DNA knots reveal a chiral organization of DNA in phage capsids

Arsuaga, Javier; Vázquez, Mariel; McGuirk, Paul R.; Trigueros, Sònia; Sumners, D. W.; Roca, Joaquím

doi:10.1073/pnas.0409323102

Cited by 231 publications

(294 citation statements)

References 44 publications

(50 reference statements)

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“…3 do not resemble the repertoire of topologies commonly formed by biopolymers such as proteins and DNA, whether in solution or under confinement [34][35][36][37][38][39][40][41] . Arguably, a key element favouring the self-assembly of the knots in Fig.…”

Section: Resultsmentioning

confidence: 99%

Self-assembling knots of controlled topology by designing the geometry of patchy templates

et al. 2015

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The self-assembly of objects with a set of desired properties is a major goal of material science and physics. A particularly challenging problem is that of self-assembling structures with a target topology. Here we show by computer simulation that one may design the geometry of string-like rigid patchy templates to promote their efficient and reproducible self-assembly into a selected repertoire of non-planar closed folds including several knots. In particular, by controlling the template geometry, we can direct the assembly process so as to strongly favour the formation of constructs tied in trefoil or pentafoil, or even of more exotic torus knots. Polydisperse and racemic mixtures of helical fragments of variable composition add further tunability in the topological self-assembly we discovered. Our results should be relevant to the design of new ways to synthesize molecular knots, which may prove, for instance, to be efficient cargo-carriers due to their mechanical stability.

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Section: Resultsmentioning

confidence: 99%

Self-assembling knots of controlled topology by designing the geometry of patchy templates

et al. 2015

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“…Clarifying issues related to knots and links in polymer physics has been since long recognized of key importance in a variety of fields, ranging from molecular biology to nanotechnology. [11][12][13][14][15][27][28][29][30][31] So far, for isolated ring polymers, which are the object of the present study, most theoretical and numerical approaches provided informations referring to ensembles with unrestricted topology. This means that information on the frequency of occurrence of different knots is in general not available for models of random ring polymer configurations.…”

Section: Introductionmentioning

confidence: 99%

“…Besides the translocation processes, of central importance for biology, the study of topological spectra of DNA extracted from viral capsids is a typical context where the knowledge of spectra for specific models of random polymers is very valuable. 11,12,14 Model calculations like those carried out in the present work Figure 1: Example of a collapsed interacting selfavoiding ring with N = 500 steps on the cubic lattice, and its shortened form after the BFACF 39,40 reduction procedure with a low fugacity per step. The latter reveals that the ring holds a 5 2 knot, whose projection with the minimal crossing number n c = 5 is also shown.…”

Section: Introductionmentioning

confidence: 99%

Knotted Globular Ring Polymers: How Topology Affects Statistics and Thermodynamics

2014

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The statistical mechanics of a long knotted collapsed polymer is determined by a free-energy with a knot-dependent subleading term, which is linked to the length of the shortest polymer that can hold such knot. The only other parameter depending on the knot kind is an amplitude such that relative probabilities of knots do not vary with the temperature T , in the limit of long chains. We arrive at this conclusion by simulating interacting self-avoiding rings at low T on the cubic lattice, both with unrestricted topology and with setups where the globule is divided by a slip link in two loops (preserving their topology) which compete for the chain length, either in contact or separated by a wall as for translocation through a membrane pore. These findings suggest that in macromolecular environments there may be entropic forces with a purely topological origin, whence portions of polymers holding complex knots should tend to expand at the expense of significantly shrinking other topologically simpler portions. 1

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“…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.…”

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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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DNA knots reveal a chiral organization of DNA in phage capsids

Cited by 231 publications

References 44 publications

Self-assembling knots of controlled topology by designing the geometry of patchy templates

Self-assembling knots of controlled topology by designing the geometry of patchy templates

Knotted Globular Ring Polymers: How Topology Affects Statistics and Thermodynamics

Untying Knotted DNA with Elongational Flows

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