Unknown

Dataset Information

0

B-DNA to zip-DNA: simulating a DNA transition to a novel structure with enhanced charge-transport characteristics.


ABSTRACT: The forced extension of a DNA segment is studied in a series of steered molecular dynamics simulations, employing a broad range of pulling forces. Throughout the entire force range, the formation of a zipper-like (zip-) DNA structure is observed. In that structure, first predicted by Lohikoski et al., the bases of the DNA strands interdigitate with each other and form a single-base aromatic stack. Similar motifs, albeit only a few base pairs in extent, have been observed in experimental crystal structures. Analysis of the dynamics of structural changes in pulled DNA shows that S-form DNA, thought to be adopted by DNA under applied force, serves as an intermediate between B-DNA and zip-DNA. Therefore, the phase transition plateau observed in force-extension curves of DNA is suggested to reflect the B-DNA to zip-DNA structural transition. Electronic structure analysis of purine bases in zip-DNA indicates a several-fold to order of magnitude increase in the ?-? electronic coupling among nearest-neighbor nucleobases, compared to B-DNA. We further observe that zip-DNA does not require base pair complementarity between DNA strands, and we predict that the increased electronic coupling in zip-DNA will result in a much higher rate of charge transfer through an all-purine zip-DNA compared to B-DNA of equal length.

SUBMITTER: Balaeff A 

PROVIDER: S-EPMC3615717 | biostudies-literature | 2011 Sep

REPOSITORIES: biostudies-literature

altmetric image

Publications

B-DNA to zip-DNA: simulating a DNA transition to a novel structure with enhanced charge-transport characteristics.

Balaeff Alexander A   Craig Stephen L SL   Beratan David N DN  

The journal of physical chemistry. A 20110520 34


The forced extension of a DNA segment is studied in a series of steered molecular dynamics simulations, employing a broad range of pulling forces. Throughout the entire force range, the formation of a zipper-like (zip-) DNA structure is observed. In that structure, first predicted by Lohikoski et al., the bases of the DNA strands interdigitate with each other and form a single-base aromatic stack. Similar motifs, albeit only a few base pairs in extent, have been observed in experimental crystal  ...[more]

Similar Datasets

| S-EPMC8178977 | biostudies-literature
| S-EPMC3079570 | biostudies-literature
| S-EPMC9970987 | biostudies-literature
| S-EPMC5725714 | biostudies-literature
| S-EPMC8159380 | biostudies-literature
| S-EPMC3899832 | biostudies-literature
| S-EPMC3079569 | biostudies-literature
| S-EPMC4803044 | biostudies-literature
| S-EPMC2902267 | biostudies-literature
| S-EPMC4846453 | biostudies-literature