39 results on '"Kutzner, C"'
Search Results
2. Novel pressure stable thermoelectric flow sensor in non-steady state operation mode for inline process analysis in micro reactors
- Author
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Jacobs, T., Kutzner, C., Kropp, M., Lang, W., Kienle, A., and Hauptmann, P.
- Published
- 2009
- Full Text
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3. A CUDA fast multipole method with highly efficient M2L farfield evaluationfield evaluation
- Author
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Kohnke, B., Kutzner, C., Beckmann, A., Lube, G., Kabadshow, I., Dachsel, H., and Grubmüller, H.
- Abstract
Solving an N-body problem, electrostatic or gravitational, is a crucial task and the main computational bottleneck in manyscientific applications. Its direct solution is an ubiquitous showcase example for the compute power of graphics processingunits (GPUs). However, the naive pairwise summation hasOðN2Þcomputational complexity. The fast multipole method(FMM) can reduce runtime and complexity toOðNÞfor any specified precision. Here, we present a CUDA-accelerated,CþþFMM implementation for multi particle systems withr1potential that are found, e.g. in biomolecular simulations.The algorithm involves several operators to exchange information in an octree data structure. We focus on the Multipole-to-Local (M2L) operator, as its runtime is limiting for the overall performance. We propose, implement and benchmarkthree different M2L parallelization approaches. Approach (1) utilizes Unified Memory to minimize programming andporting efforts. It achieves decent speedups for only little implementation work. Approach (2) employs CUDA DynamicParallelism to significantly improve performance for high approximation accuracies. The presorted list-based approach(3) fits periodic boundary conditions particularly well. It exploits FMM operator symmetries to minimize both memoryaccess and the number of complex multiplications. The result is a compute-bound implementation, i.e. performance islimited by arithmetic operations rather than by memory accesses. The complete CUDA parallelized FMM is incorporatedwithin the GROMACS molecular dynamics package as an alternative Coulomb solver.
- Published
- 2021
4. Gromex : A scalable and versatile fast multipole method for biomolecular simulation
- Author
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Kohnke, B, Ullmann, T R, Beckmann, A, Kabadshow, I, Haensel, D, Morgenstern, L, Dobrev, P, Groenhof, G, Kutzner, C, Hess, Berk, Dachsel, H, Grubmüller, H, Kohnke, B, Ullmann, T R, Beckmann, A, Kabadshow, I, Haensel, D, Morgenstern, L, Dobrev, P, Groenhof, G, Kutzner, C, Hess, Berk, Dachsel, H, and Grubmüller, H
- Abstract
Atomistic simulations of large biomolecular systems with chemical variability such as constant pH dynamic protonation offer multiple challenges in high performance computing. One of them is the correct treatment of the involved electrostatics in an efficient and highly scalable way. Here we review and assess two of the main building blocks that will permit such simulations: (1) An electrostatics library based on the Fast Multipole Method (FMM) that treats local alternative charge distributions with minimal overhead, and (2) A λ-dynamics module working in tandem with the FMM that enables various types of chemical transitions during the simulation. Our λ-dynamics and FMM implementations do not rely on third-party libraries but are exclusively using C++ language features and they are tailored to the specific requirements of molecular dynamics simulation suites such as GROMACS. The FMM library supports fractional tree depths and allows for rigorous error control and automatic performance optimization at runtime. Near-optimal performance is achieved on various SIMD architectures and on GPUs using CUDA. For exascale systems, we expect our approach to outperform current implementations based on Particle Mesh Ewald (PME) electrostatics, because FMM avoids the communication bottlenecks caused by the parallel fast Fourier transformations needed for PME., QC 20201208
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- 2020
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5. O.18Recessive mutations in the myosin chaperone UNC-45B impair muscle myofibrillar integrity, manifesting as progressive myopathy with eccentric cores
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Donkervoort, S., primary, Hu, Y., additional, Lornage, X., additional, Kutzner, C., additional, Mroczek, M., additional, Neuhaus, S., additional, Kuntz, N., additional, Töpf, A., additional, Monges, S., additional, Lubieniecki, F., additional, Chao, K., additional, Böhm, J., additional, Romero, N., additional, Straub, V., additional, Laporte, J., additional, Foley, A., additional, Ottenheijm, C., additional, Hoppe, T., additional, and Bönnemann, C., additional
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- 2019
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6. From stable dipolar towards reversing numerical dynamos
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Kutzner, C. and Christensen, U.R.
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- 2002
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7. Acute myocardial infarction delineated by noninvasive thallium-201/technetium-99m pyrophosphate tomography
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KRAUSE, T., JOSEPH, A., KUTZNER, C., KASPER, W., SCHUEMICHEN, C., JUST, H., and MOSER, E.
- Published
- 1990
8. Scaling of the GROMACS 4.6 molecular dynamics code on SuperMUC
- Author
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Kutzner, C., Apostolov, R., Hess, B., and Grubmüller, H.
