Zinc-finger Nucleases Expression Research Articles

Mutagenic repair of a ZFN-induced double-strand break in yeast: Effects of cleavage site sequence and spacer size

Double-strand breaks are repaired by error-free homologous recombination or by relatively error-prone pathways that directly join broken ends. Both types of repair have been extensively studied in Saccharomyces cerevisiae using enzymes HO or I-SceI, which create breaks with 4-nt 3′ overhangs. In the current study, a galactose-regulated zinc-finger nuclease (ZFN) designed to cleave the Drosophila rosy locus was used to generate breaks with 4-nt 5′ overhangs at out-of-frame cleavage sites inserted into the yeast LYS2 gene. Mutagenic repair was examined following selection of prototrophs on lysine-deficient medium containing galactose or surviving colonies on galactose-containing rich medium. Following cleavage of the original rosy spacer (ACGAAT), most Lys+ colonies contained 1- or 4-bp insertions at the cleavage site while most survivors had either a 2-bp insertion or a large deletion. Small insertions reflected nonhomologous end joining (NHEJ) and large deletions were the product of microhomology-mediated end joining (MMEJ). Changing the original ACGAAT spacer to either AGCAAT, ACGCGT or CTATTA altered the molecular features of NHEJ events as well as their frequency relative to MMEJ. Altering the optimal 6-bp spacer size between the zinc-finger protein binding sites to 5 bp or 7 bp eliminated the effect of continuous ZFN expression on survival, but Lys+ prototrophs were still generated. Analysis of Lys+ revertants after cleavage of the 5-bp spacer indicated that both the position and spacing of ZFN-generated nicks were variable. Results provide insight into effects of overhang sequence on mutagenic outcomes and demonstrate ZFN cleavage of 5- or 7-bp spacers in vivo.

Zinc-Finger Nucleases Induced by HIV-1 Tat Excise HIV-1 from the Host Genome in Infected and Latently Infected Cells

Highly active anti-retroviral therapy (HAART) cannot clear infected cells harboring HIV-1 proviral DNA from HIV-1-infected patients. We previously demonstrated that zinc-finger nucleases (ZFNs) can specifically and efficiently excise HIV-1 proviral DNA from latently infected human T cells by targeting long terminal repeats (LTRs), a novel and alternative antiretroviral strategy for eradicating HIV-1 infection. To prevent unwanted off-target effects from constantly expressed ZFNs, in this study, we engineered the expression of ZFNs under the control of HIV-1 LTR, by which ZFN expression can be activated by the HIV-1 (Trans-Activator of Transcription) Tat protein. Our results show that functional expression of ZFNs induced by Tat excise the integrated proviral DNA of HIV-NL4-3-eGFP in approximately 30% of the population of HIV-1-infected cells. The results from HIV-1-infected human primary T cells and latently infected T cells treated with the inducible ZFNs further validated that proviral DNA can be excised. Taken together, positively regulated expression of ZFNs in the presence of HIV-1 Tat may provide a safer and novel implementation of genome-editing technology for eradicating HIV-1 proviral DNA from infected host cells.

An Improved Genome Engineering Method Using Surrogate Reporter-Coupled Suicidal ZFNs.

Using engineered nucleases such as zinc-finger nucleases (ZFNs) and TALE nuclease (TALEN) to accomplish genome editing often causes high cellular toxicity because of the consistent expression of artificial nucleases and off-targeting effect. And lacking selection marker in modified cells makes it hard to enrich these positive cells. Here we introduce a method by incorporating a surrogate reporter enrichment into a suicidal ZFN system, which is designed by a pair of ZFN expression cassettes flanked with its target sites. Our data demonstrated that this modified system achieved almost the same ZFN activity as the original method but reduced ~40% toxicity. This new suicidal ZFN expression system coupled with a surrogate reporter not only enables decreased cellular toxicity but also makes the genetic modified cells to be enriched by EGFP analysis.

