced Muscle Pain.

Activity-induced pain is common in those with chronic musculoskeletal pain and limits participation in daily activities and exercise. Our laboratory developed a model of activity-induced pain and shows that depletion of muscle macrophages prevents development of hyperalgesia. Adenosine triphosphate (ATP) is released from fatiguing muscle and activates purinergic receptors (P2X), and P2X4 receptors are expressed on macrophages. We hypothesized that exercise releases ATP to activate P2X4 receptors on muscle macrophages, which subsequently release interleukin-1ß (IL-1ß) to produce hyperalgesia. In an animal model of activity-induced pain, using male and female C57BL6/J mice, we show increased expression of P2X4 on muscle macrophages, and blockade of P2X4 receptors in muscle prevented development of hyperalgesia. Using a lentivirus expressing an artificial micro-RNA to P2X4 under the control of a CD68 promoter, we decreased expression of P2X4 mRNA in cultured macrophages, decreased expression of P2X4 protein in muscle macrophages in vivo, and prevented development of activity-induced hyperalgesia. We further show that macrophages primed with LPS differentially released IL-1ß when treated with ATP in neutral or acidic pH. Lastly, blockade of IL-1ß in muscle prevented development of hyperalgesia in this model. Thus, our data suggest that P2X4 receptors could be a valid pharmacological target to control activity-induced muscle pain experienced by patients with chronic musculoskeletal pain.

Positively Charged Residues in the Head Domain of P2X4 Receptors Assist the Binding of ATP.

P2X receptors are a family of trimeric cationic channels located in the membrane of mammalian cells. They open in response to the binding of ATP. The differences between the closed and open structures have been described in detail for some members of the family. However, the order in which the conformational changes take place as ATP enters the binding cleft, and the residues involved in the intermediate stages, are still unknown. Here, we present the results of umbrella sampling simulations aimed to elucidate the sequence of conformational changes that occur during the reversible binding of ATP to the P2X4 receptor. The simulations also provided information about the interactions that develop in the course of the process. In particular, they revealed the existence of a metastable state which assists the binding. This state is stabilized by positively charged residues located in the head domain of the receptor. Based on these findings, we propose a novel mechanism for the capture of ATP by P2X4 receptors.

Dexmedetomidine attenuates P2X4 and NLRP3 expression in the spine of rats with diabetic neuropathic pain.

PURPOSE: To evaluate the effects of Dexmedetomidine (Dex) on spinal pathology and inflammatory factor in a rat model of Diabetic neuropathic pain (DNP). METHODS: The rats were divided into 3 groups (eight in each group): normal group (N group), diabetic neuropathic pain model group (DNP group), and DNP model with dexmedetomidine (Dex group). The rat model of diabetes was established with intraperitoneal streptozotocin (STZ) injections. Nerve cell ultrastructure was evaluated with transmission electron microscopy (TEM). The mechanical withdrawal threshold (MWT) and motor nerve conduction velocity (MNCV) tests documented that DNP rat model was characterized by a decreased pain threshold and nerve conduction velocity. RESULTS: Dex restored the phenotype of neurocytes, reduced the extent of demyelination and improved MWT and MNCV of DNP-treated rats (P=0.01, P=0.038, respectively). The expression of three pain-and inflammation-associated factors (P2X4, NLRP3, and IL-IP) was significantly upregulated at the protein level in DNP rats, and this change was reversed by Dex administration (P=0.0022, P=0.0092, P=0.0028, respectively). CONCLUSION: The P2X4/NLRP3 signaling pathway is implicated in the development and presence of DNP in vivo, and Dex protects from this disorder.