- Abstract
Here we report on the performance of GROMACS 4.6 on the SuperMUC cluster at the Leibniz Rechenzentrum in Garching. We carried out benchmarks with three biomolecular systems consisting of eighty thousand to twelve million atoms in a strong scaling test each. The twelve million atom simulation system reached a performance of 49 nanoseconds per day on 32,768 cores.
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- 2014
9. GromEx : Electrostatics with chemical variability for realistic molecular simulations on the exascale
- Author
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Ullmann, R. T., Kutzner, C., Beckmann, A., Kohnke, B., Kabadashow, I., Dachsel, H., Hess, Berk, Grubmueller, H., Ullmann, R. T., Kutzner, C., Beckmann, A., Kohnke, B., Kabadashow, I., Dachsel, H., Hess, Berk, and Grubmueller, H.
- Abstract
QC 20190304
- Published
- 2015
10. Some applications of the vibro-replacement process
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Rathgeb, E., primary and Kutzner, C., additional
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- 1976
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11. Novel screen printed humidity sensor on textiles for smart textile applications
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Kutzner, C., primary, Lucklum, R., additional, Torah, R., additional, Beeby, S., additional, and Tudor, J., additional
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- 2013
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12. Einfluss von Training und Crataegus-Extrakt WS®1442 auf körperliche Leistungsfähigkeit und Lebensqualität bei leichter Herzinsuffizienz - eine randomisierte kontrollierte Studie
- Author
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Härtel, S, primary, Kutzner, C, additional, Burkart, M, additional, and Bös, K, additional
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- 2012
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13. Oxygenation of the calf muscle during an incremental, intermittent walking exercise assessed by NIRS
- Author
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Härtel, S., primary, Kutzner, C., additional, Schneider, D., additional, Grieger, S., additional, Neumaier, M., additional, and Kohl-Bareis, M., additional
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- 2011
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14. Inline chemical process analysis in micro-plants based on thermoelectric flow and impedimetric sensors
- Author
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Jacobs, T, primary, Kutzner, C, additional, Kropp, M, additional, Brokmann, G, additional, Lang, W, additional, Steinke, A, additional, Kienle, A, additional, and Hauptmann, P, additional
- Published
- 2010
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15. Novel impedimetric and perforated thermal flow sensor for inline chemical process analysis in micro residence time reactors
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Jacobs, T., primary, Kutzner, C., additional, Kropp, M., additional, Brokmann, G., additional, Lang, W., additional, Steinke, A., additional, Kienle, A., additional, and Hauptmann, P., additional
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- 2009
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16. Pressure stable thermoelectric flow sensors by means of membrane perforation
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Kropp, M., primary, Kutzner, C., additional, Hartgenbusch, N., additional, Gu, S., additional, Sosna, C., additional, Buchner, R., additional, Hauptmann, P., additional, and Lang, W., additional
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- 2009
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17. Acute myocardial infarction delineated by noninvasive thallium-201/technetium-99m pyrophosphate tomography
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C. Schuemichen, Kutzner C, Kasper W, Thomas Krause, H. Just, Joseph A, and Ernst Moser
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Adult ,medicine.medical_specialty ,Technetium Tc 99m Pyrophosphate ,Myocardial Infarction ,chemistry.chemical_element ,Infarction ,Physical examination ,Sensitivity and Specificity ,Text mining ,Internal medicine ,medicine ,Humans ,Radiology, Nuclear Medicine and imaging ,cardiovascular diseases ,Myocardial infarction ,Radionuclide Imaging ,Aged ,Observer Variation ,medicine.diagnostic_test ,business.industry ,Electrocardiography in myocardial infarction ,Technetium ,General Medicine ,Middle Aged ,medicine.disease ,Diphosphates ,Thallium Radioisotopes ,chemistry ,ROC Curve ,Cardiology ,Thallium ,Tomography ,business ,Technetium-99m - Abstract
The purpose of this study was to validate different scintigraphic approaches for assessing acute myocardial infarctions. 201Tl, 99Tcm pyrophosphate (PPi) and combined 201Tl/99Tcm PPi tomograms were evaluated in 115 consecutive patients, in 85 of whom clinical examination revealed acute myocardial infarction. The overall sensitivity and specificity for infarct detection was 80% versus 56% for 201Tl alone, 61% versus 97% for 99Tcm PPi alone, and 100% each for the combined 201Tl/99Tcm PPi imaging. The sensitivity for nontransmural infarcts was 57% for 201Tl, 37% for 99Tcm PPi and 100% for combined imaging. The overlay of 201Tl and 99Tcm PPi images increases the observer's confidence in the diagnosis and provides better localization of the infarction. 201Tl alone could localize the infarction in 80%, 99Tcm PPi alone in 49% and 201Tl/99Tcm PPi in 100% of the cases. ECG and 201Tl/99Tcm PPi tomography concurred upon infarct localization in 98% of the patients. Based on the 201Tl/99Tcm accumulation pattern, 94% of the Q-wave infarctions were judged to be transmural and 83% of the non-Q-wave infarctions were judged to be nontransmural. It is concluded that combined 201Tl/99Tcm PPi tomography is highly accurate for determining the presence and location of acute myocardial infarction. This technique appears to be superior to studies where only one radioisotope is used.
