2015
DOI: 10.1021/acs.jctc.5b00965
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Computing Nonequilibrium Conformational Dynamics of Structured Nucleic Acid Assemblies

Abstract: Synthetic nucleic acids can be programmed to form precise three-dimensional structures on the nanometer-scale. These thermodynamically stable complexes can serve as structural scaffolds to spatially organize functional molecules including multiple enzymes, chromophores, and force-sensing elements with internal dynamics that include substrate reaction-diffusion, excitonic energy transfer, and force-displacement response that often depend critically on both the local and global conformational dynamics of the nuc… Show more

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Cited by 17 publications
(19 citation statements)
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“…The FE model of a single-stranded crossover is identical to that of a double-stranded crossover except that the rotational stiffness defined by pivoting about the reference axis z is reduced (Figure 1B) (72). In contrast, rotation about the x -axis or the y -axis results in steric overlap between the duplexes in the single crossover (Figure 1B).…”
Section: Methodsmentioning
confidence: 99%
See 1 more Smart Citation
“…The FE model of a single-stranded crossover is identical to that of a double-stranded crossover except that the rotational stiffness defined by pivoting about the reference axis z is reduced (Figure 1B) (72). In contrast, rotation about the x -axis or the y -axis results in steric overlap between the duplexes in the single crossover (Figure 1B).…”
Section: Methodsmentioning
confidence: 99%
“…Double and single-crossovers are treated explicitly by constraining the relative motions of joined duplexes, and bulges and open nicks are similarly modeled empirically using spring-like elements. A nonlinear FE solver is then used to compute the ground-state equilibrium structure (5,29,30) and mechanical properties of stable DNA assemblies, the latter comprising thermal fluctuations (29,30,72) and force-deformation responses (20), with significantly reduced computational cost compared with all-atom and nucleotide-level models. Previously, we introduced the FE framework CanDo (5,29) to compute equilibrium structures of a class of DNA assemblies in which DNA duplexes are placed on a honeycomb (16) or square (18) lattice.…”
Section: Introductionmentioning
confidence: 99%
“…All simulations were performed using the program NAMD2 ( 76 ) with the CHARMM27 force field ( 77 , 78 ) and Allnér Mg 2 + ( 79 ) parameters. This procedure as follows has been successfully utilized in several previous studies of DNA origami nanostructures ( 80 , 81 ). An integration time step of 2 fs and periodic boundary conditions were applied in an orthogonal simulation cell.…”
Section: Methodsmentioning
confidence: 99%
“…The increasing interest in DNA-based materials and devices has led to efforts to understand the mechanical properties of various DNA assemblies [18]. Mechanical modeling studies have largely focused on predicting the assembled structure geometry and flexibility [19], while a few experimental studies have used force spectroscopy [20,21] and imaging of thermal fluctuations [22] to quantify the mechanical properties of DNA nanostructures. These prior studies have led to a basic understanding of the mechanical stiffness, in particular bending stiffness, of various DNA assemblies and the ability to predict folded shapes including cases where local stresses lead to curvature [23,24].…”
Section: Introductionmentioning
confidence: 99%