Protein-mediated loops in supercoiled DNA create large topological domains

Yan, Yan; Ding, Yue; Leng, Fenfei; Dunlap, David; Finzi, Laura

doi:10.1093/nar/gky153

Cited by 27 publications

(26 citation statements)

References 46 publications

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“…Recent chromosome conformation capture studies have revealed chromatin looping anchored by SMC proteins (condensin and cohesin) and self-association between similar epigenetically marked chromatin states as the two universal principles of structural and functional organization of eukaryotic genome (35). Remarkably, loops anchored by the SMC proteins could be strong enough to maintain a locally altered DNA supercoiling within a closed loop (36). Chromatin loops play an important functional role in mediating interactions between transcription-activating DNA elements such as enhancers and promoters (37,38).…”

Section: Discussionmentioning

confidence: 99%

Nucleosome spacing periodically modulates nucleosome chain folding and DNA topology in circular nucleosome arrays

Bass

Nikitina

Norouzi

et al. 2019

Journal of Biological Chemistry

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Section: Discussionmentioning

confidence: 99%

Nucleosome spacing periodically modulates nucleosome chain folding and DNA topology in circular nucleosome arrays

Bass

Nikitina

Norouzi

et al. 2019

Journal of Biological Chemistry

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“…[4][5][6][7][8][9]), that generate stretching and twisting forces on the chromosomal DNA [10][11][12][13][14][15]. It is also known that chromosomes form extensive adhesion contacts with a number of nuclear membrane proteins, establishing force-transmitting links between the chro-plexes (such as eukaryotic/archaeal histones) [23,24,35]; 2) DNA-bending proteins, which sharply curve DNA at the protein binding site (like bacterial HU, IHF and Fis) [22, 25-28, 30, 32, 36]; 3) DNA-bridging proteins that cross-link DNA duplexes (for example, bacterial H-NS, human HMGA2, or any other protein that mediates DNA loops) [29,[37][38][39], and 4) DNA-stiffening proteins forming rigid nucleoprotein filaments along DNA (like archaeal TrmBL2 and Alba) [31,33,40]. Thus, the four major groups of DNA-architectural proteins form nucleoprotein complexes, which have very different 3D structures, leading to diverse responses of these proteins to force and torque constraints applied to DNA.…”

Section: Introductionmentioning

confidence: 99%

Transfer-matrix calculations of the effects of tension and torque constraints on DNA–protein interactions

Efremov

Yan

2018

Nucleic Acids Research

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Organization and maintenance of the chromosomal DNA in living cells strongly depends on the DNA interactions with a plethora of DNA-binding proteins. Single-molecule studies show that formation of nucleoprotein complexes on DNA by such proteins is frequently subject to force and torque constraints applied to the DNA. Although the existing experimental techniques allow to exert these type of mechanical constraints on individual DNA biopolymers, their exact effects in regulation of DNA–protein interactions are still not completely understood due to the lack of systematic theoretical methods able to efficiently interpret complex experimental observations. To fill this gap, we have developed a general theoretical framework based on the transfer-matrix calculations that can be used to accurately describe behaviour of DNA–protein interactions under force and torque constraints. Potential applications of the constructed theoretical approach are demonstrated by predicting how these constraints affect the DNA-binding properties of different types of architectural proteins. Obtained results provide important insights into potential physiological functions of mechanical forces in the chromosomal DNA organization by architectural proteins as well as into single-DNA manipulation studies of DNA–protein interactions.

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“…Based on recent experimental results ( 12 , 13 , 14 , 15 , 16 ), one may wonder whether DNA loops are ipso facto independent topological domains or whether some additional, more subtle properties of DNA-bridging proteins are required to achieve this goal. We emphasize that the word “loop” is used here according to its biological meaning and not the geometrical one.…”

Section: Resultsmentioning

confidence: 99%

“…The most straightforward explanation for this result is that two bridges in tandem are required to sustain the torque arising from the difference in torsional stress in the two DNA loops. Yet, single molecule experiments have demonstrated that a single LacI bridge can sustain the torque associated with physiological values of supercoiling, that is σ ≈ −0.06 ( 16 ). In this context, we surmise that the slow relaxation observed in ( 15 ) for single DNA bridges may correspond to the slow intrication obtained with our second model for DNA-bridging proteins, whereas the more stable topological separation observed in ( 15 ) for bridges in tandem corresponds to true barriers obtained with the third model for DNA-bridging proteins.…”

Section: Resultsmentioning

confidence: 99%

“…Although this question has now been addressed for nearly two decades ( 7 , 8 , 9 ), the mechanisms underlying the formation of topological barriers remain mostly elusive. The most plausible models for the formation of topological barriers are 1) actively transcribing RNA polymerases (RNAPs), which generate both positive and negative supercoils ( 10 ) and may consequently block the displacement and dissipation of plectonemes ( 11 , 12 ); and 2) the formation of DNA loops by certain nucleoid proteins that may serve as topological barriers ( 13 , 14 , 15 , 16 ). In this work, we focus on this latter mechanism and establish under which conditions DNA-bridging proteins may serve as topological barriers.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Requirements for DNA-Bridging Proteins to Act as Topological Barriers of the Bacterial Genome

Joyeux

Junier

2020

Biophysical Journal

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Bacterial genomes have been shown to be partitioned into several-kilobase-long chromosomal domains that are topologically independent from each other, meaning that change of DNA superhelicity in one domain does not propagate to neighbors. Both in vivo and in vitro experiments have been performed to question the nature of the topological barriers at play, leading to several predictions on possible molecular actors. Here, we address the question of topological barriers using polymer models of supercoiled DNA chains that are constrained such as to mimic the action of predicted molecular actors. More specifically, we determine under which conditions DNA-bridging proteins may act as topological barriers. To this end, we developed a coarse-grained bead-and-spring model and investigated its properties through Brownian dynamics simulations. As a result, we find that DNA-bridging proteins must exert rather strong constraints on their binding sites; they must block the diffusion of the excess of twist through the two binding sites on the DNA molecule and, simultaneously, prevent the rotation of one DNA segment relative to the other one. Importantly, not all DNA-bridging proteins satisfy this second condition. For example, single bridges formed by proteins that bind DNA nonspecifically, like H-NS dimers, are expected to fail with this respect. Our findings might also explain, in the case of specific DNA-bridging proteins like LacI, why multiple bridges are required to create stable independent topological domains. Strikingly, when the relative rotation of the DNA segments is not prevented, relaxation results in complex intrication of the two domains. Moreover, although the value of the torsional stress in each domain may vary, their differential is preserved. Our work also predicts that nucleoid-associated proteins known to wrap DNA must form higher protein-DNA complexes to efficiently work as topological barriers.

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Protein-mediated loops in supercoiled DNA create large topological domains

Cited by 27 publications

References 46 publications

Nucleosome spacing periodically modulates nucleosome chain folding and DNA topology in circular nucleosome arrays

Nucleosome spacing periodically modulates nucleosome chain folding and DNA topology in circular nucleosome arrays

Transfer-matrix calculations of the effects of tension and torque constraints on DNA–protein interactions

Requirements for DNA-Bridging Proteins to Act as Topological Barriers of the Bacterial Genome

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