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Literature DB >> 24791158

Characterization of the geometry and topology of DNA pictured as a discrete collection of atoms.

Nicolas Clauvelin¹, Wilma K Olson¹, Irwin Tobias¹.

Abstract

The structural and physical properties of DNA are closely related to its geometry and topology. The classical mathematical treatment of DNA geometry and topology in terms of ideal smooth space curves was not designed to characterize the spatial arrangements of atoms found in high-resolution and simulated double-helical structures. We present here new and rigorous numerical methods for the rapid and accurate assessment of the geometry and topology of double-helical DNA structures in terms of the constituent atoms. These methods are well designed for large DNA datasets obtained in detailed numerical simulations or determined experimentally at high-resolution. We illustrate the usefulness of our methodology by applying it to the analysis of three canonical double-helical DNA chains, a 65-bp minicircle obtained in recent molecular dynamics simulations, and a crystallographic array of protein-bound DNA duplexes. Although we focus on fully base-paired DNA structures, our methods can be extended to treat the geometry and topology of melted DNA structures as well as to characterize the folding of arbitrary molecules such as RNA and cyclic peptides.

Entities: Chemical Disease Gene Species

Year: 2012 PMID： 24791158 PMCID： PMC4004093 DOI： 10.1021/ct200657e

Source DB: PubMed Journal: J Chem Theory Comput ISSN： 1549-9618 Impact factor: 6.006

39 in total

Characterization of the geometry and topology of DNA pictured as a discrete collection of atoms.

1. The Protein Data Bank.

2. Structural dynamics of the lac repressor-DNA complex revealed by a multiscale simulation.

3. Kinking occurs during molecular dynamics simulations of small DNA minicircles.

4. A novel roll-and-slide mechanism of DNA folding in chromatin: implications for nucleosome positioning.

5. Writhe formulas and antipodal points in plectonemic DNA configurations.

6. Looping dynamics of linear DNA molecules and the effect of DNA curvature: a study by Brownian dynamics simulation.

7. The elastic rod model for DNA and its application to the tertiary structure of DNA minicircles in mononucleosomes.

8. The effect of intrinsic curvature on conformational properties of circular DNA.

9. The role of DNA shape in protein-DNA recognition.

10. Mapping the phase diagram of the writhe of DNA nanocircles using atomistic molecular dynamics simulations.

Review 1. Structural insights into the role of architectural proteins in DNA looping deduced from computer simulations.

2. Insights into Genome Architecture Deduced from the Properties of Short Lac Repressor-mediated DNA Loops.

3. DNA topology confers sequence specificity to nonspecific architectural proteins.

4. Weak operator binding enhances simulated Lac repressor-mediated DNA looping.

5. Surprising Twists in Nucleosomal DNA with Implication for Higher-order Folding.

6. Synergy between Protein Positioning and DNA Elasticity: Energy Minimization of Protein-Decorated DNA Minicircles.

7. DSSR: an integrated software tool for dissecting the spatial structure of RNA.

8. Features of genomic organization in a nucleotide-resolution molecular model of the Escherichia coli chromosome.

9. Interplay of protein and DNA structure revealed in simulations of the lac operon.

10. What controls DNA looping?