Recombinant vectors based on adeno-associated virus (rAAV) are promising tools to specifically alter complex genomes through homologous recombination (HR)-based gene targeting. In a therapeutic setting, an AAV donor vector will recombine with a mutant target locus in order to correct the mutation directly in the genome. The low frequency of HR in mammalian cells can be significantly improved by insertion of a DNA double-strand break (DSB) into the target locus through expression of a site-specific endonuclease. Here, we have scrutinized the fate of rAAV vector genomes during DSB-induced gene targeting and assessed the targeting frequency and the targeting ratio as a risk–benefit indicator. In various human cell lines carrying a mutated enhanced green fluorescent protein locus with a recognition site for the homing endonuclease I-SceI, rAAV-transduced cells were assayed by flow cytometry and by quantitative allele-specific polymerase chain reaction to assess HR and unspecific integration events. Under optimal conditions gene-targeting frequencies of 65% and targeting ratios of 2:1 were achieved, that is, more gene correction than unspecific integrations. The gene-targeting frequency was highly dependent on rAAV vector design, the cell line, and on the presence of a DSB in the target locus. Although expression of I-SceI led to a significant increase in gene targeting, it did not augment unspecific integration. In conclusion, our results reveal the side effects associated with rAAV-mediated gene targeting, but also its great potential for precise genome engineering in a therapeutic context.
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References
1.
AlwinS., GereM.B., GuhlE., EffertzK., BarbasC.F.III, SegalD.J., WeitzmanM.D., CathomenT.2005. Custom zinc-finger nucleases for use in human cells. Mol. Ther., 12:610–617.
2.
BartlettJ.S., WilcherR., SamulskiR.J.2000. Infectious entry pathway of adeno-associated virus and adeno-associated virus vectors. J. Virol., 74:2777–2785.
3.
BellP., MoscioniA.D., McCarterR.J., WuD., GaoG., HoangA., SanmiguelJ.C., SunX., WivelN.A., RaperS.E., FurthE.E., BatshawM.L., WilsonJ.M.2006. Analysis of tumors arising in male B6C3F1 mice with and without AAV vector delivery to liver. Mol. Ther., 14:34–44.
4.
BohneJ., CathomenT.2008. Genotoxicity in gene therapy: An account of vector integration and designer nucleases. Curr. Opin. Mol. Ther., 10:214–223.
5.
BuningH., PeraboL., CoutelleO., Quadt-HummeS., HallekM.2008. Recent developments in adeno-associated virus vector technology. J. Gene Med., 10:717–733.
6.
CarrollD.2008. Progress and prospects: Zinc-finger nucleases as gene therapy agents. Gene Ther., 15:1463–1468.
CathomenT., JoungJ.K.2008. Zinc-finger nucleases: the next generation emerges. Mol. Ther., 16:1200–1207.
9.
CervelliT., PalaciosJ.A., ZentilinL., ManoM., SchwartzR.A., WeitzmanM.D., GiaccaM.2008. Processing of recombinant AAV genomes occurs in specific nuclear structures that overlap with foci of DNA-damage-response proteins. J. Cell Sci., 121:349–357.
10.
ChamberlainJ.R., DeyleD.R., SchwarzeU., WangP., HirataR.K., LiY., ByersP.H., RussellD.W.2008. Gene targeting of mutant COL1A2 alleles in mesenchymal stem cells from individuals with osteogenesis imperfecta. Mol. Ther., 16:187–193.
11.
ChoiV.W., McCartyD.M., SamulskiR.J.2006. Host cell DNA repair pathways in adeno-associated viral genome processing. J. Virol., 80:10346–10356.
12.
ChoulikaA., PerrinA., DujonB., NicolasJ.F.1995. Induction of homologous recombination in mammalian chromosomes by using the I-SceI system of Saccharomyces cerevisiae. Mol. Cell. Biol., 15:1968–1973.
CornuT.I., Thibodeau-BegannyS., GuhlE., AlwinS., EichtingerM., JoungJ.K., CathomenT.2008. DNA-binding specificity is a major determinant of the activity and toxicity of zinc-finger nucleases. Mol. Ther., 16:352–358.
15.
CumminsJ.M., RagoC., KohliM., KinzlerK.W., LengauerC., VogelsteinB.2004. Tumour suppression: Disruption of HAUSP gene stabilizes. 53Nature, 4281 p following 486.
DuanD., YueY., EngelhardtJ.F.2003. Consequences of DNA-dependent protein kinase catalytic subunit deficiency on recombinant adeno-associated virus genome circularization and heterodimerization in muscle tissue. J. Virol., 77:4751–4759.
18.
EngelhardtJ.F.2006. AAV hits the genomic bull's-eye. Nat. Biotechnol., 24:949–950.
19.
FattahF.J., LichterN.F., FattahK.R., OhS., HendricksonE.A.2008. Ku70, an essential gene, modulates the frequency of rAAV-mediated gene targeting in human somatic cells. Proc. Natl. Acad. Sci. U.S.A., 105:8703–8708.
HändelE.M., AlwinS., CathomenT.2009. Expanding or restricting the target site repertoire of zinc-finger nucleases: the inter-domain linker as a major determinant of target site selectivity. Mol. Ther., 17:104–111.
22.
HendrieP.C., RussellD.W.2005. Gene targeting with viral vectors. Mol. Ther., 12:9–17.
23.
HendrieP.C., HirataR.K., RussellD.W.2003. Chromosomal integration and homologous gene targeting by replication-incompetent vectors based on the autonomous parvovirus minute virus of mice. J. Virol., 77:13136–13145.