- Published
- 1990
18. Simulated geomagnetic reversals and preferred virtual geomagnetic pole paths
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Kutzner, C., primary and Christensen, U. R., additional
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- 2004
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19. Book review
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Schetelig, K. and Kutzner, C.
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- 1986
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20. Some applications of the vibro-replacement process.
- Author
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Rathgeb, E. and Kutzner, C.
- Published
- 1975
- Full Text
- View/download PDF
21. Acute myocardial infarction delineated by noninvasive thallium201technetium99m pyrophosphate tomography
- Author
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KRAUSE, T., JOSEPH, A., KUTZNER, C., KASPER, W., SCHUEMICHEN, C., JUST, H., and MOSER, E.
- Abstract
The purpose of this study was to validate different scintigraphic approaches for assessing acute myocardial infarctions. 201Tl, 99Tcmpyrophosphate (PPi) and combined 201Tl/99TcmPPi tomograms were evaluated in 115 consecutive patients, in 85 of whom clinical examination revealed acute myocardial infarction. The overall sensitivity and specificity for infarct detection was 80 versus56 for 201Tl alone, 61 versus97 for 99TcmPPi alone, and 100 each for the combined 201Tl/99TcmPPi imaging. The sensitivity for nontransmural infarcts was 57 for 201Tl, 37 for 99TcmPPi and 100 for combined imaging. The overlay of 201Tl and 99TcmPPi images increases the observer's confidence in the diagnosis and provides better localization of the infarction. 201Tl alone could localize the infarction in 80, 99TcmPPi alone in 49 and 201Tl/ 99TcmPPi in 100 of the cases. ECG and 201Tl/99TcmPPi tomography concurred upon infarct localization in 98 of the patients. Based on the 201Tl/99Tcmaccumulation pattern, 94 of the Q-wave infarctions were judged to be transmural and 83 of the non-Q-wave infarctions were judged to be nontransmural.
- Published
- 1990
22. Fluid-rock interaction and grouting.
- Author
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Kutzner C. and Kutzner C.
- Abstract
Some points to be considered in developing a theory of grouting are presented. The application of some of the theoretical ideas to practice, such as grouting tests in boreholes and stability testing of the grout mix are described. Automatic recording of grouting application is required for proper control and for payment of the contractor., Some points to be considered in developing a theory of grouting are presented. The application of some of the theoretical ideas to practice, such as grouting tests in boreholes and stability testing of the grout mix are described. Automatic recording of grouting application is required for proper control and for payment of the contractor.
23. GROMACS in the Cloud: A Global Supercomputer to Speed Up Alchemical Drug Design.
- Author
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Kutzner C, Kniep C, Cherian A, Nordstrom L, Grubmüller H, de Groot BL, and Gapsys V
- Subjects
- Cloud Computing, Drug Design, Ligands, Molecular Dynamics Simulation, Computers, Computing Methodologies
- Abstract
We assess costs and efficiency of state-of-the-art high-performance cloud computing and compare the results to traditional on-premises compute clusters. Our use case is atomistic simulations carried out with the GROMACS molecular dynamics (MD) toolkit with a particular focus on alchemical protein-ligand binding free energy calculations. We set up a compute cluster in the Amazon Web Services (AWS) cloud that incorporates various different instances with Intel, AMD, and ARM CPUs, some with GPU acceleration. Using representative biomolecular simulation systems, we benchmark how GROMACS performs on individual instances and across multiple instances. Thereby we assess which instances deliver the highest performance and which are the most cost-efficient ones for our use case. We find that, in terms of total costs, including hardware, personnel, room, energy, and cooling, producing MD trajectories in the cloud can be about as cost-efficient as an on-premises cluster given that optimal cloud instances are chosen. Further, we find that high-throughput ligand-screening can be accelerated dramatically by using global cloud resources. For a ligand screening study consisting of 19 872 independent simulations or ∼200 μs of combined simulation trajectory, we made use of diverse hardware available in the cloud at the time of the study. The computations scaled-up to reach peak performance using more than 4 000 instances, 140 000 cores, and 3 000 GPUs simultaneously. Our simulation ensemble finished in about 2 days in the cloud, while weeks would be required to complete the task on a typical on-premises cluster consisting of several hundred nodes.
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- 2022
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24. A GPU-Accelerated Fast Multipole Method for GROMACS: Performance and Accuracy.
