Your search keyword '"E. Deniz Tekin"' showing total 14 results

1. Investigation of human β-defensins 1, 2 and 3 in human saliva by molecular dynamics

Author

E. Deniz Tekin and Metin Calisir

Subjects

Biophysics, General Materials Science, Surfaces and Interfaces, General Chemistry, Biotechnology

Published

2022

2. Investigation of the effects of N-Acetylglucosamine on the stability of the spike protein in SARS-CoV-2 by molecular dynamics simulations

Author

E. Deniz Tekin

Subjects

Physical and Theoretical Chemistry, Condensed Matter Physics, Biochemistry

Published

2023

3. A comparison of peptide amphiphile nanofiber macromolecular assembly strategies

Author

Aykutlu Dana, E. Deniz Tekin, and Ayse B. Tekinay

Subjects

chemistry.chemical_classification, Quantitative Biology::Biomolecules, Materials science, Biophysics, Theoretical models, Supramolecular chemistry, Peptide, Nanotechnology, 02 engineering and technology, Surfaces and Interfaces, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Quantitative Biology::Subcellular Processes, Macromolecular assembly, Molecular dynamics, chemistry, Nanofiber, Peptide amphiphile, Molecule, General Materials Science, 0210 nano-technology, Biotechnology

Abstract

Supramolecular peptide nanofibers that are composed of peptide amphiphile molecules have been widely used for many purposes from biomedical applications to energy conversion. The self-assembly mechanisms of these peptide nanofibers also provide convenient models for understanding the self-assembly mechanisms of various biological supramolecular systems; however, the current theoretical models that explain these mechanisms do not sufficiently explain the experimental results. In this study, we present a new way of modeling these nanofibers that better fits with the experimental data. Molecular dynamics simulations were applied to create model fibers using two different layer models and two different tilt angles. Strikingly, the fibers which were modeled to be tilting the peptide amphiphile molecules and/or tilting the plane were found to be more stable and consistent with the experiments.

Published

2019

4. Force and time-dependent self-assembly, disruption and recovery of supramolecular peptide amphiphile nanofibers

Author

Alper D. Ozkan, Ayse B. Tekinay, F. Begum Dikecoglu, Ahmet Topal, Aykutlu Dana, E. Deniz Tekin, Mustafa O. Guler, and Güler, Mustafa O.

Subjects

Materials science, Nanostructure, Nanofibers, Supramolecular chemistry, Bioengineering, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Biomaterials, Atomic force microscopy, Recovery, Peptide amphiphile, Molecule, General Materials Science, Fiber, Electrical and Electronic Engineering, Aqueous solution, Mechanical Engineering, Self-assembly, General Chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Mechanics of Materials, Nanofiber, Biophysics, 0210 nano-technology

Abstract

Biological feedback mechanisms exert precise control over the initiation and termination of molecular self-assembly in response to environmental stimuli, while minimizing the formation and propagation of defects through self-repair processes. Peptide amphiphile (PA) molecules can self-assemble at physiological conditions to form supramolecular nanostructures that structurally and functionally resemble the nanofibrous proteins of the extracellular matrix, and their ability to reconfigure themselves in response to external stimuli is crucial for the design of intelligent biomaterials systems. Here, we investigated real-time self-assembly, deformation, and recovery of PA nanofibers in aqueous solution by using a force-stabilizing double-pass scanning atomic force microscopy imaging method to disrupt the self-assembled peptide nanofibers in a force-dependent manner. We demonstrate that nanofiber damage occurs at tip-sample interaction forces exceeding 1 nN, and the damaged fibers subsequently recover when the tip pressure is reduced. Nanofiber ends occasionally fail to reconnect following breakage and continue to grow as two individual nanofibers. Energy minimization calculations of nanofibers with increasing cross-sectional ellipticity (corresponding to varying levels of tip-induced fiber deformation) support our observations, with high-ellipticity nanofibers exhibiting lower stability compared to their non-deformed counterparts. Consequently, tip-mediated mechanical forces can provide an effective means of altering nanofiber integrity and visualizing the self-recovery of PA assemblies. We thank Z Erdogan for her assistance in LC-MS, and S Hamsici for the fluorescence spectroscopy measurements of peptide nanostructures. ABT acknowledges the Science Academy Distinguished Young Scientist Award Program (BAGEP) support. The numerical calculations reported in this paper were fully/partially performed at TUBITAK ULAK-BIM, High Performance and Grid Computing Center (TRUBA resources).

