Your search keyword '"Chze Ling Wee"' showing total 7 results

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

Author

David J. Gavaghan, Chze Ling Wee, and Mark S.P. Sansom

Subjects

Models, Molecular, Lipid Bilayers, Biophysics, Spider Venoms, Model lipid bilayer, 01 natural sciences, 03 medical and health sciences, Molecular dynamics, Orientations of Proteins in Membranes database, 0103 physical sciences, Computer Simulation, Channels, Receptors, and Electrical Signaling, Lipid bilayer phase behavior, Amino Acids, Lipid bilayer, 030304 developmental biology, 0303 health sciences, 010304 chemical physics, Chemistry, Bilayer, Reproducibility of Results, Lipid bilayer mechanics, Crystallography, Membrane protein, Potassium Channels, Voltage-Gated, Thermodynamics, Peptides, Hydrophobic and Hydrophilic Interactions, Ion Channel Gating

Abstract

A number of membrane proteins act via binding at the water/lipid bilayer interface. An important example of such proteins is provided by the gating-modifier toxins that act on voltage-gated potassium (Kv) channels. They are thought to partition to the headgroup region of lipid bilayers, and so provide a good system for probing the nature of interactions of a protein with the water/bilayer interface. We used coarse-grained molecular dynamics simulations to compute the one-dimensional potential of mean force (i.e., free energy) profile that governs the interaction between a Kv channel gating-modifier toxin (VSTx1) and model phospholipid bilayers. The reaction coordinate sampled corresponds to the position of the toxin along the bilayer normal. The course-grained representation of the protein and lipids enabled us to explore extended time periods, revealing aspects of toxin/bilayer dynamics and energetics that would be difficult to observe on the timescales currently afforded by atomistic molecular dynamics simulations. In particular, we show for this model system that the bilayer deforms as it interacts with the toxin, and that such deformations perturb the free energy profile. Bilayer deformation therefore adds an additional layer of complexity to be addressed in investigations of membrane/protein systems. In particular, one should allow for local deformations that may arise due to the spatial array of charged and hydrophobic elements of an interfacially located membrane protein.

Published

2008

2. The Interaction of Phospholipase A2 with a Phospholipid Bilayer: Coarse-Grained Molecular Dynamics Simulations

Author

Chze Ling Wee, Mark S.P. Sansom, Kia Balali-Mood, and David J. Gavaghan

Subjects

Models, Molecular, Membrane Fluidity, Lipid Bilayers, Biophysics, Biophysical Theory and Modeling, Model lipid bilayer, 010402 general chemistry, 01 natural sciences, Hydrophobic effect, 03 medical and health sciences, Molecular dynamics, Lamellar phase, Computer Simulation, Lipid bilayer phase behavior, Lipid bilayer, Phospholipids, 030304 developmental biology, 0303 health sciences, Chemistry, Bilayer, technology, industry, and agriculture, Membrane Proteins, Lipid bilayer mechanics, 0104 chemical sciences, Phospholipases A2, Crystallography, Models, Chemical, Chemical physics, lipids (amino acids, peptides, and proteins), Protein Binding

Abstract

A number of membrane-active enzymes act in a complex environment formed by the interface between a lipid bilayer and bulk water. Although x-ray diffraction studies yield structures of isolated enzyme molecules, a detailed characterization of their interactions with the interface requires a measure of how deeply such a membrane-associated protein penetrates into a lipid bilayer. Here, we apply coarse-grained (CG) molecular dynamics (MD) simulations to probe the interaction of porcine pancreatic phospholipase A2 (PLA2) with a lipid bilayer containing palmitoyl-oleoyl-phosphatidyl choline and palmitoyl-oleoyl-phosphatidyl glycerol molecules. We also used a configuration from a CG-MD trajectory to initiate two atomistic (AT) MD simulations. The results of the CG and AT simulations are evaluated by comparison with available experimental data. The membrane-binding surface of PLA2 consists of a patch of hydrophobic residues surrounded by polar and basic residues. We show this proposed footprint interacts preferentially with the anionic headgroups of the palmitoyl-oleoyl-phosphatidyl glycerol molecules. Thus, both electrostatic and hydrophobic interactions determine the location of PLA2 relative to the bilayer. From a general perspective, this study demonstrates that CG-MD simulations may be used to reveal the orientation and location of a membrane-surface-bound protein relative to a lipid bilayer, which may subsequently be refined by AT-MD simulations to probe more detailed interactions.