- Author
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Kohnke B, Kutzner C, and Grubmüller H
- Abstract
An important and computationally demanding part of molecular dynamics simulations is the calculation of long-range electrostatic interactions. Today, the prevalent method to compute these interactions is particle mesh Ewald (PME). The PME implementation in the GROMACS molecular dynamics package is extremely fast on individual GPU nodes. However, for large scale multinode parallel simulations, PME becomes the main scaling bottleneck as it requires all-to-all communication between the nodes; as a consequence, the number of exchanged messages scales quadratically with the number of involved nodes in that communication step. To enable efficient and scalable biomolecular simulations on future exascale supercomputers, clearly a method with a better scaling property is required. The fast multipole method (FMM) is such a method. As a first step on the path to exascale, we have implemented a performance-optimized, highly efficient GPU FMM and integrated it into GROMACS as an alternative to PME. For a fair performance comparison between FMM and PME, we first assessed the accuracies of the methods for various sets of input parameters. With parameters yielding similar accuracies for both methods, we determined the performance of GROMACS with FMM and compared it to PME for exemplary benchmark systems. We found that FMM with a multipole order of 8 yields electrostatic forces that are as accurate as PME with standard parameters. Further, for typical mixed-precision simulation settings, FMM does not lead to an increased energy drift with multipole orders of 8 or larger. Whereas an ≈50 000 atom simulation system with our FMM reaches only about a third of the performance with PME, for systems with large dimensions and inhomogeneous particle distribution, e.g., aerosol systems with water droplets floating in a vacuum, FMM substantially outperforms PME already on a single node.
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- 2020
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25. More bang for your buck: Improved use of GPU nodes for GROMACS 2018.
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Kutzner C, Páll S, Fechner M, Esztermann A, de Groot BL, and Grubmüller H
- Abstract
We identify hardware that is optimal to produce molecular dynamics (MD) trajectories on Linux compute clusters with the GROMACS 2018 simulation package. Therefore, we benchmark the GROMACS performance on a diverse set of compute nodes and relate it to the costs of the nodes, which may include their lifetime costs for energy and cooling. In agreement with our earlier investigation using GROMACS 4.6 on hardware of 2014, the performance to price ratio of consumer GPU nodes is considerably higher than that of CPU nodes. However, with GROMACS 2018, the optimal CPU to GPU processing power balance has shifted even more toward the GPU. Hence, nodes optimized for GROMACS 2018 and later versions enable a significantly higher performance to price ratio than nodes optimized for older GROMACS versions. Moreover, the shift toward GPU processing allows to cheaply upgrade old nodes with recent GPUs, yielding essentially the same performance as comparable brand-new hardware. © 2019 Wiley Periodicals, Inc., (© 2019 Wiley Periodicals, Inc.)
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- 2019
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26. Automated cryo-EM structure refinement using correlation-driven molecular dynamics.
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Igaev M, Kutzner C, Bock LV, Vaiana AC, and Grubmüller H
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- Automation, Computational Biology methods, Cryoelectron Microscopy methods, Molecular Dynamics Simulation
- Abstract
We present a correlation-driven molecular dynamics (CDMD) method for automated refinement of atomistic models into cryo-electron microscopy (cryo-EM) maps at resolutions ranging from near-atomic to subnanometer. It utilizes a chemically accurate force field and thermodynamic sampling to improve the real-space correlation between the modeled structure and the cryo-EM map. Our framework employs a gradual increase in resolution and map-model agreement as well as simulated annealing, and allows fully automated refinement without manual intervention or any additional rotamer- and backbone-specific restraints. Using multiple challenging systems covering a wide range of map resolutions, system sizes, starting model geometries and distances from the target state, we assess the quality of generated models in terms of both model accuracy and potential of overfitting. To provide an objective comparison, we apply several well-established methods across all examples and demonstrate that CDMD performs best in most cases., Competing Interests: MI, CK, LB, AV, HG No competing interests declared, (© 2019, Igaev et al.)
- Published
- 2019
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27. GROmaρs: A GROMACS-Based Toolset to Analyze Density Maps Derived from Molecular Dynamics Simulations.
