Programmable control of gene expression is essential to understanding gene function, engineering cellular behaviors, and developing therapeutics. Beyond the gene editing applications enabled by the ...nuclease CRISPR–Cas9 and CRISPR–Cas12a, the invention of the nuclease-dead Cas molecules (dCas9 and dCas12a) offers a platform for the precise control of genome function without gene editing. Diverse dCas tools have been developed, which constitute a comprehensive toolbox that allows for interrogation of gene function and modulation of the cellular behaviors. This review summarizes current applications of the dCas tools for transcription regulation, epigenetic engineering, genome imaging, genetic screens, and chromatin immunoprecipitation. We also highlight the advantages and existing challenges of the current dCas tools in genetic engineering and synthetic biology, and provide perspectives on future directions and applications.
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•The dCas system is a programmable and versatile platform for gene regulation and epigenome control.•Focus on advances of tool development and synthetic biology applications of the dCas platform•Highlight using dCas for transcription, epigenetics, imaging, screening, and ChIP•Summarize advantages, challenges, and perspectives of the dCas system as a technology platform
CRISPR Cas9 in Genome Editing and Beyond Wang, Haifeng; La Russa, Marie; Qi, Lei S
Annual review of biochemistry,
06/2016, Letnik:
85, Številka:
1
Journal Article
Recenzirano
Odprti dostop
The Cas9 protein (CRISPR-associated protein 9), derived from type II CRISPR (clustered regularly interspaced short palindromic repeats) bacterial immune systems, is emerging as a powerful tool for ...engineering the genome in diverse organisms. As an RNA-guided DNA endonuclease, Cas9 can be easily programmed to target new sites by altering its guide RNA sequence, and its development as a tool has made sequence-specific gene editing several magnitudes easier. The nuclease-deactivated form of Cas9 further provides a versatile RNA-guided DNA-targeting platform for regulating and imaging the genome, as well as for rewriting the epigenetic status, all in a sequence-specific manner. With all of these advances, we have just begun to explore the possible applications of Cas9 in biomedical research and therapeutics. In this review, we describe the current models of Cas9 function and the structural and biochemical studies that support it. We focus on the applications of Cas9 for genome editing, regulation, and imaging, discuss other possible applications and some technical considerations, and highlight the many advantages that CRISPR Cas9 technology offers.
Compact and versatile CRISPR-Cas systems will enable genome engineering applications through high-efficiency delivery in a wide variety of contexts. Here, we create an efficient miniature Cas system ...(CasMINI) engineered from the type V-F Cas12f (Cas14) system by guide RNA and protein engineering, which is less than half the size of currently used CRISPR systems (Cas9 or Cas12a). We demonstrate that CasMINI can drive high levels of gene activation (up to thousands-fold increases), while the natural Cas12f system fails to function in mammalian cells. We show that the CasMINI system has comparable activities to Cas12a for gene activation, is highly specific, and allows robust base editing and gene editing. We expect that CasMINI can be broadly useful for cell engineering and gene therapy applications ex vivo and in vivo.
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•Protein and RNA engineering enable Cas12f to function robustly in mammalian cells•The engineered CasMINI is compact and less than half the size of Cas9 and Cas12a•CasMINI is efficient and specific for gene activation and is comparable with Cas12a•CasMINI is versatile and allows robust genome editing and base editing
Xu et. al developed a miniature CRISPR system for genome engineering via protein and guide RNA engineering. Whereas the natural Cas12f does not function in mammalian cells, engineered Cas12f mutants, named CasMINI, show comparable activities with Cas12a for efficient gene activation. CasMINI also enables robust gene editing and base editing.
While the catalog of mammalian transcripts and their expression levels in different cell types and disease states is rapidly expanding, our understanding of transcript function lags behind. We ...present a robust technology enabling systematic investigation of the cellular consequences of repressing or inducing individual transcripts. We identify rules for specific targeting of transcriptional repressors (CRISPRi), typically achieving 90%–99% knockdown with minimal off-target effects, and activators (CRISPRa) to endogenous genes via endonuclease-deficient Cas9. Together they enable modulation of gene expression over a ∼1,000-fold range. Using these rules, we construct genome-scale CRISPRi and CRISPRa libraries, each of which we validate with two pooled screens. Growth-based screens identify essential genes, tumor suppressors, and regulators of differentiation. Screens for sensitivity to a cholera-diphtheria toxin provide broad insights into the mechanisms of pathogen entry, retrotranslocation and toxicity. Our results establish CRISPRi and CRISPRa as powerful tools that provide rich and complementary information for mapping complex pathways.
