Your search keyword '"Valeriy V Bezrodnyi"' showing total 9 results

1. Application of High Performance Computing for Comparison of Two Highly Branched Lysine Molecules of Different Topology.

Author

Igor M. Neelov, Oleg V. Shavykin, Maxim Y. Ilyash, Valeriy V. Bezrodnyi, Sofia E. Mikhtaniuk, Anna A. Marchenko, Emil I. Fatullaev, Anatolii A. Darinskii, and Frans A. M. Leermakers

Published

2018

2. Size and Structure of Empty and Filled Nanocontainer Based on Peptide Dendrimer with Histidine Spacers at Different pH

Author

Valeriy V. Bezrodnyi, Sofia E. Mikhtaniuk, Oleg V. Shavykin, Igor M. Neelov, Nadezhda N. Sheveleva, and Denis A. Markelov

Subjects

peptide dendrimer, pH responsive spacers, molecular dynamics simulation, histidine–histidine pairing, nanocontainer capacity, Organic chemistry, QD241-441

Abstract

Novel peptide dendrimer with Lys-2His repeating units was recently synthesized, studied by NMR (Molecules, 2019, 24, 2481) and tested as a nanocontainer for siRNA delivery (Int. J. Mol. Sci., 2020, 21, 3138). Histidine amino acid residues were inserted in the spacers of this dendrimer. Increase of their charge with a pH decrease turns a surface-charged dendrimer into a volume-charged one and should change all properties. In this paper, the molecular dynamics simulation method was applied to compare the properties of the dendrimer in water with explicit counterions at two different pHs (at normal pH with neutral histidines and at low pH with fully protonated histidines) in a wide interval of temperatures. We obtained that the dendrimer at low pH has essentially larger size and size fluctuations. The electrostatic properties of the dendrimers are different but they are in good agreement with the theoretical soft sphere model and practically do not depend on temperature. We have shown that the effect of pairing of side imidazole groups is much stronger in the dendrimer with neutral histidines than in the dendrimer with protonated histidines. We also demonstrated that the capacity of a nanocontainer based on this dendrimer with protonated histidines is significantly larger than that of a nanocontainer with neutral histidines.

Published

2021

3. Local Orientational Mobility of Collapsed Dendrimers

Author

Anastasia V. Penkova, Denis A. Markelov, Sofia E Mikhtaniuk, Mikhail A. Vovk, Nadezhda N. Sheveleva, I. I. Tarasenko, Oleg V. Shavykin, Valeriy V Bezrodnyi, Igor M. Neelov, and M. E. Mikhailova

Subjects

Inorganic Chemistry, Materials science, Relaxation spectrum, Polymers and Plastics, Chemical physics, Dendrimer, Organic Chemistry, Materials Chemistry, Macromolecule

Abstract

Dendrimers are regular hyperbranched macromolecules. The complex structure of the relaxation spectrum is one of the many features of dendrimers that does not fit into the classical concepts of poly...

Published

2021

4. Size and Structure of Empty and Filled Nanocontainer Based on Peptide Dendrimer with Histidine Spacers at Different pH

Author

Sofia E Mikhtaniuk, Valeriy V Bezrodnyi, Oleg V. Shavykin, Denis A. Markelov, Nadezhda N. Sheveleva, and Igor M. Neelov

Subjects

Dendrimers, Surface Properties, peptide dendrimer, Pharmaceutical Science, Organic chemistry, Protonation, Article, Analytical Chemistry, chemistry.chemical_compound, Molecular dynamics, QD241-441, nanocontainer capacity, Dendrimer, Drug Discovery, Imidazole, Molecule, Histidine, Physical and Theoretical Chemistry, Particle Size, histidine–histidine pairing, chemistry.chemical_classification, Molecular Structure, Nanocontainer, Hydrogen-Ion Concentration, Crystallography, molecular dynamics simulation, chemistry, Chemistry (miscellaneous), Molecular Medicine, Nanoparticles, Counterion, Peptides, pH responsive spacers

