Recurrence time statistics: versatile tools for genomic DNA sequence analysis.

Yinhe Cao, Wen-Wen Tung, J B Gao
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引用次数: 10

Abstract

With the completion of the human and a few model organisms' genomes, and the genomes of many other organisms waiting to be sequenced, it has become increasingly important to develop faster computational tools which are capable of easily identifying the structures and extracting features from DNA sequences. One of the more important structures in a DNA sequence is repeat-related. Often they have to be masked before protein coding regions along a DNA sequence are to be identified or redundant expressed sequence tags (ESTs) are to be sequenced. Here we report a novel recurrence time based method for sequence analysis. The method can conveniently study all kinds of periodicity and exhaustively find all repeat-related features from a genomic DNA sequence. An efficient codon index is also derived from the recurrence time statistics, which has the salient features of being largely species-independent and working well on very short sequences. Efficient codon indices are key elements of successful gene finding algorithms, and are particularly useful for determining whether a suspected EST belongs to a coding or non-coding region. We illustrate the power of the method by studying the genomes of E. coli, the yeast S. cervisivae, the nematode worm C. elegans, and the human, Homo sapiens. Computationally, our method is very efficient. It allows us to carry out analysis of genomes on the whole genomic scale by a PC.

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复发时间统计:基因组DNA序列分析的通用工具。
随着人类和一些模式生物基因组的完成,以及许多其他生物的基因组等待测序,开发更快的计算工具,能够轻松地从DNA序列中识别结构和提取特征变得越来越重要。DNA序列中一个更重要的结构是重复相关的。通常,在确定DNA序列中的蛋白质编码区或对冗余表达序列标签(ESTs)进行测序之前,必须先对它们进行掩盖。本文报告了一种新的基于递归时间的序列分析方法。该方法可以方便地研究基因组DNA序列的各种周期性,并穷尽地找出基因组DNA序列中所有与重复相关的特征。根据重复时间统计量推导出有效的密码子索引,该索引具有很大程度上与物种无关的特点,并能很好地适用于非常短的序列。有效的密码子索引是成功的基因发现算法的关键要素,对于确定可疑EST是否属于编码区或非编码区特别有用。我们通过研究大肠杆菌、酵母S. cervisivae、线虫C. elegans和人类智人(Homo sapiens)的基因组来说明该方法的力量。计算上,我们的方法是非常有效的。它允许我们在PC上对整个基因组进行分析。
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