English

Mesoscopic modeling for nucleic acid chain dynamics

Biomolecules 2009-11-11 v1

Abstract

To gain a deeper insight into cellular processes such as transcription and translation, one needs to uncover the mechanisms controlling the configurational changes of nucleic acids. As a step toward this aim, we present here a novel mesoscopic-level computational model that provides a new window into nucleic acid dynamics. We model a single-stranded nucleic as a polymer chain whose monomers are the nucleosides. Each monomer comprises a bead representing the sugar molecule and a pin representing the base. The bead-pin complex can rotate about the backbone of the chain. We consider pairwise stacking and hydrogen-bonding interactions. We use a modified Monte Carlo dynamics that splits the dynamics into translational bead motion and rotational pin motion. By performing a number of tests we first show that our model is physically sound. We then focus on the study of a the kinetics of a DNA hairpin--a single-stranded molecule comprising two complementary segments joined by a non-complementary loop--studied experimentally. We find that results from our simulations agree with experimental observations, demonstrating that our model is a suitable tool for the investigation of the hybridization of single strands.

Keywords

Cite

@article{arxiv.q-bio/0506001,
  title  = {Mesoscopic modeling for nucleic acid chain dynamics},
  author = {M. Sales-Pardo and R. Guimera and A. A. Moreira and J. Widom and L. A. N. Amaral},
  journal= {arXiv preprint arXiv:q-bio/0506001},
  year   = {2009}
}

Comments

27 pages, 13 figures