Dexmedetomidine attenuates P2X4 and NLRP3 expression in the spine of rats with diabetic neuropathic pain

Abstract Purpose: To evaluate the effects of Dexmedetomidine (Dex) on spinal pathology and inflammatory factor in a rat model of Diabetic neuropathic pain (DNP). Methods: The rats were divided into 3 groups (eight in each group): normal group (N group), diabetic neuropathic pain model group (DNP group), and DNP model with dexmedetomidine (Dex group). The rat model of diabetes was established with intraperitoneal streptozotocin (STZ) injections. Nerve cell ultrastructure was evaluated with transmission electron microscopy (TEM). The mechanical withdrawal threshold (MWT) and motor nerve conduction velocity (MNCV) tests documented that DNP rat model was characterized by a decreased pain threshold and nerve conduction velocity. Results: Dex restored the phenotype of neurocytes, reduced the extent of demyelination and improved MWT and MNCV of DNP-treated rats (P=0.01, P=0.038, respectively). The expression of three pain-and inflammation-associated factors (P2X4, NLRP3, and IL-IP) was significantly upregulated at the protein level in DNP rats, and this change was reversed by Dex administration (P=0.0022, P=0.0092, P=0.0028, respectively). Conclusion: The P2X4/NLRP3 signaling pathway is implicated in the development and presence of DNP in vivo, and Dex protects from this disorder.

P2X4 receptor as a modulator in the function of P2X receptor in CD4+ T cells from peripheral blood and adipose tissue.

Obesity is characterized by immune cell infiltration and inflammation. Purinergic receptors such as P2X1, 4 and 7 are expressed on immune cells and their activation contributes with an inflammatory response. However, the simultaneous expression of P2X1, 4 and 7 during overweight or obesity have not been described. Therefore, the aim of this study was to determine single and simultaneously expression and function of the P2X1, 4 and 7 receptors in lymphocytes and CD4 + T cells from peripheral blood (PB) and adipose tissue (AT). Our results showed a higher expression of the P2X4 receptor on CD4 + T cells from PB regarding P2X7 and P2X1 receptor expression. In addition, P2X4 receptor expression on CD4 + T cells from PB and AT was increased in individuals with BMI ≥ 25 Kg/m2. Moreover, a higher simultaneous expression of the P2X4 and P2X7 receptors on CD4 + T cells from AT compared to CD4 + T cells expressing P2X1 and P2X7 receptors simultaneously. Besides, CD4 + T cells expressing P2X4 and P2X7 receptors from PB and AT were augmented in individuals with BMI ≥ 25 Kg/m2. In addition, the percentage of lymphocytes and also CD4 + T cells expressing P2X4 receptor were elevated both in PB and AT compared to cells expressing P2X7 or P2X1. However, CD4 + T cells expressing P2X4 and P2X7 were augmented in AT compared to PB. The function of the receptors showed a lower shedding of CD62 L in adipose tissue mononuclear cells (ATMC) compared with peripheral blood mononuclear cells (PBMC) and a greater participation of P2X4 in the mobilization of intracellular calcium. We concluded that it was possible to determine for the first time the simultaneous expression of purinergic receptors in ATMC, where the P2X4 receptor has a greater participation in the activation of CD4 + T cells possibly modulating the function of the other two receptors.

The P2X7/P2X4 interaction shapes the purinergic response in murine macrophages.

The ATP-gated P2X4 and P2X7 receptors are cation channels, co-expressed in excitable and non-excitable cells and play important roles in pain, bone development, cytokine release and cell death. Although these receptors interact the interacting domains are unknown and the functional consequences of this interaction remain unclear. Here we show by co-immunoprecipitation that P2X4 interacts with the C-terminus of P2X7 and by fluorescence resonance energy transfer experiments that this receptor-receptor interaction is driven by ATP. Furthermore, disrupting the ATP-driven interaction by knocking-out P2X4R provoked an attenuation of P2X7-induced cell death, dye uptake and IL-1ß release in macrophages. Thus, P2X7 interacts with P2X4 via its C-terminus and disrupting the P2X7/P2X4 interaction hinders physiological responses in immune cells.

The spinal anti-inflammatory mechanism of motor cortex stimulation: cause of success and refractoriness in neuropathic pain?

