Abstract
Magi 5, from the hexathelid spider Macrothele gigas, is a 29-residue polypeptide containing three disulfide bridges. It binds specifically to receptor site 4 on mammalian voltage-gated sodium channels and competes with scorpion beta-toxins, such as Css IV from Centruroides suffusus suffusus. As a consequence, Magi 5 shifts the activation voltage of the mammalian rNav1.2a channel to more hyperpolarized voltages, whereas the insect channel, DmNav1, is not affected. To gain insight into toxin-channel interactions, Magi 5 and 23 analogues were synthesized. The three-dimensional structure of Magi 5 in aqueous solution was determined, and its voltage-gated sodium channel-binding surfaces were mapped onto this structure using data from electrophysiological measurements on a series of Ala-substituted analogues. The structure clearly resembles the inhibitor cystine knot structural motif, although the triple-stranded beta-sheet typically found in that motif is partially distorted in Magi 5. The interactive surface of Magi 5 toward voltage-gated sodium channels resembles in some respects the Janus-faced atracotoxins, with functionally important charged residues on one face of the toxin and hydrophobic residues on the other. Magi 5 also resembles the scorpion beta-toxin Css IV, which has distinct nonpolar and charged surfaces that are critical for channel binding and has a key Glu involved in voltage sensor trapping. These two distinct classes of toxin, with different amino acid sequences and different structures, may utilize similar groups of residues on their surface to achieve the common end of modifying voltage-gated sodium channel function.
Highlights
Voltage-gated sodium channels (VGSC)3 are responsible for the generation and propagation of electrical signals in excitable cells
Structure of a Spider Toxin That Affects Sodium Channels consist of a functional discontinuous surface composed of a number of nonpolar and three charged amino acids clustered around the main ␣-helical motif and the C-tail
NMR Spectroscopy—The 1H NMR spectrum of Magi 5 in solution was characterized by broad backbone amide chemical shift dispersion, typical of a structured polypeptide stabilized by disulfide bonds
Summary
Peptide Synthesis—All of the chemicals used in this study were of analytical grade. The C-terminally carboxylated forms (identical to native) of Magi 5, and all of the Magi 5 mutants were chemically synthesized by a solid-phase method using the 0.1-mmol Fmoc (N-(9-fluorenyl)methoxycarbonyl) methodology on an Applied Biosystems 433A peptide synthesizer. Current traces were evoked in an oocyte expressing the cloned sodium channels according to the following protocols: 1) For current-voltage relationships, from a holding potential of Ϫ90 mV, the cells were depolarized with a three-step protocol. The peak currents elicited in the third depolarization were plotted as a function of voltage, resulting in a current-voltage relationship (I-V curve) This data set was used for assessing toxin effect on channel activation. 4) For the dose-response curve, the oocytes were depolarized from a holding potential of Ϫ90 mV to 100 ms test potentials ranging from Ϫ70 to 0 mV with 10-mV increments at a frequency of 0.2 Hz. The data were fitted with the Hill equation
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