Zinc-finger nucleases as a novel therapeutic strategy for targeting hepatitis B virus DNAs.

Hepatitis B virus (HBV) chronically infects 350-400 million people worldwide and causes >1 million deaths yearly. Current therapies prevent new viral genome formation, but do not target pre-existing viral genomic DNA, thus curing only approximately 1/2 of patients. We targeted HBV DNA for cleavage using zinc-finger nucleases (ZFNs), which cleave as dimers. Co-transfection of our ZFN pair with a target plasmid containing the HBV genome resulted in specific cleavage. After 3 days in culture, 26% of the target remained linear, whereas approximately10% was cleaved and misjoined tail-to-tail. Notably, ZFN treatment decreased levels of the hepatitis C virus pregenomic RNA by 29%. A portion of cleaved plasmids are repaired in cells, often with deletions and insertions. To track misrepair, we introduced an XbaI restriction site in the spacer between the ZFN sites. Targeted cleavage and misrepair destroys the XbaI site. After 3 days in culture, approximately 6% of plasmids were XbaI-resistant. Thirteen of 16 clones sequenced contained frameshift mutations that would lead to truncations of the viral core protein. These results demonstrate, for the first time, the possibility of targeting episomal viral DNA genomes using ZFNs.

Enhanced protein production by engineered zinc finger proteins.

Increasing the yield of therapeutic proteins from mammalian production cell lines reduces costs and decreases the time to market. To this end, we engineered a zinc finger protein transcription factor (ZFP TF) that binds a DNA sequence within the promoter driving transgene expression. This ZFP TF enabled >100% increase in protein yield from CHO cells in transient, stable, and fermentor production run settings. Expression vectors engineered to carry up to 10 ZFP binding sites further enhanced ZFP-mediated increases in protein production up to approximately 500%. The multimerized ZFP binding sites function independently of the promoter, and therefore across vector platforms. CHO cell lines stably expressing ZFP TFs demonstrated growth characteristics similar to parental cell lines. ZFP TF expression and gains in protein production were stable over >30 generations in the absence of antibiotic selection. Our results demonstrate that ZFP TFs can rapidly and stably increase protein production in mammalian cells.

Controlling gene expression in Drosophila using engineered zinc finger protein transcription factors.

Zinc finger protein transcription factors (ZFP TFs) have been designed to control the expression of endogenous genes in a variety of cells. However, thus far the use of engineered ZFP TFs in germline transgenic settings has been restricted to plants. Here we report that ZFP TFs can regulate gene expression in transgenic Drosophila. To demonstrate this, we targeted the promoter of the well-characterized fushi tarazu (ftz) gene with a ZFP TF activator using the VP16 activation domain from Herpes simplex virus, and ZFP TF repressors using the Drosophila methyl-CpG binding domain (MBD)-like Delta protein. Heat-shock-inducible expression of the ZFP TF activator and repressors resulted in reciprocal effects on ftz regulation, as deduced from changes in the staining pattern and intensity of ftz and en gene expression, and from the cuticular analysis of first instar larvae. These data demonstrate the utility of ZFP TFs as tools for controlling gene expression in the context of a metazoan organism.

Gene regulation in planta by plant-derived engineered zinc finger protein transcription factors.

The ability to modify plant traits is of great commercial potential in agricultural biotechnology. To this end we have engineered plant-based zinc finger protein transcription factors (ZFP TFs) that minimize the use of non-plant DNA sequences. This novel architecture supports the use of tandem arrays of zinc-finger DNA recognition domains such that the ZFP TF binds a contiguous DNA target site - thus emulating the design of ZFP TFs described previously for mammalian gene regulation. We show that this plant-based ZFP TF architecture supports high affinity DNA binding while allowing the specificity of the DNA-protein interaction to be determined by the amino acid sequences of the recognition helices. This plant-based backbone thus supports the use of previously characterized DNA recognition helices originally identified in a mammalian ZFP context without using mammalian DNA sequences. Moreover, we show that plant-based ZFP TFs employing this new architecture can up-regulate endogenous ADH activity by > 20-fold in transgenic Arabidopsis. Thus plant-based ZFP TFs are shown to be potent regulators of gene expression in vivo.

Highly efficient endogenous human gene correction using designed zinc-finger nucleases.

Permanent modification of the human genome in vivo is impractical owing to the low frequency of homologous recombination in human cells, a fact that hampers biomedical research and progress towards safe and effective gene therapy. Here we report a general solution using two fundamental biological processes: DNA recognition by C2H2 zinc-finger proteins and homology-directed repair of DNA double-strand breaks. Zinc-finger proteins engineered to recognize a unique chromosomal site can be fused to a nuclease domain, and a double-strand break induced by the resulting zinc-finger nuclease can create specific sequence alterations by stimulating homologous recombination between the chromosome and an extrachromosomal DNA donor. We show that zinc-finger nucleases designed against an X-linked severe combined immune deficiency (SCID) mutation in the IL2Rgamma gene yielded more than 18% gene-modified human cells without selection. Remarkably, about 7% of the cells acquired the desired genetic modification on both X chromosomes, with cell genotype accurately reflected at the messenger RNA and protein levels. We observe comparably high frequencies in human T cells, raising the possibility of strategies based on zinc-finger nucleases for the treatment of disease.

