Evaluation of OPEN Zinc Finger Nucleases for Direct Gene Targeting of the ROSA26 Locus in Mouse Embryos

Zinc finger nucleases (ZFNs) enable precise genome modification in a variety of organisms and cell types. Commercial ZFNs were reported to enhance gene targeting directly in mouse zygotes, whereas similar approaches using publicly available resources have not yet been described. Here we report precise targeted mutagenesis of the mouse genome using Oligomerized Pool Engineering (OPEN) ZFNs. OPEN ZFN can be constructed using publicly available resources and therefore provide an attractive alternative for academic researchers. Two ZFN pairs specific to the mouse genomic locus gt(ROSA26)Sor were generated by OPEN selections and used for gene disruption and homology-mediated gene replacement in single cell mouse embryos. One specific ZFN pair facilitated non-homologous end joining (NHEJ)-mediated gene disruption when expressed in mouse zygotes. We also observed a single homologous recombination (HR)-driven gene replacement event when this ZFN pair was co-injected with a targeting vector. Our experiments demonstrate the feasibility of achieving both gene ablation through NHEJ and gene replacement by HR by using the OPEN ZFN technology directly in mouse zygotes.     

锌指核酸酶技术的应用

锌指核酸酶(zinc finger nuclease,ZFN)技术是近年来发展起来的一种对基因组DNA实现靶向修饰的新技术。ZFN通过作用于基因组DNA上特异的靶位点产生DNA双链切口(double strand break,DSB),然后经过非同源末端连接(non-homologous end joining,NHEJ)或同源重组(homologous recombination,HR)途径实现对基因组DNA的靶向敲除或者替换。该技术近些年来已经被广泛应用于基因靶向修饰的研究。本文在简要介绍ZFN技术的基础上,重点综述了目前该技术在基因靶向修饰中的应用研究进展,并同时对该技术目前所需解决的一些问题以及未来的研究方向进行了分析。     

Target frequency and integration pattern for insertion and replacement vectors in embryonic stem cells.

Gene targeting has been used to direct mutations into specific chromosomal loci in murine embryonic stem (ES) cells. The altered locus can be studied in vivo with chimeras and, if the mutated cells contribute to the germ line, in their offspring. Although homologous recombination is the basis for the widely used gene targeting techniques, to date, the mechanism of homologous recombination between a vector and the chromosomal target in mammalian cells is essentially unknown. Here we look at the nature of gene targeting in ES cells by comparing an insertion vector with replacement vectors that target hprt. We found that the insertion vector targeted up to ninefold more frequently than a replacement vector with the same length of homologous sequence. We also observed that the majority of clones targeted with replacement vectors did not recombine as predicted. Analysis of the recombinant structures showed that the external heterologous sequences were often incorporated into the target locus. This observation can be explained by either single reciprocal recombination (vector insertion) of a recircularized vector or double reciprocal recombination/gene conversion (gene replacement) of a vector concatemer. Thus, single reciprocal recombination of an insertion vector occurs 92-fold more frequently than double reciprocal recombination of a replacement vector with crossover junctions on both the long and short arms.     

Case studies of ends‐out gene targeting in Drosophila

Ends‐in and ends‐out gene replacement approaches have been successfully used to disrupt Drosophila genes involved in a variety of biological processes. These methods combine double‐strand breaks and homologous recombination to replace a targeted chromosome region with a designed DNA sequence. Unfortunately, these methods require large numbers of single animal crosses, making them both time consuming and labor intensive. Here, we designed a single complete targeting vector for use in a mass crossing ends‐out gene targeting study. Importantly, our gene targeting method included a balancer chromosome to block endogenous homologous chromosome pairing and to promote pairing between the foreign targeting DNA fragment and the targeted chromosome. This technique provided successful and efficient gene replacement, greatly facilitating the gene knockout procedure. genesis 47:305–308, 2009. © 2009 Wiley‐Liss, Inc.     

Replacement-like recombination induced by an integration vector with a murine homology flank at the immunoglobulin heavy-chain locus in mouse and rat hybridoma cells

Vectors for homologous recombination are commonly designed as replacement or integration constructs. We have evaluated integration vectors for the substitution of the immunoglobulin heavy-chain constant region by various human isotypes in mouse and rat hybridomas. It is known that under certain circumstances replacement vectors exhibit a lower target efficiency and can be incorporated by integration events. Conversely, we show here that an integration vector can undergo a replacement event despite having free homologous adjacent DNA ends, which would be expected to initiate integration according to the double-strand break repair model. Moreover, in cases of replacement recombination the 5 crossover is not necessarily located within the homology region, thereby giving rise to a truncated gene product. Whether or not the replacement leads to such deletions is clearly dependent on the isotypes involved in the targeting reaction. The fact that the vector is correctly targeted to the heavy-chain locus, but that the homology region is not always the site of recombination, points to a novel recombination mechanism that may be specific for the immunoglobulin loci and that seems to be predominant even in the presence of the free homologous adjacent ends of an integration vector. Furthermore we demonstrate that homologous recombination at the heavy-chain locus is also possible between sequences from different species. The implications of our findings for the production of chimeric antibodies are discussed.     

