Single-strand conformation polymorphism (SSCP) of oligodeoxyribonucleotides: an insight into solution structural dynamics of DNAs provided by gel electrophoresis and molecular dynamics simulations.

Studies on the solution structure dynamics of RNA/DNA are becoming crucially important. The phenomena of SSCP (single-strand conformation polymorphism), small RNA dynamics in a cell, and others can be related to the conformational changes of single-stranded (ss) RNAs/DNAs in solution. However, little is known about those dynamics. Only the intra-structural transition of ssDNAs in solution has been reported based on Watson-Crick (W-C) base-pairing. Here, we found a general feature of the SSCP phenomenon by studying the simpler molecules of ss-oligodeoxyribonucleotides. A single base substitution or a positional exchange of nucleotide in a highly homologous series of ss-dodecanucleotides led to a change in the mobility-in-gel. This was unexpected, since most of these nucleotides [such as d(A(11)G) or d(A(11)C)] have no possibility of forming W-C base-pairing. MD (molecular dynamics) experiments revealed differences in shape and size between the dynamic structures of these molecules which could affect their mobility-in-gel. In addition, a high correlation was observed between the electrophoretic mobility and the size-related parameters such as end-to-end distance obtained from MD simulations. Because the simulation was considerably shorter (nanosecond) than the experimental time-scale (second), the result must be considered conservatively; but it is nevertheless encouraging for utilizing MD simulation for structural analysis of oligonucleotides.