Abstract

Novel peptide dendrimer with Lys-2His repeating units was recently synthesized, studied by NMR (Molecules, 2019, 24, 2481) and tested as a nanocontainer for siRNA delivery (Int. J. Mol. Sci., 2020, 21, 3138). Histidine amino acid residues were inserted in the spacers of this dendrimer. Increase of their charge with a pH decrease turns a surface-charged dendrimer into a volume-charged one and should change all properties. In this paper, the molecular dynamics simulation method was applied to compare the properties of the dendrimer in water with explicit counterions at two different pHs (at normal pH with neutral histidines and at low pH with fully protonated histidines) in a wide interval of temperatures. We obtained that the dendrimer at low pH has essentially larger size and size fluctuations. The electrostatic properties of the dendrimers are different but they are in good agreement with the theoretical soft sphere model and practically do not depend on temperature. We have shown that the effect of pairing of side imidazole groups is much stronger in the dendrimer with neutral histidines than in the dendrimer with protonated histidines. We also demonstrated that the capacity of a nanocontainer based on this dendrimer with protonated histidines is significantly larger than that of a nanocontainer with neutral histidines.

Published

2021

5. Why the Orientational Mobility in Arginine and Lysine Spacers of Peptide Dendrimers Designed for Gene Delivery Is Different?

Author

Denis A. Markelov, Nadezhda N. Sheveleva, Oleg V. Shavykin, Sofia E Mikhtaniuk, Igor M. Neelov, and Valeriy V Bezrodnyi

Subjects

Dendrimers, Polymers, peptide dendrimer, Lysine, Peptide, 02 engineering and technology, Molecular Dynamics Simulation, Arginine, 010402 general chemistry, 01 natural sciences, Article, Catalysis, spin-lattice relaxation time, Inorganic Chemistry, lcsh:Chemistry, Molecular dynamics, zeta potential, Dendrimer, Zeta potential, computer simulation, Humans, Physical and Theoretical Chemistry, Molecular Biology, lcsh:QH301-705.5, Spectroscopy, chemistry.chemical_classification, Organic Chemistry, Gene Transfer Techniques, Spin–lattice relaxation, Genetic Therapy, General Medicine, Polymer, 021001 nanoscience & nanotechnology, Peptide Fragments, molecular dynamics, NMR, 0104 chemical sciences, Computer Science Applications, Crystallography, chemistry, lcsh:Biology (General), lcsh:QD1-999, Pairing, 0210 nano-technology

Abstract

New peptide dendrimer with Lys-2Arg repeating units was recently studied experimentally by NMR (RSC Advances, 2019, 9, 18018) and tested as gene carrier successfully (Int. J. Mol. Sci., 2020, 21, 3138). The unusual slowing down of the orientational mobility of 2Arg spacers in this dendrimer was revealed. It has been suggested that this unexpected behavior is caused by the Arg-Arg pairing effect in water, which leads to entanglements between dendrimer branches. In this paper, we determine the reason for this slowing down using atomistic molecular dynamics simulation of this dendrimer. We present that the structural properties of Lys-2Arg dendrimer are close to those of the Lys-2Lys dendrimer at all temperatures (Polymers, 2020, 12, 1657). However, the orientational mobility of the H-H vector in CH2-N groups of 2Arg spacers in Lys-2Arg dendrimer is significantly slower than the mobility of the same vector in the Lys-2Lys dendrimer. This result is in agreement with the recent NMR experiments for the same systems. We revealed that this difference is not due to the arginine-arginine pairing, but is due to the semiflexibility effect associated with the different contour length from CH2-N group to the end of the side arginine or lysine segment in spacers.