Elevation of seed alpha-tocopherol levels using plant-based transcription factors targeted to an endogenous locus.

Synthetic zinc finger transcription factors (ZFP-TFs) were designed to upregulate the expression of the endogenous Arabidopsis gamma-tocopherol methyltransferase (GMT) gene. This gene encodes the enzyme responsible for the conversion of gamma-tocopherol to alpha-tocopherol, the tocopherol species with the highest vitamin E activity. Five three-finger zinc finger protein (ZFP) DNA binding domains were constructed and proven to bind tightly to 9 bp DNA sequences located in either the promoter or coding region of the GMT gene. When these ZFPs were fused to a nuclear localization signal and the maize C1 activation domain, four of the five resulting ZFP-TFs were able to upregulate the expression of the GMT gene in leaf protoplast transient assays. Seed-specific expression of these ZFP-TFs in transgenic Arabidopsis produced several lines with a heritable elevation in seed alpha-tocopherol. These results demonstrate that engineered ZFP-TFs comprised of plant-derived elements are capable of modulating the expression of endogenous genes in plants.

Repression of vascular endothelial growth factor A in glioblastoma cells using engineered zinc finger transcription factors.

Angiogenic factors are necessary for tumor proliferation and thus are attractive therapeutic targets. In this study, we have used engineered zinc finger protein (ZFP) transcription factors (TFs) to repress expression of vascular endothelial growth factor (VEGF)-A in human cancer cell lines. We create potent transcriptional repressors by fusing a designed ZFP targeted to the VEGF-A promoter with either the ligand-binding domain of thyroid hormone receptor alpha or its viral relative, vErbA. Moreover, this ZFP-vErbA repressor binds its intended target site in vivo and mediates the specific deacetylation of histones H3 and H4 at the targeted promoter, a result that emulates the natural repression mechanism of these domains. The potential therapeutic relevance of ZFP-mediated VEGF-A repression was addressed using the highly tumorigenic glioblastoma cell line U87MG. Despite the aberrant overexpression of VEGF-A in this cell line, engineered ZFP TFs were able to repress the expression of VEGF-A by >20-fold. The VEGF-A levels observed after ZFP TF-mediated repression were comparable to those of a nonangiogenic cancer line (U251MG), suggesting that the degree of repression obtained with the ZFP TF would be sufficient to suppress tumor angiogenesis. Thus, engineered ZFP TFs are shown to be potent regulators of gene expression with therapeutic promise in the treatment of disease.

Drug discovery with engineered zinc-finger proteins.

Zinc-finger proteins (ZFPs) that recognize novel DNA sequences are the basis of a powerful technology platform with many uses in drug discovery and therapeutics. These proteins have been used as the DNA-binding domains of novel transcription factors (ZFP TFs), which are useful for validating genes as drug targets and for engineering cell lines for small-molecule screening and protein production. Recently, they have also been used as a basis for novel human therapeutics. Most of our advances in the design and application of these ZFP TFs rely on our ability to engineer ZFPs that bind short stretches of DNA (typically 9-18 base pairs) located within the promoters of target genes. Here, we summarize the methods used to design these DNA-binding domains, explain how they are incorporated into novel transcription factors (and other useful molecules) and describe some key applications in drug discovery.

Induction of angiogenesis in a mouse model using engineered transcription factors.

The relationship between the structure of zinc-finger protein (ZFP) transcription factors and DNA sequence binding specificity has been extensively studied. Advances in this field have made it possible to design ZFPs de novo that will bind to specific targeted DNA sequences. It has been proposed that such designed ZFPs may eventually be useful in gene therapy. A principal advantage of this approach is that activation of an endogenous gene ensures expression of the natural array of splice variants. Preliminary studies in tissue culture have validated the feasibility of this approach. The studies reported here were intended to test whether engineered transcription factors are effective in a whole-organism model. ZFPs were designed to regulate the endogenous gene encoding vascular endothelial growth factor-A (Vegfa). Expression of these new ZFPs in vivo led to induced expression of the protein VEGF-A, stimulation of angiogenesis and acceleration of experimental wound healing. In addition, the neovasculature resulting from ZFP-induced expression of Vegfa was not hyperpermeable as was that produced by expression of murine Vegfa(164) cDNA. These data establish, for the first time, that specifically designed transcription factors can regulate an endogenous gene in vivo and evoke a potentially therapeutic biophysiologic effect.