Correction of a CADASIL point mutation using adenine base editors in hiPsCsandbloodvessel organoids

Cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy (CADASIL) is a monogenic small vessel disease caused by mutations in the NOTCH3 gene. However, the pathogenesis of CADASIL remains unclear, and patients have limited treatment options. Here, we use human induced pluripotent stem cells (hiPSCs) generated from the peripheral blood mononuclear cells of a patient with CADASIL carrying a heterozygous NOTCH3 mutation (c.1261C>T, p.R421C) to develop a disease model. The correction efficiency of different adenine base editors (ABEs) is tested using the HEK293T-NOTCH3 reporter cell line. ABEmax is selected based on its higher efficiency and minimization of predicted off-target effects. Vascular smooth muscle cells (VSMCs) differentiated from CADASIL hiPSCs show NOTCH3 deposition and abnormal actin cytoskeleton structure, and the abnormalities are recovered in corrected hiPSC-derived VSMCs. Furthermore, CADASIL blood vessel organoids generated for in vivo modeling show altered expression of genes related to disease phenotypes, including the downregulation of cell adhesion, extracellular matrix organization, and vessel development. The dual adeno-associated virus (AAV) split-ABEmax system is applied to the genome editing of vascular organoids with an average editing efficiency of 8.82%. Collectively, we present potential genetic therapeutic strategies for patients with CADASIL using blood vessel organoids and the dual AAV split-ABEmax system.

Artificial evolution of OsEPSPS through an improved dual cytosine and adenine base editor generated a novel allele conferring rice glyphosate tolerance

Exploiting novel endogenous glyphosate-tolerant alleles is highly desirable and has promising potential for weed control in rice breeding. Here,through fusions of different effective cytosine and adenine deaminases with nCas9-NG, we engineered an effective surrogate two-component composite base editing system, STCBE-2, with improved C-to-T and A-to-G base editing efficiency and expanded the editing window. Furthermore,we targeted a rice endogenous OsEPSPS gene for artificial evolution through STCBE-2-mediated near-saturated mutagenesis. After hygromycin and glyphosate selection, we identified a novel OsEPSPS allele with an Asp-213-Asn(D213N)mutation(OsEPSPS-D213N) in the predicted glyphosate-binding domain, which conferred rice plants reliable glyphosate tolerance and had not been reported or applied in rice breeding. Collectively, we developed a novel dual base editor which will be valuable for artificial evolution of important genes in crops. And the novel glyphosate-tolerant rice germplasm generated in this study will benefit weeds management in rice paddy fields.

Single-nucleotide editing for zebra3 and wsl5 phenotypes in rice using CRISPR/Cas9-mediated adenine base editors

The CRISPR/Cas9-mediated base editing technology can efficiently generate point mutations in the genome without introducing a double-strand break(DSB)or supplying a DNA donor template for homology-directed repair(HDR).In this study,adenine base editors(ABEs)were used for rapid generation of precise point mutations in two distinct genes,OsWSL5,and OsZEBRA3(Z3),in both rice protoplasts and regenerated plants.The precisely engineered point mutations were stably inherited to subsequent generations.These single nucleotide alterations resulted in single amino acid changes and associated wsl5 and z3 phenotypes as evidenced by white stripe leaf and light green/dark green leaf pattern,respectively.Through selfing and genetic segregation,transgene-free,base edited wsl5 and z3 mutants were obtained in a short period of time.We noticed a novel mutation(V540A)in Z3 locus could also mimic the phenotype of Z3 mutation(S542P).Furthermore,we observed unexpected non-A/G or T/C mutations in the ABE editing window in a few of the edited plants.The ABE vectors and the method from this study could be used to simultaneously generate point mutations in multiple target genes in a single transformation and serve as a useful base editing tool for crop improvement as well as basic studies in plant biology.

Precise genome editing with base editors

Single-nucleotide variants account for about half of known pathogenic genetic variants in human.Genome editing strategies by reversing pathogenic point mutations with minimum side effects have great therapeutic potential and are now being actively pursued.The emerge of precise and effcient genome editing strategies such as base editing and prime editing provide powerful tools for nucleotide conversion without inducing double-stranded DNA breaks(DSBs),which have shown great potential for curing genetic disorders.A diverse toolkit of base editors has been devel-oped to improve the editing effciency and accuracy in different context of application.Here,we summarized the evolving of base editors(BEs),their limitations and future perspective of base editing-based therapeutic strategies.

CRISPR-Cas nucleases and base editors for plant genome editing

Clustered regularly interspaced short palindromic repeats(CRISPR)—CRISPR-associated protein(Cas)and base editors are fundamental tools in plant genome editing.Cas9 from Streptococcus pyogenes(SpCas9),recognizing an NGG protospacer adjacent motif(PAM),is a widely used nuclease for genome editing in living cells.Cas12a nucleases,targeting T-rich PAMs,have also been recently demonstrated in several plant species.Furthermore,multiple Cas9 and Cas12a engineered variants and orthologs,with different PAM recognition sites,editing efficiencies and fidelity,have been explored in plants.These RNA-guided sequence-specific nucleases(SSN)generate double-stranded breaks(DSBs)in DNA,which trigger non-homologous end-joining(NHEJ)repair or homology-directed repair(HDR),resulting in insertion and deletion(indel)mutations or precise gene replacement,respectively.Alternatively,genome editing can be achieved by base editors without introducing DSBs.So far,several base editors have been applied in plants to introduce C-to-T or A-to-G transitions,but they are still undergoing improvement in editing window size,targeting scope,off-target effects in DNA and RNA,product purity and overall activity.Here,we summarize recent progress on the application of Cas nucleases,engineered Cas variants and base editors in plants.

CRISPR base editing and prime editing:DSB and template-free editing systems for bacteria and plants

CRISPR-Cas(Clustered Regularly Interspaced Short Palindromic Repeats-CRISPR associated)has been extensively exploited as a genetic tool for genome editing.The RNA guided Cas nucleases generate DNA doublestrand break(DSB),triggering cellular repair systems mainly Non-homologous end-joining(NHEJ,imprecise repair)or Homology-directed repair(HDR,precise repair).However,DSB typically leads to unexpected DNA changes and lethality in some organisms.The establishment of bacteria and plants into major bio-production platforms require efficient and precise editing tools.Hence,in this review,we focus on the non-DSB and template-free genome editing,i.e.,base editing(BE)and prime editing(PE)in bacteria and plants.We first highlight the development of base and prime editors and summarize their studies in bacteria and plants.We then discuss current and future applications of BE/PE in synthetic biology,crop improvement,evolutionary engineering,and metabolic engineering.Lastly,we critically consider the challenges and prospects of BE/PE in PAM specificity,editing efficiency,off-targeting,sequence specification,and editing window.