Project description:The clustered regularly interspaced short palindromic repeat (CRISPR)-associated enzyme Cas9 is an RNA-guided nuclease that has been widely adapted for genome editing in eukaryotic cells. However, the in vivo target specificity of Cas9 is poorly understood and most studies rely on in silico predictions to define the potential off-target editing spectrum. Using chromatin immunoprecipitation followed by sequencing (ChIP-seq), we delineate the genome-wide binding panorama of catalytically inactive Cas9 directed by two different single guide (sg) RNAs targeting the Trp53 locus. Cas9:sgRNA complexes are able to load onto multiple sites with short seed regions adjacent to 5’NGG3’ protospacer adjacent motifs (PAM). Examination of dmCas9 binding sites using two Trp53 targeting sgRNAs in Arf -/- MEF cell line (mouse).

Project description:We identified robust cleavage by non-canonically-targeted SpCas9 that target protospacer with a few bases from the canonical NGG PAM in biochemistry assay. To determine whether this spaced SpCas9 cleavage exists in human cells, we employed high-throughput genome-wide translocation sequencing (LAM-HTGTS) using SpCas9 with three independent canonical sgRNAs served as bait (bait-A, bait-L and bait-D) to compared the cleavage activities of canonically-targeted and non-canonically-targeted SpCas9 in eight locus (RAG1B-D, RAG1K-O) in chromosome 11. We found that almost all 1bp-target shifted SpCas9 generated substantial DSBs as the canonical controls. While detected less frequently, 2bp-targeted shifted SpCas9 generated significant amounts of DSBs in RAG1D and RAG1L locus. These findings underscore the spaced PAM-mediated DSBs occurred in living cells.

Project description:The clustered regularly interspaced short palindromic repeat (CRISPR)-associated enzyme Cas9 is an RNA-guided nuclease that has been widely adapted for genome editing in eukaryotic cells. However, the in vivo target specificity of Cas9 is poorly understood and most studies rely on in silico predictions to define the potential off-target editing spectrum. Using chromatin immunoprecipitation followed by sequencing (ChIP-seq), we delineate the genome-wide binding panorama of catalytically inactive Cas9 directed by two different single guide (sg) RNAs targeting the Trp53 locus. Cas9:sgRNA complexes are able to load onto multiple sites with short seed regions adjacent to 5’NGG3’ protospacer adjacent motifs (PAM).

Project description:In this study, we used a surrogate lentivirus library to capture CRISPR editing outcome in HEK cells. The dataset include quantification of indel frequencies for SpCas9 gRNAs in 12,000 surrogate sites. After filtering low quality sites, the high quality SpCas9 gRNA activities from a total of 10592 sites have been used to develop an improved deep learning-based prediction model CRISPRon (https://rth.dk/resources/crispr/.).

Project description:The Detect-seq provides an unbiased method for genome-wide identification of CBE induced off-targets inside of cells. Purpose: Cytosine base editors (CBEs) have the potential to correct human pathogenic point mutations. However, its genome-wide specificity remains poorly understood, precluding its therapeutic applications. Unbiased tools are urgently needed to comprehensively evaluate CBE off-targets at the genome-wide level. Methods: The genomic DNA from CBE transfected cells are processed with fragmentation, endogenous d5fC protection, damage repair, biotin-dUTP and 5fdCTP labeling, and pull-down steps. After the sequencing library preparation, the FASTQ files are produced by the Illumina HiSeq XTen platform. To guarantee the reproducibility, each case of the experiment is present with two biological replicates. Results: Through Detect-seq, we comprehensively profiled the genome-wide off-targets of CBE for several representative sgRNAs, and observed both weak, “random-like” off-targets as well as strong Cas9-dependent off-targets in different human cell lines. Cas9-dependent off-targets can be prevalent for several sgRNAs, and demonstrate a divergent degrees of sequence similarity to the sgRNA. These CBE-induced off-target sites differ greatly from those caused by Cas9 nuclease alone, suggesting inherently different properties among these genome editing tools. Targeted amplicon sequencing further corroborated the novel off-target sites by Detect-seq; quite a few sites showed editing ratio that is on the same order of magnitude or even comparable to the on-target sites. Detect-seq also revealed two unexpected types of Cas9-dependent off-targets, which are out-of-protospacer editing and target-strand editing. These novel off-targets were likely caused by an unstable structure at the PAM-distal side of the Cas9-sgRNA-DNA complex. Based upon such understanding to the off-target editing, we engineered several CBE variants bearing mutations in APOBEC1 and obtained improved CBEs with significantly reduced off-target editing activities.

