dCas9: A Versatile Tool for Epigenome Editing

Brocken, Daan J.W.; Tark-Dame, Mariliis; Dame, Remus T.

doi:10.21775/cimb.026.015

Cited by 79 publications

(54 citation statements)

References 148 publications

(207 reference statements)

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“…These considerations seem particularly relevant for the more recently described 6mAmodifying enzymes, whose effects on TEs may be unrelated to their ability to modulate 6mA levels. The advent of epigenetic editing tools offers the opportunity to tackle these questions by altering the levels of DNA modifications at specific loci while also controlling for catalytic effects 161 .…”

Section: [H1] Conclusion and Perspectivesmentioning

confidence: 99%

Regulation of transposable elements by DNA modifications

2019

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Maintenance of genome stability requires control over the expression of transposable elements (TEs), whose activity can have substantial deleterious effects on the host. Chemical modification of DNA is a commonly used strategy to achieve this, and it has long been argued that the emergence of 5-methylcytosine (5mC) in many species was driven by the requirement to silence TEs. Potential roles in TE regulation have also been suggested for other DNA modifications, such as N6-methyladenine and oxidation derivatives of 5mC, although the underlying mechanistic relationships are poorly understood. Here, we discuss current evidence implicating DNA modifications and DNA modifying enzymes in TE regulation across different species. 100 LINE-1 elements account for virtually all of the transposition activity observed today 18 , including retrotransposition of non-autonomous short interspersed nuclear elements (SINEs), which depend on proteins encoded by LINE-1 elements 19. Although many TEs are neutral in their effect on the host, some insertions can disrupt gene function or lead to harmful chromosomal rearrangements, as demonstrated by over 120 disease-causing TE insertions in humans 20. Additionally, exacerbated TE expression in the germline can lead to sterility in mice and fruit flies 21,22. The resulting selective pressure has driven the evolution of numerous transcriptional and posttranscriptional host defence mechanisms that repress TE expression (Figure 2), which have been recently reviewed by Molaro and Malik 22. Small RNAs, including PIWI-interacting RNAs [G] (piRNAs), are the

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Section: [H1] Conclusion and Perspectivesmentioning

confidence: 99%

Regulation of transposable elements by DNA modifications

2019

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“…It is possible to mutate the genome precisely, reversibly and at multiple sites simultaneously 168 . Furthermore, one can tether proteins of interest to selected genomic positions in order to silence or activate genes, to induce reversible changes in 3D chromatin architecture and to visualize loci of interest in live imaging experiments 169,170 . This surge in approaches and technologies is revolutionizing the ways in which epigenetic processes can be studied, understood and harnessed to understand biological and pathological processes and to develop novel therapeutic strategies.…”

Section: Novel Approaches For Epigeneticsmentioning

confidence: 99%

Advances in epigenetics link genetics to the environment and disease

Cavalli

Heard

2019

Nature

1,074

696

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Epigenetic research has accelerated rapidly in the twenty-first century, generating justified excitement and hope, but also a degree of hype. Here we review how the field has evolved over the last few decades and reflect on some of the recent advances that are changing our understanding of biology. We discuss the interplay between epigenetics and DNA sequence variation as well as the implications of epigenetics for cellular memory and plasticity. We consider the effects of the environment and both intergenerational and transgenerational epigenetic inheritance on biology, disease and evolution. Finally, we present some new frontiers in epigenetics with implications for human health.

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“…While CRISPR/Cas9 is able to target near many genetic features, the necessity of a protospacer adjacent motif (PAM) in the target site often makes it impossible to design guide RNAs (gRNAs) to bind exactly at features such as SNPs, individual CpGs, intron/exon boundaries, or specific transcription factor binding sites ( Fig 1A ). Indeed this limitation has led to many efforts to expand the targeting lexicon using engineered or natural variant Cas9 proteins [ 7 – 10 ]. However, nearly all have been similarly or even more restricted than the 5’-NGG-3’ PAM site of the canonical Sp Cas9 [ 11 ].…”

Section: Introductionmentioning

confidence: 99%

Unexpected binding behaviors of bacterial Argonautes in human cells cast doubts on their use as targetable gene regulators

et al. 2018

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Prokaryotic Argonaute proteins (pAgos) have been proposed as an alternative to the CRISPR/Cas9 platform for gene editing. Although Argonaute from Natronobacterium gregoryi (NgAgo) was recently shown unable to cleave genomic DNA in mammalian cells, the utility of NgAgo or other pAgos as a targetable DNA-binding platform for epigenetic editing has not been explored. In this report, we evaluated the utility of two prokaryotic Argonautes (NgAgo and TtAgo) as DNA-guided DNA-binding proteins. NgAgo showed no meaningful binding to chromosomal targets, while TtAgo displayed seemingly non-specific binding to chromosomal DNA even in the absence of guide DNA. The observed lack of DNA-guided targeting and unexpected guide-independent genome sampling under the conditions in this study provide evidence that these pAgos might be suitable for neither gene nor epigenome editing in mammalian cells.

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dCas9: A Versatile Tool for Epigenome Editing

Cited by 79 publications

References 148 publications

Regulation of transposable elements by DNA modifications

Regulation of transposable elements by DNA modifications

Advances in epigenetics link genetics to the environment and disease

Unexpected binding behaviors of bacterial Argonautes in human cells cast doubts on their use as targetable gene regulators

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