Lipid Bilayer Deformation and the Free Energy of Interaction of a Kv Channel Gating-Modifier Toxin

Wee, Chze Ling; Gavaghan, David; Sansom, Mark S. P.

doi:10.1529/biophysj.108.130971

Cited by 26 publications

(66 citation statements)

References 76 publications

(112 reference statements)

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“…However, our simulations suggest that the shallow mode is more favorable than the deep mode, as the deep mode evolves spontaneously to the shallow mode over a simulation period of 50 ns (Figure 3B,C). The interfacial binding by GsMTx4 observed here is consistent with the binding modes of SGTx1 [34] and VSTx1 [35] to POPC bilayers observed in previous computational studies.…”

Section: Resultssupporting

confidence: 90%

“…For example, SGTx1 also binds most favorably to this interfacial region [34]. The position of the PMF minima observed here is similar to that for the binding of VSTx1 to several different types of lipid bilayers, including POPC determined by Wee et al [35,36]. Moreover, HaTx1 binds to the interfacial region of lipid bilayers according to the experimental measurements of Phillips et al [29].…”

Section: Resultssupporting

confidence: 83%

“…Several molecular dynamics (MD) simulation studies have been carried out to understand the binding mechanism of gating modifier toxins in model membranes [33,34,35,36,37,38]. In these studies, the toxins are frequently embedded into the lipid bilayer at different depths at the start of the simulations to probe the most preferred position of toxin binding.…”

Section: Introductionmentioning

confidence: 99%

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Effect of Gating Modifier Toxins on Membrane Thickness: Implications for Toxin Effect on Gramicidin and Mechanosensitive Channels

Chen

Chung

2013

Toxins

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Various gating modifier toxins partition into membranes and interfere with the gating mechanisms of biological ion channels. For example, GsMTx4 potentiates gramicidin and several bacterial mechanosensitive channels whose gating kinetics are sensitive to mechanical properties of the membrane, whereas binding of HpTx2 shifts the voltage-activity curve of the voltage-gated potassium channel Kv4.2 to the right. The detailed process by which the toxin partitions into membranes has been difficult to probe using molecular dynamics due to the limited time scale accessible. Here we develop a protocol that allows the spontaneous assembly of a polypeptide toxin into membranes in atomistic molecular dynamics simulations of tens of nanoseconds. The protocol is applied to GsMTx4 and HpTx2. Both toxins, released in water at the start of the simulation, spontaneously bind into the lipid bilayer within 50 ns, with their hydrophobic patch penetrated into the bilayer beyond the phosphate groups of the lipids. It is found that the bilayer is about 2 Å thinner upon the binding of a GsMTx4 monomer. Such a thinning effect of GsMTx4 on membranes may explain its potentiation effect on gramicidin and mechanosensitive channels.

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Section: Resultssupporting

confidence: 90%

Section: Resultssupporting

confidence: 83%

Section: Introductionmentioning

confidence: 99%

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Effect of Gating Modifier Toxins on Membrane Thickness: Implications for Toxin Effect on Gramicidin and Mechanosensitive Channels

Chen

Chung

2013

Toxins

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“…The results of neutron diffraction experiments also demonstrate that the toxin produces a thinning of the membrane (Fig. 3 A and B), in quantitative agreement with the solid-state NMR results and with earlier moleculardynamics simulations (65). Partitioning of the VSTx1 into the membrane also broadens the water distribution determined using neutron diffraction (Fig.…”