Targeted introduction and effective expression of hFIX at the AAVS1 locus in mesenchymal stem cells.

Hemophilia B occurs due to a deficiency in human blood coagulation factor IX (hFIX). Currently, no effective treatment for hemophilia B has been identified, and gene therapy has been considered the most appropriate treatment. Mesenchymal stem cells (MSCs) have homing abilities and low immunogenicity, and therefore they may be potential cell carriers for targeted drug delivery to lesional tissues. The present study constructed an adeno-associated virus integration site 1 (AAVS1)-targeted vector termed AAVS1-green fluorescent protein (GFP)-hFIX and a zinc finger nuclease (ZFN) expression vector. Nucleofection was used to co-transfect the targeting vector and the ZFN expression vector into human MSCs. The GFP-positive cells were selected using flow cytometry. Site-specific integration clones were obtained following the monoclonal culture, subsequent detections were performed using polymerase chain reaction and Southern blotting. Following the confirmation of stem cell traits of the site-specific integration MSCs, the in vivo and in vitro expression levels of hFIX were detected. The results demonstrated that the hFIX gene was successfully transfected into the AAVS1 locus in human MSCs. The clones with the site-specific integration retained stem cell traits of the MSCs. In addition, hFIX was effectively expressed in vivo and in vitro. No significant differences in expression levels were identified among the individual clones. In conclusion, the present study demonstrated that the exogenous gene hFIX was effectively expressed following site-specific targeting into the AAVS1 locus in MSCs; therefore, MSCs may be used as potential cell carriers for gene therapy of hemophilia B.

Low frequency of zinc-finger nuclease-induced mutagenesis in Populus

Gene flow from recombinant-DNA-modified (GMO) trees is a major barrier to their public acceptance and regulatory approval. Because many intensively grown trees are vegetatively propagated, complete sexual sterility could be a powerful means to mitigate or prevent gene flow. We tested four pairs of zinc-finger nucleases (ZFNs) as mutagenic agents against the LEAFY and AGAMOUS orthologs in poplar that are expected to be required for sexual fertility. To reduce the potential for pleiotropic effects from mutagenesis, each of the pairs was functionally linked to a heat shock promoter to provide inducible ZFN expression. Using Agrobacterium tumefaciens, we transformed more than 21,000 total explants compromised of both male and female hybrid poplar. The rate of transformation for the ZFN constructs (2 %) was generally reduced compared to the transgenic control (8 %). We produced 391 ZFN transgenic shoots of which only two developed into plants with mutations in a target gene; both were 7-bp deletions in one allele of the PtAG2 locus. No mutations were observed in the PtAG1 or PtLFY loci. Our results indicate a mutation rate of zero to 0.3 % per explant per allele, among the lowest reported for ZFN mutagenesis in plants. The combined effects of low recovery of transgenic plants, a modest mutation frequency, and much higher reported rates of directed mutation for other gene editing methods suggest that the efficient use of ZFNs in poplar requires further technical improvements.