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•CRISPRi and CRISPRa provide complementary information for mapping complex pathways•CRISPRi/a expression series (up to ∼1,000-fold) reveal how gene dose controls function•CRISPRi provides strong (typically 90%–99%) knockdown with minimal off-target effects•Genome-scale screens elucidate pathways controlling cholera/diphtheria toxicity
Genome-scale-specific targeting of transcriptional repressors (CRISPRi) and activators (CRISPRa) to endogenous genes via endonuclease-deficient Cas9 have been applied to growth and toxin-resistance screens, establishing CRISPRi and CRISPRa as powerful tools that provide rich and complementary information.
The genetic interrogation and reprogramming of cells requires methods for robust and precise targeting of genes for expression or repression. The CRISPR-associated catalytically inactive dCas9 ...protein offers a general platform for RNA-guided DNA targeting. Here, we show that fusion of dCas9 to effector domains with distinct regulatory functions enables stable and efficient transcriptional repression or activation in human and yeast cells, with the site of delivery determined solely by a coexpressed short guide (sg)RNA. Coupling of dCas9 to a transcriptional repressor domain can robustly silence expression of multiple endogenous genes. RNA-seq analysis indicates that CRISPR interference (CRISPRi)-mediated transcriptional repression is highly specific. Our results establish that the CRISPR system can be used as a modular and flexible DNA-binding platform for the recruitment of proteins to a target DNA sequence, revealing the potential of CRISPRi as a general tool for the precise regulation of gene expression in eukaryotic cells.
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•CRISPRi enables robust gene repression and activation in human cells•CRISPRi knockdown is specific with minimal off-target effects in human cells•CRISPRi can effectively repress endogenous genes in human and yeast•dCas9 enables modular and programmable RNA-guided genome regulation in eukaryotes
Catalytically inactive CRISPR can be targeted to specific loci in human and yeast cells to specifically repress and activate transcription. The study demonstrates the potential for adapting CRISPRi for multiple modes of transcriptional control, chromatin modification, and regulatory element mapping in a broad range of eukaryotes.
The spatiotemporal organization and dynamics of chromatin play critical roles in regulating genome function. However, visualizing specific, endogenous genomic loci remains challenging in living ...cells. Here, we demonstrate such an imaging technique by repurposing the bacterial CRISPR/Cas system. Using an EGFP-tagged endonuclease-deficient Cas9 protein and a structurally optimized small guide (sg) RNA, we show robust imaging of repetitive elements in telomeres and coding genes in living cells. Furthermore, an array of sgRNAs tiling along the target locus enables the visualization of nonrepetitive genomic sequences. Using this method, we have studied telomere dynamics during elongation or disruption, the subnuclear localization of the MUC4 loci, the cohesion of replicated MUC4 loci on sister chromatids, and their dynamic behaviors during mitosis. This CRISPR imaging tool has potential to significantly improve the capacity to study the conformation and dynamics of native chromosomes in living human cells.
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•An optimized CRISPR enables live imaging and better gene regulation in human cells•CRISPR imaging visualizes either repetitive or nonrepetitive genomic sequences•CRISPR imaging reports telomere length change and telomere movements•CRISPR imaging monitors the dynamics of gene loci throughout the cell cycle
A new CRISPR-based technology allows precise visualization of individual gene loci in living cells.
Targeted gene regulation on a genome-wide scale is a powerful strategy for interrogating, perturbing, and engineering cellular systems. Here, we develop a method for controlling gene expression based ...on Cas9, an RNA-guided DNA endonuclease from a type II CRISPR system. We show that a catalytically dead Cas9 lacking endonuclease activity, when coexpressed with a guide RNA, generates a DNA recognition complex that can specifically interfere with transcriptional elongation, RNA polymerase binding, or transcription factor binding. This system, which we call CRISPR interference (CRISPRi), can efficiently repress expression of targeted genes in Escherichia coli, with no detectable off-target effects. CRISPRi can be used to repress multiple target genes simultaneously, and its effects are reversible. We also show evidence that the system can be adapted for gene repression in mammalian cells. This RNA-guided DNA recognition platform provides a simple approach for selectively perturbing gene expression on a genome-wide scale.
