Electrostatic mechanism of nucleosomal array folding revealed by computer simulation

Sun, Jinsheng; Zhang, Qing; Schlick, Tamar

doi:10.1073/pnas.0408867102

Cited by 106 publications

(120 citation statements)

References 72 publications

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“…In the first place, chromatin structure may differently affect their substrate availability. Torsional elasticity of chromatin could be smaller than for naked DNA, leading to a smaller driving torque and thus to a low activity of topo I. Conversely, chromatin might favor DNA transport activity of topo II by increasing the juxtaposition probability of DNA segments (Sun et al, 2005). Such increase may be significant in ( þ ) supercoiled chromatin.…”

Section: Discussionmentioning

confidence: 99%

Topoisomerase II, not topoisomerase I, is the proficient relaxase of nucleosomal DNA

Salceda¹,

Fernández²,

Roca

2006

EMBO J

101

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Eukaryotic topoisomerases I and II efficiently remove helical tension in naked DNA molecules. However, this activity has not been examined in nucleosomal DNA, their natural substrate. Here, we obtained yeast minichromosomes holding DNA under ( þ ) helical tension, and incubated them with topoisomerases. We show that DNA supercoiling density can rise above þ 0.04 without displacement of the histones and that the typical nucleosome topology is restored upon DNA relaxation. However, in contrast to what is observed in naked DNA, topoisomerase II relaxes nucleosomal DNA much faster than topoisomerase I. The same effect occurs in cell extracts containing physiological dosages of topoisomerase I and II. Apparently, the DNA strand-rotation mechanism of topoisomerase I does not efficiently relax chromatin, which imposes barriers for DNA twist diffusion. Conversely, the DNA cross-inversion mechanism of topoisomerase II is facilitated in chromatin, which favor the juxtaposition of DNA segments. We conclude that topoisomerase II is the main modulator of DNA topology in chromatin fibers. The nonessential topoisomerase I then assists DNA relaxation where chromatin structure impairs DNA juxtaposition but allows twist diffusion.

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Section: Discussionmentioning

confidence: 99%

Topoisomerase II, not topoisomerase I, is the proficient relaxase of nucleosomal DNA

Salceda¹,

Fernández²,

Roca

2006

EMBO J

101

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“…The modeling approach involves Monte Carlo simulations of a coarse-grained ''mesoscale'' chromatin model that accounts for important structural and energetic components whereas still making oligonucleosome simulations computationally feasible (26)(27)(28)(29). Because experimental observations emphasize the polymorphic and irregular nature of chromatin fiber in vitro and in vivostemming from linker DNA flexibility, rotational flexibility of DNA in the nucleosome core, and flexible histone tails that interact with the DNA and counterions within as well as between the nucleosomes (11, 30)-our mesoscale modeling approach uniquely takes into account histone-tail flexibility, linker-histone electrostatics and orientation, Mg 2ϩ -induced electrostatic screening, and linker-DNA bending at physiological conditions, as well as thermal fluctuations and entropic effects.…”

mentioning

confidence: 99%

Evidence for heteromorphic chromatin fibers from analysis of nucleosome interactions

Grigoryev

Arya

Correll

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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241

358

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The architecture of the chromatin fiber, which determines DNA accessibility for transcription and other template-directed biological processes, remains unknown. Here we investigate the internal organization of the 30-nm chromatin fiber, combining Monte Carlo simulations of nucleosome chain folding with EM-assisted nucleosome interaction capture (EMANIC). We show that at physiological concentrations of monovalent ions, linker histones lead to a tight 2-start zigzag dominated by interactions between alternate nucleosomes (i ؎ 2) and sealed by histone N-tails. Divalent ions further compact the fiber by promoting bending in some linker DNAs and hence raising sequential nucleosome interactions (i ؎ 1). Remarkably, both straight and bent linker DNA conformations are retained in the fully compact chromatin fiber as inferred from both EMANIC and modeling. This conformational variability is energetically favorable as it helps accommodate DNA crossings within the fiber axis. Our results thus show that the 2-start zigzag topology and the type of linker DNA bending that defines solenoid models may be simultaneously present in a structurally heteromorphic chromatin fiber with uniform 30 nm diameter. Our data also suggest that dynamic linker DNA bending by linker histones and divalent cations in vivo may mediate the transition between tight nucleosome packing within discrete 30-nm fibers and self-associated higher-order chromosomal forms.chromatin structure ͉ electron microscopy ͉ mesoscopic modeling ͉ Monte Carlo simulations ͉ linker histone T he DNA in eukaryotic chromatin is packed and functionally regulated by histones and nonhistone architectural proteins (1). The primary packing level is represented by an array of repeating units, the nucleosomes, where the DNA is wound around histone octamers (2). Further compaction is achieved through a hierarchy of folding levels, including the 30-nm chromatin fiber (secondary level) and more compact and self-associating tertiary and quaternary forms whose structures are unknown (3-6). Because DNA conformation in chromatin and nucleosome packing are intimately connected to DNA/protein recognition and gene regulation, there has been intense interest in understanding chromatin structure, energetics, and dynamics. Some experimental studies have suggested that nucleosomal arrays fold in a zigzag arrangement with relatively straight linkers and a 2-start nucleosome interaction pattern that brings each nucleosome in proximity to its second nearest neighbor (7-10) consistent with chromatin fibers observed in situ (11). Other evidence suggests that chromatin condensed with linker histones and divalent cations such as Mg 2ϩ can form either zigzag structures with various nucleosome topologies (12, 13) or solenoid-like arrangements. The latter class of structures has bent DNA linkers and predominant interactions between either nearest neighbor nucleosomes (14, 15) and/or between every fifth or sixth nucleosome along the chain (16,17).The picture has became more complex recently with our heighte...

