Protamine reversibly decreases cation permeability and alters the structure of Necturus gallbladder tight junctions. Conflicting results, however, have been published whether or not it also affects apical cell membrane permeability. We investigated this issue more systematically by measuring voltage (psi mc) and fractional resistance (fRa) of the apical membrane at varying concentrations of protamine, K+, and H+ in the bathing solution. At pH 7.6 and [K+] 2.5 mM, (Poler, M.S. and Reuss, L. (1987) Am. J. Physiol. 253, C662) 6 microM protamine caused psi mc to depolarize from -58 to -51 mV and fRa to decrease from 0.74 to 0.67. If we increased pH to 8.1 these effects were even more pronounced. At [K+] 2.5 mM, but not 4.5 mM, psi mc transiently hyperpolarized for about 5 min after adding protamine. Most importantly, if [K+] was 4.5 mM and pH was adjusted to 7.1 (Bentzel et al. (1987) J. Membr. Biol. 95, 9) no significant changes of psi mc and fRa occurred. In any case, at a supramaximal concentration of 200 microM, protamine did not further increase the paracellular response but produced decreasing psi mc and fRa. We conclude that 6 microM protamine decreases K+ conductance of the apical membrane, if it is already tuned high by high pH. At low control K+ conductance as observed at lower pH, protamine action is restricted to the paracellular pathway. Thus, conflicting results were due to different experimental conditions. At a solution pH of 7.1, 6 microM protamine fulfills criteria of a selective tool for reversibly altering structure and function of the tight junction in Necturus gallbladder.