@article {2021|2147, title = {Mechanistic Insights on Heme-to-Heme Transmembrane Electron Transfer Within NADPH Oxydases From Atomistic Simulations.}, journal = {Front Chem}, volume = {9}, year = {2021}, month = {2021}, pages = {650651}, abstract = {

NOX5 is a member of the NADPH oxidase family which is dedicated to the production of reactive oxygen species. The molecular mechanisms governing transmembrane electron transfer (ET) that permits to shuttle electrons over the biological membrane have remained elusive for a long time. Using computer simulations, we report conformational dynamics of NOX5 embedded within a realistic membrane environment. We assess the stability of the protein within the membrane and monitor the existence of cavities that could accommodate dioxygen molecules. We investigate the heme-to-heme electron transfer. We find a reaction free energy of a few tenths of eV (ca. -0.3 eV) and a reorganization free energy of around 1.1 eV (0.8 eV after including electrostatic induction corrections). The former indicates thermodynamically favorable ET, while the latter falls in the expected values for transmembrane inter-heme ET. We estimate the electronic coupling to fall in the range of the μeV. We identify electron tunneling pathways showing that not only the W378 residue is playing a central role, but also F348. Finally, we reveal the existence of two connected Obinding pockets near the outer heme with fast exchange between the two sites on the nanosecond timescale. We show that when the terminal heme is reduced, O binds closer to it, affording a more efficient tunneling pathway than when the terminal heme is oxidized, thereby providing an efficient mechanism to catalyze superoxide production in the final step. Overall, our study reveals some key molecular mechanisms permitting reactive oxygen species production by NOX5 and paves the road for further investigation of ET processes in the wide family of NADPH oxidases by computer simulations.

}, issn = {2296-2646}, doi = {10.3389/fchem.2021.650651}, author = {Wu, Xiaojing and J{\'e}r{\^o}me H{\'e}nin and Baciou, Laura and Marc Baaden and Cailliez, Fabien and de la Lande, Aur{\'e}lien} } @article {2019|2122, title = {Modelling lipid systems in fluid with Lattice Boltzmann Molecular Dynamics simulations and hydrodynamics}, journal = {Scientific Reports}, volume = {9}, year = {2019}, pages = {16450}, abstract = {

In this work we present the coupling between Dry Martini, an efficient implicit solvent coarse-grained model for lipids, and the Lattice Boltzmann Molecular Dynamics (LBMD) simulation technique in order to include naturally hydrodynamic interactions in implicit solvent simulations of lipid systems. After validating the implementation of the model, we explored several systems where the action of a perturbing fluid plays an important role. Namely, we investigated the role of an external shear flow on the dynamics of a vesicle, the dynamics of substrate release under shear, and inquired the dynamics of proteins and substrates confined inside the core of a vesicle. Our methodology enables future exploration of a large variety of biological entities and processes involving lipid systems at the mesoscopic scale where hydrodynamics plays an essential role, e.g. by modulating the migration of proteins in the proximity of membranes, the dynamics of vesicle-based drug delivery systems, or, more generally, the behaviour of proteins in cellular compartments.

}, isbn = {2045-2322}, doi = {10.1038/s41598-019-52760-y}, url = {https://doi.org/10.1038/s41598-019-52760-y}, author = {F. Brandner, Astrid and Timr, Stepan and Melchionna, Simone and Philippe Derreumaux and Marc Baaden and Sterpone, Fabio} } @article {2019|2079, title = {Molecular Graphics: Bridging Structural Biologists and Computer Scientists.}, journal = {Structure}, volume = {27}, year = {2019}, month = {2019 11 05}, pages = {1617-1623}, abstract = {

Visualization of molecular structures is one of the most common tasks carried out by structural biologists, typically using software, such as Chimera, COOT, PyMOL, or VMD. In this Perspective article, we outline how past developments in computer graphics and data visualization have expanded the understanding of biomolecular function, and we summarize recent advances that promise to further transform structural biology. We also highlight how progress in molecular graphics has been impeded by communication barriers between two communities: the computer scientists driving these advances, and the structural and computational biologists who stand to benefit. By pointing to canonical papers and explaining technical progress underlying new graphical developments in simple terms, we aim to improve communication between these communities; this, in turn, would help shape future developments in molecular graphics.