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“…The algorithms create designed to create an irregular surface for the nucleosome so that tail geometries (though rigid) are captured (top) [37]. This model captured the salt-dependent folding and unfolding of chromatin (bottom) at different univalent salt environment [38]. Figure 8: Mesoscopic oligonucleosome model.…”

Section: Discussionmentioning

confidence: 99%

“…Our first-generation "macroscopic" models treated the nucleosome and the wound DNA according to general mechanical and electrostatic properties, with the histone tails approximated as rigid bodies and linker histones neglected ( Fig. 3) [24,35,36,37,38]. As Fig.…”

Section: Chromatin Structurementioning

confidence: 99%

“…Hence modeling fiber structure and motion requires specialized models that treat the system's electrostatics as accurately as possible -since these features are thought to be crucial for chromatin organization -while approximating others so as to make possible studies of nucleosome arrays (or oligonucleosomes) with sufficient configurational sampling (e.g., 100 million configurations) or simulation times of milliseconds and longer to be biologically relevant. In recent years, a variety of computational models have been developed (e.g., [22,23,24,25,26,27,28]). …”

Section: Chromatin Structurementioning

confidence: 99%

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From Macroscopic to Mesoscopic Models of Chromatin Folding

Schlick¹

2009

Multiscale Methods

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An overview of the evolution of computer models for simulation of chromatin folding is presented. Chromatin is the protein/nucleic acid fiber that stores the genetic material in higher organisms. Many biological questions concerning the fiber structure and its dependence on internal and external factors remain a puzzle. Modeling and simulation can in theory provide molecular view for analysis, but the sheer size and range of spatial and temporal scales involved require tailored multiscale models. Our first-generation, macroscopic models ignored histone tail flexibility but generated insights into preferred zigzag configurations and folding/unfolding dynamics at univalent salt. The second-generation mesoscale models incorporated histone tail flexibility, linker histones, and the presence of divalent ions. Recent results reveal the profound compaction induced by linker histones and the polymorphic fiber structure at divalent salt environments, with a small fraction of the linker DNAs bent rather than straight for ultimate compaction. Our chromatin model can be extended further to study many important questions dealing with histone tail post-translational modifications, the effects of variations in linker DNA length and of histone variants on chromatin structure, and the nature of higher-order fiber structures. IntroductionOne of the current challenges in scientific computing is model development that entails bridging the resolution among different spatial and temporal scales. In biological applications, a wide range of spatial scales defines systems, from the quantum particles to atomic, molecular, cellular, organ, system and genome entities. Temporal scales range from sub-femtosecond for electronic motion to billions of years of evolutionary changes. As our computing power and algorithms have improved, problems of greater scientific significance can be addressed with enhanced confidence and accuracy. However, developing appropriate molecular models and simulation algorithms to answer specific biological questions that require bridging all-atom details with the macroscopic view of activity on the cellular level remains an ad-hoc endeavor which requires as much art as science.As a special volume of SIAM's journal on Multiscale Modeling and Simulation illustrated [1], multiscale biology is being developed by many varied techniques and applied to a variety of problems, such as involving protein and RNA threedimensional structures, DNA supercoiling, ribosomal motions, DNA packaging in viruses, heart muscle motion, RNA translation, or fruit fly circadian rhythm. For these applications, techniques involve hierarchical methods that transform fast, low-resolution to slower, higher-resolution models; dynamics propagation using projection of standard molecular dynamics to longer timescales using master-equation methods; rigid-body dynamics; elastic or normal-mode models; and coarse-grained studies of slow, large-scale motions and features using differential equations for global properties or statistical methods.Thi...

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Electrostatic mechanism of nucleosomal array folding revealed by computer simulation

Cited by 106 publications

References 72 publications

Topoisomerase II, not topoisomerase I, is the proficient relaxase of nucleosomal DNA

Topoisomerase II, not topoisomerase I, is the proficient relaxase of nucleosomal DNA

Evidence for heteromorphic chromatin fibers from analysis of nucleosome interactions

From Macroscopic to Mesoscopic Models of Chromatin Folding

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