Structure and Orientation of a Voltage-Sensor Toxin in Lipid Membranes

Structure and Orientation of a Voltage-Sensor Toxin in Lipid Membranes

Amphipathic protein toxins from tarantula venom inhibit voltage-activated potassium (Kv) channels by binding to a critical helix-turn-helix motif termed the voltage sensor paddle. Although these toxins partition into membranes to bind the paddle motif, their structure and orientation within the memb...

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Bibliographic Details
Published in:Biophysical journal Vol. 99; no. 2; pp. 638 - 646
Main Authors: Jung, Hyun Ho, Jung, Hoi Jong, Milescu, Mirela, Lee, Chul Won, Lee, Seungkyu, Lee, Ju Yeon, Eu, Young-Jae, Kim, Ha Hyung, Swartz, Kenton J., Kim, Jae Il
Format: Journal Article
Language:English
Published: United States Elsevier Inc 21-07-2010
Biophysical Society
The Biophysical Society
Subjects:
Amino Acid Sequence
Animals
DNA Mutational Analysis
Fluorescence
Inhibitors
Ion Channel Gating
Lipids
Membrane Lipids - chemistry
Membranes
Models, Molecular
Molecular Sequence Data
NMR
Nuclear magnetic resonance
Orientation
Paddles
Phosphatidylcholines - chemistry
Potassium
Protein
Protein Binding
Protein Structure, Secondary
Proteins
Residues
Spectrum Analysis
Spider Venoms - chemistry
Toxins
Tryptophan - metabolism
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Summary:Amphipathic protein toxins from tarantula venom inhibit voltage-activated potassium (Kv) channels by binding to a critical helix-turn-helix motif termed the voltage sensor paddle. Although these toxins partition into membranes to bind the paddle motif, their structure and orientation within the membrane are unknown. We investigated the interaction of a tarantula toxin named SGTx with membranes using both fluorescence and NMR spectroscopy. Depth-dependent fluorescence-quenching experiments with brominated lipids suggest that Trp30 in SGTx is positioned ∼9 Å from the center of the bilayer. NMR spectra reveal that the inhibitor cystine knot structure of the toxin does not radically change upon membrane partitioning. Transferred cross-saturation NMR experiments indicate that the toxin's hydrophobic protrusion contacts the hydrophobic core of the membrane, whereas most surrounding polar residues remain at interfacial regions of the bilayer. The inferred orientation of the toxin reveals a twofold symmetry in the arrangement of basic and hydrophobic residues, a feature that is conserved among tarantula toxins. These results have important implications for regions of the toxin involved in recognizing membranes and voltage-sensor paddles, and for the mechanisms by which tarantula toxins alter the activity of different types of ion channels.
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Hyun Ho Jung and Hoi Jong Jung contributed equally to this work.
ISSN:0006-3495
1542-0086
DOI:10.1016/j.bpj.2010.04.061