Project description:CRISPR activation and interference systems (CRISPRa/i) are widely used for programmable transcriptional control without introducing DNA edits. Although these technologies are capable of highly specific single-gene activity, some applications of transcriptional network reprogramming require broad, genome-wide effects. In this study, we identify a CRISPRa gRNA that is highly effective at reprogramming astrocyte transcriptional state. However, closer analysis revealed that this gRNA achieves this with widespread off-target activity capable of inducing expression changes in thousands of genes, in contrast to gRNAs targeting neighboring sites and regulating the same target gene. We use this promiscuous gRNA to further study the determinants of gRNA-driven off-target dCas9 binding in the context of transcriptional reprogramming. Employing a combination of ChIP-seq, high-throughput in vitro protein-binding microarrays, and high-throughput screening of gRNA-variant libraries in cells, we demonstrate that critical PAM-proximal bases within the gRNA seed sequence determine genomic binding, that mismatch tolerance varies by gRNA and base residue, and that mutating the PAM-proximal sequence of promiscuous gRNAs can modulate specificity. Finally, we find that CRISPRa-driven phenotypes can result from simultaneous contributions of active off-target effects and dose-dependent on-target activity. These findings highlight the potentially widespread impacts of CRISPRa off-target activity by gRNAs, underscore the need to account for cryptic effects when selecting and evaluating gRNAs for programming cell phenotypes, and demonstrate that multi-site binding in CRISPRa systems, typically viewed as a limitation, can also be exploited as a feature for network-level perturbations in cell reprogramming.

Project description:CRISPR activation and interference systems (CRISPRa/i) are widely used for programmable transcriptional control without introducing DNA edits. Although these technologies are capable of highly specific single-gene activity, some applications of transcriptional network reprogramming require broad, genome-wide effects. In this study, we identify a CRISPRa gRNA that is highly effective at reprogramming astrocyte transcriptional state. However, closer analysis revealed that this gRNA achieves this with widespread off-target activity capable of inducing expression changes in thousands of genes, in contrast to gRNAs targeting neighboring sites and regulating the same target gene. We use this promiscuous gRNA to further study the determinants of gRNA-driven off-target dCas9 binding in the context of transcriptional reprogramming. Employing a combination of ChIP-seq, high-throughput in vitro protein-binding microarrays, and high-throughput screening of gRNA-variant libraries in cells, we demonstrate that critical PAM-proximal bases within the gRNA seed sequence determine genomic binding, that mismatch tolerance varies by gRNA and base residue, and that mutating the PAM-proximal sequence of promiscuous gRNAs can modulate specificity. Finally, we find that CRISPRa-driven phenotypes can result from simultaneous contributions of active off-target effects and dose-dependent on-target activity. These findings highlight the potentially widespread impacts of CRISPRa off-target activity by gRNAs, underscore the need to account for cryptic effects when selecting and evaluating gRNAs for programming cell phenotypes, and demonstrate that multi-site binding in CRISPRa systems, typically viewed as a limitation, can also be exploited as a feature for network-level perturbations in cell reprogramming.

Project description:CRISPR activation and interference systems (CRISPRa/i) are widely used for programmable transcriptional control without introducing DNA edits. Although these technologies are capable of highly specific single-gene activity, some applications of transcriptional network reprogramming require broad, genome-wide effects. In this study, we identify a CRISPRa gRNA that is highly effective at reprogramming astrocyte transcriptional state. However, closer analysis revealed that this gRNA achieves this with widespread off-target activity capable of inducing expression changes in thousands of genes, in contrast to gRNAs targeting neighboring sites and regulating the same target gene. We use this promiscuous gRNA to further study the determinants of gRNA-driven off-target dCas9 binding in the context of transcriptional reprogramming. Employing a combination of ChIP-seq, high-throughput in vitro protein-binding microarrays, and high-throughput screening of gRNA-variant libraries in cells, we demonstrate that critical PAM-proximal bases within the gRNA seed sequence determine genomic binding, that mismatch tolerance varies by gRNA and base residue, and that mutating the PAM-proximal sequence of promiscuous gRNAs can modulate specificity. Finally, we find that CRISPRa-driven phenotypes can result from simultaneous contributions of active off-target effects and dose-dependent on-target activity. These findings highlight the potentially widespread impacts of CRISPRa off-target activity by gRNAs, underscore the need to account for cryptic effects when selecting and evaluating gRNAs for programming cell phenotypes, and demonstrate that multi-site binding in CRISPRa systems, typically viewed as a limitation, can also be exploited as a feature for network-level perturbations in cell reprogramming.

