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:Cas9, a CRISPR RNA-guided nuclease, has been rapidly adopted as a tool for biochemical and genetic manipulation of DNA. Although Cas9 offers remarkable specificity and versatility for genome manipulation, mis-targeted events occur. To extend the understanding of Cas9 target::homology requirements, we compared mismatch tolerance for a specific Cas9::gRNA complex in vitro and in vivo (in Saccharomyces cerevisiae). A variety of truncated and full-length gRNAs (with 17, 18, and 20 nucleotides of complementarity sequence) were used. In each case, we observed notable differences between in vitro and in vivo Cas9 cleavage specificity profiles, with a more stringent effect of mismatches on activity seen in vivo. Increased specificity of the 18 nt complementarity truncated gRNA was evident in vivo, but not in vitro. Overall, this study highlights differences in the specificity of Cas9 cleavage between controlled in vitro conditions and complex and chromatinized in vivo conditions. We adapted a previous high throughput sequencing approach (doi: 10.1093/nar/gku1102) to assess the effects of single base variants in vivo. We used a polymorphic random variant library matched to a specific trigger sequence (for which we used a segment from the C. elegans unc-22 gene, previously designated ‘unc-22A’ (doi: 10.1093/nar/gku1102). Cas9 in vivo and in vitro assays were carried out with four different gRNAs incorporating sequence from the unc-22A trigger segment. The four segments incorporate 17 nt, 18 nt, 20 nt, and 20+G nt of unc-22A complementarity respectively. The retention is calculated based on PMID: 25399416. File names denote the experiment-> gRNAname_gRNAlength_(invitro or invivo)_(incubation or induction time)_IlluminaRunID.dat The files contain all normalized sequences in column one with their calculated retentions in column 2.

Project description:Type VI CRISPR enzymes are RNA-targeting proteins with nuclease activity that enable specific and robust target gene knockdown without altering the genome. To define rules for the design of Cas13d guide RNAs, we conducted massively parallel screens targeting messenger RNAs of a green fluorescent protein transgene, and CD46, CD55 and CD71 cell-surface proteins in human cells. In total, we measured the activity of 24,460 gRNAs with and without mismatches relative to the target sequences. Knockdown efficacy is driven by gRNA-specific features and target site context. Single mismatches generally reduce knockdown to a modest degree, but spacer nucleotides 15–21 are largely intolerant of target site mismatches. We developed a computational model to identify optimal gRNAs and confirm their generalizability testing 3,979 guides targeting mRNAs of 48 endogenous genes. We show that Cas13 can be used in forward transcriptomic pooled screens and, using our model, predict optimized Cas13 gRNAs for all protein-coding transcripts in the human genome.

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:We previous identified enhancers that regulate MYC expression in K562 cells (Fulco et al. Science 2016). Here, we perturbed MYC enhancers with individual CRISPRi gRNAs and performed ChIP-seq to study the effects on chromatin state.

Project description:Genome-scale CRISPR interference (CRISPRi) is widely utilized to study cellular processes in a variety of organisms. To date, a genome-wide CRISPRi library, optimized for targeting the Saccharomyces cerevisiae genome, has not been presented. Here, we have generated a comprehensive, inducible CRISPRi library, based on spacer design rules optimized for yeast. We have validated this library for genome-wide interrogation of gene function across a variety of applications, including accurate discovery of haploinsufficient genes and identification of enzymatic and regulatory genes involved in adenine and arginine biosynthesis. The comprehensive nature of the library also revealed refined spacer design parameters for transcriptional repression, including location, nucleosome occupancy and nucleotide features. CRISPRi screens using this library can identify genes and pathways with high precision and low false discovery rate across a variety of experimental conditions, enabling rapid and reliable genome-wide assessment of genetic function and interactions in S. cerevisiae.

Project description:Infinium MethylationEPIC (850K) BeadChip data for wildtype SUM159 cells (2 replicates), SUM159 cells transfected with plV-KRAB (dCas9 CRISPRi system; 3 replicates), and SUM159 cells transfected with dCas9-KRAB and 4 targeting gRNAs against the ZEB1 promoter (3 replicates)

Project description:Cas9, a CRISPR RNA-guided nuclease, has been rapidly adopted as a tool for biochemical and genetic manipulation of DNA. Although Cas9 offers remarkable specificity and versatility for genome manipulation, mis-targeted events occur. To extend the understanding of Cas9 target::homology requirements, we compared mismatch tolerance for a specific Cas9::gRNA complex in vitro and in vivo (in Saccharomyces cerevisiae). A variety of truncated and full-length gRNAs (with 17, 18, and 20 nucleotides of complementarity sequence) were used. In each case, we observed notable differences between in vitro and in vivo Cas9 cleavage specificity profiles, with a more stringent effect of mismatches on activity seen in vivo. Increased specificity of the 18 nt complementarity truncated gRNA was evident in vivo, but not in vitro. Overall, this study highlights differences in the specificity of Cas9 cleavage between controlled in vitro conditions and complex and chromatinized in vivo conditions.

Project description:The vast majority of complex disease associations cannot be cleanly mapped to a gene, as they often lie within the non-cding fraction of the genome. Immune disease-associated variants are enriched within regulatory elements, such as distal enhancers, found in T cell-specific open chromatin regions. To identify the genes modulated by these regulatory elements, we developed a CRISPRi-based single-cell functional screening approach in primary human CD4+ T cells. We performed a proof-of-concept screen targeting 45 non-coding regulatory elements and 35 transcription start sites, each targeted by 4 different gRNAs. We profiled approximately 250,000 CD4+ T cell single-cell transcriptomes using 3' 10X Genomics.

Project description:We examined the influence of chemical modifications patterns in a set of miR-200c mimics, assessing the regulation of the whole transcriptome in A549 cells. We examined 37 mimics and provided an initial set of rules for designing miRNA mimics with potency and selectivity similar to an unmodified miRNA duplex.