Published

2018

5. Molecular dynamics simulations of self-assembled peptide amphiphile based cylindrical nanofibers

Author

E. Deniz Tekin

Subjects

chemistry.chemical_classification, Materials science, General Chemical Engineering, Nanotechnology, General Chemistry, Electrostatics, Hydrophobic effect, Molecular dynamics, chemistry, Chemical physics, Nanofiber, Peptide amphiphile, Molecule, Fiber, Alkyl

Abstract

We carried out united-atom molecular dynamics simulations to understand the structural properties of peptide amphiphile (PA)-based cylindrical nanofibers and the factors that play a role in the “Self-Assembly” process on some specific nanofibers. In our simulations, we start from various cylindrical nanofiber structures with a different number of layers and a different number of PAs in each layer, based on previous experimental and theoretical results. We find that the 19-layered nanofiber, with 12 PAs at each layer, distributed radially and uniformly with alkyl chains in the center, is the most stable configuration with a diameter of 8.4 nm which is consistent with experimental results. The most dominant secondary structures formed in the fibers are random coils and β-sheets, respectively. We also find that hydrophobic interactions between the VVAG–VVAG moiety of the PA molecules and electrostatic interactions between D–Na+ and between E–R are responsible for the fiber's self-assembly properties. During the aggregation process, first dimers, then trimers are formed.

Published

2015

6. Effects Of Temperature, Ph And Counterions On The Stability Of Peptide Amphiphile Nanofiber Structures

Author

Ayse B. Tekinay, Alper D. Ozkan, E. Deniz Tekin, Mustafa O. Guler, and Güler, Mustafa O.

Subjects

General Chemical Engineering, Nanofibers, Peptide, 02 engineering and technology, Root mean square deviations, Molecular dynamics, 010402 general chemistry, 01 natural sciences, Thermodynamic stability, United atom molecular dynamics simulations, Hydrogen bonds, Amphiphile, Polymer chemistry, Peptide amphiphile, Molecule, Thermal stability, Increasing temperatures, chemistry.chemical_classification, Ions, Thermodynamically stable, Temperature, Polypeptides, General Chemistry, Amphiphiles, Molecules, Self assembly, 021001 nanoscience & nanotechnology, Effects of temperature, Environmental variables, 0104 chemical sciences, Nanostructures, pH effects, Chemical engineering, chemistry, Self assembly process, Nanofiber, Self assembling molecules, Counterion, Phase equilibria, 0210 nano-technology, Peptides, Stability

Abstract

Peptide amphiphiles are a class of self-assembling molecules that are widely used to form bioactive nanostructures for various applications in bionanomedicine. However, peptide molecules can exhibit distinct behaviors under different conditions, suggesting that environmental variables such as temperature, pH, electrolytes and the presence of biological factors may greatly affect the self-assembly process. In this work, we used united-atom molecular dynamics simulations to understand the effects of three counterions (Na+, Ca2+ at pH 7 and Cl− at pH 2) and temperature change on the stability of the lauryl-VVAGERGD peptide amphiphile self-assembly. This molecule contains a bioactive RGD peptide sequence and has been shown to support cellular adhesion and proliferation in vitro. A 19-layered peptide nanostructure, containing 12 peptide amphiphile molecules per layer, was previously shown to exhibit optimal stability and it was used as the model nanofiber system. Peptide backbone stability was studied under increasing temperatures (300–358 K) using the number of hydrogen bonds and root-mean-square deviations of nanofiber size. At higher temperatures, fiber disintegration was observed to be dependent on the type of counter-ion used for nanofiber formation. Interestingly, rapid heating to higher temperatures could sometimes reestablish the integrity of the nanofiber backbone, possibly by allowing the system to bypass an energy barrier and assuming a more thermodynamically stable configuration. As counterion identity was observed to exhibit remarkable effects on the thermal stability of peptide nanofibers, we suggest that these behaviors should be considered while developing new materials for potential applications.

