Selectivity of ATP-activated GTP-dependent Ca(2+)-permeable channels in rat macrophage plasma membrane.

Outside-out configuration of the patch clamp technique was used to test whether an intracellular application of G protein activator (GTP gamma S) affects ATP-activated Ca(2+)-permeable channels in rat macrophages without any agonist in the bath solution. With 145 mM K+ (pCa 8.0) in the pipette solution, activity of channels permeable to a variety of divalent cations and Na+ was observed and general channel characteristics were found to be identical to those of ATP-activated ones. Absence of extracellular ATP makes it possible to avoid the influence of ATP receptor desensitization and to study the channel selectivity using a number of divalent cations (105 mM) and Na+ (145 mM) as the charge carriers. Permeability sequence estimated by extrapolated reversal potential measurements was: Ca2+:Ba2+:Mn2+:Sr2+: Na+:K+ = 68:30:26:10:3.5:1. Slope conductances (in pS) for permeant ions rank as follows: Ca2+:Sr2+: Na+:Mn2+:Ba2+ = 19:18:14:12:10. Unitary Ca2+ currents display a tendency to saturate with the Ca2+ concentration increase with apparent dissociation constant (Kd) of 10 mM. No block of Na+ permeation by extracellular Ca2+ in millimolar range was found. The data obtained suggest that (i) activation of some G protein is sufficient to gate the channels without the ATP receptor being occupied, (ii) the ATP receptor activation results in the gating of a special channel with the properties that differ markedly from those of the receptor-operated or voltage-gated Ca(2+)-permeable channels on the other cell types.