Synthetic BZLF1-targeted transcriptional activator for efficient lytic induction therapy against EBV-associated epithelial cancers

Cancer + MetastasisCheng LabCRISPR/Cas + TALENDiseasesEpigeneticsGene TherapyRepresentativeSynthetic Biology + Genome Engineering
Man Wu*, Pok Man Hau*, Linxian Li*, Chi Man Tsang, Yike Yang, Aziz Taghbalout, Grace Tin-Yun Chung, Shin Yee Hui, Wing Chung Tang, Nathaniel Jillette, Jacqueline Jufen Zhu, Horace Hok Yeung Lee, Ee Ling Kong, Melissa Sue Ann Chan, Jason Ying Kuen Chan, Brigette Buig Yue Ma, Mei-Ru Chen, Charles Lee, Ka Fai To, Albert Wu Cheng#, Kwok-Wai Lo# (co-corresponding)
Nat Commun 15, 3729
Publication year: 2024

The unique virus-cell interaction in Epstein-Barr virus (EBV)-associated malignancies implies targeting the viral latent-lytic switch is a promising therapeutic strategy. However, the lack of specific and efficient therapeutic agents to induce lytic cycle in these cancers is a major challenge facing clinical implementation. We develop a synthetic transcriptional activator that specifically activates endogenous BZLF1 and efficiently induces lytic reactivation in EBV-positive cancer cells. A lipid nanoparticle encapsulating nucleoside-modified mRNA which encodes a BZLF1-specific transcriptional activator (mTZ3-LNP) is synthesized for EBV-targeted therapy. Compared with conventional chemical inducers, mTZ3-LNP more efficiently activates EBV lytic gene expression in EBV-associated epithelial cancers. Here we show the potency and safety of treatment with mTZ3-LNP to suppress tumor growth in EBV-positive cancer models. The combination of mTZ3-LNP and ganciclovir yields highly selective cytotoxic effects of mRNA-based lytic induction therapy against EBV-positive tumor cells, indicating the potential of mRNA nanomedicine in the treatment of EBV-associated epithelial cancers.

Simultaneous multifunctional transcriptome engineering by CRISPR RNA scaffold

Cheng LabCRISPR/Cas + TALENRepresentativeRNA Splicing + RBPsSynthetic Biology + Genome Engineering
Liu, Z., Jillette N., Robson, P., Cheng, A.W.
Nucleic Acid Research gkad547 doi: 10.1093/nar/gkad547
Publication year: 2023

RNA processing and metabolism are subjected to precise regulation in the cell to ensure integrity and functions of RNA. Though targeted RNA engineering has become feasible with the discovery and engineering of the CRISPR-Cas13 system, simultaneous modulation of different RNA processing steps remains unavailable. In addition, off-target events resulting from effectors fused with dCas13 limit its application. Here we developed a novel platform, Combinatorial RNA Engineering via Scaffold Tagged gRNA (CREST), which can simultaneously execute multiple RNA modulation functions on different RNA targets. In CREST, RNA scaffolds are appended to the 3’ end of Cas13 gRNA and their cognate RNA binding proteins are fused with enzymatic domains for manipulation. Taking RNA alternative splicing, A-to-G and C-to-U base editing as examples, we developed bifunctional and tri-functional CREST systems for simultaneously RNA manipulation. Furthermore, by fusing two split fragments of the deaminase domain of ADAR2 to dCas13 and/or PUFc respectively, we reconstituted its enzyme activity at target sites. This split design can reduce nearly 99% of off-target events otherwise induced by a full-length effector. The flexibility of the CREST framework will enrich the transcriptome engineering toolbox for the study of RNA biology.

Multiplex RNA targeting

Cheng LabCRISPR/Cas + TALENPatentsRNA Splicing + RBPsSynthetic Biology + Genome Engineering
Albert Cheng, Zukai LIU
WO2022187524A1
Publication year: 2023

Provided herein, in some aspects, is a multiplex RNA targeting system that enables live cell imaging and/or modification of multiple RNA targets. Specifically, the disclosure provides a method of live cell imaging of ribonucleic acid (RNA), or targeting RNA in a live cell, comprising: (a) delivering to a cell an RNA-editing complex that comprises a catalytically inactive Cas13 (dCas13) nuclease, a Cas 13 guide RNA (gRNA) comprising an RNA aptamer sequence, and a detectable molecule linked to an RNA-binding domain (RBD), or an RNA effector molecule linked to an RBD sequence that specifically binds to the RNA aptamer sequence; and (b) imaging the detectable molecule or RNA aptamer and RBD binding.

