Your search keyword '"Christine Peter"' showing total 7 results

1. Combining molecular dynamics simulations and scoring method to computationally model ubiquitylated linker histones in chromatosomes.

Author

Kevin Sawade, Andreas Marx, Christine Peter, and Oleksandra Kukharenko

Subjects

Biology (General), QH301-705.5

Abstract

The chromatin in eukaryotic cells plays a fundamental role in all processes during a cell's life cycle. This nucleoprotein is normally tightly packed but needs to be unpacked for expression and division. The linker histones are critical for such packaging processes and while most experimental and simulation works recognize their crucial importance, the focus is nearly always set on the nucleosome as the basic chromatin building block. Linker histones can undergo several modifications, but only few studies on their ubiquitylation have been conducted. Mono-ubiquitylated linker histones (HUb), while poorly understood, are expected to influence DNA compaction. The size of ubiquitin and the globular domain of the linker histone are comparable and one would expect an increased disorder upon ubiquitylation of the linker histone. However, the formation of higher order chromatin is not hindered and ubiquitylation of the linker histone may even promote gene expression. Structural data on chromatosomes is rare and HUb has never been modeled in a chromatosome so far. Descriptions of the chromatin complex with HUb would greatly benefit from computational structural data. In this study we generate molecular dynamics simulation data for six differently linked HUb variants with the help of a sampling scheme tailored to drive the exploration of phase space. We identify conformational sub-states of the six HUb variants using the sketch-map algorithm for dimensionality reduction and iterative HDBSCAN for clustering on the excessively sampled, shallow free energy landscapes. We present a highly efficient geometric scoring method to identify sub-states of HUb that fit into the nucleosome. We predict HUb conformations inside a nucleosome using on-dyad and off-dyad chromatosome structures as reference and show that unbiased simulations of HUb produce significantly more fitting than non-fitting HUb conformations. A tetranucleosome array is used to show that ubiquitylation can even occur in chromatin without too much steric clashes.

Published

2023

2. Towards a molecular basis of ubiquitin signaling: A dual-scale simulation study of ubiquitin dimers.

Author

Andrej Berg, Oleksandra Kukharenko, Martin Scheffner, and Christine Peter

Subjects

Biology (General), QH301-705.5

Abstract

Covalent modification of proteins by ubiquitin or ubiquitin chains is one of the most prevalent post-translational modifications in eukaryotes. Different types of ubiquitin chains are assumed to selectively signal respectively modified proteins for different fates. In support of this hypothesis, structural studies have shown that the eight possible ubiquitin dimers adopt different conformations. However, at least in some cases, these structures cannot sufficiently explain the molecular basis of the selective signaling mechanisms. This indicates that the available structures represent only a few distinct conformations within the entire conformational space adopted by a ubiquitin dimer. Here, molecular simulations on different levels of resolution can complement the structural information. We have combined exhaustive coarse grained and atomistic simulations of all eight possible ubiquitin dimers with a suitable dimensionality reduction technique and a new method to characterize protein-protein interfaces and the conformational landscape of protein conjugates. We found that ubiquitin dimers exhibit characteristic linkage type-dependent properties in solution, such as interface stability and the character of contacts between the subunits, which can be directly correlated with experimentally observed linkage-specific properties.

Published

2018

3. Tipping the Scale from Disorder to Alpha-helix: Folding of Amphiphilic Peptides in the Presence of Macroscopic and Molecular Interfaces.

Author

Cahit Dalgicdir, Christoph Globisch, Christine Peter, and Mehmet Sayar

Subjects

Biology (General), QH301-705.5

Abstract

Secondary amphiphilicity is inherent to the secondary structural elements of proteins. By forming energetically favorable contacts with each other these amphiphilic building blocks give rise to the formation of a tertiary structure. Small proteins and peptides, on the other hand, are usually too short to form multiple structural elements and cannot stabilize them internally. Therefore, these molecules are often found to be structurally ambiguous up to the point of a large degree of intrinsic disorder in solution. Consequently, their conformational preference is particularly susceptible to environmental conditions such as pH, salts, or presence of interfaces. In this study we use molecular dynamics simulations to analyze the conformational behavior of two synthetic peptides, LKKLLKLLKKLLKL (LK) and EAALAEALAEALAE (EALA), with built-in secondary amphiphilicity upon forming an alpha-helix. We use these model peptides to systematically study their aggregation and the influence of macroscopic and molecular interfaces on their conformational preferences. We show that the peptides are neither random coils in bulk water nor fully formed alpha helices, but adopt multiple conformations and secondary structure elements with short lifetimes. These provide a basis for conformation-selection and population-shift upon environmental changes. Differences in these peptides' response to macroscopic and molecular interfaces (presented by an aggregation partner) can be linked to their inherent alpha-helical tendencies in bulk water. We find that the peptides' aggregation behavior is also strongly affected by presence or absence of an interface, and rather subtly depends on their surface charge and hydrophobicity.

