Visualizing Biological Membrane Organization and Dynamics

International audienc

How Cations Can Assist DNase I in DNA Binding and Hydrolysis

DNase I requires Ca2+ and Mg2+ for hydrolyzing double-stranded DNA. However, the number and the location of DNase I ion-binding sites remain unclear, as well as the role of these counter-ions. Using molecular dynamics simulations, we show that bovine pancreatic (bp) DNase I contains four ion-binding pockets. Two of them strongly bind Ca2+ while the other two sites coordinate Mg2+. These theoretical results are strongly supported by revisiting crystallographic structures that contain bpDNase I. One Ca2+ stabilizes the functional DNase I structure. The presence of Mg2+ in close vicinity to the catalytic pocket of bpDNase I reinforces the idea of a cation-assisted hydrolytic mechanism. Importantly, Poisson-Boltzmann-type electrostatic potential calculations demonstrate that the divalent cations collectively control the electrostatic fit between bpDNase I and DNA. These results improve our understanding of the essential role of cations in the biological function of bpDNase I. The high degree of conservation of the amino acids involved in the identified cation-binding sites across DNase I and DNase I-like proteins from various species suggests that our findings generally apply to all DNase I-DNA interactions

ExaViz: a Flexible Framework to Analyse, Steer and Interact with Molecular Dynamics Simulations

International audienceThe amount of data generated by molecular dynamics simulations of large molecular assemblies and the sheer size and complexity of the systems studied call for new ways to analyse, steer and interact with such calculations. Traditionally, the analysis is performed off-line once the huge amount of simulation results have been saved to disks, thereby stressing the supercomputer I/O systems, and making it increasingly difficult to handle post-processing and analysis from the scientist's office. The ExaViz framework is an alternative approach developed to couple the simulation with analysis tools to process the data as close as possible to their source of creation, saving a reduced, more manageable and pre-processed data set to disk. ExaViz supports a large variety of analysis and steering scenarios. Our framework can be used for live sessions (simulations short enough to be fully followed by the user) as well as batch sessions (long time batch executions). During interactive sessions, at run time, the user can display plots from analysis, visualise the molecular system and steer the simulation with a haptic device. We also emphasise how a Cave-like immersive environment could be used to leverage such simulations, offering a large display surface to view and intuitively navigate the molecular system

Lessons learned from urgent computing in Europe: Tackling the COVID-19 pandemic

PRACE (Partnership for Advanced Computing in Europe), an international not-for-profit association that brings together the five largest European supercomputing centers and involves 26 European countries, has allocated more than half a billion core hours to computer simulations to fight the COVID-19 pandemic. Alongside experiments, these simulations are a pillar of research to assess the risks of different scenarios and investigate mitigation strategies. While the world deals with the subsequent waves of the pandemic, we present a reflection on the use of urgent supercomputing for global societal challenges and crisis management.Peer Reviewed"Article signat per 18 autors/es: Núria López, Luigi Del Debbio, Marc Baaden, Matej Praprotnik, Laura Grigori, Catarina Simões, Serge Bogaerts, Florian Berberich, Thomas Lippert, Janne Ignatius, Philippe Lavocat, Oriol Pineda, Maria Grazia Giuffreda, Sergi Girona, Dieter Kranzlmüller, Michael M. Resch, Gabriella Scipione, and Thomas Schulthess"Postprint (author's final draft

Advances in Human-Protein Interaction - Interactive and Immersive Molecular Simulations

International audienc

10 simple rules to create a serious game, illustrated with examples from structural biology

Serious scientific games are games whose purpose is not only fun. In the field of science, the serious goals include crucial activities for scientists: outreach, teaching and research. The number of serious games is increasing rapidly, in particular citizen science games, games that allow people to produce and/or analyze scientific data. Interestingly, it is possible to build a set of rules providing a guideline to create or improve serious games. We present arguments gathered from our own experience ( Phylo , DocMolecules , HiRE-RNA contest and Pangu) as well as examples from the growing literature on scientific serious games

Modeling the early stage of DNA sequence recognition within RecA nucleoprotein filaments