Targeted sequence insertion compositions and methods

Cheng LabCRISPR/Cas + TALENPatentsSynthetic Biology + Genome Engineering
Albert Cheng, Nathaniel Jillette
WO2022032085
Publication year: 2022

Targeted directional kilobase sequence insertion by combining prime editing with recombinases or integrases

Cheng LabCRISPR/Cas + TALENPreprintsSynthetic Biology + Genome Engineering
Nathaniel Jillette, Jacqueline Jufen Zhu, Albert Wu Cheng
BioRxiv doi: https://doi.org/10.1101/2022.05.25.493515
Publication year: 2022

Targeted insertion of exogenous sequences to genomes is useful for therapeutics and biological research. While CRISPR/Cas technologies have been very efficient in gene knockouts by double-strand breaks (DSBs) followed by indel formation through non-homologous end-joining (NHEJ) repair pathway, the precise introduction of new sequences mainly rely on inefficient homology directed repair (HDR) pathways following Cas9-induced DSBs and are restricted to dividing cells. The recent invention of Prime Editing allows short sequences to be precisely inserted at target sites without DSBs. Here, we combine Prime Editing and sequence-specific recombinases and integrases to insert kilobase sequences directionally at target sites. This technique, called PRIMAS for Prime editing, Recombinase, Integrase-mediated Addition of Sequence, will expand our genome editing toolbox for targeted insertion of long sequences up to kilobases and beyond.

Simultaneous multifunctional transcriptome engineering by CRISPR RNA scaffold

Cheng LabCRISPR/Cas + TALENPreprintsRNA Splicing + RBPs
Zukai Liu, Paul Robson, Albert Wu Cheng
BioRxiv doi: https://doi.org/10.1101/2022.06.21.497089
Publication year: 2022

RNA processing and metabolism are subjected to precise regulation in the cell to ensure integrity and functions of RNA. Though targeted RNA engineering has become feasible with the discovery and engineering of the CRISPR-Cas13 system, simultaneous modulation of different RNA processing steps remains unavailable. In addition, off-target events resulting from effectors fused with dCas13 limit its application. Here we developed a novel platform, Combinatorial RNA Engineering via Scaffold Tagged gRNA (CREST), which can simultaneously execute multiple RNA modulation functions on different RNA targets. In CREST, RNA scaffolds are appended to the 3′ end of Cas13 gRNA and their cognate RNA binding proteins are fused with enzymatic domains for manipulation. We show that CREST is capable of simultaneously manipulating RNA alternative splicing and A-to-G or C-to-U base editing. Furthermore, by fusing two split fragments of the deaminase domain of ADAR2 to dCas13 and PUFc respectively, we reconstituted its enzyme activity at target sites. This split design can reduce more than 90% of off-target events otherwise induced by a full-length effector. The flexibility of the CREST framework will enrich the transcriptome engineering toolbox for the study of RNA biology and the development of RNA-focused therapeutics.

Local recruitment of DNA repair proteins enhances CRISPR-ssODN-HDR editing

Cheng LabCRISPR/Cas + TALENPreprintsSynthetic Biology + Genome Engineering
Nathaniel Jillette, Jacqueline Jufen Zhu, Albert Wu Cheng
BioRxiv doi: https://doi.org/10.1101/2022.04.13.488255
Publication year: 2022

CRISPR-Cas technologies enable precise editing of genomic sequences. One major way to introduce precise editing is through homology directed repair (HDR) of DNA double strand breaks (DSB) templated by exogenously supplied single-stranded oligodeoxyribonucleotides (ssODN). Competing pathways determine the outcome of edits. Non-homologous end-joining pathways produce destructive insertions/deletions (indels) at target sites and are dominant over the precise homology directed repair pathways. In this study, we aim to favor HDR and use two strategies to recruit DNA repair proteins (DRPs) to Cas9 cut site, the Casilio-DRP approach that recruits RNA-binding protein-tethered DRPs to target site via aptamers appended to guide RNA; and the 53BP1-DRP approach that recruits DRPs to DSBs via DSB-sensing activity of 53BP1. We conducted two screens using these approaches and identified DRPs such as FANCF and BRCA1 that when recruited to Cas9 cut site, enhance ssODN-templated HDR and increase the proportion of precise edits. This study provides not only new constructs for enhanced CRISPR-ssODN-HDR but also a collection of DRP fusions for studying DNA repair processes.

