Tertiary structure prediction is important for understanding structure-function relationships for RNAs whose structures are unknown and for characterizing RNA states recalcitrant to direct analysis. However, it is unknown what root-mean-square deviation (RMSD) corresponds to a statistically significant RNA tertiary structure prediction. We use discrete molecular dynamics to generate RNA-like folds for structures up to 161 nucleotides (nt) that have complex tertiary interactions and then determine the RMSD distribution between these decoys. These distributions are Gaussian-like. The mean RMSD increases with RNA length and is smaller if secondary structure constraints are imposed while generating decoys. The compactness of RNA molecules with true tertiary folds is intermediate between closely packed spheres and a freely jointed chain. We use this scaling relationship to define an expression relating RMSD with the confidence that a structure prediction is better than that expected by chance. This is the prediction significance, and corresponds to a P-value. For a 100-nt RNA, the RMSD of predicted structures should be within 25 A of the accepted structure to reach the P 展开▼
机译:三级结构预测对于理解结构未知的RNA的结构-功能关系以及表征难以直接分析的RNA状态非常重要。但是,未知什么均方根偏差(RMSD)对应于统计上显着的RNA三级结构预测。我们使用离散的分子动力学为具有复杂三级相互作用的多达161个核苷酸(nt)的结构生成类似RNA的折叠,然后确定这些诱饵之间的RMSD分布。这些分布类似于高斯分布。平均RMSD随RNA长度的增加而增加,如果在生成诱饵时施加二级结构限制,则较小。具有真正三级折叠的RNA分子的紧密度介于紧密堆积的球体和自由连接的链之间。我们使用这种缩放关系来定义与RMSD相关的表达式,并确信结构预测要比偶然预期的要好。这是预测意义,并且对应于P值。对于100 nt RNA,如果从头开始预测二级结构,则预测结构的RMSD应在可接受结构的25 A以内,以达到P <或= 0.01水平;如果以二级结构信息作为预测的,则应在14 A之内。约束。这种有意义的方法对于评估各种RNA结构预测和分子建模算法应该是有用的。
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