BACKGROUND: Motor cortex stimulation (MCS) is an effective treatment in neuropathic pain refractory to pharmacological management. However, analgesia is not satisfactorily obtained in one third of patients. Given the importance of understanding the mechanisms to overcome therapeutic limitations, we addressed the question: what mechanisms can explain both MCS effectiveness and refractoriness? Considering the crucial role of spinal neuroimmune activation in neuropathic pain pathophysiology, we hypothesized that modulation of spinal astrocyte and microglia activity is one of the mechanisms of action of MCS. METHODS: Rats with peripheral neuropathy (chronic nerve injury model) underwent MCS and were evaluated with a nociceptive test. Following the test, these animals were divided into two groups: MCS-responsive and MCS-refractory. We also evaluated a group of neuropathic rats not stimulated and a group of sham-operated rats. Some assays included rats with peripheral neuropathy that were treated with AM251 (a cannabinoid antagonist/inverse agonist) or saline before MCS. Finally, we performed immunohistochemical analyses of glial cells (microglia and astrocytes), cytokines (TNF-α and IL-1ß), cannabinoid type 2 (CB2), µ-opioid (MOR), and purinergic P2X4 receptors in the dorsal horn of the spinal cord (DHSC). FINDINGS: MCS reversed mechanical hyperalgesia, inhibited astrocyte and microglial activity, decreased proinflammatory cytokine staining, enhanced CB2 staining, and downregulated P2X4 receptors in the DHSC ipsilateral to sciatic injury. Spinal MOR staining was also inhibited upon MCS. Pre-treatment with AM251 blocked the effects of MCS, including the inhibitory mechanism on cells. Finally, MCS-refractory animals showed similar CB2, but higher P2X4 and MOR staining intensity in the DHSC in comparison to MCS-responsive rats. CONCLUSIONS: These results indicate that MCS induces analgesia through a spinal anti-neuroinflammatory effect and the activation of the cannabinoid and opioid systems via descending inhibitory pathways. As a possible explanation for MCS refractoriness, we propose that CB2 activation is compromised, leading to cannabinoid resistance and consequently to the perpetuation of neuroinflammation and opioid inefficacy.

Identification of P2X2/P2X4/P2X6 heterotrimeric receptors using atomic force microscopy (AFM) imaging.

Seven P2X purinergic receptor subunits have been identified: P2X1-P2X7. The overlapping expression of P2X2, P2X4 and P2X6 subunits has been shown in different cell types, and functional analysis of P2X receptors in Leydig cells suggests that the three subunits might interact. Here, His6-tagged P2X2, HA-tagged P2X4 and FLAG-tagged P2X6 subunits were co-expressed in tsA 201 cells. After sequential co-immunoprecipitation using anti-HA and anti-FLAG beads, all three subunits were present, demonstrating their interaction. Atomic force microscopy (AFM) imaging revealed receptors that were specifically decorated by both an anti-His6 antibody and an anti-HA Fab fragment, indicating the presence of a P2X2/4/6 heterotrimer. To our knowledge, this is the first report of a P2X receptor containing three different subunits.

P2X4 subunits are part of P2X native channels in murine myenteric neurons.

The aim of the present study was to investigate if P2X4 receptors are expressed in murine myenteric neurons and if these receptors contribute to form functional channels in the neuronal membrane by using molecular and electrophysiological techniques. The whole-cell recording technique was used to measure membrane currents induced by ATP (I(ATP)) in myenteric neurons. Compared with recombinant P2X4 receptor-channels (reported by others in a previous study), native myenteric P2X receptors have a relative lower sensitivity for ATP (EC50=102 µM) and α,ß methylene ATP (not effect at 30 or 100 µM). BzATP was a weak agonist for native P2X receptors. KN-62 had no effect on myenteric P2X channels whereas PPADS (IC50=0.54 µM) or suramin (IC50=134 µM) were more potent antagonists than on P2X4 homomeric channels. I(ATP) were potentiated by ivermectin (effect that is specific on P2X4 receptors) and zinc. Western blotting shows the presence of P2X4 protein and RT-PCR the corresponding mRNA transcript in the small intestine. Immunoreactivity for P2X4 receptors was found in most myenteric neurons in culture. Single-cell RT-PCR shows the presence of P2X4 mRNA in 90% of myenteric neurons. Our results indicate that P2X4 receptors are expressed in the majority of myenteric neurons, contribute to the membrane currents activated by ATP, and because most properties of I(ATP) does not correspond to P2X4 homomeric channels it is proposed that P2X4 are forming heteromeric channels in these neurons. P2X4 subunits have a widespread distribution within the myenteric plexus and would be expected to play an important role in cell signaling.