JACKIE: Fast Enumeration of Genome-Wide Single- and Multicopy CRISPR Target Sites and Their Off-Target Numbers

BioinformaticsCheng LabCRISPR/Cas + TALENSynthetic Biology + Genome Engineering
Jacqueline Jufen Zhu, Albert Wu Cheng
The CRISPR Journal, doi: 10.1089/crispr.2022.0042
Publication year: 2022

Zinc finger protein-, transcription activator like effector-, and CRISPR-based methods for genome and epigenome editing and imaging have provided powerful tools to investigate functions of genomes. Targeting sequence design is vital to the success of these experiments. Although existing design software mainly focus on designing target sequence for specific elements, we report here the implementation of Jackie and Albert’s Comprehensive K-mer Instances Enumerator (JACKIE), a suite of software for enumerating all single- and multicopy sites in the genome that can be incorporated for genome-scale designs as well as loaded onto genome browsers alongside other tracks for convenient web-based graphic-user-interface-enabled design. We also implement fast algorithms to identify sequence neighborhoods or off-target counts of targeting sequences so that designs with low probability of off-target can be identified among millions of design sequences in reasonable time. We demonstrate the application of JACKIE-designed CRISPR site clusters for genome imaging.

CRISPR-mediated multiplexed live cell imaging of nonrepetitive genomic loci with one guide RNA per locus

Cheng LabCRISPR/Cas + TALENEpigeneticsImagingSynthetic Biology + Genome Engineering
Patricia A. Clow, Menghan Du, Nathaniel Jillette, Aziz Taghbalout, Jacqueline J. Zhu, Albert W. Cheng
Nat Commun 13, 1871 (2022). https://doi.org/10.1038/s41467-022-29343-z
Publication year: 2022

Three-dimensional (3D) structures of the genome are dynamic, heterogeneous and functionally important. Live cell imaging has become the leading method for chromatin dynamics tracking. However, existing CRISPR- and TALE-based genomic labeling techniques have been hampered by laborious protocols and are ineffective in labeling non-repetitive sequences. Here, we report a versatile CRISPR/Casilio-based imaging method that allows for a nonrepetitive genomic locus to be labeled using one guide RNA. We construct Casilio dual-color probes to visualize the dynamic interactions of DNA elements in single live cells in the presence or absence of the cohesin subunit RAD21. Using a three-color palette, we track the dynamic 3D locations of multiple reference points along a chromatin loop. Casilio imaging reveals intercellular heterogeneity and interallelic asynchrony in chromatin interaction dynamics, underscoring the importance of studying genome structures in 4D.

CRISPR-mediated multiplexed live cell imaging of nonrepetitive genomic loci with one guide RNA per locus

Cheng LabCRISPR/Cas + TALENEpigeneticsImagingRepresentative
Patricia A. Clow, Menghan Du, Nathaniel Jillette, Aziz Taghbalout, Jacqueline J. Zhu & Albert W. Cheng
Nature Communications volume 13, Article number: 1871
Publication year: 2022

Three-dimensional (3D) structures of the genome are dynamic, heterogeneous and functionally important. Live cell imaging has become the leading method for chromatin dynamics tracking. However, existing CRISPR- and TALE-based genomic labeling techniques have been hampered by laborious protocols and are ineffective in labeling non-repetitive sequences. Here, we report a versatile CRISPR/Casilio-based imaging method that allows for a nonrepetitive genomic locus to be labeled using one guide RNA. We construct Casilio dual-color probes to visualize the dynamic interactions of DNA elements in single live cells in the presence or absence of the cohesin subunit RAD21. Using a three-color palette, we track the dynamic 3D locations of multiple reference points along a chromatin loop. Casilio imaging reveals intercellular heterogeneity and interallelic asynchrony in chromatin interaction dynamics, underscoring the importance of studying genome structures in 4D.