Published

2020

6. Poly(lysine) Dendrimers Form Complexes with siRNA and Provide Its Efficient Uptake by Myeloid Cells: Model Studies for Therapeutic Nucleic Acid Delivery

Author

Olga Kopeć, Barbara Klajnert-Maculewicz, Valeriy V Bezrodnyi, Igor M. Neelov, I. I. Tarasenko, Michał Gorzkiewicz, Malgorzata Konopka, Elzbieta Pedziwiatr-Werbicka, and Anna Janaszewska

Subjects

Dendrimers, THP-1 Cells, Lysine, 02 engineering and technology, Gene delivery, 010402 general chemistry, 01 natural sciences, Catalysis, Article, Inorganic Chemistry, lcsh:Chemistry, poly(lysine) dendrimers, Dendrimer, Humans, Myeloid Cells, Polylysine, Physical and Theoretical Chemistry, RNA, Small Interfering, gene delivery, Cytotoxicity, Molecular Biology, lcsh:QH301-705.5, Spectroscopy, Molecular Structure, Chemistry, Organic Chemistry, Gene Transfer Techniques, General Medicine, Transfection, 021001 nanoscience & nanotechnology, gene therapy, 0104 chemical sciences, Computer Science Applications, transfection, lcsh:Biology (General), lcsh:QD1-999, Lipofectamine, siRNA, Nucleic acid, Biophysics, 0210 nano-technology, Fluorescence anisotropy

Abstract

The disruption of the cellular pathways of protein biosynthesis through the mechanism of RNA interference has been recognized as a tool of great diagnostic and therapeutic significance. However, in order to fully exploit the potential of this phenomenon, efficient and safe carriers capable of overcoming extra-and intracellular barriers and delivering siRNA to the target cells are needed. Recently, attention has focused on the possibility of the application of multifunctional nanoparticles, dendrimers, as potential delivery devices for siRNA. The aim of the present work was to evaluate the formation of dendriplexes using novel poly(lysine) dendrimers (containing lysine and arginine or histidine residues in their structure), and to verify the hypothesis that the use of these polymers may allow an efficient method of siRNA transfer into the cells in vitro to be obtained. The fluorescence polarization studies, as well as zeta potential and hydrodynamic diameter measurements were used to characterize the dendrimer:siRNA complexes. The cytotoxicity of dendrimers and dendriplexes was evaluated with the resazurin-based assay. Using the flow cytometry technique, the efficiency of siRNA transport to the myeloid cells was determined. This approach allowed us to determine the properties and optimal molar ratios of dendrimer:siRNA complexes, as well as to demonstrate that poly(lysine) dendrimers may serve as efficient carriers of genetic material, being much more effective than the commercially available transfection agent Lipofectamine 2000. This outcome provides the basis for further research on the application of poly(lysine) dendrimers as carriers for nucleic acids in the field of gene therapy. �� 2020 by the authors.

Published

2020

7. Application of high performance computing for comparison of two highly branched lysine molecules of different topology

Author

Emil Fatullaev, Maxim Yu. Ilyash, Anatolii A. Darinskii, Sofia E Mikhtaniuk, Oleg V. Shavykin, Igor M. Neelov, Anna A. Marchenko, Frans A. M. Leermakers, and Valeriy V Bezrodnyi

Subjects

Materials science, Dendrimer, Computer Networks and Communications, Lysine, Brush, Topology, Supercomputer, Biocompatible material, Dendritic brush, Computer Science Applications, law.invention, Molecular dynamics, Computational Theory and Mathematics, Hardware and Architecture, law, Molecule, High performance computing, Physical Chemistry and Soft Matter, Software, Topology (chemistry), Information Systems, Poly-L-lysine

Abstract

High performance computations were performed for comparison of size and other properties of big heavily charged biocompatible molecules of complex topology in water. Lysine dendrimer and short dendritic brush of the same molecular weight were studied by molecular dynamics simulation method and GROMACS software package. The size and structural properties of these two systems were compared. It was shown that dendritic brush has smaller size and more dense core than the dendrimer. Radial density profile for both molecules is not monotonous and has minimum near core of molecules. This minimum is wider and deeper for dendrimer than for dendritic brush. Thus dendrimer has larger region of low density than dendritic brush and is more suitable for use for encapsulation and delivery of hydrophobic drugs.