}, issn = {1878-4186}, doi = {10.1016/j.str.2019.09.001}, author = {Martinez, Xavier and Krone, Michael and Alharbi, Naif and Rose, Alexander S and Laramee, Robert S and O{\textquoteright}Donoghue, Sean and Marc Baaden and Chavent, Matthieu} } @article {2019|2068, title = {Molecular modelling as the spark for active learning approaches for interdisciplinary biology teaching}, journal = {Interface focus}, volume = {9}, year = {2019}, pages = {20180065}, author = {Antoine Taly and Nitti, Francesco and Marc Baaden and Pasquali, S} } @article {2019|2073, title = {A molecular perspective on mitochondrial membrane fusion: from the key players to oligomerization and tethering of mitofusin}, journal = {The Journal of membrane biology}, volume = {252}, year = {2019}, pages = {293{\textendash}306}, author = {De Vecchis, Dario and Brandner, Astrid and Marc Baaden and Cohen, Micka{\"e}l M and Antoine Taly} } @article {2018|2087, title = {The major β-catenin/E-cadherin junctional binding site is a primary molecular mechano-transductor of differentiation .}, journal = {Elife}, volume = {7}, year = {2018}, month = {2018 07 19}, abstract = {

, the primary molecular mechanotransductive events mechanically initiating cell differentiation remain unknown. Here we find the molecular stretching of the highly conserved Y654-β-catenin-D665-E-cadherin binding site as mechanically induced by tissue strain. It triggers the increase of accessibility of the Y654 site, target of the Src42A kinase phosphorylation leading to irreversible unbinding. Molecular dynamics simulations of the β-catenin/E-cadherin complex under a force mimicking a 6 pN physiological mechanical strain predict a local 45\% stretching between the two α-helices linked by the site and a 15\% increase in accessibility of the phosphorylation site. Both are quantitatively observed using FRET lifetime imaging and non-phospho Y654 specific antibody labelling, in response to the mechanical strains developed by endogenous and magnetically mimicked early mesoderm invagination of gastrulating embryos. This is followed by the predicted release of 16\% of β-catenin from junctions, observed in FRAP, which initiates the mechanical activation of the β-catenin pathway process.

}, keywords = {Amino Acid Sequence, Animals, Armadillo Domain Proteins, Binding Sites, Cadherins, Cell Differentiation, Drosophila melanogaster, Drosophila Proteins, Fluorescence Resonance Energy Transfer, Mechanotransduction, Cellular, Molecular Dynamics Simulation, Phosphorylation, Protein Binding, Protein Conformation, Proto-Oncogene Proteins pp60(c-src), Sequence Homology, Transcription Factors}, issn = {2050-084X}, doi = {10.7554/eLife.33381}, author = {R{\"o}per, Jens-Christian and Mitrossilis, D{\'e}mosth{\`e}ne and Guillaume Stirnemann and Waharte, Fran{\c c}ois and Brito, Isabel and Fernandez-Sanchez, Maria-Elena and Marc Baaden and Salamero, Jean and Farge, Emmanuel} } @article {2018|2091, title = {MinOmics, an Integrative and Immersive Tool for Multi-Omics Analysis.}, journal = {J Integr Bioinform}, volume = {15}, year = {2018}, month = {2018 Jun 21}, abstract = {

