Molecular properties of ATP-gated P2X receptor ion channels

P2X receptors for ATP are expressed throughout the body and mediate a multitude of functions, including muscle contraction, neuronal excitability and bone formation. In the mid-1990s seven genes encoding P2X receptors (P2X(1-7)) were identified. These receptors comprised a novel family of ligand-gated ion channels with subunits that possessed intracellular N- and C-termini, two transmembrane domains and an extracellular ligand-binding loop. No crystal structures are available for these channels. Furthermore, they are distinct from the nicotinic acetylcholine (Cys-loop) and glutamate families of ion channels and have no similarity to other ATP-binding proteins, thus precluding homology modelling-based studies of their structural properties. However, molecular techniques have provided insight into the properties of P2X receptors: mutagenesis and biochemical studies have identified regions associated with ATP binding, ionic conduction, channel gating and regulation. In addition, transgenic approaches have helped to characterize the role of defined receptor subunits in native systems.     

ATP-gated P2X cation-channels

P2X receptors are ATP-gated cation channels with important roles in diverse pathophysiological processes. Substantial progress has been made in the last few years with the discovery of both subunit selective antagonists and modulators. The purpose of this brief review is to summarize the advances in the pharmacology of P2X receptors, with key properties presented in an easy to access format. Ligand-gated ion channels consist of three families in mammals; the ionotropic glutamate receptors, the Cys-loop receptors (for GABA, ACh, glycine and serotonin) and the P2X receptors for ATP. The first two of these are considered in articles accompanying this Special Issue. Here we consider the pharmacological properties of P2X receptors. We do not present a detailed discussion of P2X receptor physiological roles or structure-function studies. Moreover, the pharmacological basis for discriminating between the main subtypes of P2X receptor and their nomenclature has been published by the Nomenclature Committee of the International Union of Pharmacology (NC-IUPHAR) P2X Receptor Subcommittee, and so these aspects are not revisited here. Instead in this brief article we seek to present a summary of the pharmacology of recombinant homomeric and heteromeric P2X receptors, with particular emphasis on new antagonists. In this article we have tried to present as much information as possible in two tables in the hope this will be useful as a day-to-day resource, and also because an excellent and detailed review has recently been published.     

Potential therapeutic targets for neurokinin-1 receptor antagonists

The peptide substance P and its tachykinin receptor, neurokinin-1 (NK1), have been the focus of considerable research for their role in a variety of both central and peripheral diseases. Recent preclinical data, as well as relevant clinical findings, support the potential therapeutic value of NK1 receptor antagonists in centrally mediated disease states, including anxiety and depression. In addition, a separate body of literature supports the use of NK1 receptor antagonists as inhibitors of centrally mediated emetic and cough responses. The role of NK1 receptor antagonists as analgesic agents with potential to treat migraine headache has also been investigated. NK1 receptors are also found in a number of peripheral regions, including the bladder, gastrointestinal tract and bone marrow. Preclinical models have been employed to address the potential therapeutic uses for NK1 receptor antagonists in diseases associated with inflammatory responses, including asthma, irritable bowel syndrome and cystitis of the bladder. Finally, other more recent publications suggest a role for NK1 receptor antagonists as tumour suppressants and haematopoietic agents. These applications for NK1 receptor antagonists are discussed in this review.     

Sodium ion channels as potential therapeutic targets for cancer metastasis

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Transient receptor potential channels as therapeutic targets

Transient receptor potential (TRP) cation channels have been among the most aggressively pursued drug targets over the past few years. Although the initial focus of research was on TRP channels that are expressed by nociceptors, there has been an upsurge in the amount of research that implicates TRP channels in other areas of physiology and pathophysiology, including the skin, bladder and pulmonary systems. In addition, mutations in genes encoding TRP channels are the cause of several inherited diseases that affect a variety of systems including the renal, skeletal and nervous system. This Review focuses on recent developments in the TRP channel-related field, and highlights potential opportunities for therapeutic intervention.     

