中文

Monte Carlo implementation of supercoiled double-stranded DNA

生物物理 2009-10-31 v1 软凝聚态物质 化学物理 计算物理 q-bio

摘要

Metropolis Monte Carlo simulation is used to investigate the elasticity of torsionally stressed double-stranded DNA, in which twist and supercoiling are incorporated as a natural result of base-stacking interaction and backbone bending constrained by hydrogen bonds formed between DNA complementary nucleotide bases. Three evident regimes are found in extension versus torsion and/or force versus extension plots: a low-force regime in which over- and underwound molecules behave similarly under stretching; an intermediate-force regime in which chirality appears for negatively and positively supercoiled DNA and extension of underwound molecule is insensitive to the supercoiling degree of the polymer; and a large-force regime in which plectonemic DNA is fully converted to extended DNA and supercoiled DNA behaves quite like a torsionless molecule. The striking coincidence between theoretic calculations and recent experimental measurement of torsionally stretched DNA [Strick et al., Science {\bf 271}, 1835 (1996), Biophys. J. {\bf 74}, 2016 (1998)] strongly suggests that the interplay between base-stacking interaction and permanent hydrogen-bond constraint takes an important role in understanding the novel properties of elasticity of supercoiled DNA polymer.

关键词

引用

@article{arxiv.physics/9911074,
  title  = {Monte Carlo implementation of supercoiled double-stranded DNA},
  author = {Zhang Yang and Zhou Haijun and Ouyang Zhongcan},
  journal= {arXiv preprint arXiv:physics/9911074},
  year   = {2009}
}

备注

21 pages, 6 PS figures. To appear at Biophys. J