Genomic and Proteomic Analyses of Prdm5 Reveal Interactions with Insulator Binding Proteins in Embryonic Stem Cells

Galli, Giorgio; Carrara, Matteo; Francavilla, Chiara; Lichtenberg, Kristian Honnens de; Olsen, Jesper V.; Calogero, Raffaele; Lund, Anders H.

doi:10.1128/mcb.00545-13

Cited by 30 publications

(35 citation statements)

References 59 publications

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“…Furthermore, YY1 is enriched with CTCF at TAD borders [21]. As is the case in Drosophila , TFIIIC colocalizes with CTCF, cohesin, and the DNA-binding tumor suppressor protein Prdm5 at many locations of the mammalian genome [22–24]. The POZ-Zn finger transcription factor Kaiso interacts with CTCF but its genome-wide distribution or possible role in 3D organization has not been explored in detail [25].…”

Section: Architectural Proteinsmentioning

confidence: 99%

Towards a predictive model of chromatin 3D organization

Corcés

2016

Seminars in Cell & Developmental Biology

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Architectural proteins mediate interactions between distant regions in the genome to bring together different regulatory elements while establishing a specific three-dimensional organization of the genetic material. Depletion of specific architectural proteins leads to miss regulation of gene expression and alterations in nuclear organization. The specificity of interactions mediated by architectural proteins depends on the nature, number, and orientation of their binding site at individual genomic locations. Knowledge of the mechanisms and rules governing interactions among architectural proteins may provide a code to predict the 3D organization of the genome.

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Section: Architectural Proteinsmentioning

confidence: 99%

Towards a predictive model of chromatin 3D organization

Corcés

2016

Seminars in Cell & Developmental Biology

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“…Recent experiments showing that tRNA genes can block enhancer function and that TFIIIC co-localizes with CTCF at many ETC loci through the mouse and human genomes suggest a conservation in the function of TFIIIC as an architectural protein from yeast to humans [14]. Other proteins shown to co-localize or directly interact with CTCF in vertebrates include YY1, Kaiso, chromodomain helicase DNA-binding protein 8 (CHD8), PARP1, MYC-associated zinc-finger protein (MAZ), JUND, zinc-finger protein 143 (ZNF143), PR domain zinc-finger protein 5 (PRDM5) and nucleophosmin [15-17]. Drosophila has also been a rich source of information aimed at understanding the structure and organization of this class of proteins.…”

Section: Architectural Proteins: Structure and Organizationmentioning

confidence: 99%

Architectural proteins: regulators of 3D genome organization in cell fate

Gómez-Díaz

Corcés

2014

Trends in Cell Biology

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The relationship between alterations in chromatin structure and changes in gene expression during cell differentiation has served as a paradigm to understand the link between genome organization and function. Yet the factors involved and the mechanisms by which the three-dimensional organization of the nucleus is established remain poorly understood. The use of Chromosome Conformation-Capture (3C) based approaches has resulted in a new appreciation of the role of architectural proteins in the establishment of 3D genome organization. Architectural proteins orchestrate higher-order chromatin organization through the establishment of interactions between regulatory elements across multiple spatial scales. The regulation of these proteins, their interaction with DNA, and their co occurrence in the genome, may be responsible for the plasticity of 3D-chromatin architecture that dictates cell and time-specific blueprints of gene expression.

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“…We then asked how TFIIIC could promote chromatin looping with CTCF, which is enriched at promoter regions 22 , and interacts with TFIIIC 23 . Notably, CTCF occupancy at TGAPs was significantly higher compared to a random set of promoters ( fig.…”

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confidence: 99%

TFIIIC binding to Alu elements controls gene expression via chromatin looping and histone acetylation

Ferrari

Cucalon

Vona

et al. 2018

Preprint

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The mammalian genome is shaped by the expansion of repetitive elements and its folding is governed by epigenetic modifications and architectural proteins. However, the precise way all these factors interact to coordinate genome structure and expression is poorly understood. Here we report that upon serum starvation TFIIIC, a general transcription factor, binds a subset of Alu elements close to cell cycle genes and rewires genome topology via direct histone acetylation and promoter-anchored chromatin loops to distant genes. These changes ensure basal transcription of crucial cell cycle genes and their re-activation upon serum re-exposure. Our study unveils a novel function of TFIIIC on gene expression and genome folding achieved through casting direct manipulation of the epigenetic state of Alu elements to adjust 3D genome function.

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Genomic and Proteomic Analyses of Prdm5 Reveal Interactions with Insulator Binding Proteins in Embryonic Stem Cells

Cited by 30 publications

References 59 publications

Towards a predictive model of chromatin 3D organization

Towards a predictive model of chromatin 3D organization

Architectural proteins: regulators of 3D genome organization in cell fate

TFIIIC binding to Alu elements controls gene expression via chromatin looping and histone acetylation

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