Search results for "CTCF"

showing 5 items of 5 documents

Reevaluating the function of a transcription factor: MBF-1 as a sea urchin chromatin organizer ?

2014

The Zinc-finger MBF-1 factor is involved in the expression of the early histone genes during devel-opment of the sea urchin embryo (1, 2). In spite of being a transcription activator, the DNA-binding domain of MBF-1 shares high sequence similarity with that of the chromatin organizer CTCF of vertebrates and drosophila (3). On the other hand, extensive in silico analysis failed to identify the sea urchin CTCF ortholog (4). This led us to speculate that MBF-1 somehow could have co-opted the function of CTCF during evolution of the echinoderms. Since in vertebrates CTCF binds Hox chromatin, to support our hypothesis, we first identified high-score putative binding sequences for CTCF/MBF-1 with…

MBF-1 activator; CTCF; Hox genes; chromatin immunoprecipitationSettore BIO/11 - Biologia Molecolarechromatin immunoprecipitationCTCFMBF-1 activatorHox gene
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CTCF and BORIS Regulate Rb2/p130 Gene Transcription: A Novel Mechanism and a New Paradigm for Understanding the Biology of Lung Cancer

2011

Abstract Although innumerable investigations regarding the biology of lung cancer have been carried out, many aspects thereof remain to be addressed, including the role played by the retinoblastoma-related protein Rb2/p130 during the evolution of this disease. Here we report novel findings on the mechanisms that control Rb2/p130 gene expression in lung fibroblasts and characterize the effects of Rb2/p130 deregulation on the proliferative features of lung cancer cells. We revealed for the first time that in lung fibroblasts the expression of Rb2/p130 gene is directly controlled by the chromatin insulator CCCTC-binding factor, CTCF, which by binding to the Rb2/p130 gene promoter induces, and/…

CCCTC-Binding FactorChromatin ImmunoprecipitationCancer ResearchLung NeoplasmsTranscription GeneticSettore MED/06 - Oncologia MedicaBiologyInsulator (genetics)Open Reading FramesTranscription (biology)Carcinoma Non-Small-Cell LungCell Line TumorGene expressionmedicineHumansCarcinoma Small CellPromoter Regions GeneticLung cancerChromosome PositioningMolecular BiologyGeneBinding SitesRetinoblastoma-Like Protein p130PromoterFibroblastsmedicine.diseaseChromatinDNA-Binding ProteinsGene Expression Regulation NeoplasticRepressor ProteinsGene transcriptionOncologyCTCFembryonic structuresCancer researchLung cancerLung cancer; Gene transcriptionbiological phenomena cell phenomena and immunityProtein BindingMolecular Cancer Research
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Genome wide mapping of the MBF-1 binding sites during embryogenesis of the sea urchin reveals it is a chromatin organizer.

2015

The Zinc-finger MBF1 factor is a transcription activator involved in the expression of the early histone genes during development of the sea urchin embryo (1). The DNA-binding domain of MBF1 shares high sequence similarity with that of the CTCF chromatin organizer but, unexpectedly, extensive in silico analysis failed to identify the sea urchin CTCF ortholog (2, 3). This led us to speculate that MBF1 could have co-opted the function of CTCF during evolution of the echinoderms. To support this hypothesis, we performed the genome-wide MBF1-binding sites mapping in the P. lividus genome, by chromatin immunoprecipitation coupled to next generation sequencing (ChIP-Seq). We observed that MBF1 bi…

sea urchin embryohox geneszinc-fingerzinc-finger; CTCF; sea urchin embryo; chromatin immunoprecipitation; hox genesSettore BIO/11 - Biologia Molecolarechromatin immunoprecipitationCTCF
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7C: Computational Chromosome Conformation Capture by Correlation of ChIP-seq at CTCF motifs.

2019

Abstract Background Knowledge of the three-dimensional structure of the genome is necessary to understand how gene expression is regulated. Recent experimental techniques such as Hi-C or ChIA-PET measure long-range chromatin interactions genome-wide but are experimentally elaborate, have limited resolution and such data is only available for a limited number of cell types and tissues. Results While ChIP-seq was not designed to detect chromatin interactions, the formaldehyde treatment in the ChIP-seq protocol cross-links proteins with each other and with DNA. Consequently, also regions that are not directly bound by the targeted TF but interact with the binding site via chromatin looping are…

CCCTC-Binding Factorlcsh:QH426-470Protein Conformationlcsh:Biotechnologygenetic processesComputational biologyBiologyGenomeChromosomesBioconductorChromosome conformation capture03 medical and health sciences0302 clinical medicine6CHi-Clcsh:TP248.13-248.65GeneticsTranscription factorsHumansnatural sciencesNucleotide Motifs4CChIA-PET030304 developmental biologyChromatin loops0303 health sciencesThree-dimensional genome architectureChromatinChromatinChIP-seq7Clcsh:Genetics5CCTCFChromatin Immunoprecipitation SequencingHuman genomeDNA microarrayChIA-PET3CPrediction030217 neurology & neurosurgeryChromatin interactionsBiotechnologyHeLa CellsResearch ArticleBMC genomics
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Computational Chromosome Conformation Capture by Correlation of ChIP-seq at CTCF motifs

2018

Background: Transcription factors (TFs) bind to gene promoters or distal regulatory elements that interact with the promoter via chromatin looping. While the TF binding sites themselves are detected genome-wide by ChIP-seq experiments, it is difficult to associate them regulated genes without information of chromatin looping. Recent experimental techniques such as Hi-C or ChIA-PET measure long-range interactions genome-wide but are experimentally elaborate and have limited resolution. Here, we present Computational Chromosome Conformation Capture by Correlation of ChIP-seq at CTCF motifs (7C). Results: While ChIP-seq was not designed to detect contacts, the formaldehyde treatment in the ChI…

PhysicsChromosome conformation captureCTCFgenetic processesnatural sciencesHuman genomePromoterComputational biologyBinding siteSequence motifTranscription factorChromatin
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