24.
HirataR.K., RussellD.W.2000. Design and packaging of adeno-associated virus gene targeting vectors. J. Virol., 74:4612–4620.
25.
InagakiK., PiaoC., KotcheyN.M., WuX., NakaiH.2008. Frequency and spectrum of genomic integration of recombinant adeno-associated virus serotype 8 vector in neonatal mouse liver. J. Virol., 82:9513–9524.
26.
InoueN., HirataR.K., RussellD.W.1999. High-fidelity correction of mutations at multiple chromosomal positions by adeno-associated virus vectors. J. Virol., 73:7376–7380.
27.
KohliM., RagoC., LengauerC., KinzlerK.W., VogelsteinB.2004. Facile methods for generating human somatic cell gene knockouts using recombinant adeno-associated viruses. Nucleic Acids Res., 32:e3.
28.
LiuX., YanZ., LuoM., ZakR., LiZ., DriskellR.R., HuangY., TranN., EngelhardtJ.F.2004. Targeted correction of single-base-pair mutations with adeno-associated virus vectors under nonselective conditions. J. Virol., 78:4165–4175.
29.
LombardoA., GenoveseP., BeausejourC.M., ColleoniS., LeeY.L., KimK.A., AndoD., UrnovF.D., GalliC., GregoryP.D., HolmesM.C., NaldiniL.2007. Gene editing in human stem cells using zinc finger nucleases and integrase-defective lentiviral vector delivery. Nat. Biotechnol., 25:1298–1306.
MillerD.G., PetekL.M., RussellD.W.2003. Human gene targeting by adeno-associated virus vectors is enhanced by DNA double-strand breaks. Mol. Cell. Biol., 23:3550–3557.
MillerD.G., TrobridgeG.D., PetekL.M., JacobsM.A., KaulR., RussellD.W.2005. Large-scale analysis of adeno-associated virus vector integration sites in normal human cells. J. Virol., 79:11434–11442.
34.
MillerD.G., WangP.R., PetekL.M., HirataR.K., SandsM.S., RussellD.W.2006. Gene targeting in vivo by adeno-associated virus vectors. Nat. Biotechnol., 24:1022–1026.
35.
NakaiH., IwakiY., KayM.A., CoutoL.B.1999. Isolation of recombinant adeno-associated virus vector-cellular DNA junctions from mouse liver. J. Virol., 73:5438–5447.
36.
NakaiH., YantS.R., StormT.A., FuessS., MeuseL., KayM.A.2001. Extrachromosomal recombinant adeno-associated virus vector genomes are primarily responsible for stable liver transduction in vivo. J. Virol., 75:6969–6976.
37.
NakaiH., MontiniE., FuessS., StormT.A., GrompeM., KayM.A.2003. AAV serotype 2 vectors preferentially integrate into active genes in mice. Nat. Genet., 34:297–302.
38.
NakaiH., WuX., FuessS., StormT.A., MunroeD., MontiniE., BurgessS.M., GrompeM., KayM.A.2005. Large-scale molecular characterization of adeno-associated virus vector integration in mouse liver. J. Virol., 79:3606–3614.
39.
PaquesF., DuchateauP.2007. Meganucleases and DNA double-strand break-induced recombination: perspectives for gene therapy. Curr. Gene Ther., 7:49–66.
40.
PorteusM.H., CathomenT., WeitzmanM.D., BaltimoreD.2003. Efficient gene targeting mediated by adeno-associated virus and DNA double-strand breaks. Mol. Cell. Biol., 23:3558–3565.
41.
RouetP., SmihF., JasinM.1994. Expression of a site-specific endonuclease stimulates homologous recombination in mammalian cells. Proc. Natl. Acad. Sci. U.S.A., 91:6064–6068.
42.
RussellD.W., HirataR.K.1998. Human gene targeting by viral vectors. Nat. Genet., 18:325–330.
43.
SanliogluS., BensonP., EngelhardtJ.F.2000. Loss of ATM function enhances recombinant adeno-associated virus transduction and integration through pathways similar to UV irradiation. Virology, 268:68–78.
SummerfordC., SamulskiR.J.1998. Membrane-associated heparan sulfate proteoglycan is a receptor for adeno-associated virus type 2 virions. J. Virol., 72:1438–1445.
46.
SummerfordC., BartlettJ.S., SamulskiR.J.1999. αVβ5 integrin: A co-receptor for adeno-associated virus type 2 infection. Nat. Med., 5:78–82.
47.
UrnovF.D., MillerJ.C., LeeY.L., BeausejourC.M., RockJ.M., AugustusS., JamiesonA.C., PorteusM.H., GregoryP.D., HolmesM.C.2005. Highly efficient endogenous human gene correction using designed zinc-finger nucleases. Nature, 435:646–651.
VasilevaA., LindenR.M., JessbergerR.2006. Homologous recombination is required for AAV-mediated gene targeting. Nucleic Acids Res., 34:3345–3360.
50.
VasquezK.M., MarburgerK., IntodyZ., WilsonJ.H.2001. Manipulating the mammalian genome by homologous recombination. Proc. Natl. Acad. Sci. U.S.A., 98:8403–8410.
51.
YanZ., SunX., EngelhardtJ.F.2009. Progress and prospects: Techniques for site-directed mutagenesis in animal models. Gene Ther., 16:581–588.
52.
ZentilinL., MarcelloA., GiaccaM.2001. Involvement of cellular double-stranded DNA break binding proteins in processing of the recombinant adeno-associated virus genome. J. Virol., 75:12279–12287.
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