Customized Zinc-finger Nucleases Research Articles

Genome editing of BmFib-H gene provides an empty Bombyx mori silk gland for a highly efficient bioreactor.

Evolution has produced some remarkable creatures, of which silk gland is a fascinating organ that exists in a variety of insects and almost half of the 34,000 spider species. The impressive ability to secrete huge amount of pure silk protein, and to store proteins at an extremely high concentration (up to 25%) make the silk gland of Bombyx mori hold great promise to be a cost-effective platform for production of recombinant proteins. However, the extremely low production yields of the numerous reported expression systems greatly hindered the exploration and application of silk gland bioreactors. Using customized zinc finger nucleases (ZFN), we successfully performed genome editing of Bmfib-H gene, which encodes the largest and most abundant silk protein, in B. mori with efficiency higher than any previously reported. The resulted Bmfib-H knocked-out B. mori showed a smaller and empty silk gland, abnormally developed posterior silk gland cells, an extremely thin cocoon that contain only sericin proteins, and a slightly heavier pupae. We also showed that removal of endogenous Bmfib-H protein could significantly increase the expression level of exogenous protein. Furthermore, we demonstrated that the bioreactor is suitable for large scale production of protein-based materials.

Generation of an HIV Resistant T-cell Line by Targeted “Stacking” of Restriction Factors

Restriction factors constitute a newly appreciated line of innate immune defense, blocking viral replication inside of infected cells. In contrast to these antiviral proteins, some cellular proteins, such as the CD4, CCR5, and CXCR4 cell surface receptors, facilitate HIV replication. We have used zinc finger nucleases (ZFNs) to insert a cocktail of anti-HIV restriction factors into the CCR5 locus in a T-cell reporter line, knocking out the CCR5 gene in the process. Mirroring the logic of highly active antiretroviral therapy, this strategy provides multiple parallel blocks to infection, dramatically limiting pathways for viral escape, without relying on random integration of transgenes into the genome. Because of the combination of blocks that this strategy creates, our modified T-cell lines are robustly resistant to both CCR5-tropic (R5-tropic) and CXCR4-tropic (X4-tropic) HIV-1. While zinc finger nuclease-mediated CCR5 disruption alone, which mimics the strategy being used in clinical trials, confers 16-fold protection against R5-tropic HIV, it has no effect against X4-tropic virus. Rhesus TRIM5α, chimeric human-rhesus TRIM5α, APOBEC3G D128K, or Rev M10 alone targeted to CCR5 confers significantly improved resistance to infection by both variants compared with CCR5 disruption alone. The combination of three factors targeted to CCR5 blocks infection at multiple stages, providing virtually complete protection against infection by R5-tropic and X4-tropic HIV.

A CRISPR Approach to Gene Targeting

It is getting easier and easier to determine complete genome sequences—of model organisms, animals and plants of commercial importance, and humans: Craig Venter, Jim Watson, the 1000 Genome Project, soon you and me. Now that researchers have all this information at hand, the focus has shifted in many cases to manipulating particular sequences to determine their function or to alter their impact. A new study by Jinek et al.1 proposes a new approach—based on the oldest of DNA recognition principles—to the design of reagents that can target specific genomic sequences.

A Synthetic Biology Framework for Programming Eukaryotic Transcription Functions

Eukaryotic transcription factors (TFs) perform complex and combinatorial functions within transcriptional networks. Here, we present a synthetic framework for systematically constructing eukaryotic transcription functions using artificial zinc fingers, modular DNA-binding domains found within many eukaryotic TFs. Utilizing this platform, we construct a library of orthogonal synthetic transcription factors (sTFs) and use these to wire synthetic transcriptional circuits in yeast. We engineer complex functions, such as tunable output strength and transcriptional cooperativity, by rationally adjusting a decomposed set of key component properties, e.g., DNA specificity, affinity, promoter design, protein-protein interactions. We show that subtle perturbations to these properties can transform an individual sTF between distinct roles (activator, cooperative factor, inhibitory factor) within a transcriptional complex, thus drastically altering the signal processing behavior of multi-input systems. This platform provides new genetic components for synthetic biology and enables bottom-up approaches to understanding the design principles of eukaryotic transcriptional complexes and networks.

