Purinergic P2X Receptors: Structural and Functional Features Depicted by X-Ray and Molecular Modelling Studies

Grimes, Leanne; Young, Mark T.

doi:10.2174/0929867321999141212131457

Cited by 20 publications

(14 citation statements)

References 106 publications

(170 reference statements)

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“…The P2X7R with an extended C-terminal tail of 239 aa and an overall length of 595 aa, is the largest in the P2XR family. Transmembrane domains are responsible for the interactions among subunits and the formation of the ion-permeation pathway (Hattori and Gouaux, 2012; Grimes and Young, 2015). The intracellular C-tail interacts with different intracellular molecules such as heat shock proteins (HSP), cytoskeletal components, kinases and possibly also with membrane proteins.…”

Section: The P2x7rmentioning

confidence: 99%

The P2X7 Receptor-Interleukin-1 Liaison

et al. 2017

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Interleukin-1β (IL-1β) plays a central role in stimulation of innate immune system and inflammation and in several chronic inflammatory diseases. These include rare hereditary conditions, e.g., auto-inflammatory syndromes, as well as common pathologies, such as type II diabetes, gout and atherosclerosis. A better understanding of IL-1β synthesis and release is particularly relevant for the design of novel anti-inflammatory drugs. One of the molecules mainly involved in IL-1β maturation is the P2X7 receptor (P2X7R), an ATP-gated ion channel that chiefly acts through the recruitment of the NLRP3 inflammasome-caspase-1 complex. In this review, we will summarize evidence supporting the key role of the P2X7R in IL-1β production, with special emphasis on the mechanism of release, a process that is still a matter of controversy. Four different models have been proposed: (i) exocytosis via secretory lysosomes, (ii) microvesicles shedding from plasma membrane, (iii) release of exosomes, and (iv) passive efflux across a leaky plasma membrane during pyroptotic cell death. All these models involve the P2X7R.

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Section: The P2x7rmentioning

confidence: 99%

The P2X7 Receptor-Interleukin-1 Liaison

et al. 2017

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“…In recent years, our understanding of the relationship between the structure and the function of the ATP-gated P2X receptor family of ion channels has been transformed by a series of crystal structures, from the first structure of a P2X receptor, that of Danio rerio P2X4.1 (zfP2X4) in the apo -state, published in 2009 (Kawate et al, 2009 ), via structures of zfP2X4 bound to ATP (Hattori and Gouaux, 2012 ), a Gulf Coast tick ( Amblyomma maculatum ) P2X structure (Kasuya et al, 2016 ), human P2X3 in the apo -, ATP- and antagonist-bound states (Mansoor et al, 2016 ), zfP2X4 bound to the partial agonist CTP (Kasuya et al, 2017a ), to the most recently determined structures of giant panda ( Ailuropoda melanoleuca ) P2X7 (Karasawa and Kawate, 2016 ) and chicken P2X7 (Kasuya et al, 2017b ). These impressive achievements, along with their enabling of the interpretation of a large body of prior mutagenesis data (reviewed in Chataigneau et al, 2013 ; Jiang et al, 2013 ; Alves et al, 2014 ; Samways et al, 2014 ; Grimes and Young, 2015 ; Habermacher et al, 2016 ; Kawate, 2017 ), have led to significant breakthroughs in our understanding of channel architecture, ligand binding, and the mechanisms of channel opening, desensitization and both orthosteric and allosteric antagonism. In addition, the availability of structural data has allowed for the construction and testing of molecular models of those human receptors which still lack direct high-resolution structural data (Alves et al, 2014 ; Ahmadi et al, 2015 ; Caseley et al, 2015 , 2016 ; Farmer et al, 2015 ; Fryatt et al, 2016 ), paving the way for mutational analysis to elucidate antagonist binding sites (Farmer et al, 2015 ; Allsopp et al, 2017 ), and structure-aided drug design (Ahmadi et al, 2015 ; Caseley et al, 2015 , 2016 ).…”

