Determining Peptide Partitioning Properties via Computer Simulation

The transfer of polypeptide segments into lipid bilayers to form transmembrane helices represents the crucial first step in cellular membrane protein folding and assembly. This process is driven by complex and poorly understood atomic interactions of peptides with the lipid bilayer environment. The lack of suitable experimental techniques that can resolve these processes both at atomic resolution and nanosecond timescales has spurred the development of computational techniques. In this review, we summarize the significant progress achieved in the last few years in elucidating the partitioning of peptides into lipid bilayer membranes using atomic detail molecular dynamics simulations. Indeed, partitioning simulations can now provide a wealth of structural and dynamic information. Furthermore, we show that peptide-induced bilayer distortions, insertion pathways, transfer free energies, and kinetic insertion barriers are now accurate enough to complement experiments. Further advances in simulation methods and force field parameter accuracy promise to turn molecular dynamics simulations into a powerful tool for investigating a wide range of membrane active peptide phenomena.

[1]  W. L. Jorgensen,et al.  Development and Testing of the OPLS All-Atom Force Field on Conformational Energetics and Properties of Organic Liquids , 1996 .

[2]  D. Wilkin,et al.  Neuron , 2001, Brain Research.

[3]  G. von Heijne Formation of Transmembrane Helices In Vivo—Is Hydrophobicity All that Matters? , 2007, The Journal of general physiology.

[4]  G. Heijne,et al.  Molecular code for transmembrane-helix recognition by the Sec61 translocon , 2007, Nature.

[5]  S. White,et al.  The preference of tryptophan for membrane interfaces. , 1998, Biochemistry.

[6]  N. Ben-Tal,et al.  Free Energy of Amide Hydrogen Bond Formation in Vacuum, in Water, and in Liquid Alkane Solution , 1997 .

[7]  S H White,et al.  Folding of beta-sheet membrane proteins: a hydrophobic hexapeptide model. , 1998, Journal of molecular biology.

[8]  M. Sansom,et al.  Amino acid distributions in integral membrane protein structures. , 2001, Biochimica et biophysica acta.

[9]  M. Cadene,et al.  X-ray structure of a voltage-dependent K+ channel , 2003, Nature.

[10]  W F Drew Bennett,et al.  Distribution of amino acids in a lipid bilayer from computer simulations. , 2008, Biophysical journal.

[11]  E. Lindahl,et al.  Amino-acid solvation structure in transmembrane helices from molecular dynamics simulations. , 2006, Biophysical journal.

[12]  Roderick MacKinnon,et al.  Contribution of the S4 Segment to Gating Charge in the Shaker K+ Channel , 1996, Neuron.

[13]  Ilpo Vattulainen,et al.  Defect-mediated trafficking across cell membranes: insights from in silico modeling. , 2010, Chemical reviews.

[14]  Toby W Allen,et al.  On the thermodynamic stability of a charged arginine side chain in a transmembrane helix , 2007, Proceedings of the National Academy of Sciences.

[15]  G. von Heijne,et al.  Insertion of short transmembrane helices by the Sec61 translocon , 2009, Proceedings of the National Academy of Sciences.

[16]  Erik Lindahl,et al.  Position‐resolved free energy of solvation for amino acids in lipid membranes from molecular dynamics simulations , 2007, Proteins.

[17]  Jeremy C. Smith,et al.  Mechanism and kinetics of peptide partitioning into membranes from all-atom simulations of thermostable peptides. , 2010, Journal of the American Chemical Society.

[18]  Martin B Ulmschneider,et al.  Properties of integral membrane protein structures: Derivation of an implicit membrane potential , 2005, Proteins.

[19]  G. Heijne,et al.  Recognition of transmembrane helices by the endoplasmic reticulum translocon , 2005, Nature.

[20]  S. White,et al.  How hydrogen bonds shape membrane protein structure. , 2005, Advances in protein chemistry.

[21]  Justin L. MacCallum,et al.  Partitioning of Amino Acid Side Chains into Lipid Bilayers: Results from Computer Simulations and Comparison to Experiment , 2007, The Journal of general physiology.

[22]  K. Swartz,et al.  Sensing voltage across lipid membranes , 2008, Nature.

[23]  M. Ulmschneider,et al.  Membrane adsorption, folding, insertion and translocation of synthetic trans-membrane peptides , 2008, Molecular membrane biology.

[24]  S. White,et al.  Structure, location, and lipid perturbations of melittin at the membrane interface. , 2001, Biophysical journal.

[25]  Francisco Bezanilla,et al.  Voltage-Sensing Residues in the S2 and S4 Segments of the Shaker K+ Channel , 1996, Neuron.

[26]  Jeremy C. Smith,et al.  Peptide partitioning properties from direct insertion studies. , 2010, Biophysical journal.

[27]  Erik Lindahl,et al.  Protein contents in biological membranes can explain abnormal solvation of charged and polar residues , 2009, Proceedings of the National Academy of Sciences.