Targeting DNA With Fingers and TALENs.

Researchers have long recognized that the random introduction of new DNA into the genome could result in unpredictable genetic effects due to bilateral influences between transgenic and endogenous sequences. Hence, precise editing or replacement of mutant genes has been a major goal of gene therapy since its inception. That goal looked possible with the publication of studies demonstrating that targeted cleavage of chromosomal sequences and enhanced homologous recombination (HR) could be achieved using chimeric molecules composed of a nuclease domain and separate, designer DNA-recognition domains.1,2 Zinc-finger nucleases (ZFNs) are artificial endonucleases that consist of a FokI cleavage domain tethered to engineered Cys2His2 zinc-finger, DNA-binding polypeptides.3,4,5 ZFNs have gained considerable momentum and are widely considered the most mature nuclease technology in the gene therapy field.6 However, after 15 years in the spotlight, a new chimeric nuclease has emerged, Transcription Activator-Like (TAL) Effector Nucleases (TALENs).7,8,9,10 Here, we describe functional and design characteristics of ZFNs and TALENs and discuss their expanding role as tools for research and gene therapy.

Zinc-finger nucleases transition to the CoDA

Potent and easily produced custom zinc-finger nucleases will be game-changers for the field, at a time when the field itself is changing.

Engineering of Human Pluripotent Stem Cells by AAV-mediated Gene Targeting

Precise genetic manipulation of human pluripotent stem cells will be required to realize their scientific and therapeutic potential. Here, we show that adeno-associated virus (AAV) gene targeting vectors can be used to genetically engineer human embryonic stem cells (ESCs) and induced pluripotent stem cells (iPSCs). Different types of sequence-specific changes, including the creation and correction of mutations, were introduced into the human HPRT1 and HMGA1 genes (HPRT1 mutations being responsible for Lesch-Nyhan syndrome). Gene targeting occurred at high frequencies in both ESCs and iPSCs, with over 1% of all colony-forming units (CFUs) undergoing targeting in some experiments. AAV vectors could also be used to target genes in human fibroblasts that were subsequently used to derive iPSCs. Accurate and efficient targeting took place with minimal or no cytotoxicity, and most of the gene-targeted stem cells produced were euploid and pluripotent.

Gene Correction by Homologous Recombination With Zinc Finger Nucleases in Primary Cells From a Mouse Model of a Generic Recessive Genetic Disease

Zinc Finger nucleases (ZFNs) have been used to create precise genome modifications at frequencies that might be therapeutically useful in gene therapy. We created a mouse model of a generic recessive genetic disease to establish a preclinical system to develop the use of ZFN-mediated gene correction for gene therapy. We knocked a mutated GFP gene into the ROSA26 locus in murine embryonic stem (ES) cells and used these cells to create a transgenic mouse. We used ZFNs to determine the frequency of gene correction by gene targeting in different primary cells from this model. We achieved targeting frequencies from 0.17 to 6% in different cell types, including primary fibroblasts and astrocytes. We demonstrate that ex vivo gene-corrected fibroblasts can be transplanted back into a mouse where they retained the corrected phenotype. In addition, we achieved targeting frequencies of over 1% in ES cells, and the targeted ES cells retained the ability to differentiate into cell types from all three germline lineages. In summary, potentially therapeutically relevant frequencies of ZFN-mediated gene targeting can be achieved in a variety of primary cells and these cells can then be transplanted back into a recipient.

Targeted mutagenesis in zebrafish using customized zinc-finger nucleases.

Zebrafish mutants have traditionally been obtained by using random mutagenesis or retroviral insertions, methods that cannot be targeted to a specific gene and require laborious gene mapping and sequencing. Recently, we and others have shown that customized zinc-finger nucleases (ZFNs) can introduce targeted frame-shift mutations with high efficiency, thereby enabling directed creation of zebrafish gene mutations. Here we describe a detailed protocol for constructing ZFN expression vectors, for generating and introducing ZFN-encoding RNAs into zebrafish embryos and for identifying ZFN-generated mutations in targeted genomic sites. All of our vectors and methods are compatible with previously described Zinc-Finger Consortium reagents for constructing engineered zinc-finger arrays. Using these methods, zebrafish founders carrying targeted mutations can be identified within 4 months.

