In amphibian epithelia, amiloride reduces net sodium transport by hindering the entry of sodium to the active transport mechanism, that is, by increasing the series resistance (
R
ser
). Theoretically, therefore, analysis of amiloride-induced changes in potential differences and short-circuit current should yield numerical estimates of all the parameters in the equivalent electrical circuit of the sodium transport mechanism.
The concept has been explored by analysis of such changes in toad skins (Xenopus laevis) bathed in hypotonic sulphate Ringer's, after exposure to varying doses of amiloride, or to amphotericin, dinitrophenol or Pitressin.
The estimated values ofR
ser
, of the electromotive force of the sodium pump (E
Na), and of the shunt resistance (R
sh
) were independent of the dose of amiloride employed. Skins bathed in hypotonic sulphate Ringer's exhibited a progressive rise inE
Na. Amphotericin produced a fall inR
ser
, while dinitrophenol caused a fall inE
Na; washout of the drugs reversed these effects. Pitressin produced a fall in bothR
ser
andR
sh
, with a rise inE
Na. These results are in accord with earlier suggestions regarding the site(s) of action of these agents.