Proteomic and transcriptomic technologies resulted in massive biological datasets, their interpretation requiring sophisticated computational strategies. Efficient and intuitive real-time analysis remains challenging. We use proteomic data on 1417 proteins of the green microalga Chlamydomonas reinhardtii to investigate physicochemical parameters governing selectivity of three cysteine-based redox post translational modifications (PTM): glutathionylation (SSG), nitrosylation (SNO) and disulphide bonds (SS) reduced by thioredoxins. We aim to understand underlying molecular mechanisms and structural determinants through integration of redox proteome data from gene- to structural level. Our interactive visual analytics approach on an 8.3 m2 display wall of 25 MPixel resolution features stereoscopic three dimensions (3D) representation performed by UnityMol WebGL. Virtual reality headsets complement the range of usage configurations for fully immersive tasks. Our experiments confirm that fast access to a rich cross-linked database is necessary for immersive analysis of structural data. We emphasize the possibility to display complex data structures and relationships in 3D, intrinsic to molecular structure visualization, but less common for omics-network analysis. Our setup is powered by MinOmics, an integrated analysis pipeline and visualization framework dedicated to multi-omics analysis. MinOmics integrates data from various sources into a materialized physical repository. We evaluate its performance, a design criterion for the framework.

}, keywords = {Algal Proteins, Chlamydomonas reinhardtii, Computer Graphics, Imaging, Three-Dimensional, Models, Structural, Oxidation-Reduction, Protein Conformation, Protein Interaction Maps, Protein Processing, Post-Translational, Proteome, Proteomics, Software, Virtual Reality}, issn = {1613-4516}, doi = {10.1515/jib-2018-0006}, author = {Maes, Alexandre and Martinez, Xavier and Druart, Karen and Laurent, Benoist and Gu{\'e}gan, Sean and Marchand, Christophe H and Lemaire, St{\'e}phane D and Marc Baaden} } @inbook {2018|2084, title = {The modelling and enhancement of water hydrodynamics: general discussion.}, booktitle = {Faraday Discuss}, volume = {209}, year = {2018}, month = {2018 09 28}, pages = {273-285}, issn = {1364-5498}, doi = {10.1039/c8fd90021c}, author = {Marc Baaden and Borthakur, Manash Pratim and Casanova, Serena and Coalson, Rob and Freger, Viatcheslav and Gonzalez, Miguel and G{\'o}ra, Artur and Hinds, Bruce and Hirunpinyopas, Wisit and Hummer, Gerhard and Kumar, Manish and Lynch, Charlotte and Murail, Samuel and Noy, Aleksandr and Sansom, Mark and Song, Qilei and Vashisth, Harish and V{\"o}gele, Martin} } @article {2017|2021, title = {A membrane-inserted structural model of the yeast mitofusin Fzo1}, journal = {Sci Rep}, volume = {7}, year = {2017}, month = {2017 Aug 31}, pages = {10217}, type = {Research Article}, abstract = {

Mitofusins are large transmembrane GTPases of the dynamin-related protein family, and are required for the tethering and fusion of mitochondrial outer membranes. Their full-length structures remain unknown, which is a limiting factor in the study of outer membrane fusion. We investigated the structure and dynamics of the yeast mitofusin Fzo1 through a hybrid computational and experimental approach, combining molecular modelling and all-atom molecular dynamics simulations in a lipid bilayer with site-directed mutagenesis and in vivo functional assays. The predicted architecture of Fzo1 improves upon the current domain annotation, with a precise description of the helical spans linked by flexible hinges, which are likely of functional significance. In vivo site-directed mutagenesis validates salient aspects of this model, notably, the long-distance contacts and residues participating in hinges. GDP is predicted to interact with Fzo1 through the G1 and G4 motifs of the GTPase domain. The model reveals structural determinants critical for protein function, including regions that may be involved in GTPase domain-dependent rearrangements.