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► Inactive CRISPR associated 9 protein (dCas9) is repurposed for genome engineering ► dCas9 and a complementary short guide RNA can target specific genomic sites ► CRISPR interference (CRISPRi) can regulate multiple genes without off-target effects ► CRISPRi is compact and can be ported to bacterial and mammalian cells
The authors have developed a CRISPR interference system in which a catalytically dead Cas9 protein can be targeted to a specific genomic site through a complementary small guide RNA, allowing systematic perturbation of gene transcription in bacteria and mammalian cells.
Generation of induced pluripotent stem cells typically requires the ectopic expression of transcription factors to reactivate the pluripotency network. However, it remains largely unclear what ...remodeling events on endogenous chromatin trigger reprogramming toward induced pluripotent stem cells (iPSCs). Toward this end, we employed CRISPR activation to precisely target and remodel endogenous gene loci of Oct4 and Sox2. Interestingly, we found that single-locus targeting of Sox2 was sufficient to remodel and activate Sox2, which was followed by the induction of other pluripotent genes and establishment of the pluripotency network. Simultaneous remodeling of the Oct4 promoter and enhancer also triggered reprogramming. Authentic pluripotent cell lines were established in both cases. Finally, we showed that targeted manipulation of histone acetylation at the Oct4 gene locus could also initiate reprogramming. Our study generated authentic iPSCs with CRISPR activation through precise epigenetic remodeling of endogenous loci and shed light on how targeted chromatin remodeling triggers pluripotency induction.
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•Endogenous Oct4 and Sox2 can be targeted and activated by CRISPR activation•Activation of endogenous Oct4 or Sox2 triggers reprogramming to pluripotency•Oct4 promoter and enhancer are simultaneously remodeled by dCas9-SunTag-p300core•Authentic induced pluripotent stem cells are generated with CRISPR activation
Ding and colleagues demonstrate that induced pluripotency can be achieved through targeted activation of endogenous Oct4 or Sox2 genes. With CRISPR activation, the promoter and enhancer are specifically remodeled, Oct4 or Sox2 is derepressed in fibroblasts, and reprogramming is triggered toward pluripotency.
Recent advances in genome engineering are starting a revolution in biological research and translational applications. The clustered regularly interspaced short palindromic repeats ...(CRISPR)-associated RNA-guided endonuclease CRISPR associated protein 9 (Cas9) and its variants enable diverse manipulations of genome function. In this review, we describe the development of Cas9 tools for a variety of applications in cell biology research, including the study of functional genomics, the creation of transgenic animal models, and genomic imaging. Novel genome engineering methods offer a new avenue to understand the causality between the genome and phenotype, thus promising a fuller understanding of cell biology.
The bacterial CRISPR-Cas9 system has emerged as an effective tool for sequence-specific gene knockout through non-homologous end joining (NHEJ), but it remains inefficient for precise editing of ...genome sequences. Here we develop a reporter-based screening approach for high-throughput identification of chemical compounds that can modulate precise genome editing through homology-directed repair (HDR). Using our screening method, we have identified small molecules that can enhance CRISPR-mediated HDR efficiency, 3-fold for large fragment insertions and 9-fold for point mutations. Interestingly, we have also observed that a small molecule that inhibits HDR can enhance frame shift insertion and deletion (indel) mutations mediated by NHEJ. The identified small molecules function robustly in diverse cell types with minimal toxicity. The use of small molecules provides a simple and effective strategy to enhance precise genome engineering applications and facilitates the study of DNA repair mechanisms in mammalian cells.
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•Screening identifies small molecules that modulate CRISPR genome editing•Small molecules enhance precise genome editing via HDR•Small molecules also enhance sequence-specific gene knockout via NHEJ•The identified small molecules work for different genes in diverse cell types
From a high-throughput screen, Yu et al. identify small molecules that modulate CRISPR-Cas9-mediated genome editing in human stem cells, for insertions, precise genome editing, and gene knockouts.