Published

2008

3. Membrane insertion of a voltage sensor helix

Author

Chze Ling Wee, Mark S.P. Sansom, and Alan Chetwynd

Subjects

Chemistry, Bilayer, Lipid Bilayers, Biophysics, Membrane, Membrane Proteins, Water, Molecular Dynamics Simulation, Transmembrane protein, Ion Channels, Protein Structure, Secondary, Molecular dynamics, Crystallography, Membrane protein, Side chain, Thermodynamics, Computer Simulation, Lipid bilayer, Ion Channel Gating, Ion channel, Phospholipids

Abstract

Most membrane proteins contain a transmembrane (TM) domain made up of a bundle of lipid-bilayer-spanning α-helices. TM α-helices are generally composed of a core of largely hydrophobic amino acids, with basic and aromatic amino acids at each end of the helix forming interactions with the lipid headgroups and water. In contrast, the S4 helix of ion channel voltage sensor (VS) domains contains four or five basic (largely arginine) side chains along its length and yet adopts a TM orientation as part of an independently stable VS domain. Multiscale molecular dynamics simulations are used to explore how a charged TM S4 α-helix may be stabilized in a lipid bilayer, which is of relevance in the context of mechanisms of translocon-mediated insertion of S4. Free-energy profiles for insertion of the S4 helix into a phospholipid bilayer suggest that it is thermodynamically favorable for S4 to insert from water to the center of the membrane, where the helix adopts a TM orientation. This is consistent with crystal structures of Kv channels, biophysical studies of isolated VS domains in lipid bilayers, and studies of translocon-mediated S4 helix insertion. Decomposition of the free-energy profiles reveals the underlying physical basis for TM stability, whereby the preference of the hydrophobic residues of S4 to enter the bilayer dominates over the free-energy penalty for inserting charged residues, accompanied by local distortion of the bilayer and penetration of waters. We show that the unique combination of charged and hydrophobic residues in S4 allows it to insert stably into the membrane.

Published

2009

4. Coarse-grained molecular dynamics simulations of the energetics of helix insertion into a lipid bilayer

Author

Chze Ling Wee, Peter J. Bond, and Mark S.P. Sansom

Subjects

Ions, 1,2-Dipalmitoylphosphatidylcholine, Chemistry, Bilayer, Lipid Bilayers, Sodium, Molecular Conformation, Water, Lipid bilayer mechanics, Biochemistry, Protein Structure, Secondary, Transmembrane domain, Crystallography, Molecular dynamics, Orientations of Proteins in Membranes database, Chlorides, Chemical physics, Helix, Thermodynamics, Computer Simulation, Lipid bilayer phase behavior, Amino Acids, Lipid bilayer, Hydrophobic and Hydrophilic Interactions

Abstract

Experimental and computational studies have indicated that hydrophobicity plays a key role in driving the insertion of transmembrane alpha-helices into lipid bilayers. Molecular dynamics simulations allow exploration of the nature of the interactions of transmembrane alpha-helices with their lipid bilayer environment. In particular, coarse-grained simulations have considerable potential for studying many aspects of membrane proteins, ranging from their self-assembly to the relation between their structure and function. However, there is a need to evaluate the accuracy of coarse-grained estimates of the energetics of transmembrane helix insertion. Here, three levels of complexity of model system have been explored to enable such an evaluation. First, calculated free energies of partitioning of amino acid side chains between water and alkane yielded an excellent correlation with experiment. Second, free energy profiles for transfer of amino acid side chains along the normal to a phosphatidylcholine bilayer were in good agreement with experimental and atomistic simulation studies. Third, estimation of the free energy profile for transfer of an arginine residue, embedded within a hydrophobic alpha-helix, to the center of a lipid bilayer gave a barrier of approximately 15 kT. Hence, there is a substantial barrier to membrane insertion for charged amino acids, but the coarse-grained model still underestimates the corresponding free energy estimate (approximately 29 kT) from atomistic simulations (Dorairaj, S., and Allen, T. W. (2007) Proc. Natl. Acad. Sci. U.S.A. 104, 4943-4948). Coarse-grained simulations were then used to predict the free energy profile for transfer of a simple model transmembrane alpha-helix (WALP23) across a lipid bilayer. The results indicated that a transmembrane orientation was favored by about -70 kT.

