Differential influence of DNA supercoiling on in vivo strength of promoters varying in structure and organisation in E. coli

AbstractDNA supercoiling is known to influence promoter activity in vitro and in vivo in a promoter-dependent manner in prokaryotes. In order to investigate how topology may influence promoter function, we have studied two kinds of promoter variants, (i) where only the spacer region is altered, and (ii) where the same promoter is tandemly repeated in either the same or opposite orientation. These promoters respond very differently to alterations in DNA supercoiling, suggesting that the overall structure of the promoter and its context contribute to the differential response to alterations in supercoiling in vivo

Promoter search and strength of a promoter: two important means for regulation of gene expression in Escherichia coli

Search for a promoter element by RNA polymerase from the extremely large DNA base sequence is thought to be the slowest and rate-determining for the regulation of transcription process. Few direct experiments we described here which have tried to follow the mechanistic implications of this promoter search. However, once the promoter is located, transcription complex, constituting mainly the RNA polymerase molecule and few transcription factors has to unidirectionally clear the promoter and elongate the RNA chain through a series of steps which altogether define the initiation of transcription process. Thus, it appears that the promoter sequence acts as a trap for RNA polymerase associated with a large binding constant, although to clear the promoter and to elongate the transcript such energy barrier has to be overcome. Topological state of the DNA, particularly in the neighbourhood of the promoter plays an important role in the energetics of the whole process

Dynamics of nuclear matrix proteome during embryonic development in Drosophila melanogaster

Embryonic development is a complex and dynamic process that involves spatiotemporal expression of genes in a highly coordinated manner. Multiple levels of nuclear architecture maintain the fidelity of gene expression programme. One of the components of nuclear architecture, which is believed to play an important role in regulation of gene expression, is the nuclear matrix (NuMat). Many studies over the past few years have tried to analyse the components of this non-chromatin scaffolding of the nucleus and have provided evidences of its structural and functional complexity. However, the relationship of NuMat with the process of embryonic development still remains poorly understood. Here, we report a comparative analysis of the NuMat proteomes of early and late stage Drosophila melanogaster embryos and show that 65% of the NuMat proteome is dynamic during development. Our study establishes links between the dynamics of nuclear architecture and embryonic development and provides tools to further understand the process such as cellular differentiation in the context of higher-order nuclear organization

Transposable elements as scaffold/matrix attachment regions: shaping organization and functions in genomes

The hierarchical structure of eukaryotic genomes has regulatory layers, one of them being epigenetic “indexing” of the genome that leads to cell-type-specific patterns of gene expression. By establishing loops and defining chromatin domains, cells can achieve coordinated control over multi-locus segments of the genome. This is thought to be achieved using scaffold/matrix attachment regions (S/MARs) that establish structural and functional loops and topologically associating domains (TADs) that define a self-interacting region of the genome. Large-scale genome-wide mapping of S/MARs has begun to uncover these aspects of genome organization. A recent genome-wide study showed the association of transposable elements (TEs) with a significant fraction of S/MARs, suggesting that the multitude of TE-derived repeats constitute a class of anchorage sites of chromatin loops to nuclear architecture. In this study, we provide an insight that TE-driven dispersal of S/MARs has the potential to restructure the chromosomes by creating novel loops and domains. The combination of TEs and S/MARs, as elements that can hop through the genome along with regulatory capabilities, may provide an active mechanism of genome evolution leading to the emergence of novel features in biological systems. The significance is that a genome-wide study mapping developmental S/MARs reveals an intriguing link between these elements and TEs. This article highlights the potential of the TE–S/MAR combination to drive evolution by restructuring and shaping the genome