123. Helper-Dependent Ad5/35 Vectors for ZFN Mediated Gene Editing in Hematopoietic Stem Cells

A homozygous [Delta]32 deletion in the CCR5 gene, found in about 1% of Caucasians, confers a natural resistance to HIV-1. In a recent pivotal study it was shown that transplantation of hematopoietic stem/progenitor cells (HSCs) from a donor who was homozygous for CCR5 [Delta]32 in a patient with acute myeloid leukemia and HIV-1 infection resulted in long-term control of HIV. This finding supports the development of gene therapy approaches to eliminate CCR5 in HIV target cells, including approaches based on CCR5-knockout by zinc finger nucleases (ZFNs). Recent trials involved the ex vivo transduction of patient CD4+ T-cells with a CCR5-ZFN expressing adenovirus Ad5/35 vectors. More recent attempts have focused on CCR5 gene knock-out in hematopoietic stem cells (HSCs). Because HSCs are the source for all blood cell lineages, CCR5 knock-out would protect not only CD4 cells but also all remaining lymphoid and myeloid cell types that are potential targets for HIV infection. We generated a helper-dependent, capsid-modified HD-Ad5/35 vector for CCR5-ZFN expression in HSCs from mobilized adult donors. The production of these vectors required that ZFN expression in HD-Ad5/35 producer 293-Cre cells was suppressed. To do this, we developed a miRNA-based system for regulation of gene expression based on miRNA expression profiling of 293-Cre and CD34+ cells.We demonstrated that, after in vitro CD34+ cell transduction, the HD-Ad5/35.ZFNmiR vector conferred ccr5 knock-out in primitive HSC (i.e. long-term culture initiating cells and NOD/SCID repopulating cells). Upon transplantation of in vitro transduced CD34+ cells into irradiated NOG mice, the ccr5 gene disruption frequency achieved in engrafted HSCs found in the bone marrow was about 12%. However, we also found in transplantation studies that the HD-Ad5/35.ZFNmiR vector decreased CD34+ engraftment rates 7-10-fold compared to HD-Ad5/35-GFP (control) transduced cells. A possible interpretation of these data is that sustained high-level ZFN expression afforded by the HD-Ad5/35 vector platform might be detrimental to the HSC, particularly if the cells do not actively divide allowing the extended persistence of HD-Ad5/35 vector genome. This deficit has not been observed with previous first generation recombinant adenoviral vector delivery of ZFNs to CD34+ HSCs (Li et al. Mol Ther 2013), thus the source of the engraftment inhibition is unclear. However, we plan to investigate and develop methods for maximal ccr5 knock-out efficiency in HCSs for future HIV challenge experiments.

Efficient genome editing in hematopoietic stem cells with helper-dependent Ad5/35 vectors expressing site-specific endonucleases under microRNA regulation

Genome editing with site-specific endonucleases has implications for basic biomedical research as well as for gene therapy. We generated helper-dependent, capsid-modified adenovirus (HD-Ad5/35) vectors for zinc-finger nuclease (ZFN)– or transcription activator-like effector nuclease (TALEN)–mediated genome editing in human CD34+ hematopoietic stem cells (HSCs) from mobilized adult donors. The production of these vectors required that ZFN and TALEN expression in HD-Ad5/35 producer 293-Cre cells was suppressed. To do this, we developed a microRNA (miRNA)-based system for regulation of gene expression based on miRNA expression profiling of 293-Cre and CD34+ cells. Using miR-183-5p and miR-218-5p based regulation of transgene gene expression, we first produced an HD-Ad5/35 vector expressing a ZFN specific to the HIV coreceptor gene ccr5. We demonstrated that HD-Ad5/35.ZFNmiR vector conferred ccr5 knock out in primitive HSC (i.e., long-term culture initiating cells and NOD/SCID repopulating cells). The ccr5 gene disruption frequency achieved in engrafted HSCs found in the bone marrow of transplanted mice is clinically relevant for HIV therapy considering that these cells can give rise to multiple lineages, including all the lineages that represent targets and reservoirs for HIV. We produced a second HD-Ad5/35 vector expressing a TALEN targeting the DNase hypersensitivity region 2 (HS2) within the globin locus control region. This vector has potential for targeted gene correction in hemoglobinopathies. The miRNA regulated HD-Ad5/35 vector platform for expression of site-specific endonucleases has numerous advantages over currently used vectors as a tool for genome engineering of HSCs for therapeutic purposes.

A suicidal zinc finger nuclease expression coupled with a surrogate reporter for efficient genome engineering.