Section: Introductionmentioning

confidence: 99%

The Molecular Determinants of Small-Molecule Ligand Binding at P2X Receptors

2018

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P2X receptors are trimeric eukaryotic ATP-gated cation channels. Extracellular ATP—their physiological ligand—is released as a neurotransmitter and in conditions of cell damage such as inflammation, and substantial evidence implicates P2X receptors in diseases including neuropathic pain, cancer, and arthritis. In 2009, the first P2X crystal structure, Danio rerio P2X4 in the apo- state, was published, and this was followed in 2012 by the ATP-bound structure. These structures transformed our understanding of the conformational changes induced by ATP binding and the mechanism of ligand specificity, and enabled homology modeling of mammalian P2X receptors for ligand docking and rational design of receptor modulators. P2X receptors are attractive drug targets, and a wide array of potent, subtype-selective modulators (mostly antagonists) have been developed. In 2016, crystal structures of human P2X3 in complex with the competitive antagonists TNP-ATP and A-317491, and Ailuropoda melanoleuca P2X7 in complex with a series of allosteric antagonists were published, giving fascinating insights into the mechanism of channel antagonism. In this article we not only summarize current understanding of small-molecule modulator binding at P2X receptors, but also use this information in combination with previously published structure-function data and molecular docking experiments, to hypothesize a role for the dorsal fin loop region in differential ATP potency, and describe novel, testable binding conformations for both the semi-selective synthetic P2X7 agonist 2′-(3′)-O-(4-benzoyl)benzoyl ATP (BzATP), and the P2X4-selective positive allosteric modulator ivermectin. We find that the distal benzoyl group of BzATP lies in close proximity to Lys-127, a residue previously implicated in BzATP binding to P2X7, potentially explaining the increased potency of BzATP at rat P2X7 receptors. We also present molecular docking of ivermectin to rat P2X4 receptors, illustrating a plausible binding conformation between the first and second transmembrane domains which not only tallies with previous mutagenesis studies, but would also likely have the effect of stabilizing the open channel structure, consistent with the mode of action of this positive allosteric modulator. From our docking simulations and analysis of sequence homology we propose a series of mutations likely to confer ivermectin sensitivity to human P2X1.

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“…The tri-dimensional structure of the P2X7R subunits resembles the shape of a dolphin, in which the extracellular region represents the body (with head and fins) and the two transmembrane helices (TM1 and TM2) represent the tail (Figure 1c). The three ATP-binding pockets, which are supplied by the ATP sites of each pair of two adjacent monomers (Figure 1d), conform to the active P2X7R, which requires three ATP molecules for gating [22,29], and consequently open the low body domain pore, which is formed by the central TM of each one of the three pairs of TM domains. Interestingly, it has been suggested that the occupancy of two of the three ATP-binding pockets is sufficient to activate other P2XRs [30,31].…”

Section: The Homo-trimeric P2x7 Receptor Proteinmentioning

confidence: 99%

Structural and Functional Basis for Understanding the Biological Significance of P2X7 Receptor

Martínez-Cuesta

Blanch-Ruiz

Ortega-Luna

et al. 2020

IJMS

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The P2X7 receptor (P2X7R) possesses a unique structure associated to an as yet not fully understood mechanism of action that facilitates cell permeability to large ionic molecules through the receptor itself and/or nearby membrane proteins. High extracellular adenosine triphosphate (ATP) levels—inexistent in physiological conditions—are required for the receptor to be triggered and contribute to its role in cell damage signaling. The inconsistent data on its activation pathways and the few studies performed in natively expressed human P2X7R have led us to review the structure, activation pathways, and specific cellular location of P2X7R in order to analyze its biological relevance. The ATP-gated P2X7R is a homo-trimeric receptor channel that is occasionally hetero-trimeric and highly polymorphic, with at least nine human splice variants. It is localized predominantly in the cellular membrane and has a characteristic plasticity due to an extended C-termini, which confers it the capacity of interacting with membrane structural compounds and/or intracellular signaling messengers to mediate flexible transduction pathways. Diverse drugs and a few endogenous molecules have been highlighted as extracellular allosteric modulators of P2X7R. Therefore, studies in human cells that constitutively express P2X7R need to investigate the precise endogenous mediator located nearby the activation/modulation domains of the receptor. Such research could help us understand the possible physiological ATP-mediated P2X7R homeostasis signaling.

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Purinergic P2X Receptors: Structural and Functional Features Depicted by X-Ray and Molecular Modelling Studies

Cited by 20 publications

References 106 publications

The P2X7 Receptor-Interleukin-1 Liaison

The P2X7 Receptor-Interleukin-1 Liaison

The Molecular Determinants of Small-Molecule Ligand Binding at P2X Receptors

Structural and Functional Basis for Understanding the Biological Significance of P2X7 Receptor

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