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Literature DB >> 18178661

Theoretical study of sequence-dependent nanopore unzipping of DNA.

Abstract

We theoretically investigate the unzipping of DNA electrically driven through a nanometer-size pore. Taking the DNA base sequence explicitly into account, the unpairing and translocation process is described by a biased random walk in a one-dimensional energy landscape determined by the sequential basepair opening. Distributions of translocation times are numerically calculated as a function of applied voltage and temperature. We show that varying these two parameters changes the dynamics from a predominantly diffusive behavior to a dynamics governed by jumps over local energy barriers. The work suggests experimentally studying sequence effects, by comparing the average value and standard deviation of the statistical distribution of translocation times.

Mesh：

Substances：
Lipid Bilayers
DNA

Year: 2008 PMID： 18178661 PMCID： PMC2267141 DOI： 10.1529/biophysj.107.111732

Source DB: PubMed Journal: Biophys J ISSN： 0006-3495 Impact factor: 4.033

31 in total

1. Microsecond time-scale discrimination among polycytidylic acid, polyadenylic acid, and polyuridylic acid as homopolymers or as segments within single RNA molecules.

Authors: M Akeson; D Branton; J J Kasianowicz; E Brandin; D W Deamer
Journal: Biophys J Date: 1999-12 Impact factor: 4.033

Theoretical study of sequence-dependent nanopore unzipping of DNA.

1. Microsecond time-scale discrimination among polycytidylic acid, polyadenylic acid, and polyuridylic acid as homopolymers or as segments within single RNA molecules.

2. Voltage-driven DNA translocations through a nanopore.

3. Rapid discrimination among individual DNA hairpin molecules at single-nucleotide resolution using an ion channel.

4. Unzipping DNA with optical tweezers: high sequence sensitivity and force flips.

5. Pulling pinned polymers and unzipping DNA.

6. Sequence dependent rigidity of single stranded DNA.

7. DNA unzipped under a constant force exhibits multiple metastable intermediates.

8. Unzipping kinetics of double-stranded DNA in a nanopore.

9. Slow nucleic acid unzipping kinetics from sequence-defined barriers.

10. Extracting kinetics from single-molecule force spectroscopy: nanopore unzipping of DNA hairpins.

1. Mimicking DNA stretching with the Static Mode method: shear stress versus transverse pulling stress.

2. Probing DNA base pairing energy profiles using a nanopore.

Review 3. Controlling molecular transport through nanopores.

4. Overstretching Double-Stranded RNA, Double-Stranded DNA, and RNA-DNA Duplexes.

5. Possible scenarios of DNA double-helix unzipping process in single-molecule manipulation experiments.

6. Quantitative analysis of the nanopore translocation dynamics of simple structured polynucleotides.

7. Unzipping kinetics of duplex DNA containing oxidized lesions in an α-hemolysin nanopore.

8. Shrinking of Solid-state Nanopores by Direct Thermal Heating.