Targeted gene exchange in plant cells mediated by a zinc finger nuclease double cut

Genome modification by homology‐directed repair (HDR) is an attractive tool for the controlled genetic manipulation of plants. Here, we report the HDR‐mediated gene exchange of expression cassettes in tobacco BY‐2 cells using a designed zinc finger nuclease (ZFN). The target contained a 7‐kb fragment flanked by two ZFN cutting sites. That fragment was replaced with a 4‐kb donor cassette, which integrates gene markers for selection (kanamycin resistance) and for scoring targeting (red fluorescent protein, RFP). Candidates resulting from cassette exchange were identified by molecular analysis of calli generated by transformation via direct DNA delivery. The precision of HDR‐mediated donor integration was evaluated by Southern blot analysis, sequencing of the integration locus and analysis of RFP fluorescence by flow cytometry. Screening of 1326 kanamycin‐resistant calli yielded 18 HDR events, 16 of which had a perfect cassette exchange at the insert junction and 13 of which produced functional RFP. Our results demonstrate that ZFN‐based HDR can be used for high frequency, precise, targeted exchange of fragments of sizes that are commercially relevant in plants.     

Genome editing with CompoZr custom zinc finger nucleases (ZFNs)

Genome editing is a powerful technique that can be used to elucidate gene function and the genetic basis of disease. Traditional gene editing methods such as chemical-based mutagenesis or random integration of DNA sequences confer indiscriminate genetic changes in an overall inefficient manner and require incorporation of undesirable synthetic sequences or use of aberrant culture conditions, potentially confusing biological study. By contrast, transient ZFN expression in a cell can facilitate precise, heritable gene editing in a highly efficient manner without the need for administration of chemicals or integration of synthetic transgenes. Zinc finger nucleases (ZFNs) are enzymes which bind and cut distinct sequences of double-stranded DNA (dsDNA). A functional CompoZr ZFN unit consists of two individual monomeric proteins that bind a DNA "half-site" of approximately 15-18 nucleotides (see Figure 1). When two ZFN monomers "home" to their adjacent target sites the DNA-cleavage domains dimerize and create a double-strand break (DSB) in the DNA. Introduction of ZFN-mediated DSBs in the genome lays a foundation for highly efficient genome editing. Imperfect repair of DSBs in a cell via the non-homologous end-joining (NHEJ) DNA repair pathway can result in small insertions and deletions (indels). Creation of indels within the gene coding sequence of a cell can result in frameshift and subsequent functional knockout of a gene locus at high efficiency. While this protocol describes the use of ZFNs to create a gene knockout, integration of transgenes may also be conducted via homology-directed repair at the ZFN cut site. The CompoZr Custom ZFN Service represents a systematic, comprehensive, and well-characterized approach to targeted gene editing for the scientific community with ZFN technology. Sigma scientists work closely with investigators to 1) perform due diligence analysis including analysis of relevant gene structure, biology, and model system pursuant to the project goals, 2) apply this knowledge to develop a sound targeting strategy, 3) then design, build, and functionally validate ZFNs for activity in a relevant cell line. The investigator receives positive control genomic DNA and primers, and ready-to-use ZFN reagents supplied in both plasmid DNA and in-vitro transcribed mRNA format. These reagents may then be delivered for transient expression in the investigator's cell line or cell type of choice. Samples are then tested for gene editing at the locus of interest by standard molecular biology techniques including PCR amplification, enzymatic digest, and electrophoresis. After positive signal for gene editing is detected in the initial population, cells are single-cell cloned and genotyped for identification of mutant clones/alleles.     