Identificação de resíduos de treonina e tirosina importantes na regulação da atividade do receptor P2X4 humano através de mutagênese sítio-dirigida / Identification of threonine and tyrosine residues important for human P2X4 receptor activity by site-directed mutagenesis

O receptor P2X4 (canal iônico controlado por adenosina-5'-trifosfato-ATP) está amplamente distribuído no sistema nervoso central e, após sua ativação, pode regular os níveis de cálcio intracelulares via permeação direta e por ativação de canais de cálcio voltagem-dependentes. Tem sido proposto que a atividade do receptor pode ser importante na plasticidade sináptica. Tendo em vista a importância do receptor P2X4, sobretudo na fisiologia do sistema nervoso central, é útil caracterizá-lo farmacologicamente e entender os mecanismos moleculares que regulam sua atividade. Examinamos o papel que resíduos específicos N- e C-terminais desempenham na atividade do receptor P2X4 humano, combinando técnicas de biologia molecular, bioquímica e patch-clamp em células de rim de embrião humano (células HEK-293T). Células HEK-293T expressando o receptor P2X4 wild-type apresentaram correntes iônicas, cujas amplitudes dependeram da concentração de ATP, fornecendo um valor de EC50 de 1,37 ± 0,21 µM. Os receptores mutantes E14A e D16A exibiram respostas ao ATP equiparáveis àquelas do receptor selvagem, ao passo que os mutantes Y15A e T17A não foram funcionais, apesar de serem expressos na membrana plasmática das células. A inibição de tirosina fosfatases por pervanadato diminuiu fortemente correntes induzidas por ATP. Subsequente análise de citometria de fluxo na presença de um anticorpo contra resíduos de fosfotirosina indicaram que, entre as células que expressam o receptor P2X4, a percentagem de células fosfo-tirosina-positivas é a mesma para os mutantes Y372A (86 ± 10%) e Y378A (79 ± 6.9%), mas substancialmente menor para os mutantes Y15A (35 ± 12%), Y367A (48 ± 6.4%) e Y372F (31 ± 1.7%), quando comparados com células que expressam o receptor wild-type (76 ± 5.6%). Resultados semelhantes foram obtidos quando quantificamos a expressão relativa de proteínas fosforiladas em resíduos de tirosina e expressamos através dos valores de intensidade de fluorescência média. Ensaios de western-blot revelaram que mesmo o mutante T17A é fosforilado em resíduos de treonina, sugerindo que o receptor P2X4 contém outros sítios de fosforilação. Entretanto, nenhum sinal de fosfotirosina foi detectado no receptor wild-type e nos mutantes, em que resíduos de tirosina foram substituídos por alanina ou fenilalanina. Não parece ser o resíduo Y15 o alvo de tal fosforilação, cabendo a ele um papel estrutural mais importante. Nossos dados também sugerem que a fosforilação em resíduos de tirosina de proteínas intermediárias regula a atividade do receptor P2X4

The human P2X4 receptor (ATP-gated ion channel) is widely distributed in the CNS and, after activation, participates in regulation of levels of intracellular calcium through direct permeation and activation of voltage-dependent calcium channels with well-defined functions including synaptic plasticity. Given the importance of the P2X4 receptor, especially in CNS physiology, we investigated the role that specific N- and C-termini residues play in human P2X4 receptor activity, by combining techniques of molecular biology, biochemistry and patch-clamping in human embryonic kidney cells (HEK-293T cells). HEK-293T cells expressing the wild-type P2X4 receptor showed ionic currents whose amplitudes depended on the ATP concentration, providing an EC50 value of 1.37 ± 0.21 mM. E14A and D16A receptor mutants exhibited responses to ATP comparable to those ones of wild-type receptor, whereas Y15A and T17A mutants were not functional, despite being expressed in the plasma membrane of cells. The inhibition of tyrosine phosphatases by pervanadate decreased strongly ATP-induced currents. Subsequent flow cytometry analysis in the presence of an antibody against phosphotyrosine residues indicated that, among the cells that express the P2X4 receptor, the percentage of phosphotyrosine-positive cells was the same for Y372A (86 ± 10%) and Y378A (79 ± 6.9%) mutants, however, substantially lower for Y15A (35 ± 12%), Y367A (48 ± 6.4%) and Y372F (31 ± 1.7%) mutants when compared with cells expressing the wild-type receptor (76 ± 5.6%). Similar results were obtained by quantifying the relative expression of phosphotyrosine proteins. Western blot assays revealed that even the T17A mutant was phosphorylated at threonine residues, suggesting that the human P2X4 receptor also contains further phosphorylation sites. However, no phosphotyrosine-antibody signal was detected in the wild-type receptor and mutants in which tyrosine residues were replaced by alanine or phenylalanine. The residue Y15 is supposedly not the target of such phosphorylation, despite its important structural role. However, the present work indicates that tyrosine phosphorylation of intermediate signaling proteins regulates P2X4 receptor activity

