Delineation of the DNA Structural Features of Eukaryotic Core Promoter Classes

Vanaja, Akkinepally; Yella, Venkata Rajesh

doi:10.1021/acsomega.1c04603

Cited by 16 publications

(7 citation statements)

References 84 publications

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“…Transcription carried out by an initiator is usually from a position that overlaps a TSS [ 28 ]. A downstream promoter element (DPE) consensus (A/G-G-A/T-C/T-G/A/C) located +28 to 32 relative to the initiator, was mainly present in core promoters that lack a TATA box motif [ 30 ]. However, no potential DPE element was identified downstream of the putative initiator in the GSTe2 promoter in An.…”

Section: Discussionmentioning

confidence: 99%

Identification of putative promoter elements for epsilon glutathione s-transferases genes associated with resistance to DDT in the malaria vector mosquito anopheles arabiensis

Manu,

Abduljalal,

Rabiu

et al. 2024

Scientific African

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Section: Discussionmentioning

confidence: 99%

Identification of putative promoter elements for epsilon glutathione s-transferases genes associated with resistance to DDT in the malaria vector mosquito anopheles arabiensis

Manu,

Abduljalal,

Rabiu

et al. 2024

Scientific African

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“…In the next step, a preliminary analysis is essential to convert the TSS level methylation to gene level, focusing specifically on the -6 kb to +3 kb range around transcription start sites (TSS). This range will be subdivided into five distinct regions and probes located outside this specified range will be excluded from the analysis, which will convert rows from the CpG site level to gene-level [33][34][35][36][37] . In detail, promoter regions were delineated into three categories: the core promoter region (0-50bp upstream of TSS), the proximal promoter region (50-250bp upstream of TSS), and the distal promoter region (250-3000bp upstream of TSS).…”

Section: Mapping Data To Gene-levelmentioning

confidence: 99%

mosGraphGen: a novel tool to generate multi-omic signaling graphs to facilitate integrative and interpretable graph AI model development

Zhang,

Cao,

Chen

et al. 2024

Preprint

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Multi-omic data, i.e., genomics, epigenomics, transcriptomics, proteomics, characterize cellular complex signaling systems from multi-level and multi-view and provide a holistic view of complex cellular signaling pathways. However, it remains challenging to integrate and interpret multi-omics data. Graph neural network (GNN) AI models have been widely used to analyze graph-structure datasets and are ideal for integrative multi-omics data analysis because they can naturally integrate and represent multi-omics data as a biologically meaningful multi-level signaling graph and interpret multi-omics data by node and edge ranking analysis for signaling flow/cascade inference. However, it is non-trivial for graph-AI model developers to pre-analyze multi-omics data and convert them into graph-structure data for individual samples, which can be directly fed into graph-AI models. To resolve this challenge, we developed mosGraphGen (multi-omics signaling graph generator), a novel computational tool that generates multi-omics signaling graphs of individual samples by mapping the multi-omics data onto a biologically meaningful multi-level background signaling network. With mosGraphGen, AI model developers can directly apply and evaluate their models using these mos-graphs. We evaluated the mosGraphGen using both multi-omics datasets of cancer and Alzheimers disease (AD) samples. The code of mosGraphGen is open-source and publicly available via GitHub: https://github.com/Multi-OmicGraphBuilder/mosGraphGen

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“…A promoter is a DNA sequence that controls gene expression; it contains binding sites for transcription factors and RNA polymerases [ 19 ]. The number and spectrum of transcription factors involved and the position of their binding sites relative to the transcription start site (TSS) determine the frequency of binding of the transcription complex and, therefore, the efficiency of gene expression that corresponds to such a characteristic of the promoter as “promoter strength” [ 19 , 20 , 21 ]. The versatility or tissue-specificity of a promoter (the ability to provide gene expression in a wide range of cells or in a certain type of them) is ensured by the presence of binding sites for versatile or tissue-specific transcription factors, respectively [ 19 , 20 , 21 ].…”

Section: Cis-/transgene Expression In Cell Lines Genetically Encoded ...mentioning

confidence: 99%

“…The number and spectrum of transcription factors involved and the position of their binding sites relative to the transcription start site (TSS) determine the frequency of binding of the transcription complex and, therefore, the efficiency of gene expression that corresponds to such a characteristic of the promoter as “promoter strength” [ 19 , 20 , 21 ]. The versatility or tissue-specificity of a promoter (the ability to provide gene expression in a wide range of cells or in a certain type of them) is ensured by the presence of binding sites for versatile or tissue-specific transcription factors, respectively [ 19 , 20 , 21 ]. A constitutively active promoter contains binding sites for transcription factors that are permanently active in a certain cell type, which ensures constant gene expression.…”

Section: Cis-/transgene Expression In Cell Lines Genetically Encoded ...mentioning

confidence: 99%

The Power of Gene Technologies: 1001 Ways to Create a Cell Model

Karagyaur

Primak

Efimenko

et al. 2022

Cells

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Modern society faces many biomedical challenges that require urgent solutions. Two of the most important include the elucidation of mechanisms of socially significant diseases and the development of prospective drug treatments for these diseases. Experimental cell models are a convenient tool for addressing many of these problems. The power of cell models is further enhanced when combined with gene technologies, which allows the examination of even more subtle changes within the structure of the genome and permits testing of proteins in a native environment. The list and possibilities of these recently emerging technologies are truly colossal, which requires a rethink of a number of approaches for obtaining experimental cell models. In this review, we analyze the possibilities and limitations of promising gene technologies for obtaining cell models, and also give recommendations on the development and creation of relevant models. In our opinion, this review will be useful for novice cell biologists, as it provides some reference points in the rapidly growing universe of gene and cell technologies.

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Delineation of the DNA Structural Features of Eukaryotic Core Promoter Classes

Cited by 16 publications

References 84 publications

Identification of putative promoter elements for epsilon glutathione s-transferases genes associated with resistance to DDT in the malaria vector mosquito anopheles arabiensis

Identification of putative promoter elements for epsilon glutathione s-transferases genes associated with resistance to DDT in the malaria vector mosquito anopheles arabiensis

mosGraphGen: a novel tool to generate multi-omic signaling graphs to facilitate integrative and interpretable graph AI model development

The Power of Gene Technologies: 1001 Ways to Create a Cell Model

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