Trait stacking via targeted genome editing

Modern agriculture demands crops carrying multiple traits. The current paradigm of randomly integrating and sorting independently segregating transgenes creates severe downstream breeding challenges. A versatile, generally applicable solution is hereby provided: the combination of high‐efficiency targeted genome editing driven by engineered zinc finger nucleases (ZFNs) with modular ‘trait landing pads’ (TLPs) that allow ‘mix‐and‐match’, on‐demand transgene integration and trait stacking in crop plants. We illustrate the utility of nuclease‐driven TLP technology by applying it to the stacking of herbicide resistance traits. We first integrated into the maize genome an herbicide resistance gene, pat, flanked with a TLP (ZFN target sites and sequences homologous to incoming DNA) using WHISKERS?‐mediated transformation of embryogenic suspension cultures. We established a method for targeted transgene integration based on microparticle bombardment of immature embryos and used it to deliver a second trait precisely into the TLP via cotransformation with a donor DNA containing a second herbicide resistance gene, aad1, flanked by sequences homologous to the integrated TLP along with a corresponding ZFN expression construct. Remarkably, up to 5% of the embryo‐derived transgenic events integrated the aad1 transgene precisely at the TLP, that is, directly adjacent to the pat transgene. Importantly and consistent with the juxtaposition achieved via nuclease‐driven TLP technology, both herbicide resistance traits cosegregated in subsequent generations, thereby demonstrating linkage of the two independently transformed transgenes. Because ZFN‐mediated targeted transgene integration is becoming applicable across an increasing number of crop species, this work exemplifies a simple, facile and rapid approach to trait stacking.     

Highly efficient homology‐directed repair using CRISPR/Cpf1‐geminiviral replicon in tomato

Genome editing via the homology‐directed repair (HDR) pathway in somatic plant cells is very inefficient compared with error‐prone repair by nonhomologous end joining (NHEJ). Here, we increased HDR‐based genome editing efficiency approximately threefold compared with a Cas9‐based single‐replicon system via the use of de novo multi‐replicon systems equipped with CRISPR/LbCpf1 in tomato and obtained replicon‐free but stable HDR alleles. The efficiency of CRISPR/LbCpf1‐based HDR was significantly modulated by physical culture conditions such as temperature and light. Ten days of incubation at 31 °C under a light/dark cycle after Agrobacterium‐mediated transformation resulted in the best performance among the tested conditions. Furthermore, we developed our single‐replicon system into a multi‐replicon system that effectively increased HDR efficiency. Although this approach is still challenging, we showed the feasibility of HDR‐based genome editing of a salt‐tolerant SlHKT1;2 allele without genomic integration of antibiotic markers or any phenotypic selection. Self‐pollinated offspring plants carrying the HKT1;2 HDR allele showed stable inheritance and germination tolerance in the presence of 100 mm NaCl. Our work may pave the way for transgene‐free editing of alleles of interest in asexually and sexually reproducing plants.     

Efficient disruption and replacement of an effector gene in the oomycete Phytophthora sojae using CRISPR/Cas9

Phytophthora sojae is an oomycete pathogen of soybean. As a result of its economic importance, P. sojae has become a model for the study of oomycete genetics, physiology and pathology. The lack of efficient techniques for targeted mutagenesis and gene replacement have long hampered genetic studies of pathogenicity in Phytophthora species. Here, we describe a CRISPR/Cas9 system enabling rapid and efficient genome editing in P. sojae. Using the RXLR effector gene Avr4/6 as a target, we observed that, in the absence of a homologous template, the repair of Cas9‐induced DNA double‐strand breaks (DSBs) in P. sojae was mediated by non‐homologous end‐joining (NHEJ), primarily resulting in short indels. Most mutants were homozygous, presumably as a result of gene conversion triggered by Cas9‐mediated cleavage of non‐mutant alleles. When donor DNA was present, homology‐directed repair (HDR) was observed, which resulted in the replacement of Avr4/6 with the NPT II gene. By testing the specific virulence of several NHEJ mutants and HDR‐mediated gene replacements in soybean, we have validated the contribution of Avr4/6 to recognition by soybean R gene loci, Rps4 and Rps6, but also uncovered additional contributions to resistance by these two loci. Our results establish a powerful tool for the study of functional genomics in Phytophthora, which provides new avenues for better control of this pathogen.     