Distribution of the purinegic receptors P2X(4) and P2X(6) during rat gut development.

The purinergic receptors P2X(4) and P2X(6) are ion channels activated by ATP. These receptors are present in the gastrointestinal tract, and they are involved in synaptic transmission, taste sensation, and pain, among other functions. In this work, we studied the distribution of P2X(4) and P2X(6) receptors in proximal and distal regions of the gut newborn and adult rats. Using immunohistochemistry, purinergic receptors were found in gut epithelial cells and capillary vessels. In both proximal and distal regions of newborn rats, we observed P2X(4) signal in epithelial cells, whereas P2X(6) was present in capillary vessels in the proximal region and to a lesser extent in the distal region. In both regions of adult gut, we observed P2X(4) and P2X(6) immunostain in the capillary vessels. Semi-quantification indicated a significant difference in the amount of P2X(4) between proximal regions, whereas the P2X(6) content of both newborn regions differed from that in adult proximal gut. We conclude that P2X(4) and P2X(6) purinoreceptors are present in the gut from birth and that they are differentially distributed among regions.

Chronic intermittent hypoxia augments sympatho-excitatory response to ATP but not to L-glutamate in the RVLM of rats.

The development of sympathetic overactivity and hypertension in rats submitted to chronic intermittent hypoxia (CIH) involve alterations in the central mechanisms controlling respiratory and autonomic functions. Herein, we assessed whether CIH alters glutamatergic and/or purinergic signaling in the ventrolateral medulla (VLM), a region that encompasses the pre-sympathetic neurons and respiratory neurons of the ventral respiratory column. Groups of juvenile rats were exposed for 10 days to CIH (6% O(2) for 40s, every 9min, 8h/day) or normoxia (controls). Following treatment, in situ working heart-brainstem preparations were performed to record simultaneously respiratory and sympathetic motor outputs. In separate CIH and control groups, the VLM was dissected for western-blot analyses of ionotropic glutamatergic and P2 receptors. l-glutamate microinjections (1, 3 or 10mM) into VLM of control (n=6) and CIH groups (n=10) produced similar increases of sympathetic and abdominal activities associated with phrenic nerve inhibition; immunoreactive NMDAR1 and GluR2/3 densities at the VLM were also alike between groups (n=4). In contrast, VLM microinjections of ATP (1, 10 or 50mM) evoked larger sympatho-excitatory responses in CIH (n=8) than in control rats (n=7, P<0.05) whilst the abdominal increase and phrenic nerve inhibition were of comparable magnitudes. The immunoreactive densities of P2X3 and P2X4 receptors, but not P2X1 and P2Y2, were 20% higher in VLM of CIH (n=8; P<0.05) than controls (n=8). Altogether, our findings suggest that CIH augments purinergic signaling in the VLM, supporting the concept that nucleotides play a role in the dynamic central control of the sympathetic autonomic function.

Expression and function of P2X(7) receptor and CD39/Entpd1 in patients with type 2 diabetes and their association with biochemical parameters.

