Fine-Resolution Mapping of TF Binding and Chromatin Interactions

Jenia Gutin; Ronen Sadeh; Nitzan Bodenheimer; Daphna Joseph-Strauss; Avital Klein-Brill; Adi Alajem; Oren Ram; Nir Friedman

doi:10.1016/j.celrep.2018.02.052

Fine-Resolution Mapping of TF Binding and Chromatin Interactions

Jenia Gutin, Ronen Sadeh^*, Nitzan Bodenheimer, Daphna Joseph-Strauss, Avital Klein-Brill, Adi Alajem, Oren Ram, Nir Friedman

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

31 Scopus citations

Abstract

Transcription factor (TF) binding to DNA is crucial for transcriptional regulation. There are multiple methods for mapping such binding. These methods balance between input requirements, spatial resolution, and compatibility with high-throughput automation. Here, we describe SLIM-ChIP (short-fragment-enriched, low-input, indexed MNase ChIP), which combines enzymatic fragmentation of chromatin and on-bead indexing to address these desiderata. SLIM-ChIP reproduces a high-resolution binding map of yeast Reb1 comparable with existing methods, yet with less input material and full compatibility with high-throughput procedures. We demonstrate the robustness and flexibility of SLIM-ChIP by probing additional factors in yeast and mouse. Finally, we show that SLIM-ChIP provides information on the chromatin landscape surrounding the bound transcription factor. We identify a class of Reb1 sites where the proximal −1 nucleosome tightly interacts with Reb1 and maintains unidirectional transcription. SLIM-ChIP is an attractive solution for mapping DNA binding proteins and charting the surrounding chromatin occupancy landscape at a single-cell level. Mapping transcription factors binding to DNA by chromatin immunoprecipitation sequencing is a key step in studying transcriptional programs. Gutin et al. introduce SLIM-ChIP, a simple, automation compatible protocol, that provides insights about the chromatin landscape at the bound sites. Using this protocol, they discover promoter architectures that enforce unidirectional transcription.

Original language	American English
Pages (from-to)	2797-2807
Number of pages	11
Journal	Cell Reports
Volume	22
Issue number	10
DOIs	https://doi.org/10.1016/j.celrep.2018.02.052
State	Published - 6 Mar 2018

Bibliographical note

Funding Information:
We thank A. Appleboim, C. de Boer, S. Kadener, E. Meshorer, N. Moriel, O.J. Rando, K. Shekhar, H. Soreq, and members of the Friedman group for critical comments on the manuscript and figures. This work was supported by the ERC (grant 340712 to N.F.) and the Israeli Center of Research Excellence (I-CORE) on Chromatin and RNA in Gene Regulation (N.F. and O.R.).

Funding Information:
We thank A. Appleboim, C. de Boer, S. Kadener, E. Meshorer, N. Moriel, O.J. Rando, K. Shekhar, H. Soreq, and members of the Friedman group for critical comments on the manuscript and figures. This work was supported by the ERC (grant 340712 to N.F.) and the Israeli Center of Research Excellence (I-CORE) on Chromatin and RNA in Gene Regulation (N.F. and O.R.).

Publisher Copyright:
© 2018 The Author(s)

Keywords

CTCF
ChIP-seq
DNA-binding
Reb1
chromatin
nucleosomes
promoter directionality
transcription factor

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10.1016/j.celrep.2018.02.052

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title = "Fine-Resolution Mapping of TF Binding and Chromatin Interactions",

abstract = "Transcription factor (TF) binding to DNA is crucial for transcriptional regulation. There are multiple methods for mapping such binding. These methods balance between input requirements, spatial resolution, and compatibility with high-throughput automation. Here, we describe SLIM-ChIP (short-fragment-enriched, low-input, indexed MNase ChIP), which combines enzymatic fragmentation of chromatin and on-bead indexing to address these desiderata. SLIM-ChIP reproduces a high-resolution binding map of yeast Reb1 comparable with existing methods, yet with less input material and full compatibility with high-throughput procedures. We demonstrate the robustness and flexibility of SLIM-ChIP by probing additional factors in yeast and mouse. Finally, we show that SLIM-ChIP provides information on the chromatin landscape surrounding the bound transcription factor. We identify a class of Reb1 sites where the proximal −1 nucleosome tightly interacts with Reb1 and maintains unidirectional transcription. SLIM-ChIP is an attractive solution for mapping DNA binding proteins and charting the surrounding chromatin occupancy landscape at a single-cell level. Mapping transcription factors binding to DNA by chromatin immunoprecipitation sequencing is a key step in studying transcriptional programs. Gutin et al. introduce SLIM-ChIP, a simple, automation compatible protocol, that provides insights about the chromatin landscape at the bound sites. Using this protocol, they discover promoter architectures that enforce unidirectional transcription.",

