首页> 外文会议>International Conference on Computational Intelligence and Security >The Computation of the Barrier Tree for BHG of RNA Folding Structure

【24h】

The Computation of the Barrier Tree for BHG of RNA Folding Structure

机译：RNA折叠结构BHG的障碍树计算

获取原文

页面导航

摘要
著录项
相似文献
相关主题

摘要

The number of different RNA secondary structures makes it impossible to enumerate the entire landscape except for short RNA sequences, so one has to resort to coarse-grained approximations. The landscape of the barrier tree encodes the local minima and their connecting energy barriers. The idea that it elucidates the basin structure of a landscape by means of a barrier tree has been developed independently in different contexts. The exact computation of barrier trees in general requires the enumeration of the landscape. There are many methods to compute the barrier tree, such as the Euclidean metric and the Huffman tree. We adopt the idea of the Huffman tree to compute the barrier tree, the thought is that we can see the every node in the tree as a separate tree, and then choose the smallest roots to merge into a tree. This process will not end until only one tree left in the forest.

机译：RNA二级结构的数量众多，除了简短的RNA序列外，不可能一概而论，因此必须诉诸于粗粒度的近似。势垒树的景观对局部极小值及其连接的能垒进行编码。通过障碍树阐明景观盆地结构的想法是在不同情况下独立提出的。障碍树的精确计算通常需要对景观进行枚举。有许多计算屏障树的方法，例如欧几里得度量和霍夫曼树。我们采用霍夫曼树的思想来计算势垒树，其思想是我们可以将树中的每个节点视为单独的树，然后选择最小的根以合并为树。直到森林中只剩下一棵树，该过程才会结束。

著录项

来源
《International Conference on Computational Intelligence and Security 》|2018年|6-9|共4页
会议地点
作者
Qingxia Kong; Zhendong Liu; Xiaobing Tang; Zhaohui Yang; Yaoyao Fu; Hengfei Li;
展开▼
作者单位

展开▼
会议组织
原文格式 PDF
正文语种
中图分类
关键词
RNA; Vegetation; Prediction algorithms; Bioinformatics; Computational modeling; Forestry; Euclidean distance;

机译：RNA;植被;预测算法;生物信息学;计算模型;林业;欧氏距离;

相似文献

外文文献
中文文献
专利

1. New Algorithms in RNA Structure Prediction Based on BHG [J] . Liu Zhendong, Li Gang, Liu Jun S. International Journal of Pattern Recognition and Artificial Intelligence . 2020 ,第13期

机译：基于BHG的RNA结构预测新算法
2. The osmolyte TMAO stabilizes native RNA tertiary structures in the absence of Mg2+: evidence for a large barrier to folding from phosphate dehydration. [J] . Lambert D, Leipply D, Draper DE Journal of Molecular Biology . 2010 ,第1期

机译：在没有Mg2 +的情况下，渗透液TMAO可以稳定天然RNA的三级结构：磷酸盐脱水折叠的巨大障碍的证据。
3. StructureFold2: Bringing chemical probing data into the computational fold of RNA structural analysis [J] . Tack David C., Tang Yin, Ritchey Laura E., Methods: A Companion to Methods in Enzymology . 2018 ,第期

机译：SristrationFold2：将化学探测数据带入RNA结构分析的计算折叠中
4. The Computation of the Barrier Tree for BHG of RNA Folding Structure [C] . Qingxia Kong, Zhendong Liu, Xiaobing Tang, International Conference on Computational Intelligence and Security . 2018

机译：用于RNA折叠结构BHG的阻挡树的计算
5. Insights into RNA tertiary folding: Examination of structure formation between the P1 helix and the pre-folded Tetrahymena group I ribozyme. [D] . Bartley, Laura Elizabeth. 2002

机译：RNA三次折叠的见解：检查P1螺旋与预先折叠的四膜虫群I核酶之间的结构形成。
6. The osmolyte TMAO stabilizes native RNA tertiary structures in the absence of Mg2+: evidence for a large barrier to folding from phosphate dehydration [O] . Dominic Lambert, Desirae Leipply, David E. Draper -1

机译：在没有Mg2 +的情况下稳定渗透肌肉TMAO稳定天然RNA三级结构：从磷酸盐脱水折叠的大屏障的证据
7. The Osmolyte TMAO Stabilizes Native RNA Tertiary Structures in the Absence of Mg2+: Evidence for a Large Barrier to Folding from Phosphate Dehydration [O] . Dominic Lambert, Desirae Leipply, David E. Draper 2010

机译：在没有Mg2 +的情况下稳定渗透肌肉TMAO稳定天然RNA三级结构：从磷酸盐脱水折叠的大屏障的证据
8. Knowledge Based Synthesis of Efficient Structures for Concurrent Computation Using Fat-Trees and Pipelining [R] . King, R. M., Brown, T., Green, C. 1986

机译：基于知识的脂树和流水线并行计算高效结构的综合

The Computation of the Barrier Tree for BHG of RNA Folding Structure

摘要

著录项

相似文献

相关主题

期刊订阅