Homologous recombination is a fundamental process enabling the repair of double-strand breaks with a high degree of fidelity. In prokaryotes, it is carried out by RecA nucleofilaments formed on single-stranded DNA (ssDNA). These filaments incorporate genomic sequences that are homologous to the ssDNA and exchange the homologous strands. Due to the highly dynamic character of this process and its rapid propagation along the filament, the sequence recognition and strand exchange mechanism remains unknown at the structural level. The recently published structure of the RecA/DNA filament active for recombination (Chen et al., Mechanism of homologous recombination from the RecA-ssDNA/dsDNA structure, Nature 2008, 453, 489) provides a starting point for new exploration of the system. Here, we investigate the possible geometries of association of the early encounter complex between RecA/ssDNA filament and double-stranded DNA (dsDNA). Due to the huge size of the system and its dense packing, we use a reduced representation for protein and DNA together with state-of-the-art molecular modeling methods, including systematic docking and virtual reality simulations. The results indicate that it is possible for the double-stranded DNA to access the RecA-bound ssDNA while initially retaining its Watson–Crick pairing. They emphasize the importance of RecA L2 loop mobility for both recognition and strand exchange

Molecular simulations and visualization: introduction and overview

Here we provide an introduction and overview of current progress in the field of molecular simulation and visualization, touching on the following topics: (1) virtual and augmented reality for immersive molecular simulations; (2) advanced visualization and visual analytic techniques; (3) new developments in high performance computing; and (4) applications and model building

Simulations numériques de systèmes biologiques complexes : dynamique, structure et fonction de transporteurs, canaux et enzymes

version du 2/12/2010The main motivation of my research is to combine experimental and theoretical approaches in the field of physical chemistry in order to achieve a better understanding of phenomena at the atomic scale. My current work concerns systems of biological interest related to membrane processes and phenomena accessible by nanomanipulation methods. Fundamental biophysical and biochemical questions are at the heart of my research. I carried out complex simulations of membrane proteins in a lipid bilayer that have proven very complementary and insightful with respect to experimental studies in structural biology. A recent collaboration based on this complementarity has lead to a publication in Nature in early 2009. [[i]] My recent work also focuses on the development of approaches combining virtual reality and molecular simulations. [[ii]] The biological systems studied present a physico-chemical, biological and medical interest and can comprise a large number of atoms. In parallel, I lead very fundamental work on simulation methods and novel approaches. ----------------------- [[i]] N. Bocquet, H. Nury, M. Baaden, C. Le Poupon, J.P. Changeux, M. Delarue et P.J. Corringer: "X-ray structure of a pentameric ligand-gated ion channel in an apparently open conformation", 2009, Nature, 457, 111-114. [[ii]] O. Delalande, N. Férey, G. Grasseau et M. Baaden : "Complex Molecular Assemblies at hand via Interactive Simulations", 2009, J. Comput. Chem., 30, 2009, 2375-2387.La motivation première de mes travaux de recherche est de combiner des approches expérimentales et théoriques dans le domaine de la chimie physique pour atteindre une meilleure compréhension des phénomènes à l'échelle atomique. Mes travaux en cours traitent de systèmes d'intérêt biologique concernant les processus membranaires et des phénomènes accessibles par des méthodes de nanomanipulation. Les problèmes de la biophysique et biochimie sont au c?ur de mes recherches. J'ai effectué des simulations complexes de protéines membranaires dans une bicouche lipidique qui se sont montrées tout à fait complémentaires et révélatrices par rapport aux études expérimentales de biologie structurale. Une récente collaboration exploitant cette complémentarité a donné lieu à une publication dans la revue Nature en début 2009. [[i]] Les travaux récents visent à développer des approches combinant la réalité virtuelle avec les simulations moléculaires. [[ii]] Les systèmes biologiques étudiés présentent à la fois un intérêt physico-chimique, biologique et médical et peuvent atteindre un grand nombre d'atomes. En parallèle, je mène un travail de fond sur les méthodes de simulation et des approches novatrices. ----------------------- [[i]] N. Bocquet, H. Nury, M. Baaden, C. Le Poupon, J.P. Changeux, M. Delarue et P.J. Corringer: "X-ray structure of a pentameric ligand-gated ion channel in an apparently open conformation", 2009, Nature, 457, 111-114. [[ii]] O. Delalande, N. Férey, G. Grasseau et M. Baaden : "Complex Molecular Assemblies at hand via Interactive Simulations", 2009, J. Comput. Chem., 30, 2009, 2375-2387