Functional studies have indicated that, unlike most divalent cations, lanthanum increases both native and recombinant gamma-aminobutyric acid (GABA) receptor (GABAR) currents. In the present study, we have examined whether lanthanum shows subunit-dependent selectivity for modification of currents from different GABAR isoforms. The effects of lanthanum on three different GABAR isoforms, alpha1beta3gamma2L, alpha6beta3gamma2L, and alpha6beta3delta, were determined by transient expression of combinations of alpha1, alpha6, beta3, gamma2L, and delta subunit cDNAs in L929 fibroblasts. Whole-cell recording was used to determine the concentration-response curves for lanthanum for the three different isoforms at submaximal concentrations of GABA. Lanthanum displayed strong potentiation of alpha1beta3gamma2L GABAR currents consistent with earlier reports of potentiation of GABAR currents by lanthanum in neurons and recombinant GABAR isoforms. However, in contrast to the potentiation of alpha1beta3gamma2L GABAR currents by lanthanum, alpha6beta3delta GABAR currents were strongly inhibited and alpha6beta3gamma2L GABAR currents were weakly inhibited by lanthanum. Interaction of lanthanum with GABAR isoforms was competitive, with lanthanum decreasing the EC50 value for GABA of alpha1beta3gamma2L GABARs without changing the maximum current and increasing the EC50 value for GABA of alpha6beta3delta and alpha6beta3gamma2L GABAR currents (greater shift in EC50 value in the alpha6beta3delta compared with the alpha6beta3gamma2L GABARs) without changing the maximum GABAR current. Neither potentiation nor inhibition of GABAR currents by lanthanum showed any voltage dependence. These results suggest that 1) changing the alpha-subunit subtype from alpha1 to alpha6 altered the effect of lanthanum from potentiation to inhibition, 2) changing the gamma2L subunit to the delta-subunit changed the level of maximal inhibition of alpha6 subtype-containing GABAR currents by lanthanum, and 3) the site for interaction with lanthanum probably was on the extracellular surface of GABARs.