- Author
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Briones R, Blau C, Kutzner C, de Groot BL, and Aponte-Santamaría C
- Subjects
- Animals, Aquaporins chemistry, Bacterial Outer Membrane Proteins chemistry, Humans, Protein Conformation, Receptors, CXCR4 chemistry, Molecular Dynamics Simulation, Software
- Abstract
We introduce a computational toolset, named GROmaρs, to obtain and compare time-averaged density maps from molecular dynamics simulations. GROmaρs efficiently computes density maps by fast multi-Gaussian spreading of atomic densities onto a three-dimensional grid. It complements existing map-based tools by enabling spatial inspection of atomic average localization during the simulations. Most importantly, it allows the comparison between computed and reference maps (e.g., experimental) through calculation of difference maps and local and time-resolved global correlation. These comparison operations proved useful to quantitatively contrast perturbed and control simulation data sets and to examine how much biomolecular systems resemble both synthetic and experimental density maps. This was especially advantageous for multimolecule systems in which standard comparisons like RMSDs are difficult to compute. In addition, GROmaρs incorporates absolute and relative spatial free-energy estimates to provide an energetic picture of atomistic localization. This is an open-source GROMACS-based toolset, thus allowing for static or dynamic selection of atoms or even coarse-grained beads for the density calculation. Furthermore, masking of regions was implemented to speed up calculations and to facilitate the comparison with experimental maps. Beyond map comparison, GROmaρs provides a straightforward method to detect solvent cavities and average charge distribution in biomolecular systems. We employed all these functionalities to inspect the localization of lipid and water molecules in aquaporin systems, the binding of cholesterol to the G protein coupled chemokine receptor type 4, and the identification of permeation pathways through the dermicidin antimicrobial channel. Based on these examples, we anticipate a high applicability of GROmaρs for the analysis of molecular dynamics simulations and their comparison with experimentally determined densities., (Copyright © 2018 Biophysical Society. Published by Elsevier Inc. All rights reserved.)
- Published
- 2019
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28. Design, Implementation, and Study Protocol of a Kindergarten-Based Health Promotion Intervention.
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Kobel S, Wartha O, Wirt T, Dreyhaupt J, Lämmle C, Friedemann EM, Kelso A, Kutzner C, Hermeling L, and Steinacker JM
- Subjects
- Child, Child, Preschool, Diet, Feeding Behavior physiology, Female, Humans, Male, Obesity physiopathology, Overweight physiopathology, Program Evaluation, Exercise physiology, Health Promotion, Obesity prevention & control, Overweight prevention & control
- Abstract
Inactivity and an unhealthy diet amongst others have led to an increased prevalence of overweight and obesity even in young children. Since most health behaviours develop during childhood health promotion has to start early. The setting kindergarten has been shown as ideal for such interventions. "Join the Healthy Boat" is a kindergarten-based health promotion programme with a cluster-randomised study focussing on increased physical activity, reduced screen media use, and sugar-sweetened beverages, as well as a higher fruit and vegetable intake. Intervention and materials were developed using Bartholomew's Intervention Mapping approach considering Bandura's social-cognitive theory and Bronfenbrenner's ecological framework for human development. The programme is distributed using a train-the-trainer approach and currently implemented in 618 kindergartens. The effectiveness of this one-year intervention with an intervention and a control group will be examined in 62 kindergartens using standardised protocols, materials, and tools for outcome and process evaluation. A sample of 1021 children and their parents provided consent and participated in the intervention. Results of this study are awaited to give a better understanding of health behaviours in early childhood and to identify strategies for effective health promotion. The current paper describes development and design of the intervention and its implementation and planned evaluation. Trial Registration . The study is registered at the German Clinical Trials Register (DRKS), Freiburg University, Germany, ID: DRKS00010089., Competing Interests: The authors declare that there is no conflict of interests regarding the publication of this paper.
- Published
- 2017
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29. Insights into the function of ion channels by computational electrophysiology simulations.
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Kutzner C, Köpfer DA, Machtens JP, de Groot BL, Song C, and Zachariae U
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- Algorithms, Binding Sites, Biological Transport, Active, Computational Biology methods, Computer Simulation, Electrophysiology methods, Membrane Proteins, Molecular Dynamics Simulation, Protein Binding, Protein Conformation, Software, Ion Channel Gating, Ion Channels chemistry, Ion Channels ultrastructure, Lipid Bilayers chemistry, Membrane Potentials, Models, Chemical
- Abstract
Ion channels are of universal importance for all cell types and play key roles in cellular physiology and pathology. Increased insight into their functional mechanisms is crucial to enable drug design on this important class of membrane proteins, and to enhance our understanding of some of the fundamental features of cells. This review presents the concepts behind the recently developed simulation protocol Computational Electrophysiology (CompEL), which facilitates the atomistic simulation of ion channels in action. In addition, the review provides guidelines for its application in conjunction with the molecular dynamics software package GROMACS. We first lay out the rationale for designing CompEL as a method that models the driving force for ion permeation through channels the way it is established in cells, i.e., by electrochemical ion gradients across the membrane. This is followed by an outline of its implementation and a description of key settings and parameters helpful to users wishing to set up and conduct such simulations. In recent years, key mechanistic and biophysical insights have been obtained by employing the CompEL protocol to address a wide range of questions on ion channels and permeation. We summarize these recent findings on membrane proteins, which span a spectrum from highly ion-selective, narrow channels to wide diffusion pores. Finally we discuss the future potential of CompEL in light of its limitations and strengths. This article is part of a Special Issue entitled: Membrane Proteins edited by J.C. Gumbart and Sergei Noskov., (Copyright © 2016 Elsevier B.V. All rights reserved.)
- Published
- 2016
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30. Best bang for your buck: GPU nodes for GROMACS biomolecular simulations.