TALE.Sense: A Versatile DNA Sensor Platform for Live Mammalian Cells

Cheng LabCRISPR/Cas + TALENSynthetic Biology + Genome Engineering
Aziz Taghbalout, Nathaniel Jillette, and Albert W. Cheng
ACS Synth. Biol. doi:10.1021/acssynbio.1c00212
Publication year: 2021

Live-cell imaging shows uneven segregation of extrachromosomal DNA elements and transcriptionally active extrachromosomal DNA hubs in cancer

Cancer + MetastasisCheng LabCRISPR/Cas + TALENImagingRepresentative
Eunhee Yi, Amit D Gujar, Molly Guthrie, Hoon Kim, Dacheng Zhao, Kevin C. Johnson, Samirkumar B Amin, Megan L Costa, Qianru Yu, Sunit Das, Nathaniel Jillette, Patricia A Clow, Albert W Cheng#, Roel GW Verhaak# (co-corresponding)
Cancer Discovery, doi: 10.1158/2159-8290.CD-21-1376
Publication year: 2021

Oncogenic extrachromosomal DNA elements (ecDNAs) play an important role in tumor evolution, but our understanding of ecDNA biology is limited. We determined the distribution of single-cell ecDNA copy number across patient tissues and cell line models and observed how cell-to-cell ecDNA frequency greatly varies. The exceptional intratumoral heterogeneity of ecDNA suggested ecDNA-specific replication and propagation mechanisms. To evaluate the transfer of ecDNA genetic material from parental to offspring cells during mitosis, we established the CRISPR-based ecTag method. EcTag leverages ecDNA-specific breakpoint sequences to tag ecDNA with fluorescent markers in living cells. Applying ecTag during mitosis revealed disjointed ecDNA inheritance patterns, enabling rapid ecDNA accumulation in individual cells. Post-mitosis, ecDNAs clustered into ecDNA hubs, and ecDNA hubs colocalized with RNA polymerase II, promoting transcription of cargo oncogenes. Our observations provide direct evidence for uneven segregation of ecDNA and shed new light on mechanisms through which ecDNAs contribute to oncogenesis.

Live cell imaging of non-repetitive genomic loci

Cheng LabCRISPR/Cas + TALENImagingPatents
Albert Cheng, Patricia Clow
WO2021034585A1
Publication year: 2021

Activation of lytic genes in cancer cells

Cancer + MetastasisCheng LabCRISPR/Cas + TALENPatents
Albert Cheng, Kwok Wai Lo, Pol Man Tom Hau, Man Wu
WO2021173977A1
Publication year: 2021

Poison exon splicing regulates a coordinated network of SR protein expression during differentiation and tumorigenesis

Cancer + MetastasisCheng LabCRISPR/Cas + TALENRNA Splicing + RBPs
Leclair NK, Brugiolo M, Urbanski L, Lawson SC, Thakar K, Yurieva M, George J, Hinson JT, Cheng A, Graveley BR, Anczuków O
Molecular Cell 80(4):468-665.e9 doi: 10.1016/j.molcel.2020.10.019.
Publication year: 2020

Methods and Compositions for Recruiting DNA Repair Proteins

Cheng LabCRISPR/Cas + TALENPatentsSynthetic Biology + Genome Engineering
Albert Cheng,Nathaniel Jillette
WO2020041172
Publication year: 2020

The DNA repair complexes provided herein are, inter alia, useful for editing genome sequences by introducing precise changes in a target site in the presence of a donor sequence. The RNA-guided DNA endonuclease provided herein including embodiments thereof (e.g., Cas9 nuclease or Cas9 nickase) is capable of introducing a strand break (double- or single-strand break) at a target site in the genome of a cell (e.g., gene or transcriptional regulatory sequence) and the break is then predominantly repaired through the mechanism of HDR. By increasing the HDR efficiency significantly and in certain instances decreasing NHEJ at a target site, the compositions and methods provided herein meet the long-felt need of site directed, highly accurate genome editing.