Project description:The Detect-seq provides an unbiased method for genome-wide identification of CBE induced off-targets inside of cells. Purpose: Cytosine base editors (CBEs) have the potential to correct human pathogenic point mutations. However, its genome-wide specificity remains poorly understood, precluding its therapeutic applications. Unbiased tools are urgently needed to comprehensively evaluate CBE off-targets at the genome-wide level. Methods: The genomic DNA from CBE transfected cells are processed with fragmentation, endogenous d5fC protection, damage repair, biotin-dUTP and 5fdCTP labeling, and pull-down steps. After the sequencing library preparation, the FASTQ files are produced by the Illumina HiSeq XTen platform. To guarantee the reproducibility, each case of the experiment is present with two biological replicates. Results: Through Detect-seq, we comprehensively profiled the genome-wide off-targets of CBE for several representative sgRNAs, and observed both weak, “random-like” off-targets as well as strong Cas9-dependent off-targets in different human cell lines. Cas9-dependent off-targets can be prevalent for several sgRNAs, and demonstrate a divergent degrees of sequence similarity to the sgRNA. These CBE-induced off-target sites differ greatly from those caused by Cas9 nuclease alone, suggesting inherently different properties among these genome editing tools. Targeted amplicon sequencing further corroborated the novel off-target sites by Detect-seq; quite a few sites showed editing ratio that is on the same order of magnitude or even comparable to the on-target sites. Detect-seq also revealed two unexpected types of Cas9-dependent off-targets, which are out-of-protospacer editing and target-strand editing. These novel off-targets were likely caused by an unstable structure at the PAM-distal side of the Cas9-sgRNA-DNA complex. Based upon such understanding to the off-target editing, we engineered several CBE variants bearing mutations in APOBEC1 and obtained improved CBEs with significantly reduced off-target editing activities. Detect-seq utilized a dU-mapping strategy to profile on-target and off-target editing events by CBE at the whole-genome level. We applied Detect-seq to off-target evaluation in HEK293T and MCF7 cells for BE4max with several frequently used sgRNAs: “VEGFA site 2”, “HEK293 site 4”, “EMX1”, and “RNF2”.

Project description:CRISPR-guided DNA base editors enable the efficient installation of targeted single-nucleotide changes. Cytosine or adenine base editors (CBEs or ABEs), which are fusions of cytidine or adenosine deaminases to CRISPR-Cas nickases, can efficiently induce DNA C-to-T or A-to-G alterations in DNA, respectively. We recently demonstrated that both the widely used CBE BE3 (harboring a rat APOBEC1 cytidine deaminase) and the optimized ABEmax editor can induce tens of thousands of guide RNA-independent, transcriptome-wide RNA base edits in human cells with high efficiencies. In addition, we showed the feasibility of creating SElective Curbing of Unwanted RNA Editing (SECURE)-BE3 variants that exhibit substantially reduced unwanted RNA editing activities while retaining robust and more precise on-target DNA editing. Here we describe structure-guided engineering of SECURE-ABE variants that not only possess reduced off-target RNA editing with comparable on-target DNA activities but are also the smallest Streptococcus pyogenes Cas9 (SpCas9) base editors described to date. In addition, we tested CBEs composed of cytidine deaminases other than APOBEC1 and found that human APOBEC3A (hA3A) cytidine deaminase CBE induces substantial transcriptome-wide RNA base edits with high efficiencies. By contrast, a previously described “enhanced” A3A (eA3A) cytidine deaminase CBE or a human activation-induced cytidine deaminase (hAID) CBE induce substantially reduced or near background levels of RNA edits. In sum, our work describes broadly useful SECURE-ABE and -CBE base editors and reinforces the importance of minimizing RNA editing activities of DNA base editors for research and therapeutic applications.

Project description:CRISPR-guided DNA base editors enable the efficient installation of targeted single-nucleotide changes. Cytosine or adenine base editors (CBEs or ABEs), which are fusions of cytidine or adenosine deaminases to CRISPR-Cas nickases, can efficiently induce DNA C-to-T or A-to-G alterations in DNA, respectively. We recently demonstrated that both the widely used CBE BE3 (harboring a rat APOBEC1 cytidine deaminase) and the optimized ABEmax editor can induce tens of thousands of guide RNA-independent, transcriptome-wide RNA base edits in human cells with high efficiencies. In addition, we showed the feasibility of creating SElective Curbing of Unwanted RNA Editing (SECURE)-BE3 variants that exhibit substantially reduced unwanted RNA editing activities while retaining robust and more precise on-target DNA editing. Here we describe structure-guided engineering of SECURE-ABE variants that not only possess reduced off-target RNA editing with comparable on-target DNA activities but are also the smallest Streptococcus pyogenes Cas9 (SpCas9) base editors described to date. In addition, we tested CBEs composed of cytidine deaminases other than APOBEC1 and found that human APOBEC3A (hA3A) cytidine deaminase CBE induces substantial transcriptome-wide RNA base edits with high efficiencies. By contrast, a previously described “enhanced” A3A (eA3A) cytidine deaminase CBE or a human activation-induced cytidine deaminase (hAID) CBE induce substantially reduced or near background levels of RNA edits. In sum, our work describes broadly useful SECURE-ABE and -CBE base editors and reinforces the importance of minimizing RNA editing activities of DNA base editors for research and therapeutic applications.

Project description:The hpCasMINI exhibits high specificity for gene editing. Compared to SpCas9 and LbCas12a, hpCasMINI also exhibited higher specificity for genomic DNA cleavage at the tested sites.

Project description:A key limitation of the commonly-used CRISPR enzyme S. pyogenes Cas9 is the strict requirement of an NGG protospacer-adjacent motif (PAM) at the target site, which reduces the number of accessible genomic loci. This constraint can be limiting for genome editing applications that require precise Cas9 positioning. Recently, two Cas9 variants with a relaxed PAM requirement (NG) have been developed (xCas9 and Cas9-NG) but their activity has been measured at only a small number of endogenous sites. Here we devised a high-throughput Cas9 pooled competition screen to compare the performance of both PAM-flexible Cas9 variants and wild-type Cas9 at thousands of genomic loci and across 3 modalities (gene knock-out, transcriptional activation and suppression). We show that PAM flexibility comes at a substantial cost of decreased DNA targeting and cutting. Of the PAM-flexible variants, we found that Cas9-NG outperforms xCas9 regardless of genome engineering modality or PAM. Finally, we combined xCas9 mutations with those of Cas9-NG, creating a stronger transcriptional modulator than existing PAM-flexible Cas9 variants.