}, issn = {2045-2322}, doi = {10.1038/s41598-017-10687-2}, author = {De Vecchis, Dario and Cavellini, Laetitia and Marc Baaden and J{\'e}r{\^o}me H{\'e}nin and Cohen, Micka{\"e}l M and Antoine Taly} } @conference {2017|2101, title = {Molecular Visualization of Computational Biology Data: A Survey of Surveys}, booktitle = {EuroVis 2017 - Short Papers}, year = {2017}, publisher = {The Eurographics Association}, organization = {The Eurographics Association}, isbn = {978-3-03868-043-7}, doi = {10.2312/eurovisshort.20171146}, author = {Alharbi, Naif and Alharbi, Mohammad and Martinez, Xavier and Krone, Michael and Rose, Alexander S. and Marc Baaden and Laramee, Robert S. and Chavent, Matthieu}, editor = {Barbora Kozlikova and Tobias Schreck and Thomas Wischgoll} } @article {2017|2029, title = {Multi-scale simulations of biological systems using the OPEP coarse-grained model.}, journal = {Biochem Biophys Res Commun}, year = {2017}, month = {2017 Sep 14}, abstract = {

Biomolecules are complex machines that are optimized by evolution to properly fulfill or contribute to a variety of biochemical tasks in the cellular environment. Computer simulations based on quantum mechanics and atomistic force fields have been proven to be a powerful microscope for obtaining valuable insights into many biological, physical, and chemical processes. Many interesting phenomena involve, however, a time scale and a number of degrees of freedom, notably if crowding is considered, that cannot be explored at an atomistic resolution. To bridge the gap between reality and simulation, many different advanced computational techniques and coarse-grained (CG) models have been developed. Here, we report some applications of the CG OPEP protein model to amyloid fibril formation, the response of catch-bond proteins to two types of fluid flow, and interactive simulations to fold peptides with well-defined 3D structures or with intrinsic disorder.

