Abstract
BackgroundThe 21-residue compact tertiapin-Q (TPNQ) toxin, a derivative of honey bee toxin tertiapin (TPN), is a potent blocker of inward-rectifier K+ channel subtype, rat Kir1.1 (rKir1.1) channel, and their interaction mechanism remains unclear.Principal FindingsBased on the flexible feature of potassium channel turrets, a good starting rKir1.1 channel structure was modeled for the accessibility of rKir1.1 channel turrets to TPNQ toxin. In combination with experimental alanine scanning mutagenesis data, computational approaches were further used to obtain a reasonable TPNQ toxin-rKir1.1 channel complex structure, which was completely different from the known binding modes between animal toxins and potassium channels. TPNQ toxin mainly adopted its helical domain as the channel-interacting surface together with His12 as the pore-blocking residue. The important Gln13 residue mainly contacted channel residues near the selectivity filter, and Lys20 residue was surrounded by a polar “groove” formed by Arg118, Thr119, Glu123, and Asn124 in the channel turret. On the other hand, four turrets of rKir1.1 channel gathered to form a narrow pore entryway for TPNQ toxin recognition. The Phe146 and Phe148 residues in the channel pore region formed strong hydrophobic protrusions, and produced dominant nonpolar interactions with toxin residues. These specific structure features of rKir1.1 channel vestibule well matched the binding of potent TPNQ toxin, and likely restricted the binding of the classical animal toxins.Conclusions/SignificanceThe TPNQ toxin-rKir1.1 channel complex structure not only revealed their unique interaction mechanism, but also would highlight the diverse animal toxin-potassium channel interactions, and elucidate the relative insensitivity of rKir1.1 channel towards animal toxins.
Highlights
The diverse and ubiquitous potassium channels serve a variety of physiological and pharmacological functions [1]
Using computational techniques in combination with the experimental data, many potassium channel-animal toxin complex structures were predicted, such as shaker channel-k-PVIIA toxin complex [3], hERG channel-BeKm1 toxin complex [4], Kv1.1 channel-ADWX-1 toxin complex [5]; BKCa channel-ChTX toxin complex [6], Kv1.3 channel-Hg1 toxin complex [7]. These progresses indicated the diverse structural information on the potassium channel-animal toxin interactions, and provided various dynamic structure features of potassium channels induced by toxin recognition
The distance between the Ca atom of Asn117 residue in the turret and the channel pore central axis was about 20.7 Aso that the 21residue TPNQ toxin with small size could not contact with the functional residues in channel turrets within a distance of 5 Ain the predicted TPNQ toxin-rKir1.1 channel complexes (Fig. 1C)
Summary
The diverse and ubiquitous potassium channels serve a variety of physiological and pharmacological functions [1] These proteins are often targeted by numerous peptide toxins from the venomous animals, such as scorpions, spiders, sea anemones, honey bees, snakes and cone snails [2]. Using computational techniques in combination with the experimental data, many potassium channel-animal toxin complex structures were predicted, such as shaker channel-k-PVIIA toxin complex [3], hERG channel-BeKm1 toxin complex [4], Kv1.1 channel-ADWX-1 toxin complex [5]; BKCa channel-ChTX toxin complex [6], Kv1.3 channel-Hg1 toxin complex [7] These progresses indicated the diverse structural information on the potassium channel-animal toxin interactions, and provided various dynamic structure features of potassium channels induced by toxin recognition. The 21-residue compact tertiapin-Q (TPNQ) toxin, a derivative of honey bee toxin tertiapin (TPN), is a potent blocker of inward-rectifier K+ channel subtype, rat Kir1.1 (rKir1.1) channel, and their interaction mechanism remains unclear
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