D. Lagadicgossmann et al., EFFECTS OF S20787 ON PH(I)-REGULATING MECHANISMS IN ISOLATED RAT VENTRICULAR MYOCYTES, Journal of cardiovascular pharmacology, 28(4), 1996, pp. 547-552
Intracellular pH (pH(i)) regulation in the heart relies on the activit
y of three membrane mechanisms: the Na+/H+ exchange and an Na+, HCO3--
dependent transport, both activated after an acid load, and the Cl-/HC
O3- exchange, activated by an intracellular alkalinization. Whereas se
veral specific inhibitors of Na+/H+ exchange exist, distinguishing bet
ween the two HCO3--dependent mechanisms remains difficult, especially
near the steady state, because of the lack of specific inhibitors. To
detect one such inhibitor, we tested the effects of S20787 on pH(i) re
gulation in the rat isolated ventricular myocytes. Intracellular pH wa
s recorded with the fluorescent probe carboxy-SNARF-1. The NH4Cl (10 m
M) prepulse method was used to induce an acid load to activate the dua
l acid extrusion system; Cl-/HCO3- exchange was activated with the ace
tate (40 mM) prepulse method. Our results showed that (a) a high dose
(5.10(-6) M) of S20787 did not change intracellular intrinsic bufferin
g power, beta(i); (b) the dual acid extrusion system was unaffected by
S20787 in the concentration range of 10(-11)-10(-6) M; and (c) S20787
partially inhibited (similar to 50%) the activity of Cl-/HCO3- exchan
ge in a dose-dependent manner, with an IC50 of 8.8 x 10(-10) M. This i
nhibitory action of S20787 did not change the steady-state pH, after 5
-10 min application. Our results demonstrate that S20787 is a specific
and potent partial inhibitor of Cl-/HCO3- exchange in cardiac cells.