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Physical modeling of active bacterial DNA segregation
Auteur(s): Walter J.-C.
Conference: Biophychrom16: The Biology and Physics of Bacterial Chromosome Organisation (Paris, Collège de France, FR, 2016-09-15)
Texte intégral en Openaccess :
Ref HAL: hal-01931243_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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Physical modeling of active bacterial DNA segregation
Auteur(s): Walter J.-C.
Conférence invité: iPoLS Network Annual Meeting (Harvard, US, 2016-07-24)
Texte intégral en Openaccess :
Ref HAL: hal-01881332_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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Physical modeling of active bacterial DNA segregation
Auteur(s): Walter J.-C.
Conférence invité: Mesoscopic Modeling in Physics of Molecular and Cell Biology (Toulouse, FR, 2016-10-10)
Texte intégral en Openaccess :
Ref HAL: hal-01881271_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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Torque-Induced Rotational Dynamics in Polymers: Torsional Blobs and Thinning
Auteur(s): Laleman Michiel, Baiesi Marco, Belotserkovskii Boris P., Sakaue Takahiro, Walter J.-C., Carlon Enrico
(Article) Publié:
Macromolecules, vol. 2016 p.405-414 (2016)
Texte intégral en Openaccess :
Ref HAL: hal-01254327_v1
Ref Arxiv: 1602.00551
DOI: 10.1021/acs.macromol.5b01481
WoS: 000368322000045
Ref. & Cit.: NASA ADS
Exporter : BibTex | endNote
4 Citations
Résumé: By using the blob theory and computer simulations, we investigate the properties of a linear polymer performing a stationary rotational motion around a long impenetrable rod. In particular, in the simulations the rotation is induced by a torque applied to the end of the polymer that is tethered to the rod. Three different regimes are found, in close analogy with the case of polymers pulled by a constant force at one end. For low torques the polymer rotates maintaining its equilibrium conformation. At intermediate torques the polymer assumes a trumpet shape, being composed by blobs of increasing size. At even larger torques the polymer is partially wrapped around the rod. We derive several scaling relations between various quantities as angular velocity, elongation and torque. The analytical predictions match the simulation data well. Interestingly, we find a "thinning" regime where the torque has a very weak (logarithmic) dependence on the angular velocity. We discuss the origin of this behavior, which has no counterpart in polymers pulled by an applied force.
Commentaires: 30 pages, 8 figures, 1 TOC figure; video abstract at https://youtu.be/LwicoSkh3mI. Réf Journal: Macromolecules, 2016, 49 (1), 405-414
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Stochastic self-assembly of ParB proteins at centromeres builds bacterial DNA segregation apparatus
Auteur(s): Walter J.-C.
Conference: Architecture et Dynamique Nucléaire (ADN) (Paris, Jussieu, FR, 2015-04-01)
Ref HAL: hal-01955916_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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Physical modeling of active bacterial DNA segregation
Auteur(s): Walter J.-C.
(Séminaires)
DIMNP (Montpellier, FR), 2015-06-15 |