Section: Discussionsupporting

confidence: 88%

Structural interactions of a voltage sensor toxin with lipid membranes

Mihailescu

Krepkiy

Milescu

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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Protein toxins from tarantula venom alter the activity of diverse ion channel proteins, including voltage, stretch, and ligandactivated cation channels. Although tarantula toxins have been shown to partition into membranes, and the membrane is thought to play an important role in their activity, the structural interactions between these toxins and lipid membranes are poorly understood. Here, we use solid-state NMR and neutron diffraction to investigate the interactions between a voltage sensor toxin (VSTx1) and lipid membranes, with the goal of localizing the toxin in the membrane and determining its influence on membrane structure. Our results demonstrate that VSTx1 localizes to the headgroup region of lipid membranes and produces a thinning of the bilayer. The toxin orients such that many basic residues are in the aqueous phase, all three Trp residues adopt interfacial positions, and several hydrophobic residues are within the membrane interior. One remarkable feature of this preferred orientation is that the surface of the toxin that mediates binding to voltage sensors is ideally positioned within the lipid bilayer to favor complex formation between the toxin and the voltage sensor.voltage sensor toxin | voltage-activated ion channel | toxin-membrane interaction | membrane structure | neutron diffraction P rotein toxins from venomous organisms have been invaluable tools for studying the ion channel proteins they target. For example, in the case of voltage-activated potassium (Kv) channels, pore-blocking scorpion toxins were used to identify the pore-forming region of the channel (1, 2), and gating modifier tarantula toxins that bind to S1-S4 voltage-sensing domains have helped to identify structural motifs that move at the protein-lipid interface (3-5). In many instances, these toxin-channel interactions are highly specific, allowing them to be used in target validation and drug development (6-8).Tarantula toxins are a particularly interesting class of protein toxins that have been found to target all three families of voltageactivated cation channels (3, 9-12), stretch-activated cation channels (13-15), as well as ligand-gated ion channels as diverse as acid-sensing ion channels (ASIC) (16-21) and transient receptor potential (TRP) channels (22, 23). The tarantula toxins targeting these ion channels belong to the inhibitor cystine knot (ICK) family of venom toxins that are stabilized by three disulfide bonds at the core of the molecule (16,17,(24)(25)(26)(27)(28)(29)(30)(31). Although conventional tarantula toxins vary in length from 30 to 40 aa and contain one ICK motif, the recently discovered double-knot toxin (DkTx) that specifically targets TRPV1 channels contains two separable lobes, each containing its own ICK motif (22, 23).One unifying feature of all tarantula toxins studied thus far is that they act on ion channels by modifying the gating properties of the channel. The best studied of these are the tarantula toxins targeting voltage-activated cation channels, where the toxins bind to the S3b-S4 vol...

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“…A variant of the MARTINI force field developed by Sansom and coworkers [29,30•] has been used to examine the one-dimensional PMF (free energy profile) governing a gated potassium channel and gating modifier toxin (VSTx1) [44]. The binding constants were significantly larger than those reported experimentally for VSTx1, and the source of this discrepancy has not been resolved.…”

Section: Parameterized “Top-down” Cg Force Fields For Membrane Proteimentioning

confidence: 99%

Systematic multiscale simulation of membrane protein systems

Ayton

Voth

2009

Current Opinion in Structural Biology

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Summary of Recent Advances Current multiscale simulation approaches for membrane protein systems vary depending on their degree of connection to the underlying molecular scale interactions. Various approaches have been developed that include such information into coarse-grained models of both the membrane and the proteins. By contrast, other approaches employ parameterizations obtained from experimental data. Mesoscopic models operate at larger scales and have also been employed to examine membrane remodeling, protein inclusions, and ion channel gating. When bridged together such that molecular level information is propagated between the different scales, a systematic multiscale methodology for membrane protein systems can be achieved.

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Lipid Bilayer Deformation and the Free Energy of Interaction of a Kv Channel Gating-Modifier Toxin

Cited by 26 publications

References 76 publications

Effect of Gating Modifier Toxins on Membrane Thickness: Implications for Toxin Effect on Gramicidin and Mechanosensitive Channels

Effect of Gating Modifier Toxins on Membrane Thickness: Implications for Toxin Effect on Gramicidin and Mechanosensitive Channels

Structural interactions of a voltage sensor toxin with lipid membranes

Systematic multiscale simulation of membrane protein systems

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