Structural features of DNA that determine RNA polymerase II core promoter

Il’icheva, I. A.; Khodikov, Mingian V.; Poptsova, Maria; Nechipurenko, Dmitry; Nechipurenko, Yu. D.; Grokhovsky, S. L.

doi:10.1186/s12864-016-3292-z

Cited by 11 publications

(22 citation statements)

References 57 publications

(54 reference statements)

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“…Thse frequency of XY dinucleotides was calculated not in the whole genome but in the 200-bp-long genome fragment around the read-start positions. By doing that we took into account all the sequence biases associated with read mapping positions 18 .…”

Section: Methodsmentioning

confidence: 99%

A Method for Identification of the Methylation Level of CpG Islands From NGS Data

Урошлев

Abdullaev

Umarova

et al. 2020

Sci Rep

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In the course of sample preparation for Next Generation Sequencing (NGS), DNA is fragmented by various methods. Fragmentation shows a persistent bias with regard to the cleavage rates of various dinucleotides. With the exception of CpG dinucleotides the previously described biases were consistent with results of the DNA cleavage in solution. Here we computed cleavage rates of all dinucleotides including the methylated CpG and unmethylated CpG dinucleotides using data of the Whole Genome Sequencing datasets of the 1000 Genomes project. We found that the cleavage rate of CpG is significantly higher for the methylated CpG dinucleotides. Using this information, we developed a classifier for distinguishing cancer and healthy tissues based on their CpG islands statuses of the fragmentation. A simple Support Vector Machine classifier based on this algorithm shows an accuracy of 84%. The proposed method allows the detection of epigenetic markers purely based on mechanochemical DNA fragmentation, which can be detected by a simple analysis of the NGS sequencing data.

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Section: Methodsmentioning

confidence: 99%

A Method for Identification of the Methylation Level of CpG Islands From NGS Data

Урошлев

Abdullaev

Umarova

et al. 2020

Sci Rep

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“…The entwined aspect found suggests the promoter activity is well represented and each one of the energy-related features might describe promoter activity. The employment of structural features has shown a satisfactory way to locate transcription factor (TF) protein binding sites [13] in a way sheer consensual motifs are not enough to represent promoter activity, indeed, Deyneko et al [10] suggested that there is a feature conservation around promoter sequences.…”

Section: Rnap Binding Is Explained By Different Levels Of Enthalpy Free-stability and Base-pair Stackingmentioning

confidence: 99%

DNA structural and physical properties reveal peculiarities in promoter sequences of the bacterium Escherichia coli K-12

et al. 2021

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The gene transcription of bacteria starts with a promoter sequence being recognized by a transcription factor found in the RNAP enzyme, this process is assisted through the conservation of nucleotides as well as other factors governing these intergenic regions. Faced with this, the coding of genetic information into physical aspects of the DNA such as enthalpy, stability, and base-pair stacking could suggest promoter activity as well as protrude differentiation of promoter and non-promoter data. In this work, a total of 3131 promoter sequences associated to six different sigma factors in the bacterium E. coli were converted into numeric attributes, a strong set of control sequences referring to a shuffled version of the original sequences as well as coding regions is provided. Then, the parameterized genetic information was normalized, exhaustively analyzed through statistical tests. The results suggest that strong signals in the promoter sequences match the binding site of transcription factor proteins, indicating that promoter activity is well represented by its conversion into physical attributes. Moreover, the features tested in this report conveyed significant variances between promoter and control data, enabling these features to be employed in bacterial promoter classification. The results produced here may aid in bacterial promoter recognition by providing a robust set of biological inferences.

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“…At the scale of a few nucleotides, DNA structure is determined by the arrangement of bases, the nature of which determines the depth and hydropathy of the DNA grooves, as well as local electrostatic and electronic properties which collectively determine interactions between DNA and proteins such as transcription factors recruiting RNA polymerases [26]. At the scale of a dozen to hundreds of nucleotides, the nucleotide composition determines DNA thermodynamic and mechanical properties, such as resistance and response to topological stresses with consequences on transcription initiation and elongation [25,31,247]. Nucleotide composition-dependent mechanical properties, such as DNA bendability and rigidity, play a role in nucleosome positioning.…”

Section: Appendix A1 Genome Physical Organization: From Gene Expresmentioning

confidence: 99%

Physicochemical Foundations of Life that Direct Evolution: Chance and Natural Selection are not Evolutionary Driving Forces

Auboeuf

2020

Life

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The current framework of evolutionary theory postulates that evolution relies on random mutations generating a diversity of phenotypes on which natural selection acts. This framework was established using a top-down approach as it originated from Darwinism, which is based on observations made of complex multicellular organisms and, then, modified to fit a DNA-centric view. In this article, it is argued that based on a bottom-up approach starting from the physicochemical properties of nucleic and amino acid polymers, we should reject the facts that (i) natural selection plays a dominant role in evolution and (ii) the probability of mutations is independent of the generated phenotype. It is shown that the adaptation of a phenotype to an environment does not correspond to organism fitness, but rather corresponds to maintaining the genome stability and integrity. In a stable environment, the phenotype maintains the stability of its originating genome and both (genome and phenotype) are reproduced identically. In an unstable environment (i.e., corresponding to variations in physicochemical parameters above a physiological range), the phenotype no longer maintains the stability of its originating genome, but instead influences its variations. Indeed, environment- and cellular-dependent physicochemical parameters define the probability of mutations in terms of frequency, nature, and location in a genome. Evolution is non-deterministic because it relies on probabilistic physicochemical rules, and evolution is driven by a bidirectional interplay between genome and phenotype in which the phenotype ensures the stability of its originating genome in a cellular and environmental physicochemical parameter-depending manner.

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Structural features of DNA that determine RNA polymerase II core promoter

Cited by 11 publications

References 57 publications

A Method for Identification of the Methylation Level of CpG Islands From NGS Data

A Method for Identification of the Methylation Level of CpG Islands From NGS Data

DNA structural and physical properties reveal peculiarities in promoter sequences of the bacterium Escherichia coli K-12

Physicochemical Foundations of Life that Direct Evolution: Chance and Natural Selection are not Evolutionary Driving Forces

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