Chronic inflammation is an important contributor to the insulin resistance observed in type 2 diabetes (T2D). We evaluated the expression and function of the P2X(7) receptor and CD39/Entpd1, molecules involved in the cellular regulation of inflammation, in peripheral blood mononuclear cells from T2D patients, and their correlation with the concentration of HbA1c in blood. T2D patients with deficient metabolic control (DC) showed increased proportion of P2X(7)(+) cells compared with healthy individuals; T2D-DC subjects also displayed higher proportion of CD14(+), CD4(+) and CD19(+) subpopulations of P2X(7)(+) cells when compared with T2D patients with acceptable metabolic control. A significant association was observed between the proportion of P2X(7)(+)CD14(+) cells and blood concentration of LDL-c. In addition, the percentages of CD39(+) cells and CD39(+)CD19(+) cells were significantly associated with HbA1c and fasting plasma glucose levels. No changes were observed in the function of P2X(7)(+) cells from T2D patients; however, enhanced CD39/Entpd1 enzyme activity and low serum levels of IL-17 were detected. Therefore, CD39(+) cells could have a balancing regulatory role in the inflammatory process observed in patients with T2D.

Zinc enhances long-term potentiation through P2X receptor modulation in the hippocampal CA1 region.

Zn²(+) is an essential ion that is stored in and co-released from glutamatergic synapses and it modulates neurotransmitter receptors involved in long-term potentiation (LTP). However, the mechanism(s) underlying Zn²(+) -induced modulation of LTP remain(s) unclear. As the purinergic P2X receptors are relevant targets for Zn²(+) action, we have studied their role in LTP modulation by Zn²(+) in the CA1 region of rat hippocampal slices. Induction of LTP in the presence of Zn²(+) revealed a biphasic effect - 5-50 µm enhanced LTP induction, whereas 100-300 µm Zn²(+) inhibited LTP. The involvement of a purinergic mechanism is supported by the fact that application of the P2X receptor antagonists 2',3'-O-(2,4,6-trinitrophenyl) ATP (TNP-ATP) and periodate-oxidized ATP fully abolished the facilitatory effect of Zn²(+) . Notably, application of the P2X7 receptor-specific antagonist Brilliant Blue G did not modify the Zn²(+) -dependent facilitation of LTP. Exogenous ATP also produced a biphasic effect - 0.1-1 µm ATP facilitated LTP, whereas 5-10 µm inhibited LTP. The facilitatory effect of ATP was abolished by the application of TNP-ATP and was modified in the presence of 5 µm Zn²(+) , suggesting that P2X receptors are involved in LTP induction and that Zn²(+) leads to an increase in the affinity of P2X receptors for ATP. The latter confirms our previous results from heterologous expression systems. Collectively, our results indicate that Zn²(+) at low concentrations enhances LTP by modulating P2X receptors. Although it is not yet clear which purinergic receptor subtype(s) is responsible for these effects on LTP, the data presented here suggest that P2X4 but not P2X7 is involved.

P2X4 activation modulates volume-sensitive outwardly rectifying chloride channels in rat hepatoma cells.

Volume-sensitive outwardly rectifying (VSOR) Cl(-) channels are critical for the regulatory volume decrease (RVD) response triggered upon cell swelling. Recent evidence indicates that H(2)O(2) plays an essential role in the activation of these channels and that H(2)O(2) per se activates the channels under isotonic isovolumic conditions. However, a significant difference in the time course for current onset between H(2)O(2)-induced and hypotonicity-mediated VSOR Cl(-) activation is observed. In several cell types, cell swelling induced by hypotonic challenges triggers the release of ATP to the extracellular medium, which in turn, activates purinergic receptors and modulates cell volume regulation. In this study, we have addressed the effect of purinergic receptor activation on H(2)O(2)-induced and hypotonicity-mediated VSOR Cl(-) current activation. Here we show that rat hepatoma cells (HTC) exposed to a 33% hypotonic solution responded by rapidly activating VSOR Cl(-) current and releasing ATP to the extracellular medium. In contrast, cells exposed to 200 microm H(2)O(2) VSOR Cl(-) current onset was significantly slower, and ATP release was not detected. In cells exposed to either 11% hypotonicity or 200 microm H(2)O(2), exogenous addition of ATP in the presence of extracellular Ca(2+) resulted in a decrease in the half-time for VSOR Cl(-) current onset. Conversely, in cells that overexpress a dominant-negative mutant of the ionotropic receptor P2X4 challenged with a 33% hypotonic solution, the half-time for VSOR Cl(-) current onset was significantly slowed down. Our results indicate that, at high hypotonic imbalances, swelling-induced ATP release activates the purinergic receptor P2X4, which in turn modulates the time course of VSOR Cl(-) current onset in a extracellular Ca(2+)-dependent manner.