Published

2016

7. Odd–even effect in the potential energy of the self-assembled peptide amphiphiles

Author

E. Deniz Tekin

Subjects

chemistry.chemical_classification, Materials science, education, General Physics and Astronomy, Peptide, Nanotechnology, Molecular physics, Potential energy, chemistry, Nanofiber, mental disorders, Amphiphile, Physical and Theoretical Chemistry, Layer (electronics), Alkyl

Abstract

We report on an example of odd–even effect in self-assembled peptide amphiphiles (PAs) forming a cylindrical nanofiber. Minimum energy of the nanofiber depends on whether there are odd or even number of layers and whether each layer has odd or even number of PAs. More specifically, minimum energy for a nanofiber built of odd number of layers is achieved if each layer has even number of PAs uniformly, and radially aligned with alkyl chains in the center. On the other hand if the number of layers is even, energy is minimized if each layer has an odd number of PAs.

Published

2014

8. Alkaline Phosphatase-Mimicking Peptide Nanofibers For Osteogenic Differentiation

Author

Ayse B. Tekinay, Mustafa O. Guler, Gulcihan Gulseren, Oya Ustahüseyin, I. Ceren Yasa, E. Deniz Tekin, Gülseren, Gülcihan, Yasa, I. Ceren, Ustahuseyin, Oya, Tekin, E. Deniz, Tekinay, Ayse B., and Güler, Mustafa O.

Subjects

Bone Regeneration, Polymers and Plastics, Cell Survival, Chemical structure, Nanofibers, Bioengineering, Peptide, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Catalysis, Biomaterials, Extracellular matrix, Biomimetic Materials, Osteogenesis, Materials Chemistry, Animals, Humans, Bone regeneration, Histidine, Cells, Cultured, chemistry.chemical_classification, Osteoblasts, Molecular Structure, Cell Differentiation, Mesenchymal Stem Cells, 021001 nanoscience & nanotechnology, Alkaline Phosphatase, 0104 chemical sciences, Rats, Enzyme, chemistry, Biochemistry, Nanofiber, Alkaline phosphatase, 0210 nano-technology, Peptides

Abstract

Recognition of molecules and regulation of extracellular matrix synthesis are some of the functions of enzymes in addition to their catalytic activity. While a diverse array of enzyme-like materials have been developed, these efforts have largely been confined to the imitation of the chemical structure and catalytic activity of the enzymes, and it is unclear whether enzyme-mimetic molecules can also be used to replicate the matrix-regulatory roles ordinarily performed by natural enzymes. Self-assembled peptide nanofibers can provide multifunctional enzyme-mimetic properties, as the active sequences of the target enzymes can be directly incorporated into the peptides. Here, we report enhanced bone regeneration efficiency through peptide nanofibers carrying both catalytic and matrix-regulatory functions of alkaline phosphatase, a versatile enzyme that plays a critical role in bone formation by regulating phosphate homeostasis and calcifiable bone matrix formation. Histidine presenting peptide nanostructures were developed to function as phosphatases. These molecules are able to catalyze phosphate hydrolysis and serve as bone-like nodule inducing scaffolds. Alkaline phosphatase-like peptide nanofibers enabled osteogenesis for both osteoblast-like and mesenchymal cell lines.

Published

2015

9. Amyloid inspired self-assembled peptide nanofibers

Author

Mustafa O. Guler, Goksu Cinar, Aykutlu Dâna, Turan S. Erkal, Ayse B. Tekinay, E. Deniz Tekin, Hakan Ceylan, Mustafa Urel, Çınar, Göksu, Ceylan, Hakan, Urel, Mustafa, Erkal, Turan S., Tekin, E. Deniz, Tekinay, Ayse B., Dâna, Aykutlu, and Güler, Mustafa O.

Subjects

Models, Molecular, Amyloid, Polymers and Plastics, Cell Survival, Nanofibers, Bioengineering, Peptide, 02 engineering and technology, Molecular Dynamics Simulation, 010402 general chemistry, 01 natural sciences, Biomaterials, chemistry.chemical_compound, Molecular dynamics, Rheology, Nano, Polymer chemistry, Materials Chemistry, Rhodamine B, Cell Adhesion, Non-covalent interactions, Molecule, Humans, Particle Size, Cells, Cultured, Cell Proliferation, chemistry.chemical_classification, Molecular Structure, Amyloid peptides, amyloid inspired peptides, assembled, self-assemble, 021001 nanoscience & nanotechnology, 0104 chemical sciences, chemistry, Chemical engineering, Nanofiber, 0210 nano-technology, Oligopeptides