Fire Safety Analysis of a Railway Compartment using Computational Fluid Dynamics

Trains are considered to be the safest on-land transportation means for both passengers and cargo. Train accidents have been mainly disastrous, especially in case of fire, where the consequences are extensive loss of life and goods. The fire would generate smoke and heat which would spread quickly inside the railway compartments. Both heat and smoke are the primary reasons of casualties in a train. This study has been carried out to perform numerical analysis of fire characteristics in a railway compartment using commercial Computational Fluid Dynamics code ANSYS. Non-premixed combustion model has been used to simulate a fire scenario within a railway compartment, while Shear Stress Transport k-ω turbulence model has been used to accurately predict the hot air turbulence parameters within the compartment. The walls of the compartment have been modelled as no-slip stationary adiabatic walls, as is observed in real life conditions. Carbon dioxide concentration (CO2), temperature distribution and air flow velocity within the railway compartment has been monitored. It has been observed that the smoke above the fire source flows to both sides of the compartment. The highest temperature zone is located downstream the fire source, and gradually decreases with the increase in the distance from the fire source. It can be seen that CFD can be used as an effective tool in order to analyse the evolution of fire in railway compartments with reasonable accuracy. The paper also briefly discusses the topical reliability issues

Inheritance of chromatin structure

This article does not have an abstract

Genome-wide analysis of Bkm sequences (GATA repeats): predominant association with sex chromosomes and potential role in higher order chromatin organization and function

Motivation: Bkm (Banded krait minor) satellite DNA sequences (GATA repeats) have been shown to be associated with the sex determining chromosomes of various eukaryotes and have been implicated in the evolution and differentiation of sex chromosomes in snakes. The objective of the study is to analyze the GATA repeats of human genome specifically, the Y-chromosome, and other model organisms to understand the possible function and potential role in higher order chromatin organization. Results: Our extensive analysis of GATA repeats in the prokaryotic and eukaryotic genomes, which have been completely sequenced so far, has revealed that GATA repeats are absent in prokaryotes and have been gradually accumulated in higher organisms during the course of evolution. In human, the Y-chromosome has the highest GATA repeat density, which predominantly exists in the Yq centromeric region. Generally, occurrence of repeats in the genomes decreases steadily as the length of the repeat increases. In contrast, we report, that the occurrence of GATA repeats increases as the length of the repeat increases from six tandem repeats onwards and peaks at (GATA)10-12. This has not been observed with any other simple repeat. Distribution of (GATA)10-12 along the chromosome and their close proximity to Matrix Associated Regions (GATA-MAR) suggests that it may be demarking chromatin domains for a coordinated expression of genes residing in these domains

Bridging the gap but breaking the rule: a tunicate twists the hox puzzle

This article does not have an abstract

Genome-wide analysis of microsatellite repeats in humans: their abundance and density in specific genomic regions

BACKGROUND: Simple sequence repeats (SSRs) are found in most organisms, and occupy about 3% of the human genome. Although it is becoming clear that such repeats are important in genomic organization and function and may be associated with disease conditions, their systematic analysis has not been reported. This is the first report examining the distribution and density of simple sequence repeats (1-6 base-pairs (bp)) in the entire human genome. RESULTS: The densities of SSRs across the human chromosomes were found to be relatively uniform. However, the overall density of SSR was found to be high in chromosome 19. Triplets and hexamers were more predominant in exonic regions compared to intronic and intergenic regions, except for chromosome Y. Comparison of densities of various SSRs revealed that whereas trimers and pentamers showed a similar pattern (500-1,000 bp/Mb) across the chromosomes, di- tetra- and hexa-nucleotide repeats showed patterns of higher (2,000-3,000 bp/Mb) density. Repeats of the same nucleotide were found to be higher than other repeat types. Repeats of A, AT, AC, AAT, AAC, AAG, AGC, AAAC, AAAT, AAAG, AAGG, AGAT predominate, whereas repeats of C, CG, ACT, ACG, AACC, AACG, AACT, AAGC, AAGT, ACCC, ACCG, ACCT, CCCG and CCGG are rare. CONCLUSIONS: The overall SSR density was comparable in all chromosomes. The density of different repeats, however, showed significant variation. Tri- and hexa-nucleotide repeats are more abundant in exons, whereas other repeats are more abundant in non-coding regions