Your search keyword '"Simulation of Biomolecular Systems (HIMS, FNWI)"' showing total 3 results

1. Water structure and dynamics in the hydration layer of a type III anti-freeze protein

Author

Z. Faidon Brotzakis, Huib J. Bakker, Ilja K. Voets, Peter G. Bolhuis, Simulation of Biomolecular Systems (HIMS, FNWI), Molecular Spectroscopy (HIMS, FNWI), and Physical Chemistry

Subjects

Protein Conformation, Kinetics, Antifreeze Proteins, Type III, General Physics and Astronomy, Molecular Dynamics Simulation, 010402 general chemistry, 01 natural sciences, Molecular dynamics, Structure-Activity Relationship, Adsorption, Protein structure, Antifreeze Proteins, Type III/chemistry, Antifreeze Proteins, 0103 physical sciences, Freezing, Molecule, Physical and Theoretical Chemistry, Binding Sites, 010304 chemical physics, Chemistry, Hydrogen bond, Water, Hydrogen Bonding, 0104 chemical sciences, Crystallography, Ice binding, Water/chemistry, Polar, Type III/chemistry, Protein Binding

Abstract

We report on a molecular dynamics study on the relation between the structure and the orientational (and hydrogen bond) dynamics of hydration water around the ocean pout AFP III anti-freeze protein. We find evidence for an increasing tetrahedral structure from the area opposite to the ice binding site (IBS) towards the protein IBS, with the strongest signal of tetrahedral structure around the THR-18 residue of the IBS. The tetrahedral structural parameter mostly positively correlates with increased reorientation decay times. Interestingly, for several key (polar) residues that are not part of the IBS but are in its vicinity, we observe a decrease of the reorientation time with increasing tetrahedral structure. A similar anti-correlation is observed for the hydrogen-bonded water molecules. These effects are enhanced at a lower temperature. We interpret these results in terms of the structure-making and structure-breaking residues. Moreover, we investigate the tetrahedral structure and dynamics of waters at a partially dehydrated IBS, and for the protein adsorbed at the air-water interface. We find that the mutation changes the preferred protein orientation upon adsorption at an air-water interface. These results are in agreement with the water-air Vibration Sum Frequency Generation spectroscopic experiments showing a strongly reduced tetrahedral signal upon mutation at the IBS.

Published

2018

2. Prediction of a stable associated liquid of short amyloidogenic peptides

Author

Jurriaan A. Luiken, Peter G. Bolhuis, and Simulation of Biomolecular Systems (HIMS, FNWI)

Subjects

Phase transition, Hot Temperature, Nucleation, General Physics and Astronomy, Amyloidogenic Proteins, Molecular Dynamics Simulation, Fibril, 01 natural sciences, Oligomer, Phase Transition, Protein Structure, Secondary, 03 medical and health sciences, chemistry.chemical_compound, Molecular dynamics, Protein structure, Phase (matter), 0103 physical sciences, Amino Acid Sequence, Physical and Theoretical Chemistry, 010306 general physics, Peptide sequence, 030304 developmental biology, 0303 health sciences, Quantitative Biology::Biomolecules, Chemistry, Protein Stability, Peptide Fragments, Crystallography, Chemical physics, Anisotropy, Protein Multimerization, Hydrophobic and Hydrophilic Interactions

Abstract

Amyloid fibril formation is believed to be a nucleation-controlled process. Depending on the nature of peptide sequence, fibril nucleation can occur in one step, straight from a dilute solution, or in multiple steps via oligomers or disordered aggregates. What determines this process is poorly understood. Since the fibril formation kinetics is driven by thermodynamic forces, knowledge of the phase behavior is crucial. Here, we investigated the phase behavior of three short peptide sequences of varying side-chain hydrophobicity. Replica exchange molecular dynamics simulations of a mid-resolution model indicate that the weakly hydrophobic peptide forms fibrils directly from solution, whereas the most hydrophobic peptide forms a dense liquid phase before crystallizing into ordered fibrils at low temperatures. For the medium hydrophobic peptide we found evidence of a novel additional transition to a liquid phase consisting of clusters of aligned peptides, implying a three-step nucleation process. We tested the robustness of this prediction by applying Wertheim's theory and statistical associating fluid theory to a hard-sphere model dressed with isotropic and anisotropic attractions. We found that the ratio of interaction strengths strongly affects the phase behavior, and under certain conditions indeed gives rise to a stable polymerized liquid phase. The peptide clusters in the associated liquid tend to be slow and long-lived, which may give the oligomer droplet more time to act as a toxic oligomer, before turning into a fibril.

Published

2015

3. The self-assembly mechanism of fibril-forming silk-based block copolymers

Author

Peter G. Bolhuis, Marieke Schor, and Simulation of Biomolecular Systems (HIMS, FNWI)

Subjects

Protein Folding, Materials science, Polymers, Silk, General Physics and Astronomy, Hydrogen Bonding, macromolecular substances, Dipeptides, Molecular Dynamics Simulation, Fibril, Protein Structure, Secondary, Folding (chemistry), Molecular dynamics, SILK, Protein structure, Block (telecommunications), Polymer chemistry, Biophysics, Copolymer, Protein folding, Physical and Theoretical Chemistry

Abstract

Triblock copolymers consisting of a silk-based ((Gly-Ala)(3)Gly-Glu) repeat flanked by hydrophilic outer blocks self-assemble into micrometer long fibrils in response to a trigger. Since the exact mechanism of the fibril formation remains unclear, we employ a multiscale modelling approach in combination with rare event simulations to elucidate key processes. Atomistic scale simulations on the silk-based block suggest a mechanism in which a polypeptide prefolded into a β-roll structure docks to the growing end of a fibril through the formation of Glu-Glu sidechain contacts. Subsequently it can slide to the optimal position before water is expelled to form a dry interface between the fibril end and the attaching block copolymer. In addition, we find that the folded state of the silk-based block is further stabilised through interactions with its neighboring block. Templated folding may also play a role in case a partially folded polypeptide attaches. The coarse-grained simulations indicate that the attachment and subsequent sliding is mediated by the hydrophilic flanks in a size dependent manner. The hydrophilic blocks prevent random aggregation and allow growth only at the end of the fibril. Our multiscale approach may be used for other fibril-forming peptides.

Published

2011