Published

2018

8. Comparison of Structure and Local Dynamics of Two Peptide Dendrimers with the Same Backbone but with Different Side Groups in Their Spacers

Author

Valeriy V Bezrodnyi, Nadezhda N. Sheveleva, Igor M. Neelov, Denis A. Markelov, Anastasia V. Penkova, Oleg V. Shavykin, and Sofia E Mikhtaniuk

Subjects

chemistry.chemical_classification, Range (particle radiation), Polymers and Plastics, peptide dendrimer, Relaxation (NMR), Spin–lattice relaxation, charged macroion, Charge (physics), General Chemistry, Article, molecular dynamics, NMR, spin-lattice relaxation time, lcsh:QD241-441, zeta potential, Molecular dynamics, Crystallography, lcsh:Organic chemistry, chemistry, Dendrimer, computer simulation, Zeta potential, Counterion

Abstract

In this paper, we perform computer simulation of two lysine-based dendrimers with Lys-2Lys and Lys-2Gly repeating units. These dendrimers were recently studied experimentally by NMR (Sci. Reports, 2018, 8, 8916) and tested as carriers for gene delivery (Bioorg. Chem., 2020, 95, 103504). Simulation was performed by molecular dynamics method in a wide range of temperatures. We have shown that the Lys-2Lys dendrimer has a larger size but smaller fluctuations as well as lower internal density in comparison with the Lys-2Gly dendrimer. The Lys-2Lys dendrimer has larger charge but counterions form more ion pairs with its NH 3 + groups and reduce the bare charge and zeta potential of the first dendrimer more strongly. It was demonstrated that these differences between dendrimers are due to the lower flexibility and the larger charge (+2) of each 2Lys spacers in comparison with 2Gly ones. The terminal CH 2 groups in both dendrimers move faster than the inner CH 2 groups. The calculated temperature dependencies of the spin-lattice relaxation times of these groups for both dendrimers are in a good agreement with the experimental results obtained by NMR.

Published

2020

9. Investigation of complex of lysine dendrimer of 2nd generation with molecules of therapeutic KED peptide by computer simulation

Author

M. J. Ilyash, Anna A. Marchenko, S. E. Miktaniuk, Valeriy V Bezrodnyi, Igor M. Neelov, E. I. Bychkova, and Emil Fatullaev

Subjects

chemistry.chemical_classification, History, Materials science, chemistry, Dendrimer, Lysine, Molecule, Peptide, Combinatorial chemistry, Computer Science Applications, Education

Abstract

Lysine dendrimers could be used in many biomedical applications. For example these dendrimers could be used for delivery of short regulatory peptides consisting of several aminoacid residues. We investigated earlier interactions between lysine dendrigraft of 2nd generation and molecules of KED peptide. In present paper we study interaction of lysine dendrimer and molecules of KED peptide. The system containing one dendrimer of 2nd generation and 8 molecules of KED in water with explicit account of counterions was studied by computer simulation. The method of molecular dynamics was used for this goal. We obtained that formation of complex consisting of the dendrimer and all peptide molecules occurs during initial time (t < 40 ns) of simulation. The size, anisotropy of shape and radial density profile of stable complex (after t > 40ns) were studied also. We have shown that formation of complex occurs due to electrostatic interaction between oppositely charged dendrimer. At the same time other interactions, for example hydrogen bonds, also give their contribution to this process. Stable dendrimer-peptide complex has size close to 1,5nm and small shape anisotropy. Density of dendrimer atoms is highest in the centre of complex while density of peptides atoms has maximum at radial distance r=1nm. It total we have shown that lysine dendrimers is suitable carrier for molecules of KED peptide.

Published

2019