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Physical modeling of active bacterial DNA segregation
Auteur(s): Walter J.-C.
(Séminaires)
TIMC-IMAG (Grenoble, FR), 2015-11-15 |
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Physical modeling of active bacterial DNA segregation
Auteur(s): Walter J.-C.
(Séminaires)
Lewis-Sigler Institute for Integrative Genomics (Princeton, US), 2015-10-15 |
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Stochastic self-assembly of ParB proteins at centromeres builds bacterial DNA segregation apparatus
Auteur(s): Walter J.-C.
Conference: Quantitative Methods in Gene Regulation III (Cambridge,, GB, 2015-12-15)
Texte intégral en Openaccess :
Ref HAL: hal-01931274_v1
Exporter : BibTex | endNote
Résumé: Genome processing relies on the intracellular localization and dynamic assembly of higher-order nucleoprotein complexes. In bacteria, the mechanism of assembly for the most widespread partition systems, ParABS, responsible for active DNA segregation remains elusive. We have combined super-resolution, genome-wide, biochemical and modeling approaches to investigate quantitatively the formation of the nucleoprotein complex organized around the centromere-like sequences, parS. We found that the active confinement of nearly all ParB proteins around parS, observed at the single molecule resolution, relies on a network of synergistic interactions involving protein-protein and protein-DNA interactions. Our physico-mathematical modeling of ParB binding pattern revealed that ParB binds stochastically in the vicinity of parS over long distances. Based on our findings, and consistent with previous data, we propose a new model that relies on a nucleation and looping mechanism leading to the formation of a dynamic lattice for the partition complex assembly. We thus provide new bases to model the DNA segregation process. Our original assembly model may also apply to many unrelated proteins that self-assemble in superstructures through nucleation centers.
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Stochastic Self-Assembly of ParB Proteins Builds the Bacterial DNA Segregation Apparatus
Auteur(s): Sanchez Aurore, Cattoni Diego, Walter J.-C., Rech Jérôme, Parmeggiani A., Nollmann Marcelo, Bouet Jean-Yves
(Article) Publié:
Cell Systems, vol. 1 p.163-173 (2015)
Texte intégral en Openaccess :
Ref HAL: hal-01191677_v1
DOI: 10.1016/j.cels.2015.07.013
WoS: 000209925700010
Exporter : BibTex | endNote
60 Citations
Résumé: Many canonical processes in molecular biology rely on the dynamic assembly of higher-order nucleoprotein complexes. In bacteria, the assembly mechanism of ParABS, the nucleoprotein super-complex that actively segregates the bacterial chromosome and many plasmids, remains elusive. We combined super-resolution microscopy, quantitative genome-wide surveys, biochemistry, and mathematical modeling to investigate the assembly of ParB at the centromere-like sequences parS. We found that nearly all ParB molecules are actively confined around parS by a network of synergistic protein-protein and protein-DNA interactions. Interrogation of the empirically determined, high-resolution ParB genomic distribution with modeling suggests that instead of binding only to specific sequences and subsequently spreading, ParB binds stochastically around parS over long distances. We propose a new model for the formation of the ParABS partition complex based on nucleation and caging: ParB forms a dynamic lattice with the DNA around parS.This assembly model and approach to characterizing large-scale, dynamic interactions between macro-molecules may be generalizable to many unrelated machineries that self-assemble in superstructures.
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An introduction to Monte Carlo methods
Auteur(s): Walter J.-C., Barkema Gerard
(Article) Publié:
Physica A: Statistical Mechanics And Its Applications, vol. 418 p.78-87 (2015)
Texte intégral en Openaccess :
Ref HAL: hal-01052694_v1
Ref Arxiv: 1404.0209
DOI: 10.1016/j.physa.2014.06.014
WoS: 000346213300006
Ref. & Cit.: NASA ADS
Exporter : BibTex | endNote
41 Citations
Résumé: Monte Carlo simulations are methods for simulating statistical systems. The aim is to generate a representative ensemble of configurations to access thermodynamical quantities without the need to solve the system analytically or to perform an exact enumeration. The main principles of Monte Carlo simulations are ergodicity and detailed balance. The Ising model is a lattice spin system with nearest neighbor interactions that is appropriate to illustrate different examples of Monte Carlo simulations. It displays a second order phase transition between a disordered (high temperature) and ordered (low temperature) phases, leading to different strategies of simulations. The Metropolis algorithm and the Glauber dynamics are efficient at high temperature. Close to the critical temperature, where the spins display long range correlations, cluster algorithms are more efficient. We introduce the rejection free (or continuous time) algorithm and describe in details an interesting alternative representation of the Ising model using graphs instead of spins with the Worm algorithm. We conclude with an important discussion of the dynamical effects such as thermalization and correlation time.
Commentaires: 19 pages, 6 figures, to appear in Physica A
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Architecture of a bacterial DNA segregation apparatus: active caging of ParB by stochastic self-assembly nucleated from the centromere
Auteur(s): Walter J.-C.
Conference: Advanced Workshop on Interdisciplinary Views in Chromosome Structure and Function (Trieste, IT, 2014-09-15)
Texte intégral en Openaccess :
Ref HAL: hal-02025129_v1
Exporter : BibTex | endNote
Résumé: Many canonical processes in molecular biology rely on the dynamic assembly of higher-order nucleoprotein complexes. In bacteria, the assembly mechanism of ParABS, the nucleoprotein super-complex that actively segregates the bacterial chromosome and many plasmids, remains elusive. We combined super-resolution microscopy, quantitative genome-wide surveys, biochemistry, and mathematical modeling to investigate the assembly of ParB at the centromere-like sequences parS. We found that nearly all ParB molecules are actively confined around parS by a network of synergistic protein-protein and protein-DNA interactions. Interrogation of the empirically determined, high-resolution ParB genomic distribution with modeling suggests that instead of binding only to specific sequences and subsequently spreading, ParB binds stochastically around parS over long distances. We propose a new model for the formation of the ParABS partition complex based on nucleation and caging: ParB forms a dynamic lattice with the DNA around parS. This assembly model and approach to characterizing large-scale, dynamic interactions between macromolecules may be generalizable to many unrelated machineries that self-assemble in superstructures.
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