Genome Editing—Principles and Applications for Functional Genomics Research and Crop Improvement

Genome editing technologies are powerful tools for studying gene function and for crop improvement. The technologies rely on engineered endonucleases to generate double stranded breaks (DSBs) at target loci. The DSBs are repaired through the error-prone non-homologous end joining (NHEJ) and homology-directed repair (HDR) pathways in cells, resulting in mutations and sequence replacement, respectively. In the widely used CRISPR/Cas9 system, the endonuclease Cas9 is targeted by a CRISPR small RNA to DNA sequence of interest. In this review, we describe the four available types of genome editing tools, ZFN, TALEN, CRISPR/Cas9 and CRISPR/Cpf1, and show their applications in functional genomics research and precision molecular breeding of crops.     

Both CRISPR/Cas‐based nucleases and nickases can be used efficiently for genome engineering in Arabidopsis thaliana

Engineered nucleases can be used to induce site‐specific double‐strand breaks (DSBs) in plant genomes. Thus, homologous recombination (HR) can be enhanced and targeted mutagenesis can be achieved by error‐prone non‐homologous end‐joining (NHEJ). Recently, the bacterial CRISPR/Cas9 system was used for DSB induction in plants to promote HR and NHEJ. Cas9 can also be engineered to work as a nickase inducing single‐strand breaks (SSBs). Here we show that only the nuclease but not the nickase is an efficient tool for NHEJ‐mediated mutagenesis in plants. We demonstrate the stable inheritance of nuclease‐induced targeted mutagenesis events in the ADH1 and TT4 genes of Arabidopsis thaliana at frequencies from 2.5 up to 70.0%. Deep sequencing analysis revealed NHEJ‐mediated DSB repair in about a third of all reads in T1 plants. In contrast, applying the nickase resulted in the reduction of mutation frequency by at least 740‐fold. Nevertheless, the nickase is able to induce HR at similar efficiencies as the nuclease or the homing endonuclease I–SceI. Two different types of somatic HR mechanisms, recombination between tandemly arranged direct repeats as well as gene conversion using the information on an inverted repeat could be enhanced by the nickase to a similar extent as by DSB‐inducing enzymes. Thus, the Cas9 nickase has the potential to become an important tool for genome engineering in plants. It should not only be applicable for HR‐mediated gene targeting systems but also by the combined action of two nickases as DSB‐inducing agents excluding off‐target effects in homologous genomic regions.     

CRISPR‐Cas9‐mediated efficient directed mutagenesis and RAD51‐dependent and RAD51‐independent gene targeting in the moss Physcomitrella patens

The ability to address the CRISPR‐Cas9 nuclease complex to any target DNA using customizable single‐guide RNAs has now permitted genome engineering in many species. Here, we report its first successful use in a nonvascular plant, the moss Physcomitrella patens. Single‐guide RNAs (sgRNAs) were designed to target an endogenous reporter gene, PpAPT, whose inactivation confers resistance to 2‐fluoroadenine. Transformation of moss protoplasts with these sgRNAs and the Cas9 coding sequence from Streptococcus pyogenes triggered mutagenesis at the PpAPT target in about 2% of the regenerated plants. Mainly, deletions were observed, most of them resulting from alternative end‐joining (alt‐EJ)‐driven repair. We further demonstrate that, in the presence of a donor DNA sharing sequence homology with the PpAPT gene, most transgene integration events occur by homology‐driven repair (HDR) at the target locus but also that Cas9‐induced double‐strand breaks are repaired with almost equal frequencies by mutagenic illegitimate recombination. Finally, we establish that a significant fraction of HDR‐mediated gene targeting events (30%) is still possible in the absence of PpRAD51 protein, indicating that CRISPR‐induced HDR is only partially mediated by the classical homologous recombination pathway.     

