Targeted gene addition into a specified location in the human genome using designed zinc finger nucleases

Efficient incorporation of novel DNA sequences into a specific site in the genome of living human cells remains a challenge despite its potential utility to genetic medicine, biotechnology, and basic research. We find that a precisely placed double-strand break induced by engineered zinc finger nucleases (ZFNs) can stimulate integration of long DNA stretches into a predetermined genomic location, resulting in high-efficiency site-specific gene addition. Using an extrachromosomal DNA donor carrying a 12-bp tag, a 900-bp ORF, or a 1.5-kb promoter-transcription unit flanked by locus-specific homology arms, we find targeted integration frequencies of 15%, 6%, and 5%, respectively, within 72 h of treatment, and with no selection for the desired event. Importantly, we find that the integration event occurs in a homology-directed manner and leads to the accurate reconstruction of the donor-specified genotype at the endogenous chromosomal locus, and hence presumably results from synthesis-dependent strand annealing repair of the break using the donor DNA as a template. This site-specific gene addition occurs with no measurable increase in the rate of random integration. Remarkably, we also find that ZFNs can drive the addition of an 8-kb sequence carrying three distinct promoter-transcription units into an endogenous locus at a frequency of 6%, also in the absence of any selection. These data reveal the surprising versatility of the specialized polymerase machinery involved in double-strand break repair, illuminate a powerful approach to mammalian cell engineering, and open the possibility of ZFN-driven gene addition therapy for human genetic disease.

[1]  L. Symington Role of RAD52 Epistasis Group Genes in Homologous Recombination and Double-Strand Break Repair , 2002, Microbiology and Molecular Biology Reviews.

[2]  A. Porter,et al.  Therapeutic gene targeting , 1998, Gene Therapy.

[3]  C. Pabo,et al.  Design and selection of novel Cys2His2 zinc finger proteins. , 2001, Annual review of biochemistry.

[4]  N. Pavletich,et al.  Zinc finger-DNA recognition: crystal structure of a Zif268-DNA complex at 2.1 A , 1991, Science.

[5]  A. Klug The discovery of zinc fingers and their development for practical applications in gene regulation , 2005 .

[6]  Stephen C. West,et al.  Molecular views of recombination proteins and their control , 2003, Nature Reviews Molecular Cell Biology.

[7]  Daniel S. Ginsburg,et al.  Site-specific integration with phiC31 integrase for prolonged expression of therapeutic genes. , 2005, Advances in genetics.

[8]  J. Haber,et al.  Role of DNA Replication Proteins in Double-Strand Break-Induced Recombination in Saccharomyces cerevisiae , 2004, Molecular and Cellular Biology.

[9]  Jac A. Nickoloff,et al.  Gene Conversion Tracts from Double-Strand Break Repair in Mammalian Cells , 1998, Molecular and Cellular Biology.

[10]  Wenyi Wei,et al.  Bypass of senescence after disruption of p21CIP1/WAF1 gene in normal diploid human fibroblasts. , 1997, Science.

[11]  J. Jami,et al.  Biallelic transcription of Igf2 and H19 in individual cells suggests a post-transcriptional contribution to genomic imprinting , 1999, Current Biology.

[12]  S Chandrasegaran,et al.  Hybrid restriction enzymes: zinc finger fusions to Fok I cleavage domain. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[13]  J. Haber,et al.  Conservative Inheritance of Newly Synthesized DNA in Double-Strand Break-Induced Gene Conversion , 2006, Molecular and Cellular Biology.

[14]  Dana Carroll,et al.  Enhancing Gene Targeting with Designed Zinc Finger Nucleases , 2003, Science.

[15]  W. Engels,et al.  Differential Usage of Alternative Pathways of Double-Strand Break Repair in Drosophila , 2006, Genetics.

[16]  Dana Carroll,et al.  Stimulation of Homologous Recombination through Targeted Cleavage by Chimeric Nucleases , 2001, Molecular and Cellular Biology.

[17]  Mario R. Capecchi,et al.  High frequency targeting of genes to specific sites in the mammalian genome , 1986, Cell.

[18]  P. Rouet,et al.  Introduction of double-strand breaks into the genome of mouse cells by expression of a rare-cutting endonuclease. , 1994, Molecular and cellular biology.

[19]  K. Kinzler,et al.  Facile methods for generating human somatic cell gene knockouts using recombinant adeno-associated viruses. , 2004, Nucleic acids research.

[20]  A Klug,et al.  Repetitive zinc‐binding domains in the protein transcription factor IIIA from Xenopus oocytes. , 1985, The EMBO journal.

[21]  J. Hoeijmakers Genome maintenance mechanisms for preventing cancer , 2001, Nature.

[22]  Aaron Klug,et al.  In vivo repression by a site-specific DNA-binding protein designed against an oncogenic sequence , 1994, Nature.

[23]  P. Gregory,et al.  Biotechnologies and therapeutics: chromatin as a target. , 2002, Current opinion in genetics & development.

[24]  P. Rouet,et al.  Expression of a site-specific endonuclease stimulates homologous recombination in mammalian cells. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[25]  G. Gloor,et al.  Efficient copying of nonhomologous sequences from ectopic sites via P-element-induced gap repair , 1994, Molecular and cellular biology.

[26]  S Chandrasegaran,et al.  A detailed study of the substrate specificity of a chimeric restriction enzyme. , 1999, Nucleic acids research.

[27]  David Baltimore,et al.  Chimeric Nucleases Stimulate Gene Targeting in Human Cells , 2003, Science.

[28]  Katherine A. High,et al.  Gene therapy: The moving finger , 2005, Nature.

[29]  A. Otte,et al.  Employing epigenetics to augment the expression of therapeutic proteins in mammalian cells. , 2006, Trends in biotechnology.

[30]  S. Jackson,et al.  Sensing and repairing DNA double-strand breaks. , 2002, Carcinogenesis.

[31]  S. West,et al.  Human DNA polymerase eta promotes DNA synthesis from strand invasion intermediates of homologous recombination. , 2005, Molecular cell.

[32]  M. Sadelain,et al.  Occurrence of leukaemia following gene therapy of X-linked SCID , 2003, Nature Reviews Cancer.

[33]  J. Strathern,et al.  Homologous recombination is promoted by translesion polymerase poleta. , 2005, Molecular cell.

[34]  M Meselson,et al.  THE REPLICATION OF DNA IN ESCHERICHIA COLI. , 1958, Proceedings of the National Academy of Sciences of the United States of America.

[35]  K. Valerie,et al.  Regulation and mechanisms of mammalian double-strand break repair , 2003, Oncogene.

[36]  A. Klug Gene Regulatory Proteins and Their Interaction with DNA , 1995, Annals of the New York Academy of Sciences.

[37]  J. Haber,et al.  Multiple Pathways of Recombination Induced by Double-Strand Breaks in Saccharomyces cerevisiae , 1999, Microbiology and Molecular Biology Reviews.

[38]  D. Russell,et al.  Gene targeting with viral vectors. , 2005, Molecular therapy : the journal of the American Society of Gene Therapy.

[39]  Michael R. Green,et al.  Expressing the human genome , 2001, Nature.

[40]  Stephen P. Jackson,et al.  A means to a DNA end: the many roles of Ku , 2004, Nature Reviews Molecular Cell Biology.

[41]  K. Nozaki,et al.  Dual roles for DNA polymerase eta in homologous DNA recombination and translesion DNA synthesis. , 2005, Molecular cell.

[42]  Jeffrey C. Miller,et al.  Highly efficient endogenous human gene correction using designed zinc-finger nucleases , 2005, Nature.