Neurosteroids differentially modulate P2X ATP-gated channels through non-genomic interactions.

As neuroactive steroids modulate several ionotropic receptors, we assessed whether the ATP-gated currents elicited by P2X(4) receptors are modulated by these compounds. We transfected HEK293 cells or injected Xenopus laevis oocytes with the cDNA coding for rat P2X(4) receptor. Application of 0.1-10 microM alfaxolone potentiated within 60-s the 1 microM ATP-evoked currents with a maximal potentiation of 1.8 and 2.6-fold in HEK293 or oocytes cells respectively. Allopregnalolone or 3alpha, 21-dihydroxy-5alpha-pregnan-20-one (THDOC) also potentiated the ATP-gated currents but with a maximal effect only averaging 1.25 and 1.35-fold respectively. In contrast, 0.3-10 microM pregnanolone, but not its sulfated derivative, inhibited the ATP-gated currents; the maximal inhibition reached 40% in both cell types. THDOC, but not other neurosteroids increased significantly the tau(off) of the ATP-evoked currents, revealing another mode of neurosteroid modulation. Sexual steroids such as 17beta-estradiol or progesterone were inactive revealing explicit structural requirements. Alfaxolone or THDOC at concentrations 30- to 100-fold larger than required to modulate the receptor, gated the P2X(4) receptor eliciting ATP-like currents that were reduced with suramin or brilliant blue G, but potentiated the P2X(4) receptor more than 10-fold by 10 microM zinc. In conclusion, neurosteroids rapidly modulate via non-genomic mechanisms and with nanomolar potencies, the P2X4 receptor interacting likely at distinct modulator sites.

Alteration of purinergic P2X4 and P2X7 receptor expression in rats with temporal-lobe epilepsy induced by pilocarpine.

SUMMARY: Although ATP and P2X receptor activity have been lately associated with epilepsy, little is known regarding their exact roles in epileptogenesis. Temporal-lobe epilepsy (TLE) in rat was induced by pilocarpine in order to study changes of hippocampal P2X(2), P2X(4) and P2X(7) receptor expression during acute, latent or chronic phases of epilepsy. During acute and chronic phases increased P2X(7) receptor expression was principally observed in glial cells and glutamatergic nerve terminals, suggesting participation of this receptor in the activation of inflammatory and excitotoxic processes during epileptogenesis. No significant alterations of hippocampal P2X(2) and P2X(4) receptor expression was noted during the acute or latent phase when compared to the control group, indicating that these receptors are not directly involved with the initiation of epilepsy. However, the reduction of hippocampal P2X(4) receptor immunostaining in the chronic phase could reflect neuronal loss or decreased GABAergic signaling.

Dissecting the facilitator and inhibitor allosteric metal sites of the P2X4 receptor channel: critical roles of CYS132 for zinc potentiation and ASP138 for copper inhibition.

Zinc and copper are atypical modulators of ligand-gated ionic channels in the central nervous system. We sought to identify the amino acids of the rat P2X4 receptor involved in trace metal interaction, specifically in the immediate linear vicinity of His140, a residue previously identified as being critical for copper-induced inhibition of the ATP-evoked currents. Site-directed mutagenesis replaced conspicuous amino acids located within the extracellular domain region between Thr123 and Thr146 for alanines. cDNAs for the wild-type and the receptor mutants were expressed in Xenopus laevis oocytes and examined by the two-electrode technique. Cys132, but not Cys126, proved crucial for zinc-induced potentiation of the receptor activity, but not for copper-induced inhibition. Zinc inhibited in a concentration-dependent manner the ATP-gated currents of the C132A mutant. Likewise, Asp138, but not Asp131 was critical for copper and zinc inhibition; moreover, mutant D138A was 20-fold more reactive to zinc potentiation than wild-type receptors. Asp129, Asp131, and Thr133 had minor roles in metal modulation. We conclude that this region of the P2X4 receptor has a pocket for trace metal coordination with two distinct and separate facilitator and inhibitor metal allosteric sites. In addition, Cys132 does not seem to participate exclusively as a structural receptor channel folding motif but plays a role as a ligand for zinc modulation highlighting the role of trace metals in neuronal excitability.