Voltage-dependent calcium channels as targets for convulsant and anticonvulsant alkyl-substituted thiobutyrolactones.

Alkyl-substituted thiobutyrolactones increase or decrease gamma-aminobutyric acidA responses at or near the picrotoxin site, but they are structurally similar to ethosuximide, which prompted us to determine the actions of thiobutyrolactones on voltage-dependent Ca++ currents. We measured Ca++ currents in cultured neonatal rat dorsal root ganglion neurons in the absence and presence of the anticonvulsant alpha-ethyl,alpha-methyl-gamma-thiobutyrolactone (alpha-EMTBL) and the convulsant beta-ethyl,beta-methyl-gamma-thiobutyrolactone (beta-EMTBL). Low-voltage-activated (T-type) currents were reduced in a concentration-dependent manner, with a maximal reduction of 26% and 30% by alpha-EMTBL and beta-EMTBL, respectively. alpha-EMTBL reduced high-voltage-activated currents in a concentration- and voltage-dependent manner: maximal responses were 7% when evoked from -80 mV, with more rapid current inactivation; 29% when evoked from -40 mV, with little effect on current inactivation. beta-EMTBL increased high-voltage-activated currents < or = 20% at 10 to 300 microM, but reduced currents at higher concentrations; the latter action was similar to that of alpha-EMTBL in its magnitude and voltage dependence. Block of N-type channels with omega-conotoxin GVIA (10 microM) reduced the effect of alpha-EMTBL and eliminated its voltage dependence. The L-type current component was also reduced by alpha-EMTBL, with little effect on P- or Q-type current components. The related compound, alpha-ethyl,alpha-methyl-gamma-butyrolactone, had no effect on Ca++ currents. We conclude that thiobutyrolactones affect voltage-dependent Ca++ currents in a concentration- and voltage-dependent manner, with greater potency on low-voltage. activated channels. Both the ring structure and the position of its alkyl substitutions determine the identity of the targeted Ca++ channel subtypes and the manner of regulation.