Project description:Background: The CRISPR/Cas9 toolbox has recently been expanded to include approaches for modulating gene expression. To successfully build on this work, and apply it for answering biological questions, it is important to establish it in a broad range of circumstances. Genome-scale CRISPR interference (CRISPRi) has been used in human cells lines, however the rules for designing effective guide RNAs (gRNAs) in different organisms are not well known. We sought to determine rules that determine gRNA effectiveness at transcriptional repression in Saccharomyces cerevisiae. Results: We created an inducible single plasmid CRISPRi system for gene repression in yeast, and used it to analyze fitness effects of gRNAs under 18 small molecule treatments. Our approach correctly identified previously-described chemical-genetic interactions, as well as a new mechanism of suppressing fluconazole toxicity by repression of the ERG25 gene. Assessment of multiple target loci across treatments allowed us to determine generalizable features associated with gRNA efficacy. Guides that target regions with low nucleosome occupancy and high chromatin accessibility were clearly more effective. We also found the best region to target gRNAs was between the transcription start site (TSS) and 200bp upstream of the TSS. Finally, unlike nuclease-proficient Cas9 in human cells, point mutations were tolerated equally well by truncated (18 nt specificity sequence) and full length (20 nt) gRNAs, however, 18 nt gRNAs were generally less potent than full length gRNAs. Conclusions: Our results establish a powerful functional genomics screening method, provide rules for designing effective gRNAs for gene repression, and show that 18 nt and 20 nt gRNAs exhibit similar tolerance to mismatches in the target sequence. These findings will enable effective library design and genome-wide screening in many genetic backgrounds. An expression construct was created for inducible CRISPRi in yeast. Key features include ORFs expressing dCas9-Mxi1 and the tetracycline repressor (TetR), as well as a tetracycline inducible gRNA locus containing the RPR1 promoter with a TetO site, a NotI site for cloning new gRNA specificity sequences, and the constant part of the gRNA. When yeast containing this plasmid are grown in the absence of anhydrotetracycline (ATc) TetR binds the gRNA promoter and prevents PolIII from binding and transcribing the gRNA. This in turn prevents dCas9-Mxi1 from binding the target site. In the presence of ATc, TetR dissociates and gRNA is expressed, allowing dCas9-Mxi1 to bind its target locus, and repress gene expression. gRNA libraries were cloned into this construct and transformed into yeast to create pools. Experiments were conducted in which yeast pools were grown in inducing (+ATc) and non-inducing conditions (-ATc) in the presence of different drugs. After multiple generations of growth in these conditions, yeast plasmids were minipreped and the gRNA locus was PCRed and sequenced via MiSeq. Counts of each gRNA were compared in different conditions.

Project description:Clustered regularly interspaced short palindromic repeat (CRISPR) RNA-guided nucleases have gathered considerable excitement as a tool for genome engineering. However, questions remain about the specificity of their target site recognition. Most previous studies have examined predicted off-target binding sites that differ from the perfect target site by one to four mismatches, which represent only a subset of genomic regions. Here, we used ChIP-seq to examine genome-wide CRISPR binding specificity at gRNA-specific and gRNA-independent sites. For two guide RNAs targeting the murine Snurf gene promoter, we observed very high binding specificity at the intended target site while off-target binding was observed at 2- to 6-fold lower intensities. We also identified significant gRNA-independent off-target binding. Interestingly, we found that these regions are highly enriched in the PAM site, a sequence required for target site recognition by CRISPR. To determine the relationship between Cas9 binding and endonuclease activity, we used targeted sequence capture as a high-throughput approach to survey a large number of the potential off-target sites identified by ChIP-seq or computational prediction. A high frequency of indels was observed at both target sites and one off-target site, while no cleavage activity could be detected at other ChIP-bound regions. Our results demonstrate that even a simple configuration of a Cas9:gRNA nuclease can support very specific DNA cleavage activity and that most interactions between the CRISPR nuclease complex and genomic PAM sites do not lead to DNA cleavage. ChIP-seq using dCas9 to determine genome-wide binding of CRISPR/Cas9 noED: Cas9 doublemutant protein without an effector domain KRAB: Cas9 doublemutant protein fused to the KRAB repressor domain S1 gRNA: guide RNA targeting GCTCCCTACGCATGCGTCCC(AGG) in the mouse genome S2 gRNA: guide RNA targeting AATGGCTCAGGTTTGTCGCG(CGG) in the mouse genome VEGFA TS3 gRNA: guide RNA targeting GGTGAGTGAGTGTGTGCGTG(TGG) in the human genome

