Structuring of counterions around dna double helix: a molecular dynamics study

O. O. Liubysh, A. Vlasiuk, S. Perepelytsya, T. Shevchenko
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引用次数: 7

Abstract

Structuring of DNA counterions around the double helix has been studied by the molecular dynamics method. A DNA dodecamer d(CGCGAATTCGCG) in water solution with the alkali metal counterions Na$^{+}$, K$^{+}$, and Cs$^{+}$ has been simulated. The systems have been considered in the regimes without excess salt and with different salts (0.5 M of NaCl, KCl or CsCl) added. The results have showed that the Na$^{+}$ counterions interact with the phosphate groups directly from outside of the double helix and via water molecules at the top edge of DNA minor groove. The potassium ions are mostly localized in the grooves of the double helix, and the cesium ions penetrate deeply inside the minor groove being bonded directly to the atoms of nucleic bases. Due to the electrostatic repulsion the chlorine ions tend to be localized at large distances from the DNA polyanion, but some Cl$^{-}$ anions have been detected near atomic groups of the double helix forming electrically neutral pairs with counterions already condensed on DNA. The DNA sites, where counterions are incorporated, are characterized by local changes of double helix structure. The lifetime of Na$^{+}$ and K$^{+}$ in complex with DNA atomic groups is less than 0.5 ns, while in the case of the cesium ions it may reach several nanoseconds. In this time scale, the Cs$^{+}$ counterions form a structured system of charges in the DNA minor groove that can be considered as ionic lattice.
dna双螺旋反离子结构:分子动力学研究
用分子动力学方法研究了DNA双螺旋反离子的结构。本文模拟了DNA十二聚体d(CGCGAATTCGCG)与碱金属离子Na$^{+}$、K$^{+}$和Cs$^{+}$在水溶液中的反应。在无过量盐和添加不同盐(0.5 M NaCl、KCl或CsCl)的情况下,对体系进行了考虑。结果表明,Na$^{+}$反离子直接从双螺旋外与磷酸基相互作用,并通过DNA小槽顶部边缘的水分子与磷酸基相互作用。钾离子主要集中在双螺旋的凹槽中,而铯离子则深入到小凹槽中,直接与核酸基原子结合。由于静电斥力,氯离子倾向于定位在离DNA多阴离子较远的地方,但一些Cl$^{-}$阴离子已经在DNA上凝聚形成电中性对的双螺旋原子群附近被检测到。反离子结合的DNA位点以双螺旋结构的局部变化为特征。Na$^{+}$和K$^{+}$在与DNA原子基团配合物中的寿命小于0.5 ns,而在与铯离子配合物中的寿命可达数纳秒。在这个时间尺度上,Cs$^{+}$反离子在DNA小槽中形成了一个结构化的电荷系统,可以认为是离子晶格。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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