Efimov-DNA phase diagram: Three stranded DNA on a cubic lattice

Structure and Dynamics of dsDNA in Cell-like Environments

Deoxyribonucleic acid (DNA) is a fundamental biomolecule for correct cellular functioning and regulation of biological processes. DNA's structure is dynamic and has the ability to adopt a variety of structural conformations in addition to its most widely known double-stranded DNA (dsDNA) helix structure. Stability and structural dynamics of dsDNA play an important role in molecular biology. In vivo, DNA molecules are folded in a tightly confined space, such as a cell chamber or a channel, and are highly dense in solution; their conformational properties are restricted, which affects their thermodynamics and mechanical properties. There are also many technical medical purposes for which DNA is placed in a confined space, such as gene therapy, DNA encapsulation, DNA mapping, etc. Physiological conditions and the nature of confined spaces have a significant influence on the opening or denaturation of DNA base pairs. In this review, we summarize the progress of research on the stability and dynamics of dsDNA in cell-like environments and discuss current challenges and future directions. We include studies on various thermal and mechanical properties of dsDNA in ionic solutions, molecular crowded environments, and confined spaces. By providing a better understanding of melting and unzipping of dsDNA in different environments, this review provides valuable guidelines for predicting DNA thermodynamic quantities and for designing DNA/RNA nanostructures.

Role of Hoogsteen interaction in the stability of different phases of triplex DNA

A simple coarse-grained model of DNA which includes both Watson-Crick and Hoogsteen base pairing has been used to study the melting and unzipping of triplex DNA. Using Langevin dynamics simulations, we reproduce the qualitative features of one-step and two-step thermal melting of triplex as seen in experiments. The thermal melting phase diagram shows the existence of a stable interchain three-strand complex (bubble-bound state). Our studies based on the mechanical unzipping of a triplex revealed that it is mechanically more stable compared to an isolated duplex-DNA.