ABSTRACT
In voltage-dependent sodium channels there is some functional specialization of the four different S4 voltage sensors with regard to the gating process. Whereas the voltage sensors of domains 1 to 3 control activation gating, the movement of the voltage sensor of domain 4 (S4D4) is known to be tightly coupled to sodium channel inactivation, and there is some experimental evidence that S4D4 also participates in activation gating. To further explore its putative multifunctional role in the gating process, we changed the central part of S4D4 in rat brain IIA (rBIIA) sodium channels by the simultaneous replacement of the third (R1632), fourth (R1635) and fifth (R1638) arginine by histidine (mutation R3/4/5H). As a result, the time course of current decay observed in R3/4/5H was about three times slower, if compared to wild type (WT). On the other hand, the recovery, as well as the voltage dependence of fast inactivation, remained largely unaffected by the mutation. This suggests that at physiological pH (7.5) the effective charge of the voltage sensor was not significantly changed by the amino-acid substitutions. The well-known impact of site-3 toxin (ATX-II) on the inactivation was drastically reduced in R3/4/5H, without changing the toxin affinity of the channel. The activation kinetics of WT and R3/4/5H studied at low temperature (8 degrees C) were indistinguishable, while the inactivation time course of R3/4/5H was then clearly more slowed than in WT. These data suggest that the replacement of arginines by histidines in the central part of S4D4 clearly affects the movement of S4D4 without changing the activation kinetics.
Subject(s)
Arginine/metabolism , Histidine/metabolism , Ion Channel Gating/physiology , Sodium Channels/chemistry , Sodium Channels/physiology , Adaptation, Physiological/physiology , Animals , Arginine/chemistry , Arginine/genetics , Brain/drug effects , Brain/physiology , Cnidarian Venoms/pharmacology , Histidine/chemistry , Histidine/genetics , Ion Channel Gating/drug effects , Membrane Potentials/drug effects , Membrane Potentials/physiology , Motion , Mutagenesis, Site-Directed , Oocytes/drug effects , Oocytes/physiology , Protein Structure, Tertiary , Protein Transport/physiology , Rats , Recombinant Proteins/chemistry , Recombinant Proteins/metabolism , Sodium Channels/classification , Sodium Channels/drug effects , Structure-Activity Relationship , Xenopus laevisABSTRACT
Rat brain (rBIIA) sodium channel fast inactivation kinetics and the time course of recovery of the immobilized gating charge were compared for wild type (WT) and the pore mutant D384N heterologously expressed in Xenopus oocytes with or without the accessory beta1-subunit. In the absence of the beta1-subunit, WT and D384N showed characteristic bimodal inactivation kinetics, but with the fast gating mode significantly more pronounced in D384N. Both, for WT and D384N, coexpression of the beta1-subunit further shifted the time course of inactivation to the fast gating mode. However, the recovery of the immobilized gating charge (Qg) of D384N was clearly faster than in WT, irrespective of the presence of the beta1-subunit. This was also reflected by the kinetics of the slow Ig OFF tail. On the other hand, the voltage dependence of the Qg-recovery was not changed by the mutation. These data suggest a direct interaction between the selectivity filter and the immobilized voltage sensor S4D4 of rBIIA sodium channels.