Published

2015

4. Optimization of an elastic network augmented coarse grained model to study CCMV capsid deformation.

Author

Christoph Globisch, Venkatramanan Krishnamani, Markus Deserno, and Christine Peter

Subjects

Medicine, Science

Abstract

The major protective coat of most viruses is a highly symmetric protein capsid that forms spontaneously from many copies of identical proteins. Structural and mechanical properties of such capsids, as well as their self-assembly process, have been studied experimentally and theoretically, including modeling efforts by computer simulations on various scales. Atomistic models include specific details of local protein binding but are limited in system size and accessible time, while coarse grained (CG) models do get access to longer time and length scales but often lack the specific local interactions. Multi-scale models aim at bridging this gap by systematically connecting different levels of resolution. Here, a CG model for CCMV (Cowpea Chlorotic Mottle Virus), a virus with an icosahedral shell of 180 identical protein monomers, is developed, where parameters are derived from atomistic simulations of capsid protein dimers in aqueous solution. In particular, a new method is introduced to combine the MARTINI CG model with a supportive elastic network based on structural fluctuations of individual monomers. In the parametrization process, both network connectivity and strength are optimized. This elastic-network optimized CG model, which solely relies on atomistic data of small units (dimers), is able to correctly predict inter-protein conformational flexibility and properties of larger capsid fragments of 20 and more subunits. Furthermore, it is shown that this CG model reproduces experimental (Atomic Force Microscopy) indentation measurements of the entire viral capsid. Thus it is shown that one obvious goal for hierarchical modeling, namely predicting mechanical properties of larger protein complexes from models that are carefully parametrized on elastic properties of smaller units, is achievable.

Published

2013

5. Towards a molecular basis of ubiquitin signaling: A dual-scale simulation study of ubiquitin dimers

Author

Martin Scheffner, Oleksandra Kukharenko, Andrej Berg, and Christine Peter

Subjects

Models, Molecular, 0301 basic medicine, Dimer, Plasma protein binding, Molecular Dynamics, Biochemistry, 01 natural sciences, chemistry.chemical_compound, Molecular dynamics, Computational Chemistry, Ubiquitin, Protein Interaction Mapping, Biochemical Simulations, Amino Acids, Biology (General), Databases, Protein, Materials, Free Energy, 010304 chemical physics, Ecology, biology, Basis (linear algebra), Organic Compounds, Chemistry, Simulation and Modeling, Physics, Monomers, Monomer, Computational Theory and Mathematics, Modeling and Simulation, ddc:540, Physical Sciences, Thermodynamics, Basic Amino Acids, Signal transduction, Algorithms, Protein Binding, Signal Transduction, Research Article, QH301-705.5, Materials Science, Molecular Dynamics Simulation, Research and Analysis Methods, Protein–protein interaction, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0103 physical sciences, Genetics, Computer Simulation, Dimers, Protein Interactions, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Lysine, Organic Chemistry, Ubiquitination, Chemical Compounds, Biology and Life Sciences, Computational Biology, Proteins, Polymer Chemistry, 030104 developmental biology, Oligomers, biology.protein, Biophysics, Protein Multimerization, Protein Processing, Post-Translational

Abstract

Covalent modification of proteins by ubiquitin or ubiquitin chains is one of the most prevalent post-translational modifications in eukaryotes. Different types of ubiquitin chains are assumed to selectively signal respectively modified proteins for different fates. In support of this hypothesis, structural studies have shown that the eight possible ubiquitin dimers adopt different conformations. However, at least in some cases, these structures cannot sufficiently explain the molecular basis of the selective signaling mechanisms. This indicates that the available structures represent only a few distinct conformations within the entire conformational space adopted by a ubiquitin dimer. Here, molecular simulations on different levels of resolution can complement the structural information. We have combined exhaustive coarse grained and atomistic simulations of all eight possible ubiquitin dimers with a suitable dimensionality reduction technique and a new method to characterize protein-protein interfaces and the conformational landscape of protein conjugates. We found that ubiquitin dimers exhibit characteristic linkage type-dependent properties in solution, such as interface stability and the character of contacts between the subunits, which can be directly correlated with experimentally observed linkage-specific properties., Author summary Post-translational modification of proteins by covalent attachment of ubiquitin is a key cellular process, regulating for example the fate and recycling of proteins. We present a new method to combine multiscale simulation with advanced analysis methods to characterize the states of ubiquitin-ubiquitin conjugates. We found that the linkage position affects the conformational space of ubiquitin dimers, determining the number and stability of relevant states, the character of subunit contacts and the nature of the surface exposed to possible binding partners.