- Author
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Kutzner C, Páll S, Fechner M, Esztermann A, de Groot BL, and Grubmüller H
- Subjects
- Benchmarking, Computer Simulation, Molecular Dynamics Simulation, Software
- Abstract
The molecular dynamics simulation package GROMACS runs efficiently on a wide variety of hardware from commodity workstations to high performance computing clusters. Hardware features are well-exploited with a combination of single instruction multiple data, multithreading, and message passing interface (MPI)-based single program multiple data/multiple program multiple data parallelism while graphics processing units (GPUs) can be used as accelerators to compute interactions off-loaded from the CPU. Here, we evaluate which hardware produces trajectories with GROMACS 4.6 or 5.0 in the most economical way. We have assembled and benchmarked compute nodes with various CPU/GPU combinations to identify optimal compositions in terms of raw trajectory production rate, performance-to-price ratio, energy efficiency, and several other criteria. Although hardware prices are naturally subject to trends and fluctuations, general tendencies are clearly visible. Adding any type of GPU significantly boosts a node's simulation performance. For inexpensive consumer-class GPUs this improvement equally reflects in the performance-to-price ratio. Although memory issues in consumer-class GPUs could pass unnoticed as these cards do not support error checking and correction memory, unreliable GPUs can be sorted out with memory checking tools. Apart from the obvious determinants for cost-efficiency like hardware expenses and raw performance, the energy consumption of a node is a major cost factor. Over the typical hardware lifetime until replacement of a few years, the costs for electrical power and cooling can become larger than the costs of the hardware itself. Taking that into account, nodes with a well-balanced ratio of CPU and consumer-class GPU resources produce the maximum amount of GROMACS trajectory over their lifetime., (© 2015 The Authors. Journal of Computational Chemistry Published by Wiley Periodicals, Inc.)
- Published
- 2015
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31. The backbone dynamics of the amyloid precursor protein transmembrane helix provides a rationale for the sequential cleavage mechanism of γ-secretase.
- Author
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Pester O, Barrett PJ, Hornburg D, Hornburg P, Pröbstle R, Widmaier S, Kutzner C, Dürrbaum M, Kapurniotu A, Sanders CR, Scharnagl C, and Langosch D
- Subjects
- Amyloid Precursor Protein Secretases chemistry, Amyloid beta-Peptides chemical synthesis, Amyloid beta-Peptides chemistry, Models, Molecular, Amyloid Precursor Protein Secretases metabolism, Amyloid beta-Peptides metabolism, Thermodynamics
- Abstract
The etiology of Alzheimer's disease depends on the relative abundance of different amyloid-β (Aβ) peptide species. These peptides are produced by sequential proteolytic cleavage within the transmembrane helix of the 99 residue C-terminal fragment of the amyloid precursor protein (C99) by the intramembrane protease γ-secretase. Intramembrane proteolysis is thought to require local unfolding of the substrate helix, which has been proposed to be cleaved as a homodimer. Here, we investigated the backbone dynamics of the substrate helix. Amide exchange experiments of monomeric recombinant C99 and of synthetic transmembrane domain peptides reveal that the N-terminal Gly-rich homodimerization domain exchanges much faster than the C-terminal cleavage region. MD simulations corroborate the differential backbone dynamics, indicate a bending motion at a diglycine motif connecting dimerization and cleavage regions, and detect significantly different H-bond stabilities at the initial cleavage sites. Our results are consistent with the following hypotheses about cleavage of the substrate: First, the GlyGly hinge may precisely position the substrate within γ-secretase such that its catalytic center must start proteolysis at the known initial cleavage sites. Second, the ratio of cleavage products formed by subsequent sequential proteolysis could be influenced by differential extents of solvation and by the stabilities of H-bonds at alternate initial sites. Third, the flexibility of the Gly-rich domain may facilitate substrate movement within the enzyme during sequential proteolysis. Fourth, dimerization may affect substrate processing by decreasing the dynamics of the dimerization region and by increasing that of the C-terminal part of the cleavage region.
- Published
- 2013
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32. Molecular dynamics in principal component space.
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Michielssens S, van Erp TS, Kutzner C, Ceulemans A, and de Groot BL
- Subjects
- Molecular Weight, Principal Component Analysis, Protein Conformation, Proteins chemistry, Thermodynamics, Time Factors, Algorithms, Molecular Dynamics Simulation economics
- Abstract
A molecular dynamics algorithm in principal component space is presented. It is demonstrated that sampling can be improved without changing the ensemble by assigning masses to the principal components proportional to the inverse square root of the eigenvalues. The setup of the simulation requires no prior knowledge of the system; a short initial MD simulation to extract the eigenvectors and eigenvalues suffices. Independent measures indicated a 6-7 times faster sampling compared to a regular molecular dynamics simulation.
- Published
- 2012
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33. [Daily ailments among healthy, middle-aged adults--situation report and explanatory approaches].