Project description:High-fidelity Cas enzyme is pivotal to the safety of CRISPR technology in translational research and clinics. However, increasing editing fidelity often comes at the cost of a significant decrease in nuclease editing efficiency, e.g., the rationale designed SuperFi-Cas9 based on the structural basis for mismatch surveillance of wildtype Cas9. By conducting high-throughput profiling on the editing efficiency of 91,603 gRNAs, we found that SuperFi-Cas9/gRNA showed a strong nucleotide preference at the 21st position of the PAM-distal region of the target. A deep-learning model trained from the profiling data further provided a mutation map, which implied that a gRNA-target duplex with twenty-one matched nucleotides positively contributed to the editing efficiency of SuperFi-Cas9/gRNA. By further measuring the cleavage activities at twenty endogenous genomic locations, we demonstrated that a gRNA with extended 5' nucleotides significantly increased the editing activity of SuperFi-Cas9 while remaining its high fidelity, which makes SuperFi-Cas9 a valuable nuclease of the CRISPR toolbox. Together, by deep-learning modeling on high throughput profiling data, we reported that gRNAs with extended 5' nucleotides can rescue the impaired cleavage activities of SuperFi-Cas9.

Project description:In E. coli, editing efficiency (EE) with Cas9-mediated recombineering varies across targets due to differences in the level of Cas9:gRNA DNA double-strand break (DSB)-induced cell death. We found that EE with the same gRNA and repair template can also change with target position, cas9 promoter strength, and growth conditions. Incomplete editing, off-target activity, non-targeted mutations, and failure to cleave target DNA even if Cas9 is bound also compromise EE. These effects on EE were gRNA-specific. We propose that differences in the efficiency of Cas9:gRNA-mediated DNA DSBs and differences in rates of dissociation of Cas9:gRNA complexes from target sites account for the observed variations in EE between gRNAs. We show that editing behavior using the same gRNA can be modified by mutating the gRNA spacer, which changes the DNA DSB activity. Finally, we discuss how variable editing with different gRNAs could limit high-throughput applications and provide strategies to overcome these limitations.

Project description:Clustered regularly interspaced short palindromic repeat (CRISPR) RNA-guided nucleases have gathered considerable excitement as a tool for genome engineering. However, questions remain about the specificity of their target site recognition. Most previous studies have examined predicted off-target binding sites that differ from the perfect target site by one to four mismatches, which represent only a subset of genomic regions. Here, we used ChIP-seq to examine genome-wide CRISPR binding specificity at gRNA-specific and gRNA-independent sites. For two guide RNAs targeting the murine Snurf gene promoter, we observed very high binding specificity at the intended target site while off-target binding was observed at 2- to 6-fold lower intensities. We also identified significant gRNA-independent off-target binding. Interestingly, we found that these regions are highly enriched in the PAM site, a sequence required for target site recognition by CRISPR. To determine the relationship between Cas9 binding and endonuclease activity, we used targeted sequence capture as a high-throughput approach to survey a large number of the potential off-target sites identified by ChIP-seq or computational prediction. A high frequency of indels was observed at both target sites and one off-target site, while no cleavage activity could be detected at other ChIP-bound regions. Our results demonstrate that even a simple configuration of a Cas9:gRNA nuclease can support very specific DNA cleavage activity and that most interactions between the CRISPR nuclease complex and genomic PAM sites do not lead to DNA cleavage.

Project description:CRISPR-Cas transcriptional tools have been widely applied for programmable regulation of complex biological networks. In comparison to eukaryotic systems, bacterial CRISPR activation (CRISPRa) has stringent target site requirements for effective gene activation. While genes may not always have an NGG protospacer adjacent motif (PAM) at the appropriate position, PAM-flexible dCas9 variants can expand the range of targetable sites. Here we systematically evaluate a panel of PAM-flexible dCas9 variants for their ability to activate bacterial genes. We observe that dxCas9-NG provides a high dynamic range of gene activation for sites with NGN PAMs while dSpRY permits modest activity across almost any PAM. Similar trends were observed for heterologous and endogenous promoters. For all variants tested, improved PAM-flexibility comes with the tradeoff that CRISPRi-mediated gene repression becomes less effective. Weaker CRISPR interference (CRISPRi) gene repression can be partially rescued by expressing multiple sgRNAs to target many sites in the gene of interest. Our work provides a framework to choose the most effective dCas9 variant for a given set of gene targets, which will further expand the utility of CRISPRa/i gene regulation in bacterial systems.

Project description:Neuronal Wwox overexpression using CRISPRa in Drosophila melanogaster also expressing human AB42 can rescue amyloid related phenotypes. To understand how this may occur we performed bulk transcriptomics on day 14 heads from the same genotypes: 1) Control gRNA + lacZ expression control, 2) Control gRNA + amyloid, 3) Wwox gRNA + LacZ control, 4) Wwox gRNA + amyloid.