Go it alone no more--P2X7 joins the society of heteromeric ATP-gated receptor channels

P2X receptors (P2XR) function as ATP-gated nonselective ion channels permeable to Na+, K+, and Ca2+, and they are expressed in a wide range of excitable, epithelial/endothelial, and immune effector cell types. The channels are trimeric complexes composed of protein subunits encoded by seven different P2XR genes expressed in mammalian and other vertebrate genomes. Current genetic, biochemical, and/or physiological evidence indicates that the extended family of functional P2X receptors includes six homomeric channels composed of P2X1, P2X2, P2X3, P2X4, P2X5, or P2X7 subunits and six heteromeric channels that involve subunit pairings of P2X1/P2X2, P2X1/P2X4, P2X1/P2X5, P2X2/P2X3, P2X2/P2X6, or P2X4/P2X6. Thus, all P2XR subtypes--with the salient exception of P2X7R--have previously been implicated in the assembly of heteromeric ATP-gated ion channels that can comprise unique pharmacological targets in different tissues. The assumed "go-it alone" function of the P2X7R has important implications because agents that target this particular receptor have been proposed as useful therapeutics in various autoinflammatory diseases or amelioration of inflammatory pain. However, this assumption and the interpretations based on it now require reevaluation in light of a new report in this issue of Molecular Pharmacology (p. 1447) that provides convincing biochemical and electrophysiological evidence for the existence of P2X4/P2X7 heteromeric receptors.     

Ethanol differentially affects ATP-gated P2X(3) and P2X(4) receptor subtypes expressed in Xenopus oocytes

P2X receptors are cation-selective, ligand-gated ion channels activated by synaptically released, extracellular adenosine 5'-triphosphate (ATP). ATP-gated currents are inhibited by ethanol when tested in dorsal root ganglion and CA1 neurons. Recently, we reported differences in sensitivity to ethanol inhibition between homomeric P2X(2) and P2X(4) receptors expressed in Xenopus oocytes, which suggested that subunit composition of native P2X receptors determines their ethanol sensitivity. The present study extended the investigation to P2X(3) receptors. The effects of ethanol and zinc ions (Zn(2+)) were tested on homomeric P2X(3) and P2X(4) receptors expressed in Xenopus oocytes using two-electrode voltage clamp. Ethanol potentiated ATP-gated P2X(3) receptor currents in a concentration dependent manner. In contrast, ethanol inhibited P2X(4) receptor function. Ethanol did not directly alter receptor function, nor did it alter the Hill coefficient or maximal ATP response (E(max)) in either P2X(3) or P2X(4) receptors. Ethanol increased the maximal response to Zn(2+) ATP-gated currents in P2X3 receptors which suggests that ethanol and Zn(2+) act on different sites. The differences in ethanol response of P2X(3) and P2X(4) receptors set the stage for future investigations that will use chimeric P2X receptors or other molecular manipulations of P2X structure to investigate the molecular sites and mechanisms of action of ethanol.     

Activation and regulation of purinergic P2X receptor channels

Mammalian ATP-gated nonselective cation channels (P2XRs) can be composed of seven possible subunits, denoted P2X1 to P2X7. Each subunit contains a large ectodomain, two transmembrane domains, and intracellular N and C termini. Functional P2XRs are organized as homomeric and heteromeric trimers. This review focuses on the binding sites involved in the activation (orthosteric) and regulation (allosteric) of P2XRs. The ectodomains contain three ATP binding sites, presumably located between neighboring subunits and formed by highly conserved residues. The detection and coordination of three ATP phosphate residues by positively charged amino acids are likely to play a dominant role in determining agonist potency, whereas an AsnPheArg motif may contribute to binding by coordinating the adenine ring. Nonconserved ectodomain histidines provide the binding sites for trace metals, divalent cations, and protons. The transmembrane domains account not only for the formation of the channel pore but also for the binding of ivermectin (a specific P2X4R allosteric regulator) and alcohols. The N- and C- domains provide the structures that determine the kinetics of receptor desensitization and/or pore dilation and are critical for the regulation of receptor functions by intracellular messengers, kinases, reactive oxygen species and mercury. The recent publication of the crystal structure of the zebrafish P2X4.1R in a closed state provides a major advance in the understanding of this family of receptor channels. We will discuss data obtained from numerous site-directed mutagenesis experiments accumulated during the last 15 years with reference to the crystal structure, allowing a structural interpretation of the molecular basis of orthosteric and allosteric ligand actions.     

