纳米液滴中RNA碱基对的模拟揭示了溶剂化依赖性稳定性。
Simulations of RNA base pairs in a nanodroplet reveal solvation-dependent stability.
作者信息
Sykes Michael T, Levitt Michael
机构信息
Department of Structural Biology, Stanford University School of Medicine, D100 Fairchild Building, Stanford, CA 94305, USA.
出版信息
Proc Natl Acad Sci U S A. 2007 Jul 24;104(30):12336-40. doi: 10.1073/pnas.0705573104. Epub 2007 Jul 16.
Abstract
We show that RNA base pairs have variable stability depending on their degree of solvation. This finding has far-reaching biological implications for nucleic acid structure in a partially solvated cellular environment such as inside RNA-protein complexes. Molecular dynamics simulations of partially solvated Watson-Crick RNA base pairs show that whereas water serves to destabilize a base pair by competing for and disrupting base-base hydrogen bonds, when sufficient water molecules are present, fewer hydrogen bonds are available to disrupt the base pairs and the destabilization effect is reduced. The result is that base pairs exist at a stability minimum when solvated in between 20 and 100 water molecules, the upper limit of which corresponds to the approximate number of water molecules contained in the first hydration shell.
摘要
我们发现,RNA碱基对的稳定性因其溶剂化程度而异。这一发现对于诸如RNA-蛋白质复合物内部等部分溶剂化的细胞环境中的核酸结构具有深远的生物学意义。对部分溶剂化的沃森-克里克RNA碱基对进行分子动力学模拟表明,水通过竞争和破坏碱基间的氢键使碱基对不稳定,然而,当存在足够数量的水分子时,可供破坏碱基对的氢键数量减少,去稳定化效应降低。结果是,当在20至100个水分子之间进行溶剂化时,碱基对处于最低稳定性状态,其中上限对应于第一水化层中所含水分子的近似数量。
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