- Author
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Krell J, Kutzner C, Härtel S, and Bös K
- Subjects
- Cross-Sectional Studies, Energy Metabolism, Female, Germany, Humans, Male, Middle Aged, Motor Activity, Reference Values, Surveys and Questionnaires, Walking, Chronic Disease epidemiology, Muscle Strength, Physical Endurance, Physical Fitness, Pliability, Postural Balance
- Abstract
Background: Physical performance steadily declines with increasing age even among healthy adults., Methods: A sport scientific screening-battery was used to determine the relationship between physical performance--that is endurance, strength, coordination, flexibility--and typical daily ailments as measured by a questionnaire among 222 healthy, middle-aged women and men. Cardiopulmonary performance was estimated by a 2-km walking test., Results: Cardiopulmonary performance declined significantly as a result of increasing age and increasing body-mass index. 44% of men and 29% of women reached substandard values when compared to norm tables. Daily ailments such as "Problems while climbing stairs" or "Breathing difficulty" showed a strong correlation to the estimated cardiopulmonary performance. In contrast, they were less influenced by strength or flexibility. The subjects were oblivious of the relationship between the decreased performance of the cardiovascular system and daily ailments., Conclusion: Performing a simple screening-battery may be a good chance to promote the participation of middle-aged and non-athletic people in an adequate and health oriented sports program.
- Published
- 2011
34. Computational electrophysiology: the molecular dynamics of ion channel permeation and selectivity in atomistic detail.
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Kutzner C, Grubmüller H, de Groot BL, and Zachariae U
- Subjects
- Drug Resistance, Microbial genetics, Electric Conductivity, Ion Channel Gating, Ions, Lipid Bilayers metabolism, Mutation genetics, Permeability, Electrophysiological Phenomena, Ion Channels metabolism, Molecular Dynamics Simulation, Neisseria meningitidis metabolism, Porins metabolism
- Abstract
Presently, most simulations of ion channel function rely upon nonatomistic Brownian dynamics calculations, indirect interpretation of energy maps, or application of external electric fields. We present a computational method to directly simulate ion flux through membrane channels based on biologically realistic electrochemical gradients. In close analogy to single-channel electrophysiology, physiologically and experimentally relevant timescales are achieved. We apply our method to the bacterial channel PorB from pathogenic Neisseria meningitidis, which, during Neisserial infection, inserts into the mitochondrial membrane of target cells and elicits apoptosis by dissipating the membrane potential. We show that our method accurately predicts ion conductance and selectivity and elucidates ion conduction mechanisms in great detail. Handles for overcoming channel-related antibiotic resistance are identified., (Copyright © 2011 Biophysical Society. Published by Elsevier Inc. All rights reserved.)
- Published
- 2011
- Full Text
- View/download PDF
35. Keep It Flexible: Driving Macromolecular Rotary Motions in Atomistic Simulations with GROMACS.
- Author
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Kutzner C, Czub J, and Grubmüller H
- Abstract
We describe a versatile method to enforce the rotation of subsets of atoms, e.g., a protein subunit, in molecular dynamics (MD) simulations. In particular, we introduce a "flexible axis" technique that allows realistic flexible adaptions of both the rotary subunit as well as the local rotation axis during the simulation. A variety of useful rotation potentials were implemented for the GROMACS 4.5 MD package. Application to the molecular motor F(1)-ATP synthase demonstrates the advantages of the flexible axis approach over the established fixed axis rotation technique.
- Published
- 2011
- Full Text
- View/download PDF
36. Caught in the act: visualization of SNARE-mediated fusion events in molecular detail.
- Author
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Risselada HJ, Kutzner C, and Grubmüller H
- Subjects
- Cell Membrane chemistry, Cell Membrane metabolism, Molecular Dynamics Simulation, Membrane Fusion, SNARE Proteins chemistry, SNARE Proteins metabolism
- Abstract
Neurotransmitter release at the synapse requires fusion of synaptic vesicles with the presynaptic plasma membrane. SNAREs are the core constituents of the protein machinery responsible for this membrane fusion, but the actual fusion mechanism remains unclear. Here, we have simulated neuronal SNARE-mediated membrane fusion in molecular detail. In our simulations, membrane fusion progresses through an inverted micelle fusion intermediate before reaching the hemifused state. We show that at least one single SNARE complex is required for fusion, as has also been confirmed in a recent in vitro single-molecule fluoresence study. Further, the transmembrane regions of the SNAREs were found to play a vital role in the initiation of fusion by causing distortions of the lipid packing of the outer membrane leaflets, and the C termini of the transmembrane regions are associated with the formation of the fusion pores. The inherent mechanical stress in the linker region of the SNARE complex was found to drive both the subsequent formation and expansion of fusion pores. Our simulations also revealed that the presence of homodimerizations between the transmembrane regions leads to the formation of unstable fusion intermediates that are under high curvature stress. We show that multiple SNARE complexes mediate membrane fusion in a cooperative and synchronized process. Finally, we show that after fusion, the zipping of the SNAREs extends into the membrane region, in agreement with the recently resolved X-ray structure of the fully assembled state., (Copyright © 2011 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)
