Olga V. Levtsova

A molecular dynamics study of the interaction between domain I-BAR of the IRSp53 protein and negatively charged membranes

The methods of computer simulation in all-atom and coarse-grained approximations have been used to study specific interactions of the isolated domain I-BAR of the actin-binding protein IRSp53 with model membranes containing neutral phospholipids and those including negatively charged PI(4,5)P2 phospholipids. It has been shown that the I-BAR domain does not interact with neutral lipids but induces bending of the synthetic membrane rich in negatively charged phospholipids. Clustering of charged lipids on the surface of the membrane at the sites of its interaction with the protein has been observed. This indicates that the interaction of I-BAR with negatively charged lipids is of electrostatic and hydrophobic nature.

The structural and dynamic model of the serotonin 5-HT3 receptor. Comparative analysis of the structure of the channel domain of pentameric ligand-gated ion channels

The three-dimensional structure of the 5-HT3 receptor is currently unknown. An available structure of the nicotinic acetylcholine receptor closely related by homology to the 5-HT3 receptor was used as a template for the computer-based homology modeling of the 5-HT3 receptor. The study of the ion migration through the channel by the steered molecular dynamics method has shown that the steric factor in the region of residue Thr279 and the region of Glu272, Asp293 influences the ion transmission. The characteristic of the close interaction between the ion and the amino acid substitutions of the 5-HT3 channel was studied by computing the energy profile using constraint force molecular dynamic simulations. The amino acid sequence responsible for selective ion transmission has been investigated. The structure of the channel domain of the serotonin 5-HT3 receptor as a universal functional unit of the ligand-gated ion channels was discussed.

Research Article: Interaction of zervamicin IIB with lipid bilayers. Molecular dynamics study

In this work we have studied the interaction of zervamicin IIB (ZrvIIB) with the model membranes of eukaryotes and prokaryotes using all-atom molecular dynamics. In all our simulations zervamicin molecule interacted only with lipid headgroups but did not penetrate the hydrophobic core of the bilayers. During the interaction with the prokaryotic membrane zervamicin placed by its N-termini towards the lipids and rotated at an angle of 40° relatively to the bilayer surface. In the case of eukaryotic membrane zervamicin stayed in the water and located parallel to the membrane surface. We compared hydrogen bonds between peptide and lipids and concluded that interactions of ZrvIIB with prokaryotic membrane are stronger than those with eukaryotic one. Also it was shown that two zervamicin molecules formed dimer and penetrated deeper in the area of lipid headgroups.

Comparative molecular dynamics study of the structural properties of melittin in water and trifluoroethanol/water

The structural properties and dynamic behavior of the antimicrobial peptide melittin in hydrophobic and polar environments have been investigated. The main characteristics of the secondary structure of melittin in different media have been analyzed and compared with the data on an ideal α-helix. It has been shown that melittin is an α-helix bent in the region of Pro14; the N-terminus of the peptide tends to unfold, while the C-terminal segment (residues 14–23) retains a helical structure for 20 ns of the simulation. 2,2,2-Trifluoroethanol molecules stabilize the helical structure of the peptide by lowering the dielectric constant of the environment and preferentially accumulating near particular sites of the polypeptide chain.

Human EGF-derived direct and reverse short linear motifs: conformational dynamics insight into the receptor-binding residues

Short linear motifs (SLiMs) have been recognized to perform diverse functions in a variety of regulatory proteins through the involvement in protein–protein interactions, signal transduction, cell cycle regulation, protein secretion, etc. However, detailed molecular mechanisms underlying their functions including roles of definite amino acid residues remain obscure. In our previous studies, we demonstrated that conformational dynamics of amino acid residues in oligopeptides derived from regulatory proteins such as alpha-fetoprotein (AFP), carcino-embryonic antigen (CEA), and pregnancy specific β1-glycoproteins (PSGs) contributes greatly to their biological activities. In the present work, we revealed the 22-member linear modules composed of direct and reverse AFP14–20-like heptapeptide motifs linked by CxxGY/FxGx consensus motif within epidermal growth factor (EGF), growth factors of EGF family and numerous regulatory proteins containing EGF-like modules. We showed, first, the existence of similarity in amino acid signatures of both direct and reverse motifs in terms of their physicochemical properties. Second, molecular dynamics (MD) simulation study demonstrated that key receptor-binding residues in human EGF in the aligned positions of the direct and reverse motifs may have similar distribution of conformational probability densities and dynamic behavior despite their distinct physicochemical properties. Third, we found that the length of a polypeptide chain (from 7 to 53 residues) has no effect, while disulfide bridging and backbone direction significantly influence the conformational distribution and dynamics of the residues. Our data may contribute to the atomic level structure–function analysis and protein structure decoding; additionally, they may provide a basis for novel protein/peptide engineering and peptide-mimetic drug design.

Molecular dynamics of zervamicin II and its analogs in water and methanol

A comparative study has been made of the molecular dynamics of zervamicin II (an antimicrobial peptide of the peptaibol group, which has channel-forming activity) in water and methanol. The influence of amino acid substitutions on the dynamics and stability of the peptide structure has been investigated. The amino acid sequence responsible for the absence of swivel motions in short peptaibols has been determined.

Conformational transitions in the nootropic peptide semax (MEHFPGP) and its N-terminal modifications

We use molecular dynamics simulation to examine the conformational possibilities in solution for the peptide MEHFPGP (Semax) representing the minimal nootropic fragment of MSH, and its versions with N-terminal substitutions of K, G, or R for M. We discuss the possible relationship between molecule structure and physiological activity, considering the influence of Coulomb interactions on the dynamics and the putative stabilization of a certain peptide conformation at pH < 6.

Molecular dynamics of oligopeptides. A comparative study of residue interactions in dipeptides

The molecular dynamics of dipeptides of natural amino acids were examined using protocols that do not violate the principle of equal distribution of energy over the degrees of freedom. Comparative analysis involved autocorrelation functions of complex exponentials from dihedrals. The mutual influence of residues was classified by the effects on the dynamic properties of the neighbors.

Comparative Study of Molecular Dynamics, Diffusion, and Permeability for Ligands in Biomembranes of Different Lipid Composition

A comparative study of several model lipid bilayers of different composition, which included analysis of kinetic parameters of model lipid bilayers and permeability of bilayer membranes for small molecules, has been carried out. The conformity of results of numeric experiments to experimental data (structure of membrane lipid bilayers, lateral diffusion coefficients, and relative permeability of biomembranes for ligands) is discussed in the framework of a standard molecular dynamics protocol.