Abstract
Upon continuous stimulation, the pore of the monovalent cation-selective P2X7 receptor (P2X7R) expands to accommodate large molecules such as N-methyl-D-glucamine (NMDG+). How the change in P2X7R permeability is regulated is not known. Here we report that extracellular Cl- (Cl-(o)) regulates the outward current, whereas extracellular Na+ (Na+(o)) regulates the inward current of large molecules by P2X7Rs. The P2X7R-mediated current was measured in parotid acinar and duct cells of wild type and P2X7R-/- mice and in HEK293 cells expressing the human or mouse P2X7R isoforms. In symmetrical NaCl, triethylammonium chloride, and NMDG+ chloride solutions, the P2X7R current followed a linear current/voltage relationship. In symmetrical NaCl, removal of Cl-(o) reduced the inward Na+ current by approximately 35% and the outward Na+ current by only 10%. By contrast, in the absence of Na+(i) and the presence of Na+(o) or NMDG+(o), the removal of Cl-(o) reduced the inward Na+ or NMDG+ currents by 35% but the outward NMDG+ current by >95%. The effect of Cl-(o) was half-maximal at approximately 60 mm. Reducing Cl-(i) from 150 to 10 mm did not reproduce the effects of Cl-(o). All currents were eliminated in P2X7R-/- cells and reproduced by expressing the P2X7Rs in HEK cells. These findings suggest that Cl-(o) primarily regulates the outward P2X7R current of large molecules. When cells dialyzed with NMDG+ were stimulated in the presence of Na+(o), subsequent removal of Na+(o) resulted in a strongly outward rectifying NMDG+ current, indicating maintained high selectivity for Na+ over NMDG+. During continuous incubation in Na+-free medium, the permeability of the P2X7Rs to NMDG+ gradually increased. On the other hand, when the cells were incubated in symmetrical NMDG+ and only then stimulated with ATP, the NMDG+ current by P2X7Rs followed a linear current/voltage relationship and did not change with time. These findings suggest that the P2X7R has a "Na+(o) memory" and that Na+(o) regulates the inward permeability of P2X7Rs to large molecules. The novel regulation of P2X7R outward and inward permeability to large molecules by Cl-(o) and Na+(o), respectively, may have an important protective function, particularly in secretory epithelial cells.
Highlights
Epithelial cells of secretory glands secrete ATP to both the basal and luminal spaces [6, 7] that can activate the P2 receptors in the respective membranes
As part of our effort to understand the role of P2X7 receptor (P2X7R) in salivary gland physiology, we re-examined the effect of ATP on cation and anion currents in parotid acinar and duct cells of WT and P2X7RϪ/Ϫ cells and in HEK293 cells transfected with the hP2X7Rs and mP2X7Rs
P2X7Rs Mediate the Current in Symmetrical TEACl Solutions—Previous work reported an apparent activation of a ClϪ current by stimulation of mouse parotid acinar cells with high concentrations of ATP or with 3Ј-O-(4-benzoyl)benzoyl ATP
Summary
P2X7R, P2X7 receptor; ClϪo, extracellular ClϪ; ClϪi, intracellular ClϪ; hP2X7, human P2X7; I/V, current/ voltage; mP2X7, mouse P2X7; Naϩo, extracellular Naϩ; Naϩi, intracellular Naϩ; NMDGϩ, N-methyl-D-glucamine; NMDGCl, NMDG chloride; TEA, tetraethyl ammonium; TEACl, TEA chloride; WT, wild type. P2X7Rs, ClϪo, and Naϩo modifies the electrolyte composition and osmolarity of the secreted fluid by absorbing the Naϩ and ClϪ and secreting Kϩ and HCO3Ϫ [17, 18] The function of both cell types is mediated by ClϪ and Kϩ channels. We discovered novel regulation of P2X7R permeability to large molecules by ClϪo and Naϩo, which may have a particular significance in the secretory epithelia that modify the ClϪ concentration and osmolarity of the secreted fluid
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