Your search keyword '"Bernauer, Julie"' showing total 5 results

1. GARN2: coarse-grained prediction of 3D structure of large RNA molecules by regret minimization.

Author

Boudard M, Barth D, Bernauer J, Denise A, and Cohen J

Subjects

Algorithms, RNA metabolism, Sequence Analysis, RNA methods, Computational Biology methods, Models, Molecular, Nucleic Acid Conformation, RNA chemistry, Software

Abstract

Motivation: Predicting the 3D structure of RNA molecules is a key feature towards predicting their functions. Methods which work at atomic or nucleotide level are not suitable for large molecules. In these cases, coarse-grained prediction methods aim to predict a shape which could be refined later by using more precise methods on smaller parts of the molecule., Results: We developed a complete method for sampling 3D RNA structure at a coarse-grained model, taking a secondary structure as input. One of the novelties of our method is that a second step extracts two best possible structures close to the native, from a set of possible structures. Although our method benefits from the first version of GARN, some of the main features on GARN2 are very different. GARN2 is much faster than the previous version and than the well-known methods of the state-of-art. Our experiments show that GARN2 can also provide better structures than the other state-of-the-art methods., Availability and Implementation: GARN2 is written in Java. It is freely distributed and available at http://garn.lri.fr/., Contact: melanie.boudard@lri.fr or johanne.cohen@lri.fr., Supplementary Information: Supplementary data are available at Bioinformatics online., (© The Author (2017). Published by Oxford University Press. All rights reserved. For Permissions, please email: journals.permissions@oup.com)

Published

2017

2. Elucidating Mechanisms of Molecular Recognition Between Human Argonaute and miRNA Using Computational Approaches.

Author

Jiang H, Zhu L, Héliou A, Gao X, Bernauer J, and Huang X

Subjects

Argonaute Proteins chemistry, Argonaute Proteins genetics, Humans, MicroRNAs chemistry, MicroRNAs genetics, Molecular Dynamics Simulation, Protein Binding, Protein Conformation, Argonaute Proteins antagonists & inhibitors, Computational Biology methods, Drug Delivery Systems methods, MicroRNAs antagonists & inhibitors

Abstract

MicroRNA (miRNA) and Argonaute (AGO) protein together form the RNA-induced silencing complex (RISC) that plays an essential role in the regulation of gene expression. Elucidating the underlying mechanism of AGO-miRNA recognition is thus of great importance not only for the in-depth understanding of miRNA function but also for inspiring new drugs targeting miRNAs. In this chapter we introduce a combined computational approach of molecular dynamics (MD) simulations, Markov state models (MSMs), and protein-RNA docking to investigate AGO-miRNA recognition. Constructed from MD simulations, MSMs can elucidate the conformational dynamics of AGO at biologically relevant timescales. Protein-RNA docking can then efficiently identify the AGO conformations that are geometrically accessible to miRNA. Using our recent work on human AGO2 as an example, we explain the rationale and the workflow of our method in details. This combined approach holds great promise to complement experiments in unraveling the mechanisms of molecular recognition between large, flexible, and complex biomolecules.

Published

2017

3. Evaluating mixture models for building RNA knowledge-based potentials.

Author

Sim AY, Schwander O, Levitt M, and Bernauer J

Subjects

Knowledge Bases, Models, Molecular, RNA metabolism, Computational Biology methods, RNA chemistry

Abstract

Ribonucleic acid (RNA) molecules play important roles in a variety of biological processes. To properly function, RNA molecules usually have to fold to specific structures, and therefore understanding RNA structure is vital in comprehending how RNA functions. One approach to understanding and predicting biomolecular structure is to use knowledge-based potentials built from experimentally determined structures. These types of potentials have been shown to be effective for predicting both protein and RNA structures, but their utility is limited by their significantly rugged nature. This ruggedness (and hence the potential's usefulness) depends heavily on the choice of bin width to sort structural information (e.g. distances) but the appropriate bin width is not known a priori. To circumvent the binning problem, we compared knowledge-based potentials built from inter-atomic distances in RNA structures using different mixture models (Kernel Density Estimation, Expectation Minimization and Dirichlet Process). We show that the smooth knowledge-based potential built from Dirichlet process is successful in selecting native-like RNA models from different sets of structural decoys with comparable efficacy to a potential developed by spline-fitting - a commonly taken approach - to binned distance histograms. The less rugged nature of our potential suggests its applicability in diverse types of structural modeling.

Published

2012

4. ESBTL: efficient PDB parser and data structure for the structural and geometric analysis of biological macromolecules.

Author

Loriot S, Cazals F, and Bernauer J

Subjects

Proteins chemistry, Computational Biology methods, Databases, Protein, Software

Abstract

Unlabelled: The ever increasing number of structural biological data calls for robust and efficient software for analysis. Easy Structural Biology Template Library (ESBTL) is a lightweight C++ library that allows the handling of PDB data and provides a data structure suitable for geometric constructions and analyses. The parser and data model provided by this ready-to-use include-only library allows adequate treatment of usually discarded information (insertion code, atom occupancy, etc.) while still being able to detect badly formatted files. The template-based structure allows rapid design of new computational structural biology applications and is fully compatible with the new remediated PDB archive format. It also allows the code to be easy-to-use while being versatile enough to allow advanced user developments., Availability: ESBTL is freely available under the GNU General Public License from http://esbtl.sf.net. The web site provides the source code, examples, code snippets and documentation.

Published

2010

5. Protein-RNA Complexes and Efficient Automatic Docking: Expanding RosettaDock Possibilities.

Author

Guilhot-Gaudeffroy, Adrien, Froidevaux, Christine, Azé, Jérôme, and Bernauer, Julie

Subjects

RNA-protein interactions, MOLECULAR docking, PROTEIN structure, GENETIC algorithms, MOLECULAR biology, ARTIFICIAL intelligence

Abstract

Protein-RNA complexes provide a wide range of essential functions in the cell. Their atomic experimental structure solving, despite essential to the understanding of these functions, is often difficult and expensive. Docking approaches that have been developed for proteins are often challenging to adapt for RNA because of its inherent flexibility and the structural data available being relatively scarce. In this study we adapted the RosettaDock protocol for protein-RNA complexes both at the nucleotide and atomic levels. Using a genetic algorithm-based strategy, and a non-redundant protein-RNA dataset, we derived a RosettaDock scoring scheme able not only to discriminate but also score efficiently docking decoys. The approach proved to be both efficient and robust for generating and identifying suitable structures when applied to two protein-RNA docking benchmarks in both bound and unbound settings. It also compares well to existing strategies. This is the first approach that currently offers a multi-level optimized scoring approach integrated in a full docking suite, leading the way to adaptive fully flexible strategies. [ABSTRACT FROM AUTHOR]

Published

2014