Graph embedding and unsupervised learning predict genomic sub-compartments from HiC chromatin interaction data

BioinformaticsCheng LabEpigenetics
Haitham Ashoor, Xiaowen Chen, Wojciech Rosikiewicz, Jiahui Wang, Albert Cheng, Ping Wang, Yijun Ruan & Sheng Li
Nature Communications 11:1173. doi: 10.1038/s41467-020-14974-x
Publication year: 2020

C11orf95-RELA reprograms 3D epigenome in supratentorial ependymoma

Cancer + MetastasisCheng LabEpigenetics
Jacqueline Jufen Zhu, Nathaniel Jillette, Xiao-Nan Li, Albert Wu Cheng# & Ching C. Lau# (co-corresponding)
Acta Neuropathol (2020). https://doi.org/10.1007/s00401-020-02225-8
Publication year: 2020

Supratentorial ependymoma (ST-EPN) is a type of malignant brain tumor mainly seen in children. Since 2014, it has been known that an intrachromosomal fusion C11orf95-RELA is an oncogenic driver in ST-EPN [Parker et al. Nature 506:451–455 (2014); Pietsch et al. Acta Neuropathol 127:609–611 (2014)] but the molecular mechanisms of oncogenesis are unclear. Here we show that the C11orf95 component of the fusion protein dictates DNA binding activity while the RELA component is required for driving the expression of ependymoma-associated genes. Epigenomic characterizations using ChIP-seq and HiChIP approaches reveal that C11orf95-RELA modulates chromatin states and mediates chromatin interactions, leading to transcriptional reprogramming in ependymoma cells. Our findings provide important characterization of the molecular underpinning of C11orf95-RELA fusion and shed light on potential therapeutic targets for C11orf95-RELA subtype ependymoma.

Artificial RNA-guided splicing factors

Cheng LabCRISPR/Cas + TALENDiseasesPatentsRNA Splicing + RBPsSynthetic Biology + Genome Engineering
Albert Cheng, Nathaniel Jillette
WO2020069331
Publication year: 2020

Provided herein, in some aspects, are compositions and methods for artificially modulating alternative splicing, for example, inducing exon inclusion and/or exon exclusion events. In some embodiments, a catalytically inactive programmable nuclease, such as dCasRx, is fused to an RNA-binding protein (or fragment or isoform thereof) and, when guided to a target of interest by a specific guide RNA (gRNA), can regulate alternative splicing in eukaryotic cells.

Transgenic selection methods and compositions

Cheng LabCRISPR/Cas + TALENPatentsSynthetic Biology + Genome Engineering
Albert Cheng,Nathaniel JILLETTE,Menghan DU
WO2019075200A1
Publication year: 2019

The present disclosure provides a split intein selectable marker system for the production and selection of transgenic cells.

Split Selectable Markers

Cheng LabCRISPR/Cas + TALENRepresentativeSynthetic Biology + Genome Engineering
Nathaniel Jillette, Menghan Du, Jacqueline Jufen Zhu, Peter Cardoz, Albert Wu Cheng
Nature Communications 10:4968
Publication year: 2019

Selectable markers are widely used in transgenesis and genome editing for selecting engineered cells with a desired genotype but the variety of markers is limited. Here we present split selectable markers that each allow for selection of multiple “unlinked” transgenes in the context of lentivirus-mediated transgenesis as well as CRISPR-Cas-mediated knock-ins. Split marker gene segments fused to protein splicing elements called “inteins” can be separately co-segregated with different transgenic vectors, and rejoin via protein trans-splicing to reconstitute a full-length marker protein in host cells receiving all intended vectors. Using a lentiviral system, we create and validate 2-split Hygromycin, Puromycin, Neomycin and Blasticidin resistance genes as well as mScarlet fluorescent proteins. By combining split points, we create 3- and 6-split Hygromycin resistance genes, demonstrating that higher-degree split markers can be generated by a “chaining” design. We adapt the split marker system for selecting biallelically engineered cells after CRISPR gene editing. Future engineering of split markers may allow selection of a higher number of genetic modifications in target cells.

Sequence detection systems

Cheng LabCRISPR/Cas + TALENPatentsSynthetic Biology + Genome Engineering
Albert Cheng,Aziz TAGHBALOUT,Nathaniel Lee JILLETTE
WO2019090287A2
Publication year: 2019

The present disclosure, in some embodiments, provides sequence detection systems (sequence detectors) for the detection of specific nucleotides sequences present in the genome of live cells (e.g., single live cells) to achieve, for example, in vivo and in situ imaging, cell selection, and/or cell ablation.