keywords = "CTCF, ChIP-seq, DNA-binding, Reb1, chromatin, nucleosomes, promoter directionality, transcription factor",

author = "Jenia Gutin and Ronen Sadeh and Nitzan Bodenheimer and Daphna Joseph-Strauss and Avital Klein-Brill and Adi Alajem and Oren Ram and Nir Friedman",

note = "Funding Information: We thank A. Appleboim, C. de Boer, S. Kadener, E. Meshorer, N. Moriel, O.J. Rando, K. Shekhar, H. Soreq, and members of the Friedman group for critical comments on the manuscript and figures. This work was supported by the ERC (grant 340712 to N.F.) and the Israeli Center of Research Excellence (I-CORE) on Chromatin and RNA in Gene Regulation (N.F. and O.R.). Funding Information: We thank A. Appleboim, C. de Boer, S. Kadener, E. Meshorer, N. Moriel, O.J. Rando, K. Shekhar, H. Soreq, and members of the Friedman group for critical comments on the manuscript and figures. This work was supported by the ERC (grant 340712 to N.F.) and the Israeli Center of Research Excellence (I-CORE) on Chromatin and RNA in Gene Regulation (N.F. and O.R.). Publisher Copyright: {\textcopyright} 2018 The Author(s)",

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AU - Sadeh, Ronen

AU - Bodenheimer, Nitzan

AU - Joseph-Strauss, Daphna

AU - Klein-Brill, Avital

AU - Alajem, Adi

AU - Ram, Oren

AU - Friedman, Nir

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N2 - Transcription factor (TF) binding to DNA is crucial for transcriptional regulation. There are multiple methods for mapping such binding. These methods balance between input requirements, spatial resolution, and compatibility with high-throughput automation. Here, we describe SLIM-ChIP (short-fragment-enriched, low-input, indexed MNase ChIP), which combines enzymatic fragmentation of chromatin and on-bead indexing to address these desiderata. SLIM-ChIP reproduces a high-resolution binding map of yeast Reb1 comparable with existing methods, yet with less input material and full compatibility with high-throughput procedures. We demonstrate the robustness and flexibility of SLIM-ChIP by probing additional factors in yeast and mouse. Finally, we show that SLIM-ChIP provides information on the chromatin landscape surrounding the bound transcription factor. We identify a class of Reb1 sites where the proximal −1 nucleosome tightly interacts with Reb1 and maintains unidirectional transcription. SLIM-ChIP is an attractive solution for mapping DNA binding proteins and charting the surrounding chromatin occupancy landscape at a single-cell level. Mapping transcription factors binding to DNA by chromatin immunoprecipitation sequencing is a key step in studying transcriptional programs. Gutin et al. introduce SLIM-ChIP, a simple, automation compatible protocol, that provides insights about the chromatin landscape at the bound sites. Using this protocol, they discover promoter architectures that enforce unidirectional transcription.

AB - Transcription factor (TF) binding to DNA is crucial for transcriptional regulation. There are multiple methods for mapping such binding. These methods balance between input requirements, spatial resolution, and compatibility with high-throughput automation. Here, we describe SLIM-ChIP (short-fragment-enriched, low-input, indexed MNase ChIP), which combines enzymatic fragmentation of chromatin and on-bead indexing to address these desiderata. SLIM-ChIP reproduces a high-resolution binding map of yeast Reb1 comparable with existing methods, yet with less input material and full compatibility with high-throughput procedures. We demonstrate the robustness and flexibility of SLIM-ChIP by probing additional factors in yeast and mouse. Finally, we show that SLIM-ChIP provides information on the chromatin landscape surrounding the bound transcription factor. We identify a class of Reb1 sites where the proximal −1 nucleosome tightly interacts with Reb1 and maintains unidirectional transcription. SLIM-ChIP is an attractive solution for mapping DNA binding proteins and charting the surrounding chromatin occupancy landscape at a single-cell level. Mapping transcription factors binding to DNA by chromatin immunoprecipitation sequencing is a key step in studying transcriptional programs. Gutin et al. introduce SLIM-ChIP, a simple, automation compatible protocol, that provides insights about the chromatin landscape at the bound sites. Using this protocol, they discover promoter architectures that enforce unidirectional transcription.

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KW - DNA-binding

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KW - chromatin

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JF - Cell Reports

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Fine-Resolution Mapping of TF Binding and Chromatin Interactions

Abstract

Bibliographical note

Keywords

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