Published

2018

6. Tipping the Scale from Disorder to Alpha-helix: Folding of Amphiphilic Peptides in the Presence of Macroscopic and Molecular Interfaces

Author

Mehmet Sayar, Cahit Dalgicdir, Christoph Globisch, Christine Peter, Dalgıçdır, Cahit, Sayar, Mehmet (ORCID 0000-0003-0553-0353 & YÖK ID 109820), Globisch, Christoph, Peter, Christine, Graduate School of Sciences and Engineering, College of Engineering, Department of Computional Sciences and Engineering, and Department of Mechanical Engineering

Subjects

Protein Folding, 010402 general chemistry, 01 natural sciences, Protein Structure, Secondary, 03 medical and health sciences, Cellular and Molecular Neuroscience, Molecular dynamics, Protein structure, Genetics, Computer Simulation, lcsh:QH301-705.5, Molecular Biology, Protein secondary structure, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Cell-penetrating peptides, Air-water-interface, Amphipathic peptides, Synuclein, Recognition, Simulations, Membranes, Dynamics, Delivery, 0303 health sciences, Ecology, Hydrogen bond, Chemistry, Computational Biology, Biochemical research methods, Mathematical and computational biology, Protein tertiary structure, 0104 chemical sciences, Folding (chemistry), Hydrogen bonding, Leucine, Lysine, Molecular structure, Alanine, Electrostatics, Peptides, Glutamic acid, lcsh:Biology (General), Computational Theory and Mathematics, Biochemistry, Chemical physics, Modeling and Simulation, ddc:540, Protein folding, Peptides, Hydrophobic and Hydrophilic Interactions, Algorithms, Alpha helix, Research Article

Abstract

Secondary amphiphilicity is inherent to the secondary structural elements of proteins. By forming energetically favorable contacts with each other these amphiphilic building blocks give rise to the formation of a tertiary structure. Small proteins and peptides, on the other hand, are usually too short to form multiple structural elements and cannot stabilize them internally. Therefore, these molecules are often found to be structurally ambiguous up to the point of a large degree of intrinsic disorder in solution. Consequently, their conformational preference is particularly susceptible to environmental conditions such as pH, salts, or presence of interfaces. In this study we use molecular dynamics simulations to analyze the conformational behavior of two synthetic peptides, LKKLLKLLKKLLKL (LK) and EAA LAEALAEALAE (EALA), with built-in secondary amphiphilicity upon forming an alpha-helix. We use these model peptides to systematically study their aggregation and the influence of macroscopic and molecular interfaces on their conformational preferences. We show that the peptides are neither random coils in bulk water nor fully formed alpha helices, but adopt multiple conformations and secondary structure elements with short lifetimes. These provide a basis for conformation-selection and population-shift upon environmental changes. Differences in these peptides' response to macroscopic and molecular interfaces (presented by an aggregation partner) can be linked to their inherent alpha-helical tendencies in bulk water. We find that the peptides' aggregation behavior is also strongly affected by presence or absence of an interface, and rather subtly depends on their surface charge and hydrophobicity., Scientific and Technological Research Council of Turkey (TÜBİTAK); Max-Planck Society; German Research Foundation

Published

2015

7. Safety and preliminary efficacy of orally administered lyophilized fecal microbiota product compared with frozen product given by enema for recurrent Clostridium difficile infection: A randomized clinical trial.

Author

Zhi-Dong Jiang, Robert R Jenq, Nadim J Ajami, Joseph F Petrosino, Ashley A Alexander, Shi Ke, Tehseen Iqbal, Andrew W DuPont, Kenneth Muldrew, Yushu Shi, Christine Peterson, Kim-Anh Do, and Herbert L DuPont

Subjects

Medicine, Science

Abstract

BACKGROUND:Fecal microbiota transplantation (FMT) via colonoscopy or enema has become a commonly used treatment of recurrent C. difficile infection (CDI). AIMS:To compare the safety and preliminary efficacy of orally administered lyophilized microbiota product compared with frozen product by enema. METHODS:In a single center, adults with ≥ 3 episodes of recurrent CDI were randomized to receive encapsulated lyophilized fecal microbiota from 100-200 g of donor feces (n = 31) or frozen FMT from 100 g of donor feces (n = 34) by enema. Safety during the three months post FMT was the primary study objective. Prevention of CDI recurrence during the 60 days after FMT was a secondary objective. Fecal microbiome changes were examined in first 39 subjects studied. RESULTS:Adverse experiences were commonly seen in equal frequency in both groups and did not appear to relate to the route of delivery of FMT. CDI recurrence was prevented in 26 of 31 (84%) subjects randomized to capsules and in 30 of 34 (88%) receiving FMT by enema (p = 0.76). Both products normalized fecal microbiota diversity while the lyophilized orally administered product was less effective in repleting Bacteroidia and Verrucomicrobia classes compared to frozen product via enema. CONCLUSIONS:The route of delivery, oral or rectal, did not influence adverse experiences in FMT. In preliminary evaluation, both routes appeared to show equivalent efficacy, although the dose may need to be higher for lyophilized product. Spore-forming bacteria appear to be the most important engrafting organisms in FMT by the oral route using lyophilized product. TRIAL REGISTRATION:ClinicalTrials.gov NCT02449174.

Published

2018