Weak Signal Carried by Chromatin DNA Sequences: Zooming In and Sobering Surprises

2016 Second International Symposium on Stochastic Models in Reliability Engineering, Life Science and Operations Management (SMRLO) Pub Date : 2016-02-15 DOI:10.1109/SMRLO.2016.73

E. Trifonov

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Abstract

The 35 year long story of the chromatin signal (code) started with discovery of a very weak 10-11 base sequence periodicity of AA and TT dinucleotides, detected by distance analysis (equivalent of autocorrelation in time series). It soon became clear that this is counter-phase oscillation of AA and TT, or rather of RR and YY - by a version of multiple alignment ("synchronous detection" in signal processing). The campaign incrementally agonized through reconstruction of signal from its parts, N-gram Shannon extension and strong nucleosomes (SNs) with visible sequence periodicity to (RRRRRYYYYY)n pattern, and culminated in this form, with small changes suggested by consensuses from strong nucleosomes. 10-11 base YR dinucleotide periodicity (first suggested by Zhurkin) is a part of the above consensus. The periodically repeating YR elements form long tracks of hundreds to thousands base-pairs indicating that the chromatin consists of columnar structures, rather than of solitary nucleosomes. In particular, the classical SV40 minichromosome appears to form one continuous column.

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染色质DNA序列携带的弱信号:放大和清醒的惊喜

染色质信号(代码)长达35年的历史始于发现AA和TT二核苷酸非常弱的10-11个碱基序列周期，通过距离分析(相当于时间序列的自相关)检测到。很快就清楚了，这是AA和TT的反相振荡，或者更确切地说，是RR和YY的反相振荡——通过一种版本的多重对准(信号处理中的“同步检测”)。通过部分信号的重建，n -gram香农延伸和具有明显序列周期性(RRRRRYYYYY)n模式的强核小体(SNs)，运动逐渐痛苦，最终以这种形式结束，由强核小体的共识提示微小变化。10-11碱基YR二核苷酸周期性(最早由Zhurkin提出)是上述共识的一部分。周期性重复的YR元素形成数百到数千个碱基对的长轨迹，表明染色质由柱状结构组成，而不是孤立的核小体。特别是，经典的SV40小染色体似乎形成一个连续的柱。

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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2016 Second International Symposium on Stochastic Models in Reliability Engineering, Life Science and Operations Management (SMRLO)

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