CRISPR/Cas基因编辑技术及其在作物育种中的应用

CRISPR/Cas基因编辑技术在植物基因功能研究和作物遗传改良方面具有重要应用价值,其主要依赖gRNA引导核酸内切酶在目标基因组位置产生双链断裂（DSBs）,DSBs在通过非同源末端连接（NHEJ）或同源重组（HDR）方式进行修复时,会引起靶标位置核苷酸序列的缺失、插入或者替换,从而实现基因编辑。介绍了CRISPR/Cas基因编辑技术的作用机理及发展趋势,并对CRISPR/Cas技术在主要粮食及经济作物育种中的应用进展进行了总结,以期为农作物育种提供有益的参考。     

In vivo cleavage of transgene donors promotes nuclease‐mediated targeted integration

Targeted DNA integration is commonly used to eliminate position effects on transgene expression. Integration can be targeted to specific sites in the genome via both homology‐based and homology‐independent processes. Both pathways start the integration process with a site‐specific break in the chromosome, typically from a zinc‐finger nuclease (ZFN). We previously described an efficient homology‐independent targeted integration technique that captures short (<100 bp) pieces of DNA at chromosomal breaks created by ZFNs. We show here that inclusion of a nuclease target site on the donor plasmid followed by in vivo nuclease cleavage of both the donor and the chromosome results in efficient integration of large, transgene‐sized DNA molecules into the chromosomal double‐strand break. Successful targeted integration via in vivo donor linearization is demonstrated at five distinct loci in two mammalian cell types, highlighting the generality of the approach. Finally, we show that CHO cells, a cell type recalcitrant to homology‐based integration, are proficient at capture of in vivo‐linearized transgene donors. Moreover, we demonstrate knockout of the hamster FUT8 gene via the simultaneous ZFN‐ or TALE nuclease‐mediated integration of an antibody cassette. Our results enable efficient targeted transgene addition to cells and organisms that fare poorly with traditional homology‐driven approaches. Biotechnol. Bioeng. 2013; 110: 871–880. © 2012 Wiley Periodicals, Inc.     

Precision genome editing in plants via gene targeting and piggyBac‐mediated marker excision

Precise genome engineering via homologous recombination (HR)‐mediated gene targeting (GT) has become an essential tool in molecular breeding as well as in basic plant science. As HR‐mediated GT is an extremely rare event, positive–negative selection has been used extensively in flowering plants to isolate cells in which GT has occurred. In order to utilize GT as a methodology for precision mutagenesis, the positive selectable marker gene should be completely eliminated from the GT locus. Here, we introduce targeted point mutations conferring resistance to herbicide into the rice acetolactate synthase (ALS) gene via GT with subsequent marker excision by piggyBac transposition. Almost all regenerated plants expressing piggyBac transposase contained exclusively targeted point mutations without concomitant re‐integration of the transposon, resulting in these progeny showing a herbicide bispyribac sodium (BS)‐tolerant phenotype. This approach was also applied successfully to the editing of a microRNA targeting site in the rice cleistogamy 1 gene. Therefore, our approach provides a general strategy for the targeted modification of endogenous genes in plants.     

Efficient and error-free fluorescent gene tagging in human organoids without double-strand DNA cleavage

CRISPR-associated nucleases are powerful tools for precise genome editing of model systems, including human organoids. Current methods describing fluorescent gene tagging in organoids rely on the generation of DNA double-strand breaks (DSBs) to stimulate homology-directed repair (HDR) or non-homologous end joining (NHEJ)-mediated integration of the desired knock-in. A major downside associated with DSB-mediated genome editing is the required clonal selection and expansion of candidate organoids to verify the genomic integrity of the targeted locus and to confirm the absence of off-target indels. By contrast, concurrent nicking of the genomic locus and targeting vector, known as in-trans paired nicking (ITPN), stimulates efficient HDR-mediated genome editing to generate large knock-ins without introducing DSBs. Here, we show that ITPN allows for fast, highly efficient, and indel-free fluorescent gene tagging in human normal and cancer organoids. Highlighting the ease and efficiency of ITPN, we generate triple fluorescent knock-in organoids where 3 genomic loci were simultaneously modified in a single round of targeting. In addition, we generated model systems with allele-specific readouts by differentially modifying maternal and paternal alleles in one step. ITPN using our palette of targeting vectors, publicly available from Addgene, is ideally suited for generating error-free heterozygous knock-ins in human organoids.