Oligomerized pool engineering (OPEN): an 'open-source' protocol for making customized zinc-finger arrays.

Engineered zinc-finger nucleases (ZFNs) form the basis of a broadly applicable method for targeted, efficient modification of eukaryotic genomes. In recent work, we described OPEN (oligomerized pool engineering), an 'open-source,' combinatorial selection-based method for engineering zinc-finger arrays that function well as ZFNs. We have also shown in direct comparisons that the OPEN method has a higher success rate than previously described 'modular-assembly' methods for engineering ZFNs. OPEN selections are carried out in Escherichia coli using a bacterial two-hybrid system and do not require specialized equipment. Here we provide a detailed protocol for carrying out OPEN to engineer zinc-finger arrays that have a high probability of functioning as ZFNs. Using OPEN, researchers can generate multiple, customized ZFNs in approximately 8 weeks.

415. Further Improvements and Applications of OPEN (Oligomerized Pool ENgineering): A Rapid, Robust, and Publicly Available Method for Engineering Customized Zinc Finger Nucleases

415. Further Improvements and Applications of OPEN (Oligomerized Pool ENgineering): A Rapid, Robust, and Publicly Available Method for Engineering Customized Zinc Finger Nucleases

Rapid Mutation of Endogenous Zebrafish Genes Using Zinc Finger Nucleases Made by Oligomerized Pool ENgineering (OPEN)

BackgroundCustomized zinc finger nucleases (ZFNs) form the basis of a broadly applicable tool for highly efficient genome modification. ZFNs are artificial restriction endonucleases consisting of a non-specific nuclease domain fused to a zinc finger array which can be engineered to recognize specific DNA sequences of interest. Recent proof-of-principle experiments have shown that targeted knockout mutations can be efficiently generated in endogenous zebrafish genes via non-homologous end-joining-mediated repair of ZFN-induced DNA double-stranded breaks. The Zinc Finger Consortium, a group of academic laboratories committed to the development of engineered zinc finger technology, recently described the first rapid, highly effective, and publicly available method for engineering zinc finger arrays. The Consortium has previously used this new method (known as OPEN for Oligomerized Pool ENgineering) to generate high quality ZFN pairs that function in human and plant cells.Methodology/Principal FindingsHere we show that OPEN can also be used to generate ZFNs that function efficiently in zebrafish. Using OPEN, we successfully engineered ZFN pairs for five endogenous zebrafish genes: tfr2, dopamine transporter, telomerase, hif1aa, and gridlock. Each of these ZFN pairs induces targeted insertions and deletions with high efficiency at its endogenous gene target in somatic zebrafish cells. In addition, these mutations are transmitted through the germline with sufficiently high frequency such that only a small number of fish need to be screened to identify founders. Finally, in silico analysis demonstrates that one or more potential OPEN ZFN sites can be found within the first three coding exons of more than 25,000 different endogenous zebrafish gene transcripts.Conclusions and SignificanceIn summary, our study nearly triples the total number of endogenous zebrafish genes successfully modified using ZFNs (from three to eight) and suggests that OPEN provides a reliable method for introducing targeted mutations in nearly any zebrafish gene of interest.

Rapid “Open-Source” Engineering of Customized Zinc-Finger Nucleases for Highly Efficient Gene Modification

Custom-made zinc-finger nucleases (ZFNs) can induce targeted genome modifications with high efficiency in cell types including Drosophila, C. elegans, plants, and humans. A bottleneck in the application of ZFN technology has been the generation of highly specific engineered zinc-finger arrays. Here we describe OPEN (Oligomerized Pool ENgineering), a rapid, publicly available strategy for constructing multifinger arrays, which we show is more effective than the previously published modular assembly method. We used OPEN to construct 37 highly active ZFN pairs which induced targeted alterations with high efficiencies (1%-50%) at 11 different target sites located within three endogenous human genes (VEGF-A, HoxB13, and CFTR), an endogenous plant gene (tobacco SuRA), and a chromosomally integrated EGFP reporter gene. In summary, OPEN provides an "open-source" method for rapidly engineering highly active zinc-finger arrays, thereby enabling broader practice, development, and application of ZFN technology for biological research and gene therapy.