The P2X7 receptor as a therapeutic target

Background: The P2X7 receptor is present in a variety of cell types involved in pain, inflammatory processes and neurodegenerative conditions, thus it may be an appealing target for pharmacological intervention. The extensive use of high-throughput screening (HTS) followed by a hit-to-lead (HtL) program, has prompted a number of firms to identify highly selective and metabolically stable small-molecules possessing activity for both the rat and human P2X₇ receptor, which provide a novel therapeutic approach to the treatment of pain as well as neurodegenerative and inflammatory disorders. Objective: To describe the current status of and potential for development of P2X₇ receptor-antagonists. Methods: A literature review. Results/conclusions: We describe the recent discoveries of novel P2X₇ receptor-selective antagonists, along with their biological activity and therapeutic potential.     

Potential therapeutic targets for schizophrenia

Schizophrenia is a serious mental illness that affects 1% of the population (lifetime prevalence) in all areas of the world. Neuroleptics are undoubtedly a striking improvement over previous treatments for schizophrenia (or lack thereof) and they do ameliorate positive symptoms. But schizophrenia remains a terribly disabling condition and outcomes, especially in industrialised countries, have remained poor. The rapid progress of neuroscience research has provided some insights into the neurobiology of this debilitating illness, and informed the approach to developing novel treatments. However, the genetics, aetiology and pathophysiology of schizophrenia and other psychiatric diseases are still incompletely understood, so that development of more effective and benign drugs is difficult. Current efforts in finding new treatments are often aimed at refining existing neuroleptics and understanding the factors that affect neuroleptic drug action. In this paper, we review the present understanding of the neurobiology and genetics of schizophrenia, novel antipsychotics, and discuss the pharmacological factors that influence antipsychotic effects, side effects and improvement in negative symptoms. The study of the neurobiology of schizophrenia is still at an early stage but, in conjunction with the improvements in antipsychotics, our understanding of and treatment for schizophrenia will continue to improve.     

P2X and P2Y receptors as possible targets of therapeutic manipulations in CNS illnesses

Adenine and/or uridine nucleotide-sensitive receptors are classified into two types belonging to the ligand-gated ionotropic family (P2X) and the metabotropic, G-protein-coupled family (P2Y). In humans, seven different P2X receptors (P2X(1-7)) and eight different P2Y receptors (P2Y(1), P2Y(2), P2Y(4), P2Y(6), P2Y(11-14)) have been detected hitherto. All P2 receptors are expressed in the CNS, with the preferential expression of the P2X(2), P2X(4), P2X(6) and P2Y(1) receptors in neurons. In addition to the neurotransmitter and modulator functions, neurite outgrowth, proliferation of glial cells and the expression of transmitter receptors at target cells have also been suggested to be regulated by extracellular nucleotides in the nervous system. In spite of the expanding knowledge in the purinergic research field, the present therapeutic utilization of P2 receptor ligands is mostly related to peripheral diseases such as thromboembolic disorders and cystic fibrosis. In this review we provide some evidence that P2 receptors play an important role in the regulation of CNS functions related to hippocampal activity, the mesolimbic dopaminergic system and the nociceptive system. The role of purinergic receptors located on astrocytes/microglia and implications of these receptors for neurodegenerative/neuroinflammatory disorders, CNS injury and epilepsy will be highlighted as well.     