A major downside of double-strand break-mediated genome editing is the need to verify the genomic integrity of the targeted locus and confirm the absence of off-target indels. This study shows that in-trans paired nicking is a mutation-free CRISPR strategy to introduce precise knock-ins into human organoids; its genomic fidelity allows all knock-in cells to be pooled, accelerating the establishment of new organoid models.     

动物基因组定点整合转基因技术研究进展

传统转基因技术,如显微注射、转座子、慢病毒转染等将目的基因插入基因组内的整合方式是随机的,这些随机整合对后期转基因动物品系组建和育种带来诸多不利,因此有研究人员提出了定点整合转基因技术。目前该技术的定点整合效率非常低,主要取决于两个方面：一是靶位点产生DNA双链断裂(double-strand break, DSB)的效率;二是断裂后的靶位点与携带同源臂及外源基因的供体质粒发生同源重组的效率,其中同源重组修复(homologous recombination repair, HDR)是基因组定点整合最为依赖的修复机制。靶位点产生DSB后,机体的DNA修复既可能发生HDR,也可能发生非同源末端连接(nonhomologous end joining, NHEJ),并且两者之间存在竞争关系,因此激活HDR或抑制NEHJ都可提高定点整合转基因的效率。本文结合影响定点整合的因素,对提高定点整合效率最新探索方面进行了综述。     

ZFN‐mediated gene targeting of the Arabidopsis protoporphyrinogen oxidase gene through Agrobacterium‐mediated floral dip transformation

Previously, we showed that ZFN‐mediated induction of double‐strand breaks (DSBs) at the intended recombination site enhanced the frequency of gene targeting (GT) at an artificial target locus using Agrobacterium‐mediated floral dip transformation. Here, we designed zinc finger nucleases (ZFNs) for induction of DSBs in the natural protoporphyrinogen oxidase (PPO) gene, which can be conveniently utilized for GT experiments. Wild‐type Arabidopsis plants and plants expressing the ZFNs were transformed via floral dip transformation with a repair T‐DNA with an incomplete PPO gene, missing the 5′ coding region but containing two mutations rendering the enzyme insensitive to the herbicide butafenacil as well as an extra KpnI site for molecular analysis of GT events. Selection on butafenacil yielded 2 GT events for the wild type with a frequency of 0.8 × 10^?3 per transformation event and 8 GT events for the ZFNs expressing plant line with a frequency of 3.1 × 10^?3 per transformation event. Molecular analysis using PCR and Southern blot analysis showed that 9 of the GT events were so‐called true GT events, repaired via homologous recombination (HR) at the 5′ and the 3′ end of the gene. One plant line contained a PPO gene repaired only at the 5′ end via HR. Most plant lines contained extra randomly integrated T‐DNA copies. Two plant lines did not contain extra T‐DNAs, and the repaired PPO genes in these lines were transmitted to the next generation in a Mendelian fashion.     

Zinc-finger nuclease-driven targeted integration into mammalian genomes using donors with limited chromosomal homology

We previously demonstrated high-frequency, targeted DNA addition mediated by the homology-directed DNA repair pathway. This method uses a zinc-finger nuclease (ZFN) to create a site-specific double-strand break (DSB) that facilitates copying of genetic information into the chromosome from an exogenous donor molecule. Such donors typically contain two ∼750 bp regions of chromosomal sequence required for homology-directed DNA repair. Here, we demonstrate that easily-generated linear donors with extremely short (50 bp) homology regions drive transgene integration into 5–10% of chromosomes. Moreover, we measure the overhangs produced by ZFN cleavage and find that oligonucleotide donors with single-stranded 5′ overhangs complementary to those made by ZFNs are efficiently ligated in vivo to the DSB. Greater than 10% of all chromosomes directly incorporate this exogenous DNA via a process that is dependent upon and guided by complementary 5′ overhangs on the donor DNA. Finally, we extend this non-homologous end-joining (NHEJ)-based technique by directly inserting donor DNA comprising recombinase sites into large deletions created by the simultaneous action of two separate ZFN pairs. Up to 50% of deletions contained a donor insertion. Targeted DNA addition via NHEJ complements our homology-directed targeted integration approaches, adding versatility to the manipulation of mammalian genomes.     