Genome editing with engineered nucleases, such as zinc-finger nucleases (ZFNs) and TALE nucleases, remains confronted with a high risk of cellular toxicity induced by off-targeting. Here we describe the construction of a suicidal nuclease expression vector in which a pair of ZFNs genes were flanked of its target sites. To further enrich the targeted cells, the suicidal ZFN expression cassette was also inserted within an eGFP reporter, to disrupt the ORF of eGFP gene. ZFN-associated toxicity was reduced by ~40 % with this new system, and the activities of ZFNs were ~4.5 % lower. We conclude that using this new suicidal ZFN expression and surrogate reporter system represents an improvement for genomic editing by reducing toxicity and allowing easy detection of edited cells by eGFP analysis.

Codon swapping of zinc finger nucleases confers expression in primary cells and in vivo from a single lentiviral vector.

Zinc finger nucleases (ZFNs) are promising tools for genome editing for biotechnological as well as therapeutic purposes. Delivery remains a major issue impeding targeted genome modification. Lentiviral vectors are highly efficient for delivering transgenes into cell lines, primary cells and into organs, such as the liver. However, the reverse transcription of lentiviral vectors leads to recombination of homologous sequences, as found between and within ZFN monomers. We used a codon swapping strategy to both drastically disrupt sequence identity between ZFN monomers and to reduce sequence repeats within a monomer sequence. We constructed lentiviral vectors encoding codon-swapped ZFNs or unmodified ZFNs from a single mRNA transcript. Cell lines, primary hepatocytes and newborn rats were used to evaluate the efficacy of integrative-competent (ICLV) and integrative-deficient (IDLV) lentiviral vectors to deliver ZFNs into target cells. We reduced total identity between ZFN monomers from 90.9% to 61.4% and showed that a single ICLV allowed efficient expression of functional ZFNs targeting the rat UGT1A1 gene after codon-swapping, leading to much higher ZFN activity in cell lines (up to 7-fold increase compared to unmodified ZFNs and 60% activity in C6 cells), as compared to plasmid transfection or a single ICLV encoding unmodified ZFN monomers. Off-target analysis located several active sites for the 5-finger UGT1A1-ZFNs. Furthermore, we reported for the first time successful ZFN-induced targeted DNA double-strand breaks in primary cells (hepatocytes) and in vivo (liver) after delivery of a single IDLV encoding two ZFNs. These results demonstrate that a codon-swapping approach allowed a single lentiviral vector to efficiently express ZFNs and should stimulate the use of this viral platform for ZFN-mediated genome editing of primary cells, for both ex vivo or in vivo applications.

Targeted genome correction by a single adenoviral vector simultaneously carrying an inducible zinc finger nuclease and a donor template

Zinc finger nuclease (ZFN) technology, which can be used to induce targeted genome correction in the presence of a DNA donor template, is becoming an attractive strategy for treating monogenic diseases. This strategy requires efficient delivery of ZFN and donor template into cells, ideally, in a single viral vector to achieve efficient genome editing and to avoid unwanted mutagenesis. In this study, we successfully produced a single adenoviral (Ad) vector with high titer that carried a ZFN expression cassette and a donor template simultaneously. We then demonstrated that this single Ad system could mediate efficient site-specific genome correction in vitro and ex vivo. The gene correction efficiency of the single Ad was significantly higher than that of the double Ad system. This novel vector will be a promising ZFN and donor delivery system for treatment of monogenic diseases.

Dissecting the Mechanism of Histone Deacetylase Inhibitors to Enhance the Activity of Zinc Finger Nucleases Delivered by Integrase-Defective Lentiviral Vectors

Integrase-defective lentiviral vectors (IDLVs) have been of limited success in the delivery of zinc finger nucleases (ZFNs) to human cells, due to low expression. A reason for reduced gene expression has been proposed to involve the epigenetic silencing of vector genomes, carried out primarily by histone deacetylases (HDACs). In this study, we tested valproic acid (VPA), a known HDAC inhibitor (HDACi), for its ability to increase transgene expression from IDLVs, especially in the context of ZFN delivery. Using ZFNs targeting the human adenosine deaminase (ADA) gene in K562 cells, we demonstrated that treatment with VPA enhanced ZFN expression by up to 3-fold, resulting in improved allelic disruption at the ADA locus. Furthermore, three other U.S. Food and Drug Administration-approved HDACis (vorinostat, givinostat, and trichostatin-A) exhibited a similar effect on the activity of ZFN-IDLVs in K562 cells. In primary human CD34(+) cells, VPA- and vorinostat-treated cells showed higher levels of expression of both green fluorescent protein (GFP) as well as ZFNs from IDLVs. A major mechanism for the effects of HDAC inhibitors on improving expression was from their modulation of the cell cycle, and the influence of heterochromatinization was determined to be a lesser contributing factor.

