Biophys J, July 1999, p. 229-240, Vol. 77, No. 1

Tonic and Phasic Tetrodotoxin Block of Sodium Channels with Point Mutations in the Outer Pore Region

Istituto di Cibernetica e Biofisica, CNR, I-16149 Genova, Italy  ^#National Institute for Physiological Sciences, Okazaki 444, Japan

Tonic and use-dependent block by tetrodotoxin (TTX) has been studied in cRNA-injected Xenopus oocytes expressing mutants W386Y, E945Q, D1426K, and D1717Q, of the outer-pore region of the rat brain IIA -subunit of sodium channels. The various phenotypes are tonically half-blocked at TTX concentrations, IC₅₀^(t), that span a range of more than three orders of magnitude, from 4 nM in mutant D1426K to 11 µM in mutant D1717Q. When stimulated with repetitive depolarizing pulses at saturating frequencies, all channels showed a monoexponential increase in their TTX-binding affinity with time constants that span an equally wide range of values ([TTX]  IC₅₀^(t), from ~60 s for D1426K to ~30 ms for D1717Q) and are in most phenotypes roughly inversely proportional to IC₅₀^(t). In contrast, all phenotypes show the same approximately threefold increase in their TTX affinity under stimulation. The invariance of the free-energy difference between tonic and phasic configurations of the toxin-receptor complex, together with the extreme variability of phasic block kinetics, is fully consistent with the trapped-ion mechanism of use dependence suggested by Salgado et al. (1986) and developed by Conti et al. (1996). Using this model, we estimated for each phenotype both the second-order association rate constant, k_on, and the first-order dissociation rate constant, k_off, for TTX binding. Except for mutant E945Q, all phenotypes have roughly the same value of k_on  2 µM¹ s¹ and owe their large differences in IC₅₀^(t) to different k_off values. However, a 60-fold reduction in k_on is the main determinant of the low TTX sensitivity of mutant E945Q. This suggests that the carboxyl group of E945 occupies a much more external position in the pore vestibule than that of the homologous residue D1717.

Biophys J, July 1999, p. 229-240, Vol. 77, No. 1
© 1999 by the Biophysical Society   0006-3495/99/07/229/12  $2.00

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