Efficient somatic gene targeting in the lymphoid human cell line DG75

Among the different approaches used to define the function of a protein of interest, alteration and/or deletion of its encoding gene is the most direct strategy. Homologous recombination between the chromosomal gene locus and an appropriately designed targeting vector results in an alteration or knockout of the gene of interest. Homologous recombination is easily performed in yeast or in murine embryonic stem cells, but is cumbersome in more differentiated and diploid somatic cell lines. Here we describe an efficient method for targeting both alleles of a complex human gene locus in DG75 cells, a cell line of lymphoid origin. The experimental approach included a conditional knockout strategy with three genotypic markers, which greatly facilitated the generation and phenotypic identification of targeted recombinant cells. The vector was designed such that it could be reused for two consecutive rounds of recombination to target both alleles. The human DG75 cell line appears similar to the chicken DT40 pre B-cell line, which supports efficient homologous recombination. Therefore, the DG75 cell line is a favorable addition to the limited number of cell lines amenable to gene targeting and should prove useful for studying gene function through targeted gene alteration or deletion in human somatic cells.     

Genetic stability of gene-targeted immunoglobulin loci. II. Influence of the cell line and the vector linearization site

The site-specific integration of exogenous gene fragments by homologous recombination provides a convenient method for altering the immunoglobulin loci of B cells and specifically designing antibody molecules. To introduce a human isotype into the heavy chain locus of mouse hybridoma cells we compared the recombination frequencies of vectors that could be linearized either as integration or as replacement constructs in different cell lines. Integration as well as replacement recombination was observed, irrespective of the location of the site at which the vector was cleaved. Integration events involving the human IgG1 vectors were lost at high frequency due to secondary vector excision, so that all stable recombinations were found to be replacement events. Replacement recombination of an integration vector involves an illegitimate crossover at least at the 3′ side and sometimes gives rise to deletion of the C_H1 domain. However, a homologous event at the 3′ side is more efficient than an illegitimate one, so that a homology that is distributed on both sides of the heterologous region promotes targeting at higher frequency than a contiguous sequence of the same total length. The position of the linearization site in the vector markedly influenced the targeting efficiency, but surprisingly, whether a double-strand break in the homology or in the heterology region more efficiently promoted integration was dependent on the cell line. In all cells, however, cleavage of the vector outside the homology region favoured stable replacements with a bias against C_H1-truncated clones. We further show that the frequency of replacements induced by integration vectors is not correlated to the homology length and cannot be increased by irradiation of the cells. Our findings indicate that for targeting the IgH locus other mechanisms might be involved than at other loci. Received: 20 January 1997 / Accepted: 9 June 1997     

Genetic stability of gene-targeted immunoglobulin loci. II. Influence of the cell line and the vector linearization site

The site-specific integration of exogenous gene fragments by homologous recombination provides a convenient method for altering the immunoglobulin loci of B cells and specifically designing antibody molecules. To introduce a human isotype into the heavy chain locus of mouse hybridoma cells we compared the recombination frequencies of vectors that could be linearized either as integration or as replacement constructs in different cell lines. Integration as well as replacement recombination was observed, irrespective of the location of the site at which the vector was cleaved. Integration events involving the human IgG1 vectors were lost at high frequency due to secondary vector excision, so that all stable recombinations were found to be replacement events. Replacement recombination of an integration vector involves an illegitimate crossover at least at the 3′ side and sometimes gives rise to deletion of the C_H1 domain. However, a homologous event at the 3′ side is more efficient than an illegitimate one, so that a homology that is distributed on both sides of the heterologous region promotes targeting at higher frequency than a contiguous sequence of the same total length. The position of the linearization site in the vector markedly influenced the targeting efficiency, but surprisingly, whether a double-strand break in the homology or in the heterology region more efficiently promoted integration was dependent on the cell line. In all cells, however, cleavage of the vector outside the homology region favoured stable replacements with a bias against C_H1-truncated clones. We further show that the frequency of replacements induced by integration vectors is not correlated to the homology length and cannot be increased by irradiation of the cells. Our findings indicate that for targeting the IgH locus other mechanisms might be involved than at other loci.     