- Published
- 2011
- Full Text
- View/download PDF
37. GROMACS 4: Algorithms for Highly Efficient, Load-Balanced, and Scalable Molecular Simulation.
- Author
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Hess B, Kutzner C, van der Spoel D, and Lindahl E
- Abstract
Molecular simulation is an extremely useful, but computationally very expensive tool for studies of chemical and biomolecular systems. Here, we present a new implementation of our molecular simulation toolkit GROMACS which now both achieves extremely high performance on single processors from algorithmic optimizations and hand-coded routines and simultaneously scales very well on parallel machines. The code encompasses a minimal-communication domain decomposition algorithm, full dynamic load balancing, a state-of-the-art parallel constraint solver, and efficient virtual site algorithms that allow removal of hydrogen atom degrees of freedom to enable integration time steps up to 5 fs for atomistic simulations also in parallel. To improve the scaling properties of the common particle mesh Ewald electrostatics algorithms, we have in addition used a Multiple-Program, Multiple-Data approach, with separate node domains responsible for direct and reciprocal space interactions. Not only does this combination of algorithms enable extremely long simulations of large systems but also it provides that simulation performance on quite modest numbers of standard cluster nodes.
- Published
- 2008
- Full Text
- View/download PDF
38. Speeding up parallel GROMACS on high-latency networks.
- Author
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Kutzner C, van der Spoel D, Fechner M, Lindahl E, Schmitt UW, de Groot BL, and Grubmüller H
- Abstract
We investigate the parallel scaling of the GROMACS molecular dynamics code on Ethernet Beowulf clusters and what prerequisites are necessary for decent scaling even on such clusters with only limited bandwidth and high latency. GROMACS 3.3 scales well on supercomputers like the IBM p690 (Regatta) and on Linux clusters with a special interconnect like Myrinet or Infiniband. Because of the high single-node performance of GROMACS, however, on the widely used Ethernet switched clusters, the scaling typically breaks down when more than two computer nodes are involved, limiting the absolute speedup that can be gained to about 3 relative to a single-CPU run. With the LAM MPI implementation, the main scaling bottleneck is here identified to be the all-to-all communication which is required every time step. During such an all-to-all communication step, a huge amount of messages floods the network, and as a result many TCP packets are lost. We show that Ethernet flow control prevents network congestion and leads to substantial scaling improvements. For 16 CPUs, e.g., a speedup of 11 has been achieved. However, for more nodes this mechanism also fails. Having optimized an all-to-all routine, which sends the data in an ordered fashion, we show that it is possible to completely prevent packet loss for any number of multi-CPU nodes. Thus, the GROMACS scaling dramatically improves, even for switches that lack flow control. In addition, for the common HP ProCurve 2848 switch we find that for optimum all-to-all performance it is essential how the nodes are connected to the switch's ports. This is also demonstrated for the example of the Car-Parinello MD code., (Copyright 2007 Wiley Periodicals, Inc.)
- Published
- 2007
- Full Text
- View/download PDF
39. Anatomy and dynamics of a supramolecular membrane protein cluster.
- Author
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Sieber JJ, Willig KI, Kutzner C, Gerding-Reimers C, Harke B, Donnert G, Rammner B, Eggeling C, Hell SW, Grubmüller H, and Lang T
- Subjects
- Amino Acid Motifs, Animals, Cell Membrane chemistry, Chemical Phenomena, Chemistry, Physical, Computer Simulation, Diffusion, Fluorescence Recovery After Photobleaching, Green Fluorescent Proteins, Immunoblotting, Microscopy, Confocal, Microscopy, Fluorescence, Models, Biological, Nanotechnology, PC12 Cells, Protein Structure, Tertiary, Rats, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins metabolism, Cell Membrane metabolism, Syntaxin 1 chemistry, Syntaxin 1 metabolism
- Abstract
Most plasmalemmal proteins organize in submicrometer-sized clusters whose architecture and dynamics are still enigmatic. With syntaxin 1 as an example, we applied a combination of far-field optical nanoscopy, biochemistry, fluorescence recovery after photobleaching (FRAP) analysis, and simulations to show that clustering can be explained by self-organization based on simple physical principles. On average, the syntaxin clusters exhibit a diameter of 50 to 60 nanometers and contain 75 densely crowded syntaxins that dynamically exchange with freely diffusing molecules. Self-association depends on weak homophilic protein-protein interactions. Simulations suggest that clustering immobilizes and conformationally constrains the molecules. Moreover, a balance between self-association and crowding-induced steric repulsions is sufficient to explain both the size and dynamics of syntaxin clusters and likely of many oligomerizing membrane proteins that form supramolecular structures.
- Published
- 2007
- Full Text
- View/download PDF
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