AI Article Synopsis
- The study created energy maps for various DNA structures (tetramers, hexamers, octamers) focusing on the degrees of freedom called slide and shift at the central step.
- The research compiled data on structural properties, flexibility measures, and how sequences behave under certain conditions, highlighting that most DNA adopts a B-DNA form while becoming less flexible as length increases.
- Specific sequences like GGC and GCC show bistability and a tendency towards A-form DNA, while AA sequences prefer B-DNA; furthermore, flexibility doesn't correlate with curvature, yet bent DNA is generally less stable.
Article Abstract
We have constructed the potential energy surfaces for all unique tetramers, hexamers and octamers in double helical DNA, as a function of the two principal degrees of freedom, slide and shift at the central step. From these potential energy maps, we have calculated a database of structural and flexibility properties for each of these sequences. These properties include: the values of each of the six step parameters (twist roll, tilt, rise, slide and shift), for each step of the sequence; flexibility measures for both decrease and increase in each property value from the minimum energy conformation for the central step; and the deviation from the path of a hypothetical straight octamer. In an analysis of structural change as a function of sequence length, we observe that almost all DNA tends to B-DNA and becomes less flexible. A more detailed analysis of octamer properties has allowed us to determine the structural preferences of particular sequence elements. GGC and GCC sequences tend to confer bistability, low stability and a predisposition to A-form DNA, whereas AA steps strongly prefer B-DNA and inhibit A-structures. There is no correlation between flexibility and intrinsic curvature, but bent DNA is less stable than straight. The most difficult deformation is undertwisting. The TA step stands out as the most flexible sequence element with respect to decreasing twist and increasing roll. However, as with the structural properties, this behavior is highly context-dependent and some TA steps are very straight.
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| http://dx.doi.org/10.1016/j.jmb.2003.08.006 | DOI Listing |
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