Critical Parameters for Genome Editing Using Zinc Finger Nucleases

The possibility to make precise modifications to the genome at high frequency holds tremendous potential for biotechnology, conventional drug development and gene therapy. Homologous recombination is a powerful method for introducing such modifications in organisms such as mice. However, in mammals and plants, the frequency of gene modification by homologous recombination is quite low, precluding the therapeutic use of this methodology. In the past few years, tremendous progress has been made in overcoming one of primary barriers to efficient recombination, namely the introduction of a targeted double-strand break near the intended recombination site. This review will discuss the advances in engineering custom zinc-finger nucleases and their application in stimulating homologous recombination in higher eukaryotic cells at efficiencies approaching 1 in 2 cells.

Custom Zinc-Finger Nucleases for Use in Human Cells

Genome engineering through homologous recombination (HR) is a powerful instrument for studying biological pathways or creating treatment options for genetic disorders. In mammalian cells HR is rare but the creation of targeted DNA double-strand breaks stimulates HR significantly. Here, we present a method to generate, evaluate, and optimize rationally designed endonucleases that promote HR. The DNA-binding domains were synthesized by assembling predefined zinc-finger modules selected by phage display. Attachment of a transcriptional activation domain allowed assessment of DNA binding in reporter assays, while fusion with an endonuclease domain created custom nucleases that were tested for their ability to stimulate HR in episomal and chromosomal gene repair assays. We demonstrate that specificity, expression kinetics, and protein design are crucial parameters for efficient gene repair and that our two-step assay allows one to go quickly from design to testing to successful employment of the custom nucleases in human cells.

371. Optimizing Custom Zinc-Finger Nucleases for Use in Human Cells

Genome engineering is a powerful instrument to study basic biological questions or to create treatment options for genetic diseases. A safe way to correct genetic mutations is through homologous recombination (HR), during which a mutant sequence is replaced with the corresponding wild-type sequence. While HR is predominant in yeast, it is a rare event in mammalian cells where non-homologous recombination is much more frequent. The creation of a targeted DNA double-strand break (DSB) has been shown to locally stimulate HR several hundred-fold by activating the cellular machinery for double-strand break repair, but it presupposes the availability of a site-specific endonuclease to create the DSB. Some initial experiments with artificial nucleases in human cells revealed that cytotoxicity of such enzymes is a major issue, most likely through cleavage at non-specific sites. Here, we present a rapid two-step method to evaluate and optimize novel, rationally designed endonucleases. In a first step, the DNA-binding domain was synthesized by assembling predefined C2H2-zinc-finger modules and fused to a transcriptional activation domain. Each zinc-finger module is designed to recognize 3 bp of DNA and the modules can be assembled in any order necessary to recognize any given sequence in a target locus. DNA-binding specificity of these artificial transcription factors was assessed in a reporter assay. In a second step, the DNA-binding domain was attached to the catalytic domain of the FokI restriction endonuclease to generate the custom nucleases. Upon co-transfection with a repair matrix, they were assessed for their ability to stimulate HR in an episomal gene repair assay. We have engineered several kinds of custom nucleases and demonstrate that high specificity, fine-tuned expression kinetics and protein design are absolutely critical to promote HR. Importantly, the same parameters are also crucial for a low level of cytotoxicity. After optimization, expression of the custom nucleases stimulated both episomal and chromosomal gene repair and HR was achieved in 35% or 2.5% of transfected cells, respectively. Thus, custom nucleases will be a valuable tool to stimulate gene repair for therapeutic purposes. Moreover, they can be easily combined with viral vector systems for efficient delivery.