[28]  C. Brooks,et al.  Interfacial folding and membrane insertion of designed peptides studied by molecular dynamics simulations. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[29]  N. F. Hall,et al.  RELATIONS BETWEEN THE STRUCTURE AND STRENGTH OF CERTAIN ORGANIC BASES IN AQUEOUS SOLUTION , 1932 .

[30]  B Honig,et al.  Free-energy determinants of alpha-helix insertion into lipid bilayers. , 1996, Biophysical journal.

[31]  M. Ulmschneider,et al.  Folding Peptides into Lipid Bilayer Membranes. , 2008, Journal of chemical theory and computation.

[32]  S H White,et al.  The nature of the hydrophobic binding of small peptides at the bilayer interface: implications for the insertion of transbilayer helices. , 1989, Biochemistry.

[33]  I. Vorobyov,et al.  Electrostatics of deformable lipid membranes. , 2010, Biophysical journal.

[34]  Jakob P Ulmschneider,et al.  Sampling efficiency in explicit and implicit membrane environments studied by peptide folding simulations , 2009, Proteins.

[35]  Peter L. Freddolino,et al.  Ten-microsecond molecular dynamics simulation of a fast-folding WW domain. , 2008, Biophysical journal.

[36]  P. Booth,et al.  The activation energy for insertion of transmembrane alpha-helices is dependent on membrane composition. , 2002, Journal of molecular biology.

[37]  E. Lindahl,et al.  The role of lipid composition for insertion and stabilization of amino acids in membranes. , 2009, The Journal of chemical physics.

[38]  Stephen H. White,et al.  Membrane Protein Insertion: The Biology–Physics Nexus , 2007, The Journal of general physiology.

[39]  Mark S.P. Sansom,et al.  Molecular simulations and biomembranes : from biophysics to function , 2010 .

[40]  S H White,et al.  Folding of amphipathic alpha-helices on membranes: energetics of helix formation by melittin. , 1999, Journal of molecular biology.

[41]  T. Creamer,et al.  Solvation energies of amino acid side chains and backbone in a family of host-guest pentapeptides. , 1996, Biochemistry.

[42]  G. von Heijne,et al.  Interface connections of a transmembrane voltage sensor. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[43]  S. White,et al.  Membrane protein folding and stability: physical principles. , 1999, Annual review of biophysics and biomolecular structure.

[44]  T. Allen Modeling Charged Protein Side Chains in Lipid Membranes , 2007, The Journal of general physiology.

[45]  Stephen H. White,et al.  Experimentally determined hydrophobicity scale for proteins at membrane interfaces , 1996, Nature Structural Biology.

[46]  Gunnar von Heijne,et al.  Membrane Insertion of a Potassium-Channel Voltage Sensor , 2005, Science.

[47]  Jakob P Ulmschneider,et al.  Folding Simulations of the Transmembrane Helix of Virus Protein U in an Implicit Membrane Model. , 2007, Journal of chemical theory and computation.

[48]  Toby W Allen,et al.  Potential of mean force and pKa profile calculation for a lipid membrane-exposed arginine side chain. , 2008, The journal of physical chemistry. B.

[49]  A. Gorfe,et al.  Thermodynamics of Peptide Insertion and Aggregation in a Lipid Bilayer , 2008, The journal of physical chemistry. B.

[50]  J. Killian,et al.  Synthetic peptides as models for intrinsic membrane proteins , 2003, FEBS letters.

[51]  G. von Heijne,et al.  Prediction of membrane-protein topology from first principles , 2008, Proceedings of the National Academy of Sciences.

[52]  D. Engelman,et al.  Membrane protein folding and oligomerization: the two-stage model. , 1990, Biochemistry.

[53]  Jeremy C. Smith,et al.  Peptide Partitioning and Folding into Lipid Bilayers. , 2009, Journal of chemical theory and computation.

[54]  W. Warburton,et al.  549. The basic strengths of methylated guanidines , 1951 .

[55]  B. Honig,et al.  Stability of "salt bridges" in membrane proteins. , 1984, Proceedings of the National Academy of Sciences of the United States of America.

[56]  Stephen H. White,et al.  Designing Transmembrane α-Helices That Insert Spontaneously† , 2000 .

[57]  E. Lindahl,et al.  Membrane proteins: molecular dynamics simulations. , 2008, Current opinion in structural biology.

[58]  S. White,et al.  Interfacial folding and membrane insertion of a designed helical peptide. , 2004, Biochemistry.

[59]  Is arginine charged in a membrane? , 2008, Biophysical journal.

[60]  H. Nymeyer,et al.  Folding is not required for bilayer insertion: Replica exchange simulations of an α‐helical peptide with an explicit lipid bilayer , 2004, Proteins.

[61]  M. Ulmschneider,et al.  United Atom Lipid Parameters for Combination with the Optimized Potentials for Liquid Simulations All-Atom Force Field. , 2009, Journal of chemical theory and computation.