Identification of Thr283 as a key determinant of P2X7 receptor function

Abstract

Background and purpose: The ATP-gated P2X7 receptor is an unusual ion channel that couples to multiple downstream signalling cascades. We noted differences in mouse cDNA sequences that may indicate polymorphisms; the aim of this study was to compare function and expression of these mouse P2X7 receptor mutations. Experimental approach: There are three differences in the sequences of P2X7 cDNA cloned from mouse NTW8 microglial cells or C57 BL/6 mice: [Phe11,Ala221,Met283]P2X7 in the former and [Leu11,Thr221,Thr283]P2X7 in the latter. We expressed these receptors and measured membrane currents, ethidium uptake, calcium influx and surface membrane expression. We also carried out these assays on the previously described polymorphism observed between C57 BL/6 and Balb/c mice ([Leu451]P2X7 vs [Pro451]P2X7). Key results: Maximum current densities at [Phe11,Ala221,Met283]P2X7 were <12% of those at [Leu11,Thr221,Thr283]P2X7 without change in the agonist concentration- response. Replacing methionine with threonine at residue 283 yielded a receptor whose properties were the same as [Leu11,Thr221,Thr283]P2X7. Replacing T283 in the rat P2X7 receptor with methionine yielded currents that were <10% of wildtype and no ethidium uptake was associated with its activation. Maximum current densities and agonist EC50 values were the same at mouse [Thr283,Leu451]P2X7 and [Thr283,Pro451]P2X7 but ethidium uptake and Fluo4 fluorescence were significantly reduced at the [Thr283,Leu451]P2X7 receptor. There was equivalent surface membrane expression of all P2X7 receptors. Conclusions: This study has revealed a residue (Thr283) in the ectodomain that is critical for P2X7 receptor function and suggests that the intracellular residue 451 alters downstream signalling independently of ion channel activity.