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Journal of Virology, May 2000, p. 3953-3966, Vol. 74, No. 9
Curriculum in Genetics and Molecular
Biology,1 Lineberger Comprehensive
Cancer Center,3 Department of
Pharmacology,4 and the Gene Therapy
Center,2 University of North Carolina at
Chapel Hill, Chapel Hill, North Carolina 27599
Received 13 December 1999/Accepted 20 January 2000
Adeno-associated virus type 2 (AAV) is the only known eucaryotic
virus capable of targeted integration in human cells. AAV integrates
preferentially into human chromosome (ch) 19q13.3qter. The
nonstructural proteins of AAV-2, Rep78 and Rep68, are essential for
targeted integration. Rep78 and Rep68 are multifunctional proteins with
diverse biochemical activities, including site-specific binding to AAV
and ch-19 target sequences, helicase activity, and strand-specific,
site-specific endonuclease activities. Both a Rep DNA binding element
(RBE) and a nicking site essential for AAV replication present within
the viral terminal repeats are also located on ch-19. Recently,
identical RBE sequences have been identified at other locations in the
human genome. This fact raises numerous questions concerning AAV
targeted integration; specifically, how many RBE sequences are in the
human genome? How does Rep discriminate between these and the ch-19 RBE
sequence? Does Rep interact with all sites and, if so, how is targeted
integration within a fixed time frame facilitated? To better
characterize the role of Rep in targeted integration, we established a
Rep-dependent filter DNA binding assay using a highly purified Rep-68
fusion protein. Electron microscopy (EM) analysis was also performed to
determine the characteristics of the Rep-RBE interaction. Our results
determined that the Rep affinity for ch-19 is not distinct compared to
other RBEs in the human genome when utilizing naked DNA. In fact, a
minimum-binding site (GAGYGAGC) efficiently associated with Rep,
suggesting that as many as 2 × 105 sites may exist.
In addition, such sites also exist frequently in nonprimate mammalian
genomes, although AAV integrates site specifically into primate
genomes. EM analysis demonstrated that only one Rep-DNA complex was
formed on ch-19 target DNA. Surprisingly, identically sized complexes
were observed on all substrates containing a RBE sequence, but never on
DNA lacking an RBE. Rep-DNA complexes involved a multimeric protein
structure that spanned ca. 60 bp. Immunoprecipitation of AAV latently
infected cells determined that 1,000 to 4,000 copies of Rep78 and Rep68
protein are expressed per cell. Comparison of the Rep association
constant with those of established DNA binding proteins indicates that
sufficient molecules of Rep are present to interact with all potential
RBE sites. Moreover, Rep expression in the absence of AAV
cis-acting substrate resulted in Rep-dependent
amplification and rearrangement of the target sequence in ch-19. This
result suggests that this locus is a hot spot for Rep-dependent
recombination. Finally, we engineered mice to carry a single 2.7-kb
human ch-19 insertion containing the AAV ch-19 target locus. Using
cells derived from these mice, we demonstrated that this sequence was
sufficient for site-specific recombination after infection with
transducing vectors expressing Rep. This result indicates that any host
factors required for targeting are conserved between human and mouse. Furthermore, the human ch-19 cis sequences and chromatin
structure required for site-specific recombination are contained within this fragment. Overall, these results indicate that the specificity of
targeted recombination to human ch-19 is not dictated by differential Rep affinities for RBE sites. Instead, specificity is likely dictated by human ch-19 sequences that serve as a Rep protein-mediated origin of
replication, thus facilitating viral targeting through Rep-Rep
interactions and host enzymes, resulting in site-specific recombination. Control of specificity is clearly dictated by the ch-19
sequences, since transfer of these sequences into the mouse genome are
sufficient to achieve Rep-dependent site-specific integration.
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Roles of Adeno-Associated Virus Rep Protein and
Human Chromosome 19 in Site-Specific Recombination
*
Corresponding author. Mailing address: Gene Therapy
Center, 7119 Thurston Bowles CB 7352, University of North Carolina at Chapel Hill, Chapel Hill, NC 27599. Phone: (919) 962-3285. Fax: (919)
966-0907. E-mail: rjs{at}med.unc.edu.
Journal of Virology, May 2000, p. 3953-3966, Vol. 74, No. 9
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
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