Your search keyword '"ChIP-STARR-seq"' showing total 4 results

1. High-resolution dissection of human cell type-specific enhancers in cis and trans activities

Author

Wang, Meng, Yang, Xiaoxu, and Wu, Qixi

Published

2025

2. Functional Dissection of the Enhancer Repertoire in Human Embryonic Stem Cells

Author

Barakat, T.S. (Tahsin Stefan), Halbritter, F. (Florian), Zhang, M. (Man), Rendeiro, A.F. (André F.), Perenthaler, E. (Elena), Bock, G.H. (Geertruida) de, Chambers, I. (Ian), Barakat, T.S. (Tahsin Stefan), Halbritter, F. (Florian), Zhang, M. (Man), Rendeiro, A.F. (André F.), Perenthaler, E. (Elena), Bock, G.H. (Geertruida) de, and Chambers, I. (Ian)

Abstract

Enhancers are genetic elements that regulate spatiotemporal gene expression. Enhancer function requires transcription factor (TF) binding and correlates with histone modifications. However, the extent to which TF binding and histone modifications functionally define active enhancers remains unclear. Here, we combine chromatin immunoprecipitation with a massively parallel reporter assay (ChIP-STARR-seq) to identify functional enhancers in human embryonic stem cells (ESCs) genome-wide in a quantitative unbiased manner. Although active enhancers associate with TFs, only a minority of regions marked by NANOG, OCT4, H3K27ac, and H3K4me1 function as enhancers, with activity markedly changing under naive versus primed culture conditions. We identify an enhancer set associated with functions extending to non-ESC-specific processes. Moreover, although transposable elements associate with putative enhancers, only some exhibit activity. Similarly, within super-enhancers, large tracts are non-functional, with activity restricted to small sub-domains. This catalog of validated enhancers provides a valuable resource for further functional dissection of the regulatory genome.Barakat et al. use a combination of chromatin immunoprecipitation and a massively parallel reporter assay to identify functional enhancers in primed and naive human embryonic stem cells. This genome-wide catalog of validated enhancers provides a valuable resource for the further dissection of the regulatory genome.

Published

2018

3. Functional Dissection of the Enhancer Repertoire in Human Embryonic Stem Cells

Author

Barakat, Tahsin Stefan, Halbritter, Florian, Zhang, Man, Rendeiro, André F., Perenthaler, Elena, Bock, Christoph, Chambers, Ian, and Clinical Genetics

Subjects

NANOG, genome-wide functional enhancer map, naive pluripotency, super-enhancers, H3K4me1, ChIP-STARR-seq, OCT4, transposable elements, H3K27ac

Abstract

Enhancers are genetic elements that regulate spatiotemporal gene expression. Enhancer function requires transcription factor (TF) binding and correlates with histone modifications. However, the extent to which TF binding and histone modifications functionally define active enhancers remains unclear. Here, we combine chromatin immunoprecipitation with a massively parallel reporter assay (ChIP-STARR-seq) to identify functional enhancers in human embryonic stem cells (ESCs) genome-wide in a quantitative unbiased manner. Although active enhancers associate with TFs, only a minority of regions marked by NANOG, OCT4, H3K27ac, and H3K4me1 function as enhancers, with activity markedly changing under naive versus primed culture conditions. We identify an enhancer set associated with functions extending to non-ESC-specific processes. Moreover, although transposable elements associate with putative enhancers, only some exhibit activity. Similarly, within super-enhancers, large tracts are non-functional, with activity restricted to small sub-domains. This catalog of validated enhancers provides a valuable resource for further functional dissection of the regulatory genome.

Published

2018

4. Functional Dissection of the Enhancer Repertoire in Human Embryonic Stem Cells

Author

Tahsin Stefan, Barakat, Florian, Halbritter, Man, Zhang, André F, Rendeiro, Elena, Perenthaler, Christoph, Bock, and Ian, Chambers

Subjects

Chromatin Immunoprecipitation, Human Embryonic Stem Cells, naive pluripotency, super-enhancers, H3K4me1, ChIP-STARR-seq, OCT4, H3K27ac, Article, Enhancer Elements, Genetic, NANOG, genome-wide functional enhancer map, Humans, Female, transposable elements, Cells, Cultured

Abstract

Summary Enhancers are genetic elements that regulate spatiotemporal gene expression. Enhancer function requires transcription factor (TF) binding and correlates with histone modifications. However, the extent to which TF binding and histone modifications functionally define active enhancers remains unclear. Here, we combine chromatin immunoprecipitation with a massively parallel reporter assay (ChIP-STARR-seq) to identify functional enhancers in human embryonic stem cells (ESCs) genome-wide in a quantitative unbiased manner. Although active enhancers associate with TFs, only a minority of regions marked by NANOG, OCT4, H3K27ac, and H3K4me1 function as enhancers, with activity markedly changing under naive versus primed culture conditions. We identify an enhancer set associated with functions extending to non-ESC-specific processes. Moreover, although transposable elements associate with putative enhancers, only some exhibit activity. Similarly, within super-enhancers, large tracts are non-functional, with activity restricted to small sub-domains. This catalog of validated enhancers provides a valuable resource for further functional dissection of the regulatory genome., Graphical Abstract, Highlights • Massively parallel reporter assay assessed over 350,000 genome regions • ChIP-STARR-seq catalogs functional enhancers in primed and naive hESCs • Identification of transcription factors and transposable elements linked to enhancers • ChIP-STARR-seq dissects super-enhancers into small functional units, Barakat et al. use a combination of chromatin immunoprecipitation and a massively parallel reporter assay to identify functional enhancers in primed and naive human embryonic stem cells. This genome-wide catalog of validated enhancers provides a valuable resource for the further dissection of the regulatory genome.

Published

2017