Abstract

Cataloged from PDF version of article. Amyloid peptides are important components in many degenerative diseases as well as in maintaining cellular metabolism. Their unique stable structure provides new insights in developing new materials. Designing bioinspired selfassembling peptides is essential to generate new forms of hierarchical nanostructures. Here we present oppositely charged amyloid inspired peptides (AIPs), which rapidly self-assemble into nanofibers at pH 7 upon mixing in water caused by noncovalent interactions. Mechanical properties of the gels formed by selfassembled AIP nanofibers were analyzed with oscillatory rheology. AIP gels exhibited strong mechanical characteristics superior to gels formed by self-assembly of previously reported synthetic short peptides. Rheological studies of gels composed of oppositely charged mixed AIP molecules (AIP-1 + 2) revealed superior mechanical stability compared to individual peptide networks (AIP-1 and AIP-2) formed by neutralization of net charges through pH change. Adhesion and elasticity properties of AIP mixed nanofibers and charge neutralized AIP-1, AIP-2 nanofibers were analyzed by high resolution force− distance mapping using atomic force microscopy (AFM). Nanomechanical characterization of self-assembled AIP-1 + 2, AIP-1, and AIP-2 nanofibers also confirmed macroscopic rheology results, and mechanical stability of AIP mixed nanofibers was higher compared to individual AIP-1 and AIP-2 nanofibers self-assembled at acidic and basic pH, respectively. Experimental results were supported with molecular dynamics simulations by considering potential noncovalent interactions between the amino acid residues and possible aggregate forms. In addition, HUVEC cells were cultured on AIP mixed nanofibers at pH 7 and biocompatibility and collagen mimetic scaffold properties of the nanofibrous system were observed. Encapsulation of a zwitterionic dye (rhodamine B) within AIP nanofiber network was accomplished at physiological conditions to demonstrate that this network can be utilized for inclusion of soluble factors as a scaffold for cell culture studies. Copyright © 2012 American Chemical Society

Published

2012

10. Alkaline Phosphatase-Mimicking Peptide Nanofibersfor Osteogenic Differentiation.

Author

Gulcihan Gulseren, I. Ceren Yasa, Oya Ustahuseyin, E. Deniz Tekin, Ayse B. Tekinay, and Mustafa O. Guler

Published

2015

11. Force and time-dependent self-assembly, disruption and recovery of supramolecular peptide amphiphile nanofibers.

Author

F Begum Dikecoglu, Ahmet E Topal, Alper D Ozkan, E Deniz Tekin, Ayse B Tekinay, Mustafa O Guler, and Aykutlu Dana

Subjects

PEPTIDE amphiphiles, NANOSTRUCTURED materials, SUPRAMOLECULES

Abstract

Biological feedback mechanisms exert precise control over the initiation and termination of molecular self-assembly in response to environmental stimuli, while minimizing the formation and propagation of defects through self-repair processes. Peptide amphiphile (PA) molecules can self-assemble at physiological conditions to form supramolecular nanostructures that structurally and functionally resemble the nanofibrous proteins of the extracellular matrix, and their ability to reconfigure themselves in response to external stimuli is crucial for the design of intelligent biomaterials systems. Here, we investigated real-time self-assembly, deformation, and recovery of PA nanofibers in aqueous solution by using a force-stabilizing double-pass scanning atomic force microscopy imaging method to disrupt the self-assembled peptide nanofibers in a force-dependent manner. We demonstrate that nanofiber damage occurs at tip-sample interaction forces exceeding 1 nN, and the damaged fibers subsequently recover when the tip pressure is reduced. Nanofiber ends occasionally fail to reconnect following breakage and continue to grow as two individual nanofibers. Energy minimization calculations of nanofibers with increasing cross-sectional ellipticity (corresponding to varying levels of tip-induced fiber deformation) support our observations, with high-ellipticity nanofibers exhibiting lower stability compared to their non-deformed counterparts. Consequently, tip-mediated mechanical forces can provide an effective means of altering nanofiber integrity and visualizing the self-recovery of PA assemblies. [ABSTRACT FROM AUTHOR]

Published

2018

12. Investigation of the effects of N -Acetylglucosamine on the stability of the spike protein in SARS-CoV-2 by molecular dynamics simulations.