Published

2008

5. Improved sampling for simulations of interfacial membrane proteins: application of generalized shadow hybrid Monte Carlo to a peptide toxin/bilayer system

Author

Chze Ling Wee, Mark S.P. Sansom, Elena Akhmatskaya, and Sebastian Reich

Subjects

Models, Molecular, Chemistry, Bilayer, Lipid Bilayers, Complex system, Energy landscape, Sampling (statistics), Membrane Proteins, Nanotechnology, Force field (chemistry), Surfaces, Coatings and Films, Hybrid Monte Carlo, Molecular dynamics, Materials Chemistry, Computer Simulation, Physical and Theoretical Chemistry, Biological system, Peptides, Monte Carlo Method, Monte Carlo molecular modeling, Toxins, Biological

Abstract

The computational costs associated with performing molecular dynamics (MD) simulations are still somewhat prohibitive and therefore limit the time and length scales that can be currently achieved. One approach to overcoming the limited size and duration of a simulation is to reduce the amount of detail when representing a system of interest, generally termed "coarse-graining". An alternative approach is via more efficient sampling methods that offer an enhanced search of a complex multidimensional energy landscape. One could also combine enhanced sampling methods with a coarse-grained (CG) force field. Here, we apply generalized shadow hybrid Monte Carlo (GSHMC), a recently proposed simulation protocol, to a biomolecular system of moderate size and show that GSHMC offers improved sampling compared to standard MD simulation. Our test system is a CG representation of a small peptide toxin interacting with a phospholipid bilayer. Specifically, we show that GSHMC allows for a quicker localization of the toxin to its equilibrium location of interaction at the headgroup/water interface of the bilayer. GSHMC therefore potentially allows for future exploration of larger and more complex systems over longer periods, which would otherwise be impractical to perform using conventional simulation methodology.

Published

2008

6. Vstx1, a modifier of Kv channel gating, localizes to the interfacial region of lipid bilayers

Author

Chze Ling Wee, Zara A. Sands, Mark S.P. Sansom, and Alessandro Grottesi, and Daniele Bemporad

Subjects

Models, Molecular, Surface Properties, Chemistry, Archaeal Proteins, Bilayer, Lipid Bilayers, Spider Venoms, Lipid bilayer fusion, Gating, Biochemistry, Protein Structure, Secondary, Potassium channel, Molecular dynamics, Crystallography, chemistry.chemical_compound, Potassium Channels, Voltage-Gated, Biophysics, Computer Simulation, Lipid bilayer phase behavior, Peptides, Lipid bilayer, POPC, Protein Binding

Abstract

VSTx1 is a tarantula venom toxin which binds to the archaebacterial voltage-gated potassium channel KvAP. VSTx1 is thought to access the voltage sensor domain of the channel via the lipid bilayer phase. In order to understand its mode of action and implications for the mechanism of channel activation, it is important to characterize the interactions of VSTx1 with lipid bilayers. Molecular dynamics (MD) simulations (for a total simulation time in excess of 0.2 micros) have been used to explore VSTx1 localization and interactions with zwitterionic (POPC) and with anionic (POPE/POPG) lipid bilayers. In particular, three series of MD simulations have been used to explore the net drift of VSTx1 relative to the center of a bilayer, starting from different locations of the toxin. The preferred location of the toxin is at the membrane/water interface. Although there are differences between POPC and POPE/POPG bilayers, in both cases the toxin forms favorable interactions at the interface, maximizing H-bonding to lipid headgroups and to water molecules while retaining interactions with the hydrophobic core of the bilayer. A 30 ns unrestrained simulation reveals dynamic partitioning of VSTx1 into the interface of a POPC bilayer. The preferential location of VSTx1 at the interface is discussed in the context of Kv channel gating models and provides support for a mode of action in which the toxin interacts with the Kv voltage sensor "paddle" formed by the S3 and S4 helices.

Published

2006

7. The interaction of C60and its derivatives with a lipid bilayer via molecular dynamics simulations

Author

Chze Ling Wee, E. Jayne Wallace, Robert S. G. D'rozario, and Mark S.P. Sansom

Subjects

Models, Molecular, Chemistry, Mechanical Engineering, Bilayer, Lipid Bilayers, Bioengineering, General Chemistry, Lipid bilayer mechanics, Permeation, Model lipid bilayer, Crystallography, Molecular dynamics, Mechanics of Materials, Chemical physics, Thermodynamics, Computer Simulation, General Materials Science, Fullerenes, Lipid bilayer phase behavior, Electrical and Electronic Engineering, Solubility, Lipid bilayer

Abstract

Coarse-grained molecular dynamics simulations have been used to explore the interactions of C(60) and its derivatives with lipid bilayers. Pristine C(60) partitions into the bilayer core, whilst C(60)(OH)(20) experiences a central energetic barrier to permeation across the bilayer. For intermediate levels of derivatization, e.g. C(60)(OH)(10), this central barrier is smaller and there is an energetic well at the bilayer/water interface, thus promoting entry into cells via bilayer permeation whilst maintaining solubility in water.

Published

2009