Subcloning Plus Insertion (SPI) - A Novel Recombineering Method for the Rapid Construction of Gene Targeting Vectors

Gene targeting refers to the precise modification of a genetic locus using homologous recombination. The generation of novel cell lines and transgenic mouse models using this method necessitates the construction of a ‘targeting’ vector, which contains homologous DNA sequences to the target gene, and has for many years been a limiting step in the process. Vector construction can be performed in vivo in Escherichia coli cells using homologous recombination mediated by phage recombinases using a technique termed recombineering. Recombineering is the preferred technique to subclone the long homology sequences (>4kb) and various targeting elements including selection markers that are required to mediate efficient allelic exchange between a targeting vector and its cognate genomic locus. Typical recombineering protocols follow an iterative scheme of step-wise integration of the targeting elements and require intermediate purification and transformation steps. Here, we present a novel recombineering methodology of vector assembly using a multiplex approach. Plasmid gap repair is performed by the simultaneous capture of genomic sequence from mouse Bacterial Artificial Chromosome libraries and the insertion of dual bacterial and mammalian selection markers. This subcloning plus insertion method is highly efficient and yields a majority of correct recombinants. We present data for the construction of different types of conditional gene knockout, or knock-in, vectors and BAC reporter vectors that have been constructed using this method. SPI vector construction greatly extends the repertoire of the recombineering toolbox and provides a simple, rapid and cost-effective method of constructing these highly complex vectors.     

Generation of a triple‐gene knockout mammalian cell line using engineered zinc‐finger nucleases

Mammalian cells with multi‐gene knockouts could be of considerable utility in research, drug discovery, and cell‐based therapeutics. However, existing methods for targeted gene deletion require sequential rounds of homologous recombination and drug selection to isolate rare desired events—a process sufficiently laborious to limit application to individual loci. Here we present a solution to this problem. Firstly, we report the development of zinc‐finger nucleases (ZFNs) targeted to cleave three independent genes with known null phenotypes. Mammalian cells exposed to each ZFN pair in turn resulted in the generation of cell lines harboring single, double, and triple gene knockouts, that is, the successful disruption of two, four, and six alleles. All three biallelic knockout events were obtained at frequencies of >1% without the use of selection, displayed the expected knockout phenotype(s), and harbored DNA mutations centered at the ZFN binding sites. These data demonstrate the utility of ZFNs in multi‐locus genome engineering. Biotechnol. Bioeng. 2010; 106: 97–105. © 2009 Wiley Periodicals, Inc.     

A targeted gene knockout in Drosophila

We previously described a method for targeted homologous recombination at the yellow gene of Drosophila melanogaster. Because only a single gene was targeted, further work was required to show whether the method could be extended to become generally useful for gene modification in Drosophila. We have now used this method to produce a knockout of the autosomal pugilist gene by homologous recombination between the endogenous locus and a 2.5-kb DNA fragment. This was accomplished solely by tracking the altered genetic linkage of an arbitrary marker gene as the targeting DNA moved from chromosome X or 2 to chromosome 3. The results indicate that this method of homologous recombination is likely to be generally useful for Drosophila gene targeting.     

利用人工锌指蛋白核酸酶进行植物基因定点突变和置换

基因定点突变技术在基因组原位改变基因特定序列,避免常规转基因过程中位置效应和插入失活。定点突变生物体不含转基因或标记基因,降低风险性。高等植物基因定点突变研究初见端倪,将可能为基因原位功能研究、作物遗传改良和分子设计提供有效策略。利用锌指蛋白核酸酶（Zinc Finger Nucleases, ZFN）引入DNA定点断裂（Double-Strand Breaks, DSBs）可以高效介导基因定点突变,使得ZFN在基因定点突变中倍受关注。文章综述了植物基因定点突变的一般策略,重点介绍了锌指蛋白的结构、原理、应用,特别是ZFN介导的植物基因定点突变与置换研究进展,并对ZFN介导的植物基因定点突变与置换应用前景进行了讨论。     

Detection of gene targeting by co-conversion of a single nucleotide change during replacement recombination at the immunoglobulin mu heavy chain locus.

A method is described for detecting targeted events at the mu heavy chain gene which relies on co-conversion (or co-exchange) of a point mutation with a selectable marker contained on a replacement vector. The vector, designed for application to IgM producing hybridomas, contains a single nucleotide change within the region of homology with the target gene which encodes a different allotypic determinant of IgM. In a model system where homologous recombination corrected a defective mu gene, the length of homology between this nucleotide change and the position of the double strand break in the vector was found to have a critical influence on the co-conversion frequency. In the vector design ultimately used for targeting in hybridomas, one in 1000-2000 stable transformants produced IgM with the allotype encoded by the exogenous DNA, and Southern blot analysis confirmed that these were derived by targeted integration. The sensitivity of the screening procedure using a monoclonal antibody specific to this allotype enabled a targeted clone to be detected in a pool of stable transformants when present at a frequency at least as low as one per cent. Several different modifications of the target locus were obtained as a consequence of alternative crossover positions and, in some cases, vector DNA concatenation.     

