Compression and self-entanglement of single DNA molecules under uniform electric field

Tang, Jing; Du, Ning; Doyle, Patrick S.

doi:10.1073/pnas.1105547108

Cited by 134 publications

(180 citation statements)

References 38 publications

(55 reference statements)

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“…Although pulling on single-molecules has been well established over decades (53), pushing molecules has been a much more formidable challenge with few published examples exclusively focusing on a single DNA molecule (54)(55)(56)(57).…”

Section: Discussionmentioning

confidence: 99%

Physical manipulation of the Escherichia coli chromosome reveals its soft nature

Pelletier

Halvorsen

et al. 2012

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

181

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Replicating bacterial chromosomes continuously demix from each other and segregate within a compact volume inside the cell called the nucleoid. Although many proteins involved in this process have been identified, the nature of the global forces that shape and segregate the chromosomes has remained unclear because of limited knowledge of the micromechanical properties of the chromosome. In this work, we demonstrate experimentally the fundamentally soft nature of the bacterial chromosome and the entropic forces that can compact it in a crowded intracellular environment. We developed a unique "micropiston" and measured the force-compression behavior of single Escherichia coli chromosomes in confinement. Our data show that forces on the order of 100 pN and free energies on the order of 10 5 k B T are sufficient to compress the chromosome to its in vivo size. For comparison, the pressure required to hold the chromosome at this size is a thousand-fold smaller than the surrounding turgor pressure inside the cell. Furthermore, by manipulation of molecular crowding conditions (entropic forces), we were able to observe in real time fast (approximately 10 s), abrupt, reversible, and repeatable compaction-decompaction cycles of individual chromosomes in confinement. In contrast, we observed much slower dissociation kinetics of a histone-like protein HU from the whole chromosome during its in vivo to in vitro transition. These results for the first time provide quantitative, experimental support for a physical model in which the bacterial chromosome behaves as a loaded entropic spring in vivo.chromosome segregation | depletion forces | polymer physics | mother machine | optical trap

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Section: Discussionmentioning

confidence: 99%

Physical manipulation of the Escherichia coli chromosome reveals its soft nature

Pelletier

Halvorsen

et al. 2012

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

181

270

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“…Knots have been induced with high-electric fields 11 , optical tweezers 12,13 , topoisomerase enzymes 14,15,16 , DNA recombinases 17 , and through the cyclization of linear DNA molecules 18,19 .…”

Section: Abstract: Dna Knots Nanoporementioning

confidence: 99%

“…Optical techniques 11,12 have been used to introduce and study the behaviour of knots in DNA strands. Gel electrophoresis 15,16,18,19,21 , the dominant tool used in knot studies, is a bulk technique where knots are trapped in circular molecules which are limited to lengths in the range of 10 kbp or lower.…”

Section: Abstract: Dna Knots Nanoporementioning

confidence: 99%

Direct observation of DNA knots using a solid-state nanopore

et al. 2016

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“…Common nanofluidic experiments have led to the spontaneous formation of knots in DNA by collision with channel defects 27 or the application of moderate electric fields 28,29 during electrophoresis. More broadly, the growing library of methods to manipulate DNA molecules in nanofluidic devices has enabled fundamental research about single polymer molecules.…”

mentioning

confidence: 99%

Untying Knotted DNA with Elongational Flows

Renner

Doyle

2014

ACS Macro Lett.

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We present Brownian dynamics simulations of initially knotted double-stranded DNA molecules untying in elongational flows. We show that the motions of the knots are governed by a diffusion−convection equation by deriving scalings that collapse the simulation data. When being convected, all knots displace nonaffinely, and their rates of translation along the chain are topologically dictated. We discover that torus knots "corkscrew" when driven by flow, whereas nontorus knots do not. We show that a simple mechanism can explain a coupling between this rotation and the translation of a knot, explaining observed differences in knot translation rates. These types of knots are encountered in nanoscale manipulation of DNA, occur in biology at multiple length scales (DNA to umbilical cords), and are ubiquitous in daily life (e.g., hair). These results may have a broad impact on manipulations of such knots via flows, with applications to genomic sequencing and polymer processing.K nots are commonly encountered and manipulated in everyday experiences such as tying one's shoelaces or untangling spontaneously knotted strings. 1 Formally defined only for closed rings, the topologies of "open" knots (referred to hereafter simply as knots) are often unambiguous (e.g., shoelaces and neckties) and can be closed and algorithmically defined. 2−4 At microscopic scales, chromosomal knots are modified by topoisomerases during cell division 5 and are thought to participate in gene regulation. 6 Knots are found in proteins 7,8 and viral capsid DNA,9,10 likely with yet to be fully understood functions. It has been mathematically proven that knots become asymptotically likely as the length of a polymer increases, 11 a fact that explains their ubiquity.Due to the emerging significance of knotted polymers, a growing body of simulation literature is devoted to their study. 12,13 For instance, while the topology of a ring is fixed, an open polymer can spontaneously form and untie knots. 14 The probability of forming such knots can be nonmonotonic when the polymer is confined in slits 15,16 or tubes, 17 and increasing the stiffness of a polymer can similarly influence the knotting probability in unintuitive ways. 18,19 Such knots can substantially affect the mechanical properties 20,21 and rheological behavior 22 of a polymer, and the probability of forming knots has been used to infer the effective diameter of DNA molecules. 23 Recently, simulations have shown dramatic slowing of processes wherein a knot is driven along a chain such as entropic ejection of DNA from a viral capsid 24 and the translocation of single-stranded DNA (ssDNA) 25 and polypeptides 26 through pores.Common nanofluidic experiments have led to the spontaneous formation of knots in DNA by collision with channel defects 27 or the application of moderate electric fields 28,29 during electrophoresis. More broadly, the growing library of methods to manipulate DNA molecules in nanofluidic devices has enabled fundamental research about single polymer molecules. 30,31 Th...

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Compression and self-entanglement of single DNA molecules under uniform electric field

Cited by 134 publications

References 38 publications

Physical manipulation of the Escherichia coli chromosome reveals its soft nature

Physical manipulation of the Escherichia coli chromosome reveals its soft nature

Direct observation of DNA knots using a solid-state nanopore

Untying Knotted DNA with Elongational Flows

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