Abstract
Grayanotoxin (GTX) exerts selective effects on voltage-dependent sodium channels by eliminating fast sodium inactivation and causing a hyperpolarizing shift in voltage dependence of channel activation. In this study, we adopted a newly developed protocol that provides independent estimates of the binding and unbinding rate constants of GTX (k(on) and k(off)) to GTX sites on the sodium channel protein, important in the molecular analysis of channel modification. Novel GTX sites were determined in D2S6 (Asn-784) and D3S6 (Ser-1276) by means of site-directed mutagenesis; the results suggested that the GTX receptor consists of the S6 transmembrane segments of four homologous domains facing the ion-conducting pore. We systematically introduced at two sites in D4S6 (Na(v)1.4-Phe-1579 and Na(v)1.4-Tyr-1586) amino acid substituents with residues containing hydrophobic, aromatic, charged, or polar groups. Generally, substitutions at Phe-1579 increased both k(on) and k(off), resulting in no prominent change in dissociation constant (K(d)). It seems that the smaller the molecular size of the residue at Na(v)1.4-Phe-1579, the larger the rates of k(on) and k(off), indicating that this site acts as a gate regulating access of toxin molecules to a receptor site. Substitutions at Tyr-1586 selectively increased k(off) but had virtually no effect on k(on), thus causing a drastic increase in K(d). At position Tyr-1586, a hydrophobic or aromatic amino acid side chain was required to maintain normal sensitivity to GTX. These results suggest that the residue at position Tyr-1586 has a more critical role in mediating GTX binding than the one at position Phe-1579. Here, we propose that the affinity of GTX to Na(v)1.4 sodium channels might be regulated by two residues (Phe and Tyr) at positions Phe-1579 and Tyr-1586, which, respectively, control access and binding of GTX to its receptor.
Highlights
Grayanotoxin (GTX) exerts selective effects on voltagedependent sodium channels by eliminating fast sodium inactivation and causing a hyperpolarizing shift in voltage dependence of channel activation
Novel GTX sites were determined in D2S6 (Asn-784) and D3S6 (Ser-1276) by means of site-directed mutagenesis; the results suggested that the GTX receptor consists of the S6 transmembrane segments of four homologous domains facing the ion-conducting pore
We reported that D1S6 and D4S6 segments are required for GTX binding to the sodium channel (19 –21)
Summary
D4S6 of Nav1.4 Sodium Channel as Revealed by Improved Estimation of Toxin Sensitivity*. Substitutions at Phe-1579 increased both kon and koff, resulting in no prominent change in dissociation constant (Kd) It seems that the smaller the molecular size of the residue at Nav1.4-Phe-1579, the larger the rates of kon and koff, indicating that this site acts as a gate regulating access of toxin molecules to a receptor site. Substitutions at Tyr-1586 selectively increased koff but had virtually no effect on kon, causing a drastic increase in Kd. At position Tyr-1586, a hydrophobic or aromatic amino acid side chain was required to maintain normal sensitivity to GTX. Unexplored GTX sites in D2 and D3 have been examined in this study Within these segments, a number of putative binding sites on the rat skeletal muscle sodium channel isoform, Nav1.4 (Ile-433, Asn-434, Leu437, Ile-1575, Phe-1579, and Tyr-1586), may interact with the ␣-surface of the GTX molecule, whose pharmacological action is effected within a hydrophobic microenvironment [8]. At the sites in D4S6, we made systematic amino acid substitutions to further clarify their roles in more detail
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