Potential therapeutic targets for Parkinson's disease

Background: Parkinson's disease is a common disorder that becomes more prevalent with advanced age. The cardinal features are related to dopamine deficiency, arising from loss of neurons projecting from the substantia nigra in the midbrain to the striatum. Therapies based on dopamine replacement are well established but while highly effective, leave a number of currently unmet needs. These include features of disease that are probably not related to dopamine deficiency and are unresponsive to dopamine-replacement therapy, as well as complications of long-term dopaminergic therapy itself. The most important gap is the availability of treatments that modify the inexorable progression of disease or that could prevent its onset in subjects at risk. Objective: To identify needs that are unmet or only partially addressed by currently available therapies for Parkinson's and select approaches that may be helpful for their management. Methods: Discussion of the mechanisms that may contribute to currently unmet needs in Parkinson's disease. Based on consideration of pathogenic mechanisms and a review of recent and previous relevant literature, identification of possible approaches that are in development, including pharmacological strategies and potential targets for gene therapy. Conclusions: Better treatments for levodopa-unresponsive aspects of Parkinson's will depend upon improved understanding of the pathophysiology of these complications. Dopamine-based therapies have been extensively developed and further improvements in treatment of established disease are likely to be based on modification of other neurotransmitter systems, including 5-hydroxytryptamine, adenosine receptors, amino acid receptors and possibly neuropeptides. The failure of neuroprotective and neurorescue strategies to keep pace with expectations probably reflects a combination of inadequate models of disease pathogenesis and poor biomarkers to assess the impact of these interventions. The development of novel therapies will be heavily dependent on improvements in these arenas. Most gene therapies under development will address the symptoms of Parkinson's disease but will at best only partially address the underlying disease.     

ATP-gated currents in rat primary auditory neurones in situ arise from a heteromultimetric P2X receptor subunit assembly

Spiral ganglion neurones provide the primary afferent innervation to sensory hair cells within the mammalian cochlea. Recent evidence suggests that their function may be modulated by purinergic signalling mechanisms, associated with release of adenosine 5'-triphosphate (ATP). Utilising a newly developed slice preparation of the neonatal rat cochlea, we have investigated the response of neurones in situ, to purinergic agonists and antagonists using whole-cell voltage clamp recordings. In cells identified as type I spiral ganglion neurones on the basis of morphology and voltage-dependent conductances, pressure-applied ATP, alpha,beta-methyleneATP (alpha,beta-meATP), 2-methylthioATP (2-MeSATP) and adenosine 5'-diphosphate (ADP) elicited a consistent phenotype of desensitising, inwardly rectifying current. The ATP-activated currents were reversibly blocked by the P2X receptor antagonists pyridoxalphosphate-6-azophenyl-2',4'-disulphonic acid (PPADS, 10 microM), and 2',3'-O-(2,4,6-trinitrophenyl)-ATP (TNP-ATP; IC(50) 407 nM). Neurones were more sensitive to ATP at low pH. The EC(50) value for ATP shifted from 18 microM at pH 7.3, to 1 microM at pH 6.3, with Hill coefficients of approximately 1. The results indicate that ATP-gated ion channels in spiral ganglion neurones arise from a specific heteromultimeric assembly of P2X receptor subunits which has no correspondence with present recombinant P2X receptor models.     

Transient receptor potential ion channels as targets for the discovery of pain therapeutics

A subset of transient receptor potential (TRP) channels exhibits activity that is highly sensitive to temperature changes and is expressed in sensory tissues, such as nociceptors and skin. Some of these thermosensitive TRP channels, such as TRPV1, TRPV4 and TRPA1, are activated or sensitized by molecules generated by inflammation and/or cell damage. TRPV1, also known as the capsaicin receptor, is particularly important in mediating hyperalgesic responses in inflammatory pain states, as demonstrated by research in knockout animals and with small-molecule antagonists. It is anticipated that TRPV1 antagonists, and perhaps antagonists at other thermosensitive TRP channels, will provide new therapeutic options with which to treat clinical pain.