Dynamics of DNA breathing in the Peyrard–Bishop model with damping and external force

Sulaiman, Albertus; Zen, Freddy P.; Alatas, Husin; Handoko, L. T.

doi:10.1016/j.physd.2012.06.011

Cited by 41 publications

(25 citation statements)

References 33 publications

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“…These damped mechanical models lead to the same conclusions: viscous damping induces a quick stoppage of the soliton which thus travels less than 10 bp [107,125] and decreases drastically the soliton velocity [152,142], and the "bubble" lifetimes which becomes on the order of a few picoseconds only [155,156,157]. Deng [150], using a stochastic differential PBD equation, found base-pair opening times of about 10-400 ps.…”

Section: Mechanical Models Are Not Adapted To All Denaturation Bubblementioning

confidence: 75%

“…Several attempts to introduce a friction force in the mechanical models have been proposed [107,141,142,148,149,150]. For instance, in the geometry of the PBD model, this friction force is written as −ζ 0 ∂y/∂t where ζ 0 6πηa ∼ 10 −11 kg/s is the friction coefficient of a base-pair.…”

Section: Mechanical Models Are Not Adapted To All Denaturation Bubblementioning

confidence: 99%

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Physics of base-pairing dynamics in DNA

Manghi

Destainville

2016

Physics Reports

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As a key molecule of Life, Deoxyribonucleic acid (DNA) is the focus of numbers of investigations with the help of biological, chemical and physical techniques. From a physical point of view, both experimental and theoretical works have brought quantitative insights into DNA base-pairing dynamics that we review in this Report, putting emphasis on theoretical developments. We discuss the dynamics at the base-pair scale and its pivotal coupling with the polymer one, with a polymerization index running from a few nucleotides to tens of kilo-bases. This includes opening and closure of short hairpins and oligomers as well as zipping and unwinding of long macromolecules. We review how different physical mechanisms are either used by Nature or utilized in biotechnological processes to separate the two intertwined DNA strands, by insisting on quantitative results. They go from thermally-assisted denaturation bubble nucleation to force- or torque- driven mechanisms. We show that the helical character of the molecule, possibly supercoiled, can play a key role in many denaturation and renaturation processes. We categorize the mechanisms according to the relative timescales associated with base-pairing and chain degrees of freedom such as bending and torsional elastic ones. In some specific situations, these chain degrees of freedom can be integrated out, and the quasi- static approximation is valid. The complex dynamics then reduces to the diffusion in a low-dimensional free-energy landscape. In contrast, some important cases of experimental interest necessarily appeal to far-from-equilibrium statistical mechanics and hydrodynamics.Comment: Review Article, revised versio

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Section: Mechanical Models Are Not Adapted To All Denaturation Bubblementioning

confidence: 75%

Section: Mechanical Models Are Not Adapted To All Denaturation Bubblementioning

confidence: 99%

Physics of base-pairing dynamics in DNA

Manghi

Destainville

2016

Physics Reports

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“…In contrast, the Förster-weighted spacing estimated for the four QD:(1.0×R 0 ) n assemblies is 74.2 ± 9Å or ~1.5×R 0 which is ~20% larger. We ascribe this difference to the DNA sequence that is hybridized to the 1.0×R 0 template and hypothesize that this may reflect some, incomplete hybridization or "breathing" in this end portion of the DNA 15,16 . Alternatively, there may be some interactions between the Cy3 dye label on this DNA and the PEG layer that surrounds the QD during assembly.…”

Section: Energy Transfer Between Qd and Cy3mentioning

confidence: 99%

Improving energy transfer in QD-DNA photonic networks

et al. 2013

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There is considerable research in the area of manipulating light below the diffraction limit, with potential applications ranging from information processing to light-harvesting. In such work, a common problem is a lack of efficiency associated with non-radiative losses, e.g., ohmic loss in plasmonic structures. From this point of view, one attractive method for sub-wavelength light manipulation is to use Förster resonance energy transfer (FRET) between chromophores. Although most current work does not show high efficiency, biology suggests that this approach could achieve very high efficiency. In order to achieve this goal, the geometry and spacing of the chromophores must be optimized. For this, DNA provides an easy means for the self-assembly of these complex structures. With well established ligation chemistries, it is possible to create facile hierarchical assemblies of quantum dots (QDs) and organic dyes using DNA as the platform. These nanostructures range from simple linear wires to complex 3-dimensional structures all of which can be self-assembled around a central QD. The efficiency of the system can then be tuned by changing the spacing between chromophores, changing the DNA geometry such that the donor to acceptor ratio changes, or changing the number of DNA structures that are self-assembled around the central QD. By exploring these variables we have developed a flexible optical system for which the efficiency can be both controlled and optimized.

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“…Since the structure of DNA double helix has been discovered by Watson and Crick in 1953 [2]. Many researchers, especially ones in theoretical physics and nonlinear dynamics and also triggered the formulation of several simple models of nonlinear DNA dynamics corresponding to geometric structure, namely, the DNA double-stranded [3][4][5][6][7][8][9][10][11][12][13][14] or the double helix [15][16][17][18][19][20][21][22][23][24][25][26][27][28]. These models had been developed during the past decade to describe the nonlinear dynamics properties of open base-pairs in DNA, which commonly called denaturation bubbles [29].…”

Section: Introductionmentioning

confidence: 99%

On The Features Solitary Wave Solutions for the DoubleStructures Model of DNA

2017

International Journal of Research Studies in Biosciences

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Dynamics of DNA breathing in the Peyrard–Bishop model with damping and external force

Cited by 41 publications

References 33 publications

Physics of base-pairing dynamics in DNA

Physics of base-pairing dynamics in DNA

Improving energy transfer in QD-DNA photonic networks

On The Features Solitary Wave Solutions for the DoubleStructures Model of DNA

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