Dynamics and competition of CRISPR–Cas9 ribonucleoproteins and AAV donor-mediated NHEJ,MMEJ and HDR editing

Investigations of CRISPR gene knockout editing profiles have contributed to enhanced precision of editing outcomes. However, for homology-directed repair (HDR) in particular, the editing dynamics and patterns in clinically relevant cells, such as human iPSCs and primary T cells, are poorly understood. Here, we explore the editing dynamics and DNA repair profiles after the delivery of Cas9-guide RNA ribonucleoprotein (RNP) with or without the adeno-associated virus serotype 6 (AAV6) as HDR donors in four cell types. We show that editing profiles have distinct differences among cell lines. We also reveal the kinetics of HDR mediated by the AAV6 donor template. Quantification of T₅₀ (time to reach half of the maximum editing frequency) indicates that short indels (especially +A/T) occur faster than longer (>2 bp) deletions, while the kinetics of HDR falls between NHEJ (non-homologous end-joining) and MMEJ (microhomology-mediated end-joining). As such, AAV6-mediated HDR effectively outcompetes the longer MMEJ-mediated deletions but not NHEJ-mediated indels. Notably, a combination of small molecular compounds M3814 and Trichostatin A (TSA), which potently inhibits predominant NHEJ repairs, leads to a 3-fold increase in HDR efficiency.     

Simple embryo injection of long single‐stranded donor templates with the CRISPR/Cas9 system leads to homology‐directed repair in Xenopus tropicalis and Xenopus laevis

We report model experiments in which simple microinjection of fertilized eggs has been used to effectively perform homology‐directed repair (HDR)‐mediated gene editing in the two Xenopus species used most frequently for research: X. tropicalis and X. laevis. We have used long single‐stranded DNAs having phosphorothioate modifications as donor templates for HDR at targeted genomic sites using the Clustered Regularly Interspaced Short Palindromic Repeats/CRISPR‐associated protein 9 (CRISPR/Cas9) system. First, X. tropicalis tyr mutant (i.e., albino) embryos were successfully rescued: partially pigmented tadpoles were seen in up to 35% of injected embryos, demonstrating the potential for efficient insertion of targeted point mutations. Second, in order to demonstrate the ability to tag genes with fluorescent proteins (FPs), we targeted the melanocyte‐specific gene slc45a2.L of X. laevis to label it with the Superfolder green FP (sfGFP), seeing mosaic expression of sfGFP in melanophores in up to 20% of injected tadpoles. Tadpoles generated by these two approaches were raised to sexual maturity, and shown to successfully transmit HDR constructs through the germline with precise targeting and seamless recombination. F1 embryos showed rescue of the tyr mutation (X. tropicalis) and tagging in the appropriate pigment cell‐specific manner of slc45a2.L with sfGFP (X. laevis).     

Can Designer Indels Be Tailored by Gene Editing?

Genome editing with engineered nucleases (GEENs) introduce site‐specific DNA double‐strand breaks (DSBs) and repairs DSBs via nonhomologous end‐joining (NHEJ) pathways that eventually create indels (insertions/deletions) in a genome. Whether the features of indels resulting from gene editing could be customized is asked. A review of the literature reveals how gene editing technologies via NHEJ pathways impact gene editing. The survey consolidates a body of literature that suggests that the type (insertion, deletion, and complex) and the approximate length of indel edits can be somewhat customized with different GEENs and by manipulating the expression of key NHEJ genes. Structural data suggest that binding of GEENs to DNA may interfere with binding of key components of DNA repair complexes, favoring either classical‐ or alternative‐NHEJ. The hypotheses have some limitations, but if validated, will enable scientists to better control indel makeup, holding promise for basic science and clinical applications of gene editing. Also see the video abstract here https://youtu.be/vTkJtUsLi3w