CCR5 Gene Editing of Resting CD4(+) T Cells by Transient ZFN Expression From HIV Envelope Pseudotyped Nonintegrating Lentivirus Confers HIV-1 Resistance in Humanized Mice.

CCR5 disruption by zinc finger nucleases (ZFNs) is a promising method for HIV-1 gene therapy. However, successful clinical translation of this strategy necessitates the development of a safe and effective method for delivery into relevant cells. We used non-integrating lentivirus (NILV) for transient expression of ZFNs and pseudotyped the virus with HIV-envelope for targeted delivery to CD4+ T cells. Both activated and resting primary CD4+ T cells transduced with CCR5-ZFNs NILV showed resistance to HIV-1 infection in vitro. Furthermore, NILV transduced resting CD4+ T cells from HIV-1 seronegative individuals were resistant to HIV-1 challenge when reconstituted into NOD-scid IL2rγc null (NSG) mice. Likewise, endogenous virus replication was suppressed in NSG mice reconstituted with CCR5-ZFN–transduced resting CD4+ T cells from treatment naïve as well as ART-treated HIV-1 seropositive patients. Taken together, NILV pseudotyped with HIV envelope provides a simple and clinically viable strategy for HIV-1 gene therapy.

Histone Deacetylase Inhibition Rescues Gene Knockout Levels Achieved with Integrase-Defective Lentiviral Vectors Encoding Zinc-Finger Nucleases

Zinc-finger nucleases (ZFNs) work as dimers to induce double-stranded DNA breaks (DSBs) at predefined chromosomal positions. In doing so, they constitute powerful triggers to edit and to interrogate the function of genomic sequences in higher eukaryotes. A preferred route to introduce ZFNs into somatic cells relies on their cotransduction with two integrase-defective lentiviral vectors (IDLVs) each encoding a monomer of a functional heterodimeric pair. The episomal nature of IDLVs diminishes the risk of genotoxicity and ensures the strict transient expression profile necessary to minimize deleterious effects associated with long-term ZFN activity. However, by deploying IDLVs and conventional lentiviral vectors encoding HPRT1- or eGFP-specific ZFNs, we report that DSB formation at target alleles is limited after IDLV-mediated ZFN transfer. This IDLV-specific underperformance stems, to a great extent, from the activity of chromatin-remodeling histone deacetylases (HDACs). Importantly, the prototypic and U.S. Food and Drug Administration-approved inhibitors of metal-dependent HDACs, trichostatin A and vorinostat, respectively, did not hinder illegitimate recombination-mediated repair of targeted chromosomal DSBs. This allowed rescuing IDLV-mediated site-directed mutagenesis to levels approaching those achieved by using their isogenic chromosomally integrating counterparts. Hence, HDAC inhibition constitutes an efficacious expedient to incorporate in genome-editing strategies based on transient IDLV-mediated ZFN expression. Finally, we compared two of the most commonly used readout systems to measure targeted gene knockout activities based on restriction and mismatch-sensitive endonucleases. These experiments indicate that these enzymatic assays display a similar performance.

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.

Nonhomologous end joining-mediated gene replacement in plant cells.

