High flexibility of DNA on short length scales probed by atomic force microscopy

The mechanics of DNA bending on intermediate length scales (5-100 nm) plays a key role in many cellular processes, and is also important in the fabrication of artificial DNA structures, but previous experimental studies of DNA mechanics have focused on longer length scales than these. We use high-re...

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Published inNature nanotechnology Vol. 1; no. 2; pp. 137 - 141
Main Authors Nelson, Philip C, Wiggins, Paul A, van der Heijden, Thijn, Moreno-Herrero, Fernando, Spakowitz, Andrew, Phillips, Rob, Widom, Jonathan, Dekker, Cees
Format Journal Article
LanguageEnglish
Published England Nature Publishing Group 01.11.2006
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Summary:The mechanics of DNA bending on intermediate length scales (5-100 nm) plays a key role in many cellular processes, and is also important in the fabrication of artificial DNA structures, but previous experimental studies of DNA mechanics have focused on longer length scales than these. We use high-resolution atomic force microscopy on individual DNA molecules to obtain a direct measurement of the bending energy function appropriate for scales down to 5 nm. Our measurements imply that the elastic energy of highly bent DNA conformations is lower than predicted by classical elasticity models such as the worm-like chain (WLC) model. For example, we found that on short length scales, spontaneous large-angle bends are many times more prevalent than predicted by the WLC model. We test our data and model with an interlocking set of consistency checks. Our analysis also shows how our model is compatible with previous experiments, which have sometimes been viewed as confirming the WLC.
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ISSN:1748-3387
1748-3395
DOI:10.1038/nnano.2006.63