Investigation of Binding Modes and Functional Surface of Scorpion Toxins ANEP to Sodium Channels 1.7

The depressant β toxin anti-neuroexcitation peptide (ANEP) from the Chinese scorpion Karsch has analgesic activity by interacting with receptor site 4 of the voltage-gated sodium channels (VGSCs). Here, with molecular dynamics simulations, we examined the binding modes between ANEP and the site 4 of...

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Bibliographic Details
Published in:Toxins 2017-11, Vol.9 (12), p.387
Main Authors: Song, Yongbo, Liu, Zeyu, Zhang, Qi, Li, Chunming, Jin, Wei, Liu, Lili, Zhang, Jianye, Zhang, Jinghai
Format: Article
Language:English
Subjects:
Amino acids
analgesic activity
Analgesics
ANEP
Animal models
Binding
Binding Sites
Buckminsterfullerene
Buthus martensii Karsch
Channels
Computer simulation
Fullerenes
Homology
Hydrophobicity
Models, Molecular
Molecular dynamics
molecular dynamics simulations
Mutagenesis
NAV1.7 Voltage-Gated Sodium Channel - chemistry
Nav1.7-site 4
Pain
Pharmacology
Residues
Scorpion Venoms - chemistry
Sodium
Sodium channels (voltage-gated)
Toxins
Twisting
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Summary:The depressant β toxin anti-neuroexcitation peptide (ANEP) from the Chinese scorpion Karsch has analgesic activity by interacting with receptor site 4 of the voltage-gated sodium channels (VGSCs). Here, with molecular dynamics simulations, we examined the binding modes between ANEP and the site 4 of mice sodium channel 1.7 (mNa 1.7), a subtype of VGSCs related to peripheral pain. Homology modeling, molecular mechanics, and molecular dynamics in the biomembrane environment were adopted. The results suggested that ANEP bound to the resting site 4 mainly by amino acid residues in the β2-β3 loop and the 'NC' domains, and the activate site 4 mainly by amino acid residues in the hydrophobic domain of N-groove and residues in the 'pharmacophore'. Effects analysis of 14 mutants in the predicted functional domains of ANEP on mouse twisting models showed that the analgesic activity of mutants L15 and E24 of the 'pharmacophore', W36, T37, W38, and T39 forming the loop between the β2- and β3-strands and N8, V12, C60, and K64 in the NC domain increased distinctly after these residues were substituted for Ala, respectively. The binding modes and the active sites predicted were consistent with available mutagenesis data, and which is meaningful to understand the related mechanisms of ANEP for Na 1.7.
ISSN:2072-6651
2072-6651
DOI:10.3390/toxins9120387