产生无标记农杆菌突变体方法的建立及优化

农杆菌已经用作许多生物过程研究的模型细菌,为了解析这些生物过程的分子机理,对农杆菌的某些基因进行突变就显得非常重要．以自杀性基因sacB作为反向可选择性标记基因,利用同源重组的原理,建立了一种可对农杆菌基因进行准确插入、删除和位点置换的突变方法,所获突变体不带任何不需要的外源DNA序列．通过详细研究同源序列的长度对农杆菌同源重组效率和突变体产生概率的影响,以及对农杆菌中的同源重组机理的分析,提出了优化该突变体产生方法的方案,即通过设计不等长的上下游同源序列和选择其中一种类型的单交换重组体来筛选二次交换重组体的方法,可以显著地提高理想突变体的产生概率．研究结果对如何提高突变体的产生概率和减少突变体筛选的工作量具重要的参考价值．利用该方法成功地获得了两个基因被同时删除而且不含抗性标记的农杆菌突变株．     

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.     

Insertion of a foreign gene into the β-casein locus by Cre-mediated site-specific recombination

The expression of foreign genes in transgenic animals is generally unpredictable as transgenes are integrated at random after pro-nuclear injection into fertilized oocytes. In many cases, transgene expression is inhibited by neighbouring chromatin structures or by the repeated nature of the multiple transgene copies present at the integration site. A strategy involving homologous and site-specific recombination has been devised by which single copies of a foreign gene can be inserted specifically into the locus of a highly expressed gene. As a first step, a loxP recombination target site is introduced by homologous recombination into a predetermined gene locus such that the loxP sequence is placed next to the promoter region and replaces the translational initiation signal. In a subsequent site-specific recombination reaction, a gene of interest can be integrated into the pre-existing loxP site. This biphasic recombination strategy was used to integrate a luciferase reporter gene into the locus of the murine β-casein gene in embryonic stem cells.     

High-fidelity gene targeting in embryonic stem cells by using sequence replacement vectors.

Mutations were targeted to the Hprt locus in murine embryonic stem cells by using sequence replacement vectors. When the vector was designed such that the mutated sequences were flanked on both sides by several kilobases of DNA homologous to the target locus, replacement of chromosomal sequences with the exogenous DNA occurred with precision. If, on the other hand, the target-homologous DNA on one arm of the vector was reduced to below 1 kb in length, the fidelity of recombination was diminished.     

Parameters determining the efficiency of gene targeting in the moss Physcomitrella patens

In the moss Physcomitrella patens, transforming DNA containing homologous sequences integrates predominantly by homologous recombination with its genomic target. A systematic investigation of the parameters that determine gene targeting efficiency shows a direct relationship between homology length and targeting frequency for replacement vectors (a selectable marker flanked by homologous DNA). Overall homology of only 1 kb is sufficient to achieve a 50% yield of targeted transformants. Targeting may occur through homologous recombination in one arm, accompanied by non-homologous end-joining by the other arm of the vector, or by allele replacement following two homologous recombination events. Allele replacement frequency depends on the symmetry of the targeting vector, being proportional to the length of the shorter arm. Allele replacement may involve insertion of multiple copies of the transforming DNA, accompanied by ectopic insertions at non-homologous sites. Single-copy and single insertions at targeted loci (targeted gene replacements, ‘TGR’) occur with a frequency of 7–20% of all transformants when the minimum requirements for allele replacement are met. Homologous recombination in Physcomitrella is substantially more efficient than in any multicellular eukaryote, recommending it as the outstanding model for the study of homologous recombination in plants.     

Homology dependence of targeted recombination at the Chinese hamster APRT locus.

Using simple linear fragments of the Chinese hamster adenine phosphoribosyltransferase (APRT) gene as targeting vectors, we have investigated the homology dependence of targeted recombination at the endogenous APRT locus in Chinese hamster ovary (CHO) cells. We have examined the effects of varying either the overall length of targeting sequence homology or the length of 5' or 3' flanking homology on both the frequency of targeted homologous recombination and the types of recombination events that are obtained. We find an exponential (logarithmic) relationship between length of APRT targeting homology and the frequency of targeted recombination at the CHO APRT locus, with the frequency of targeted recombination dependent upon both the overall length of targeting homology and the length of homology flanking each side of the target gene deletion. Although most of the APRT+ recombinants analyzed reflect simple targeted replacement or conversion of the target gene deletion, a significant fraction appear to have arisen by target gene-templated extension and correction of the targeting fragment sequences. APRT fragments with limited targeting homology flanking one side of the target gene deletion yield proportionately fewer target gene conversion events and proportionately more templated extension and vector correction events than do fragments with more substantial flanking homology.