Your search keyword '"Splinter, Erik"' showing total 8 results

1. The Dynamic Architecture of Hox Gene Clusters

Author

Noordermeer, Daan, Leleu, Marion, Splinter, Erik, Rougemont, Jacques, De Laat, Wouter, and Duboule, Denis

Published

2011

2. Robust 4C-seq data analysis to screen for regulatory DNA interactions.

Author

van de Werken, Harmen J G, Landan, Gilad, Holwerda, Sjoerd J B, Hoichman, Michael, Klous, Petra, Chachik, Ran, Splinter, Erik, Valdes-Quezada, Christian, Öz, Yuva, Bouwman, Britta A M, Verstegen, Marjon J A M, de Wit, Elzo, Tanay, Amos, and de Laat, Wouter

Subjects

DNA, DATA analysis, GENETIC regulation, COMPUTATIONAL biology, GENE expression, PROMOTERS (Genetics), CHROMOSOMES, CONFORMATIONAL analysis

Abstract

Regulatory DNA elements can control the expression of distant genes via physical interactions. Here we present a cost-effective methodology and computational analysis pipeline for robust characterization of the physical organization around selected promoters and other functional elements using chromosome conformation capture combined with high-throughput sequencing (4C-seq). Our approach can be multiplexed and routinely integrated with other functional genomics assays to facilitate physical characterization of gene regulation. [ABSTRACT FROM AUTHOR]

Published

2012

3. Chapter 5 Three‐Dimensional Organization of Gene Expression in Erythroid Cells.

Author

de Laat, Wouter, Klous, Petra, Kooren, Jurgen, Noordermeer, Daan, Palstra, Robert‐Jan, Simonis, Marieke, Splinter, Erik, and Grosveld, Frank

Subjects

GENE expression, ERYTHROCYTE membranes, GLOBIN genes, DNA, TECHNOLOGICAL innovations, CHROMOSOMES

Abstract

Abstract: The history of globin research is marked by a series of contributions seminal to our understanding of the genome, its function, and its relation to disease. For example, based on studies on hemoglobinopathies, it was understood that gene expression can be under the control of DNA elements that locate away from the genes on the linear chromosome template. Recent technological developments have allowed the demonstration that these regulatory DNA elements communicate with the genes through physical interaction, which loops out the intervening chromatin fiber. Subsequent studies showed that the spatial organization of the β‐globin locus dynamically changes in relation to differences in gene expression. Moreover, it was shown that the β‐globin locus adopts a different position in the nucleus during development and erythroid maturation. Here, we discuss the most recent insight into the three‐dimensional organization of gene expression. [Copyright &y& Elsevier]

Published

2008

4. Nuclear organization of active and inactive chromatin domains uncovered by chromosome conformation capture–on-chip (4C).

Author

Simonis, Marieke, Klous, Petra, Splinter, Erik, Moshkin, Yuri, Willemsen, Rob, de Wit, Elzo, van Steensel, Bas, and de Laat, Wouter

Subjects

CHROMATIN, CHROMOSOMES, NUCLEOPROTEINS, GENOMICS, MOLECULAR genetics, HUMAN genetics

Abstract

The spatial organization of DNA in the cell nucleus is an emerging key contributor to genomic function. We developed 4C technology (chromosome conformation capture (3C)-on-chip), which allows for an unbiased genome-wide search for DNA loci that contact a given locus in the nuclear space. We demonstrate here that active and inactive genes are engaged in many long-range intrachromosomal interactions and can also form interchromosomal contacts. The active β-globin locus in fetal liver preferentially contacts transcribed, but not necessarily tissue-specific, loci elsewhere on chromosome 7, whereas the inactive locus in fetal brain contacts different transcriptionally silent loci. A housekeeping gene in a gene-dense region on chromosome 8 forms long-range contacts predominantly with other active gene clusters, both in cis and in trans, and many of these intra- and interchromosomal interactions are conserved between the tissues analyzed. Our data demonstrate that chromosomes fold into areas of active chromatin and areas of inactive chromatin and establish 4C technology as a powerful tool to study nuclear architecture. [ABSTRACT FROM AUTHOR]

Published

2006

5. The ß-globin nuclear compartment in development and erythroid differentiation.

Author

Palstra, Robert-Jan, Tolhuis, Bas, Splinter, Erik, Nijmeijer, Rian, Grosveld, Frank, and de Laat, Wouter

Subjects

BINDING sites, NUCLEOPROTEINS, HEMOGLOBINS, GENETIC transcription, CHROMOSOMES

Abstract

Efficient transcription of genes requires a high local concentration of the relevant trans-acting factors. Nuclear compartmentalization can provide an effective means to locally increase the concentration of rapidly moving trans-acting factors; this may be achieved by spatial clustering of chromatin-associated binding sites for such factors. Here we analyze the structure of an erythroid-specific spatial cluster of cis-regulatory elements and active ß-globin genes, the active chromatin hub (ACH; ref. 6), at different stages of development and in erythroid progenitors. We show, in mice and humans, that a core ACH is developmentally conserved and consists of the hypersensitive sites (HS1-HS6) of the locus control region (LCR), the upstream 5' HS-60/-62 and downstream 3' HS1. Globin genes switch their interaction with this cluster during development, correlating with the switch in their transcriptional activity. In mouse erythroid progenitors that are committed to but do not yet express ß-globin, only the interactions between 5' HS-60/-62, 3' HS1 and hypersensitive sites at the 5' side of the LCR are stably present. After induction of differentiation, these sites cluster with the rest of the LCR and the gene that is activated. We conclude that during erythroid differentiation, cis-regulatory DNA elements create a developmentally conserved nuclear compartment dedicated to RNA polymerase II transcription of ß-globin genes. [ABSTRACT FROM AUTHOR]

Published

2003

6. β-Globin Active Chromatin Hub Formation in Differentiating Erythroid Cells and in p45 NF-E2 Knock-out Mice.

