Project description:Evolved cytidine and adenosine base editors with high precision and minimized off-target activity by a novel continuous directed evolution system in mammalian cells

Project description:APOBEC3A high-precision CRISPR-Cas9 base editors with minimized bystander and off-target mutations activity

Project description:CRISPR gene editing has revolutionized biomedicine and biotechnology by providing a simple means to engineer genes in vivo by introducing mutations at target sites in the genomic DNA of living cells. However, given the stochasticity of cellular DNA repair mechanisms and the potential for introducing mutations at off-target sites, technologies capable of introducing targeted changes with increased precision, such as cytidine deaminase single-base editors, are preferred. We here present a versatile method termed CRISPR-SKIP that utilizes cytidine deaminase single-base editors to program de-novo exon skipping by mutating target DNA bases within splice acceptor sites. Given its simplicity and precision, CRISPR-SKIP will be broadly applicable in gene therapy and synthetic biology.

Project description:CRISPR gene editing has revolutionized biomedicine and biotechnology by providing a simple means to engineer genes in vivo by introducing mutations at target sites in the genomic DNA of living cells. However, given the stochasticity of cellular DNA repair mechanisms and the potential for introducing mutations at off-target sites, technologies capable of introducing targeted changes with increased precision, such as cytidine deaminase single-base editors, are preferred. We here present a versatile method termed CRISPR-SKIP that utilizes cytidine deaminase single-base editors to program de-novo exon skipping by mutating target DNA bases within splice acceptor sites. Given its simplicity and precision, CRISPR-SKIP will be broadly applicable in gene therapy and synthetic biology.

Project description:CRISPR gene editing has revolutionized biomedicine and biotechnology by providing a simple means to engineer genes in vivo by introducing mutations at target sites in the genomic DNA of living cells. However, given the stochasticity of cellular DNA repair mechanisms and the potential for introducing mutations at off-target sites, technologies capable of introducing targeted changes with increased precision, such as cytidine deaminase single-base editors, are preferred. We here present a versatile method termed CRISPR-SKIP that utilizes cytidine deaminase single-base editors to program de-novo exon skipping by mutating target DNA bases within splice acceptor sites. Given its simplicity and precision, CRISPR-SKIP will be broadly applicable in gene therapy and synthetic biology.

Project description:Precise adenine base editors that exhibit minimized cytosine catalysis

Project description:Continuous evolution of base editors with improved activity and target compatibility

Project description:Recent optimization of CRISPR/Cas9-mediated genome engineering has resulted in the development of base editors that can efficiently mediate C>T and A>G transitions. Combining these genome engineering tools with human adult stem cell (ASC)-derived organoid technology holds promise for disease modeling. Here, we demonstrate the application of base editors for the generation of complex tumor models in human ASC-derived hepatocyte, endometrial and intestinal organoids. First, using conventional and evolved Cas9-variants, we show efficacy of both cytosine and adenine base editors and use them to model four hot-spot point mutations in CTNNB1 in hepatocyte organoids. Next, we apply C>T base editors in endometrial organoids to insert nonsense mutations in PTEN and demonstrate tumorigenicity even in the heterozygous state. Furthermore, we use cytosine base editors for simultaneous oncogene activation (PIK3CA) and tumor-suppressor inactivation (APC and TP53). To increase the flexibility of base editor multiplexing, we then combine SpCas9 and SaCas9 base editors for simultaneous C>T and A>G editing at individual target sites. Finally, we show the power of base editor multiplexing by modeling colorectal tumorigenesis in a single step by simultaneously transfecting sgRNA’s targeting four cancer genes. Seven clonal organoid lines and one bulk wild-type control sample were paired-end whole-genome sequenced using the Illumina Novaseq 6000 system. We sequenced four clonal intestinal organoid lines harbouring engineered TP53 and FBXW7 mutations as well as three lines targeted for oncogenic APC/TP53/PIK3CA/SMAD4 mutations. This WGS showed, as previously reported, a genome-wide increase in C>T mutations due to C>T base editor off-target activity, which is not enriched in predicted off-target regions based on the sgRNA sequences. Furthermore, we confirmed the absence of editing-induced driver mutations and lack of off-target mutational hotspots created by the genomic engineering.

Project description:Next-generation cytosine base editors with minimized unguided DNA and RNA off-target events and high on-target activity

Project description:RNA-programmable deaminases, known as base editors (BEs), enable precise single base conversions on genomic DNA and hold great promise for therapeutic application in patients. Recent studies, however, have raised serious concern with regard to off-target effects, questioning translatability of BEs to the clinic. Here we analyze transcriptome- and genome-wide off-target effects following AAV-mediated delivery of cytosine base editors (CBEs) in vivo in an unbiased manner. We show that low expression of CBEs allows sufficient on-target editing to cure a disease phenotype with no increase in off-target effects compared to untreated controls. To further improve safety of in vivo base editing, we developed a lipid nanoparticle (LNP)-mediated delivery system to transiently express BEs. We reach up to 21% on-target editing with no detectable transcriptome- or genome-wide off-target effects, and are able to reverse the disease phenotype of a phenylketonuria mouse model. These results have important implications, underlining the feasibility of transient in vivo base editing for therapeutic use in patients.