Genomic targeting of epigenetic probes using a chemically tailored Cas9 system

Liszczak, Glen; Brown, Zachary Z.; Kim, Samuel H.; Oslund, Rob C.; David, Yael; Muir, Tom W.

doi:10.1073/pnas.1615723114

Cited by 44 publications

(38 citation statements)

References 40 publications

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“…In contrast, HDAC3 functions as a corepressor by deacetylating the H3K27ac on enhancer elements (Hatzi et al 2013). Recently, CRISPR technology has also been successfully used to recruit endogenous chromatin regulators to targeted genomic loci (Braun et al 2017; Liszczak et al 2017) or manipulation of nuclear architecture and chromatin looping (Hao et al 2017; Morgan et al 2017). However, most of these studies have not yet been tested in vivo.…”

Section: Crispr-based Epigenome Editing and Transcriptional Modulatiomentioning

confidence: 99%

“…To enable more robust epigenome editing and transcriptional modulation using AAV-CRISPR system, dCas9 conjugation through protein trans-splicing and dimerizing techniques can be adapted to recruit large endogenous chromatin regulators to specific genomic loci (Braun et al 2017; Liszczak et al 2017) (Figure 5). For example, Fkbp/Frb inducible recruitment for epigenome editing by dCas9 (FIRE-dCas9) system was a recently developed dCas9 conjugation approach that has been used to achieve rapid and reversible recruitment of endogenous chromatin regulators to specific genomic loci (Braun et al 2017).…”

Section: Recent Advances In Aav Delivery Of Crispr Fusion Proteinmentioning

confidence: 99%

“…By recruiting mSWI/SNF (BAF) complex to bivalent promoters, transcription activation was induced through the loss of repressive H3K27me3 and increase in active H3K4me3 marks. A chemically tailored dCas9 system was also recently developed by using protein trans-splicing to ligate synthetic elements (IntC-cargo such as IntC-JQ1 and IntC-UNC3866) to a dCas9-IntN (Liszczak et al 2017). The resulting dCas9-IntN:IntC-cargo fusion was capable of recruiting endogenous copies of their cognate binding partners (e.g.…”

Section: Recent Advances In Aav Delivery Of Crispr Fusion Proteinmentioning

confidence: 99%

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In vivo epigenome editing and transcriptional modulation using CRISPR technology

Lau

Suh

2018

Transgenic Res

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The rapid advancement of CRISPR technology has enabled targeted epigenome editing and transcriptional modulation in the native chromatin context. However, only a few studies have reported the successful editing of the epigenome in adult animals in contrast to the rapidly growing number of in vivo genome editing over the past few years. In this review, we discuss the challenges facing in vivo epigenome editing and new strategies to overcome the huddles. The biggest challenge has been the difficulty in packaging dCas9 fusion proteins required for manipulation of epigenome into the adeno-associated virus (AAV) delivery vehicle. We review the strategies to address the AAV packaging issue, including small dCas9 orthologues, truncated dCas9 mutants, a split-dCas9 system, and potent truncated effector domains. We discuss the dCas9 conjugation strategies to recruit endogenous chromatin modifiers and remodelers to specific genomic loci, and recently developed methods to recruit multiple copies of the dCas9 fusion protein, or to simultaneous express multiple gRNAs for robust epigenome editing or synergistic transcriptional modulation. The use of Cre-inducible dCas9-expressing mice or a genetic cross between dCas9- and sgRNA-expressing flies has also helped overcome the transgene delivery issue. We provide perspective on how a combination use of these strategies can facilitate in vivo epigenome editing and transcriptional modulation.

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Section: Crispr-based Epigenome Editing and Transcriptional Modulatiomentioning

confidence: 99%

Section: Recent Advances In Aav Delivery Of Crispr Fusion Proteinmentioning

confidence: 99%

Section: Recent Advances In Aav Delivery Of Crispr Fusion Proteinmentioning

confidence: 99%

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In vivo epigenome editing and transcriptional modulation using CRISPR technology

Lau

Suh

2018

Transgenic Res

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“…29,30 Thus, as we write this piece, many dozens of modified histones have been generated using chemistry-driven methods. These reagents have been used to study various aspects of chromatin biochemistry, 31,32 in many cases allowing mechanistic hypotheses generated from cell-based genomic data to be tested.…”

Section: Chemical Approaches For Biochemical Analysis Of Histone Ptmsmentioning

confidence: 99%

Emerging Chemistry Strategies for Engineering Native Chromatin

David

Muir

2017

J. Am. Chem. Soc.

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Chromosomes present one of most challenging of all substrates for biochemical study. This is because genomic DNA is physically associated with an astonishing collection of nuclear factors, which serve to not only store the nucleic acid in a stable form, but also grant access to the information it encodes when needed. Understanding this complex molecular choreography is central to the field of epigenetics. One of the great challenges in this area is to move beyond correlative type information, which is now in abundant supply, to the point where we can truly connect the dots at the molecular level. Establishing such causal relationships requires precise manipulation of the covalent structure of chromatin. Tools for this purpose are currently in short supply, creating an opportunity that, as we will argue in this Perspective, is well suited to the sensibilities of the chemist.

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“…Alternatively, fully synthetic histones modified by PTMs using several of the chemistry‐based labeling strategies currently available could be delivered into cells directly, assuming proper integration into nucleosomes postdelivery . Alternatively, the nuclease‐deficient Cas9 (dCas9) can be modified synthetically to display chemical or proteinaceous epigenetic probes . Upon complex formation between and a guide RNA and upon subsequent successful delivery into live cells, such constructs are directed to specific genomic localizations.…”

Section: Introductionmentioning

confidence: 99%

Efficient and Innocuous Live‐Cell Delivery: Making Membrane Barriers Disappear to Enable Cellular Biochemistry

Pellois

2019

BioEssays

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The confluence of protein engineering techniques and delivery protocols are providing new opportunities in cell biology. In particular, techniques that render the membrane of cells transiently permeable make the introduction of nongenetically encodable macromolecular probes into cells possible. This, in turn, can enable the monitoring of intracellular processes in ways that can be both precise and quantitative, ushering an area that one may envision as cellular biochemistry. Herein, the author reviews pioneering examples of such new cell‐based assays, provides evidence that challenges the paradigm that cell penetration is a necessarily damaging and stressful event for cells, and highlights some of the challenges that should be addressed to fully unlock the potential of this nascent field.

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Genomic targeting of epigenetic probes using a chemically tailored Cas9 system

Cited by 44 publications

References 40 publications

In vivo epigenome editing and transcriptional modulation using CRISPR technology

In vivo epigenome editing and transcriptional modulation using CRISPR technology

Emerging Chemistry Strategies for Engineering Native Chromatin

Efficient and Innocuous Live‐Cell Delivery: Making Membrane Barriers Disappear to Enable Cellular Biochemistry

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