Stimulation of the homologous recombination DNA-repair pathway via the induction of genomic double-strand breaks (DSBs) by zinc finger nucleases (ZFNs) has been deployed for gene replacement in plant cells. Nonhomologous end joining (NHEJ)-mediated repair of DSBs, on the other hand, has been utilized for the induction of site-specific mutagenesis in plants. Since NHEJ is the dominant DSB repair pathway and can also lead to the capture of foreign DNA molecules, we suggest that it can also be deployed for gene replacement. An acceptor DNA molecule in which a green fluorescent protein (GFP) coding sequence (gfp) was flanked by ZFN recognition sequences was used to produce transgenic target plants. A donor DNA molecule in which a promoterless hygromycin B phosphotransferase-encoding gene (hpt) was flanked by ZFN recognition sequences was constructed. The donor DNA molecule and ZFN expression cassette were delivered into target plants. ZFN-mediated site-specific mutagenesis and complete removal of the GFP coding sequence resulted in the recovery of hygromycin-resistant plants that no longer expressed GFP and in which the hpt gene was unlinked to the acceptor DNA. More importantly, ZFN-mediated digestion of both donor and acceptor DNA molecules resulted in NHEJ-mediated replacement of the gfp with hpt and recovery of hygromycin-resistant plants that no longer expressed GFP and in which the hpt gene was physically linked to the acceptor DNA. Sequence and phenotypical analyses, and transmission of the replacement events to the next generation, confirmed the stability of the NHEJ-induced gene exchange, suggesting its use as a novel method for transgene replacement and gene stacking 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.

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.1 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.2 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.

Selection-independent generation of gene knockout mouse embryonic stem cells using zinc-finger nucleases.

Gene knockout in murine embryonic stem cells (ESCs) has been an invaluable tool to study gene function in vitro or to generate animal models with altered phenotypes. Gene targeting using standard techniques, however, is rather inefficient and typically does not exceed frequencies of 10−6. In consequence, the usage of complex positive/negative selection strategies to isolate targeted clones has been necessary. Here, we present a rapid single-step approach to generate a gene knockout in mouse ESCs using engineered zinc-finger nucleases (ZFNs). Upon transient expression of ZFNs, the target gene is cleaved by the designer nucleases and then repaired by non-homologous end-joining, an error-prone DNA repair process that introduces insertions/deletions at the break site and therefore leads to functional null mutations. To explore and quantify the potential of ZFNs to generate a gene knockout in pluripotent stem cells, we generated a mouse ESC line containing an X-chromosomally integrated EGFP marker gene. Applying optimized conditions, the EGFP locus was disrupted in up to 8% of ESCs after transfection of the ZFN expression vectors, thus obviating the need of selection markers to identify targeted cells, which may impede or complicate downstream applications. Both activity and ZFN-associated cytotoxicity was dependent on vector dose and the architecture of the nuclease domain. Importantly, teratoma formation assays of selected ESC clones confirmed that ZFN-treated ESCs maintained pluripotency. In conclusion, the described ZFN-based approach represents a fast strategy for generating gene knockouts in ESCs in a selection-independent fashion that should be easily transferrable to other pluripotent stem cells.

Assembly and in vitro Functional Analysis of Zinc Finger Nuclease Specific to the 3′ Untranslated Region of Chicken Ovalbumin Gene

Synthetic zinc finger nucleases (ZFNs) are useful for the improvement of site directed integration of foreign gene into vertebrate chromosomes. To facilitate site-directed integration of foreign genes into the 3′-untranslated region of the chicken ovalbumin gene, we have constructed ZFN expression vectors using Zinc Finger Consortium Vector Kits and tested the functionality of these ZFN constructs. Coding sequences for 6 zinc fingers were assembled following the modular assembly method. The zinc finger assembly was fused to two FokI catalytic domains. Various configurations of linker regions between domains were tested for their influence on enzymatic activity, using plasmid substrate containing the target sequence. Results indicated that ZFN with an elongated linker between two nuclease domains had a high catalytic activity.

Targeted gene disruption in somatic zebrafish cells using engineered TALENs

Targeted gene disruption in somatic zebrafish cells using engineered TALENs