Author

Deniz Tekin E

Abstract

A lot of effort has been made in developing vaccine and therapeutic agents against the SARS-CoV-2, concentrating on the Spike protein that binds angiotensin-converting enzyme 2 on human cells. Nowadays, some researches study the role of the N -linked glycans as potential targets for vaccines and new agents. Due to the flexibility and diversity of the N -linked glycans, in this work, we focus on the N -Acetylglucosamine moiety, which is the precursor of nearly all eukaryotic glycans. We performed molecular dynamics simulations to study the effects of the N -Acetylglucosamine on the stability of the spike glycoprotein in SARS-CoV-2. After a 100 ns of simulation on the spike proteins without and with the N -Acetylglucosamine molecules, we found that the presence of N -Acetylglucosamine increases the local stability in their vicinity; even though their effect on the full structure is negligible. Thus; it can be inferred that the N -Acetylglucosamine moieties can potentially affect the interaction of the S protein with the ACE2 receptor. We also found that the S1 domain is more flexible than the S2 domain. We propose which of the experimentally observed glycans found on the spike may be more functional than the others. Detailed understanding of glycans is key for the development of new therapeutic strategies., Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2023 Elsevier B.V. All rights reserved.)

Published

2023

13. Investigation of human β-defensins 1, 2 and 3 in human saliva by molecular dynamics.

Author

Deniz Tekin E and Calisir M

Subjects

Humans, Molecular Dynamics Simulation, Defensins, Saliva, Water, beta-Defensins chemistry

Abstract

Human β-defensins present in saliva have a broad spectrum of antimicrobial activities that work against infections in oral cavity. To provide a better understanding of these molecules' properties and functions at the molecular level, we have investigated and compared the important structural properties of human β-defensin-1, -2 and -3 using molecular dynamics simulations. Our results have shown that human β-defensin-3 has a more flexible structure in water than the other two because of its high hydrophilicity, low β-sheet content and high repulsive forces between its charged residues. Moreover, we found that the location of the salt bridges is important in protein's stability in water. Molecular dynamics simulations of human β-defensins 1, 2 and 3 revealed that the hbd-3 is more flexible in water than hbd-1 and hbd-2., (© 2022. The Author(s), under exclusive licence to EDP Sciences, SIF and Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2022

14. Amyloid inspired self-assembled peptide nanofibers.

Author

Cinar G, Ceylan H, Urel M, Erkal TS, Deniz Tekin E, Tekinay AB, Dâna A, and Guler MO

Subjects

Cell Adhesion, Cell Proliferation, Cell Survival, Cells, Cultured, Humans, Models, Molecular, Molecular Dynamics Simulation, Molecular Structure, Particle Size, Amyloid chemistry, Nanofibers chemistry, Oligopeptides chemical synthesis, Oligopeptides chemistry

Abstract

Amyloid peptides are important components in many degenerative diseases as well as in maintaining cellular metabolism. Their unique stable structure provides new insights in developing new materials. Designing bioinspired self-assembling peptides is essential to generate new forms of hierarchical nanostructures. Here we present oppositely charged amyloid inspired peptides (AIPs), which rapidly self-assemble into nanofibers at pH 7 upon mixing in water caused by noncovalent interactions. Mechanical properties of the gels formed by self-assembled AIP nanofibers were analyzed with oscillatory rheology. AIP gels exhibited strong mechanical characteristics superior to gels formed by self-assembly of previously reported synthetic short peptides. Rheological studies of gels composed of oppositely charged mixed AIP molecules (AIP-1 + 2) revealed superior mechanical stability compared to individual peptide networks (AIP-1 and AIP-2) formed by neutralization of net charges through pH change. Adhesion and elasticity properties of AIP mixed nanofibers and charge neutralized AIP-1, AIP-2 nanofibers were analyzed by high resolution force-distance mapping using atomic force microscopy (AFM). Nanomechanical characterization of self-assembled AIP-1 + 2, AIP-1, and AIP-2 nanofibers also confirmed macroscopic rheology results, and mechanical stability of AIP mixed nanofibers was higher compared to individual AIP-1 and AIP-2 nanofibers self-assembled at acidic and basic pH, respectively. Experimental results were supported with molecular dynamics simulations by considering potential noncovalent interactions between the amino acid residues and possible aggregate forms. In addition, HUVEC cells were cultured on AIP mixed nanofibers at pH 7 and biocompatibility and collagen mimetic scaffold properties of the nanofibrous system were observed. Encapsulation of a zwitterionic dye (rhodamine B) within AIP nanofiber network was accomplished at physiological conditions to demonstrate that this network can be utilized for inclusion of soluble factors as a scaffold for cell culture studies.

Published

2012