Author

Kooren, Jurgen, Palstra, Robert-Jan, Klous, Petra, Splinter, Erik, Von Lindern, Marieke, Grosveld, Frank, and De Laat, Wouter

Subjects

*GLOBIN, *GLOBIN genes, *ERYTHROCYTES, *LABORATORY mice, *CHROMATIN, *CHROMOSOMES

Abstract

Expression of the β-globin genes proceeds from basal to exceptionally high levels during erythroid differentiation in vivo. High expression is dependent on the locus control region (LCR) and coincides with more frequent LCR-gene contacts. These contacts are established in the context of an active chromatin hub (ACH), a spatial chromatin configuration in which the LCR, together with other regulatory sequences, loops toward the active β-globin-like genes. Here, we used recently established I/11 cells as a model system that faithfully recapitulates the in vivo erythroid differentiation program to study the molecular events that accompany and underlie ACH formation. Upon I/11 cell induction, histone modifications changed, the ACH was formed, and the β-globin-like genes were transcribed at rates similar to those observed in vivo. The establishment of frequent LCR-gene contacts coincided with a more efficient loading of polymerase onto the β-globin promoter. Binding of the transcription factors GATA-1 and EKLF to the locus, although previously shown to be required, was not sufficient for ACH formation. Moreover, we used knock-out mice to show that the erythroid transcription factor p45 NF-E2, which has been implicated in β-globin gene regulation, is dispensable for β-globin ACH formation. [ABSTRACT FROM AUTHOR]

Published

2007

7. 7C: Computational Chromosome Conformation Capture by Correlation of ChIP-seq at CTCF motifs.

Author

Ibn-Salem, Jonas and Andrade-Navarro, Miguel A.

Subjects

CHROMOSOMES, FORMALDEHYDE, BINDING sites, HUMAN genome, GENE expression, TRANSCRIPTION factors

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 co-immunoprecipitated and sequenced. This produces minor ChIP-seq signals at loop anchor regions close to the directly bound site. We use the position and shape of ChIP-seq signals around CTCF motif pairs to predict whether they interact or not. We implemented this approach in a prediction method, termed Computational Chromosome Conformation Capture by Correlation of ChIP-seq at CTCF motifs (7C). We applied 7C to all CTCF motif pairs within 1 Mb in the human genome and validated predicted interactions with high-resolution Hi-C and ChIA-PET. A single ChIP-seq experiment from known architectural proteins (CTCF, Rad21, Znf143) but also from other TFs (like TRIM22 or RUNX3) predicts loops accurately. Importantly, 7C predicts loops in cell types and for TF ChIP-seq datasets not used in training. Conclusion: 7C predicts chromatin loops which can help to associate TF binding sites to regulated genes. Furthermore, profiling of hundreds of ChIP-seq datasets results in novel candidate factors functionally involved in chromatin looping. Our method is available as an R/Bioconductor package: http://bioconductor.org/packages/sevenC. [ABSTRACT FROM AUTHOR]

Published

2019

8. Diverse gene reprogramming events occur in the same spatial clusters of distal regulatory elements.

Author

Hakim, Ofir, Myong-Hee Sung, Voss, Ty C., Splinter, Erik, John, Sam, Sabo, Peter J., Thurman, Robert E., Stamatoyannopoulos, John A., de Laat, Wouter, and Hager, Gordon L.

Subjects

*GENE expression, *GENETIC regulation, *GENETIC programming, *GLUCOCORTICOID receptors, *GENOMES, *CHROMOSOMES, *CHROMATIN

Abstract

The spatial organization of genes in the interphase nucleus plays an important role in establishment and regulation of gene expression. Contradicting results have been reported to date, with little consensus about the dynamics of nuclear organization and the features of the contact loci. In this study, we investigated the properties and dynamics of genomic loci that are in contact with glucocorticoid receptor (GR)-responsive loci. We took a systematic approach, combining genome-wide interaction profiling by the chromosome conformation capture on chip (4C) technology with expression, protein occupancy, and chromatin accessibility profiles. This approach allowed a comprehensive analysis of how distinct features of the linear genome are organized in the three-dimensional nuclear space in the context of rapid gene regulation. We found that the transcriptional response to GR occurs without dramatic nuclear reorganization. Moreover, contrary to the view of transcription-driven organization, even genes with opposite transcriptional responses colocalize. Regions contacting GR-regulated genes are not particularly enriched for GR-regulated loci or for any functional group of genes, suggesting that these subnuclear environments are not organized to respond to a specific factor. The contact regions are, however, highly enriched for DNase I-hypersensitive sites that comprehensively mark cell-type-specific regulatory sites. These findings indicate that the nucleus is pre-organized in a conformation allowing rapid transcriptional reprogramming, and this organization is significantly correlated with cell-type-specific chromatin sites accessible to regulatory factors. Numerous open chromatin loci may be arranged in nuclear domains that are poised to respond to diverse signals in general and to permit efficient gene regulation. [ABSTRACT FROM AUTHOR]

Published

2011