Enhanced CRISPR-based DNA demethylation by Casilio-ME-mediated RNA-guided coupling of methylcytosine oxidation and DNA repair pathways

Cheng LabCRISPR/Cas + TALENEpigeneticsRepresentativeSynthetic Biology + Genome Engineering
Aziz Taghbalout, Menghan Du, Nathaniel Jillette, Wojciech Rosikiewicz, Abhijit Rath, Christopher D. Heinen, Sheng Li, Albert W. Cheng
Nature Communications 10:4296
Publication year: 2019

Here we develop a methylation editing toolbox, Casilio-ME, that enables not only RNA-guided methylcytosine editing by targeting TET1 to genomic sites, but also by co-delivering TET1 and protein factors that couple methylcytosine oxidation to DNA repair activities, and/or promote TET1 to achieve enhanced activation of methylation-silenced genes. Delivery of TET1 activity by Casilio-ME1 robustly alters the CpG methylation landscape of promoter regions and activates methylation-silenced genes. We augment Casilio-ME1 to simultaneously deliver the TET1-catalytic domain and GADD45A (Casilio-ME2) or NEIL2 (Casilio-ME3) to streamline removal of oxidized cytosine intermediates to enhance activation of targeted genes. Using two-in-one effectors or modular effectors, Casilio-ME2 and Casilio-ME3 remarkably boost gene activation and methylcytosine demethylation of targeted loci. We expand the toolbox to enable a stable and expression-inducible system for broader application of the Casilio-ME platforms. This work establishes a platform for editing DNA methylation to enable research investigations interrogating DNA methylomes.

Targeted Enhanced DNA Demethylation

Cheng LabCRISPR/Cas + TALENEpigeneticsPatentsSynthetic Biology + Genome Engineering
Albert Cheng,Aziz TAGHBALOUT,Nathaniel JILLETTE
WO2018053037A1
Publication year: 2018

Provided herein are, inter alia, compositions and methods for the delivery of enhanced demethylation activity to target DNA sequences in a mammalian cell. The compositions and methods are, useful for activity modulation of a targeted gene, or to create a gene regulatory network.

Targeted DNA demethylation and methylation

Cheng LabCRISPR/Cas + TALENEpigeneticsPatentsSynthetic Biology + Genome Engineering
Albert Cheng,Aziz TAGHBALOUT,Nathaniel JILLETTE
WO2018053035A1
Publication year: 2018

Provided herein are, inter alia, compositions and methods for demethylating and methylating a target DNA sequences in a mammalian cell. The compositions and methods are, useful for activity modulation of a targeted gene, or to create a gene regulatory network.

Casilio: a versatile CRISPR-Cas9-Pumilio hybrid for gene regulation and genomic labeling

Cheng LabCRISPR/Cas + TALENEpigeneticsRepresentativeRNA Splicing + RBPsSynthetic Biology + Genome Engineering
Albert W Cheng*#, Nathaniel Jillette*, Phoebe Lee, Dylan Plaskon, Yasuhiro Fujiwara, Wenbo Wang, Aziz Taghbalout, Haoyi Wang*#
Cell Research 26:254–257. doi:10.1038/cr.2016.3
Publication year: 2016

Abstract

The RNA-guided DNA endonuclease system CRISPR-Cas9 has been exploited for

genome editing in various species. The nuclease-deficient mutant dCas9 protein can,

when coupled with sgRNAs, bind specific genomic loci without inducing DNA cleavage,

thus serving as a programmable DNA binding protein. To extend the utility of the dCas9

system, we have taken advantage of the ability of Pumilio PUF domains to bind specific

8-mer RNA sequences. By combining these two systems, we established the Casilio

system, which allows for specific and independent delivery of effector proteins to

specific genomic loci. We demonstrated that the Casilio system enables independent upand

down-regulation of multiple genes, as well as live-cell imaging of multiple genomic

loci simultaneously. Importantly, multiple copy of PUF binding sites can be incorporated

on sgRNA backbone, therefore allowing for local multimerization of effectors. In

addition, the PUF domain can be engineered to recognize any 8-mer RNA sequence,

therefore enabling the generation and simultaneous operation of many Casilio modules.

A website specifically for Casilio is at http://casil.io

A three-component CRISPR/Cas complex system and uses thereof

Cheng LabCRISPR/Cas + TALENEpigeneticsPatentsSynthetic Biology + Genome Engineering
Haoyi Wang, Albert Cheng, Nathaniel Jillette
WO2016148994
Publication year: 2016

The invention described herein provides compositions and reagents for assembling a tripartite complex at a specific location of a target DNA. The invention also provides methods for using the complex to, for example, label a specific genomic locus, to regulate the expression of a target gene, or to create a gene regulatory network.