}, issn = {1090-2104}, doi = {10.1016/j.bbrc.2017.08.165}, author = {Sterpone, Fabio and Doutreligne, S{\'e}bastien and Tran, Thanh Thuy and Melchionna, Simone and Marc Baaden and Phuong Hoang Nguyen and Philippe Derreumaux} } @article {2014|1413, title = {{M}olecular simulations and visualization: introduction and overview}, journal = {Faraday Discuss.}, volume = {169}, year = {2014}, note = {[DOI:\href{http://dx.doi.org/10.1039/c4fd90024c}{10.1039/c4fd90024c}] [PubMed:\href{http://www.ncbi.nlm.nih.gov/pubmed/25285906}{25285906}]}, pages = {9{\textendash}22}, author = {Hirst, J. D. and Glowacki, D. R. and Marc Baaden} } @article {2014|2015, title = {Multiscale Simulations Give Insight into the Hydrogen In and Out Pathways of [NiFe]-Hydrogenases from Aquifex aeolicus and Desulfovibrio fructosovorans}, journal = {J. Phys. Chem. B}, volume = {118}, number = {48}, year = {2014}, month = {dec}, pages = {13800{\textendash}13811}, doi = {10.1021/jp5089965}, author = {Oteri, F and Marc Baaden and Lojou, E and S Sacquin-Mora} } @article {2013|1426, title = {MANHaptic: A Haptic Adaptive Method for Precise Manipulation, Assembly \and Navigation}, journal = {International Journal on Human Machine Interaction}, volume = {1}, year = {2013}, pages = {60{\textendash}67}, author = {A. Tek and Marc Baaden and Nicolas F{\'e}rey and P. Bourdot} } @article {2012|1458, title = {Mixing atomistic and coarse grain solvation models for MD simulations: let WT4 handle the bulk}, journal = {Jctc}, year = {2012}, month = {jun}, doi = {10.1021/ct3001816}, author = {L. Darre and A. Tek and Marc Baaden and S. Pantano} } @article {2012|1546, title = {Modeling complex biological systems: From solution chemistry to membranes and channels}, journal = {Pure Appl. Chem.}, volume = {ASAP}, year = {2012}, month = {nov}, doi = {10.1351/PAC-CON-12-04-10}, author = {B. Laurent and S. Murail and F. Da Silva and P.-J. Corringer and Marc Baaden} } @article {2010|1512, title = {{M}odeling the early stage of {D}{N}{A} sequence recognition within {R}ec{A} nucleoprotein filaments}, journal = {Nucleic Acids Res.}, volume = {38}, year = {2010}, month = {oct}, pages = {6313{\textendash}6323}, author = {A Saladin and Amourda, C. and Poulain, P. and Nicolas F{\'e}rey and Marc Baaden and Martin Zacharias and Delalande, O. and Chantal Pr{\'e}vost} } @article {2010|1516, title = {{M}ulti-resolution approach for interactively locating functionally linked ion binding sites by steering small molecules into electrostatic potential maps using a haptic device}, journal = {Pac. Symp. Biocomput.}, year = {2010}, pages = {205{\textendash}215}, author = {Delalande, O. and Nicolas F{\'e}rey and Laurent, B. and Gueroult, M. and Hartmann, B. and Marc Baaden} } @inbook {2010|1569, title = {Molecular dynamics studies of outer membrane proteins : a story of barrels}, year = {2010}, pages = {225{\textendash}247}, publisher = {Royal Society of Chemistry}, organization = {Royal Society of Chemistry}, chapter = {Molecular Simulations and Biomembranes: From Biophysics to Function}, address = {United Kingdom}, author = {S. Khalid and Marc Baaden}, editor = {P.C. Biggin and M.S.P. Sansom} } @article {2008|1390, title = {Microseconds dynamics simulations of the outer-membrane protease T}, journal = {Biophys. J.}, volume = {94}, number = {1}, year = {2008}, month = {jan}, pages = {71{\textendash}78}, author = {Neri, Marilisa and Marc Baaden and Carnevale, Vincenzo and Anselmi, Claudio and Maritan, Amos and Carloni, Paolo} } @article {2005|1476, title = {Membrane protein structure quality in molecular dynamics simulation}, journal = {Journal of Molecular Graphics \& Modelling}, volume = {24}, number = {2}, year = {2005}, note = {International Meeting of the Molecular-Graphics-and-Modelling-Society, Manchester, ENGLAND, 2004}, month = {oct}, pages = {157{\textendash}165}, author = {Law, RJ and Capener, C and Marc Baaden and Bond, PJ and Campbell, J and Patargias, G and Arinaminpathy, Y and Sansom, MSP} } @article {2003|1475, title = {A molecular dynamics investigation of mono and dimeric states of the outer membrane enzyme OMPLA}, journal = {J. Mol. Biol.}, volume = {331}, number = {1}, year = {2003}, month = {aug}, pages = {177{\textendash}189}, author = {Marc Baaden and Meier, C and Sansom, MSP} } @article {2002|1483, title = {Molecular dynamics study of the uranyl extraction by tri-n-butylphosphate (TBP): Demixing of water/{{\textquoteright}{\textquoteright}}oil{{\textquoteright}{\textquoteright}}/TBP solutions with a comparison of supercritical CO2 and chloroform}, journal = {J. Phys. Chem. B}, volume = {106}, number = {2}, year = {2002}, month = {jan}, pages = {434{\textendash}441}, author = {Marc Baaden and Schurhammer, R and Wipff, G} } @article {2000|1481, title = {M3+ lanthanide cation solvation by acetonitrile: The role of cation size, counterions, and polarization effects investigated by molecular dynamics and quantum mechanical simulations}, journal = {J. Phys. Chem. A}, volume = {104}, number = {32}, year = {2000}, month = {aug}, pages = {7659{\textendash}7671}, author = {Marc Baaden and Berny, F and Madic, C and Wipff, G} } @booklet {1999|1558, title = {Molecular Modeling with the ChemOffice Ultra 4.5 program suite.}, year = {1999}, author = {Marc Baaden} }