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Previous Article | Next Article 
Journal of Virology, May 2000, p. 4612-4620, Vol. 74, No. 10
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Design and Packaging of Adeno-Associated Virus Gene
Targeting Vectors
Roli K.
Hirata and
David W.
Russell*
Division of Hematology, Department of
Medicine, and Markey Molecular Medicine Center, University of
Washington, Seattle, Washington 98195-7720
Received 23 November 1999/Accepted 21 February 2000
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ABSTRACT |
Adeno-associated virus (AAV) vectors can transduce cells by several
mechanisms, including (i) gene addition by chromosomal integration or
episomal transgene expression or (ii) gene targeting by modification of
homologous chromosomal sequences. The latter process can be used to
correct a variety of mutations in chromosomal genes with high fidelity
and specificity. In this study, we used retroviral vectors to introduce
mutant alkaline phosphatase reporter genes into normal human cells and
subsequently corrected these mutations with AAV gene targeting vectors.
We find that increasing the length of homology between the AAV vector
and the target locus improves gene correction rates, as does
positioning the mutation to be corrected in the center of the AAV
vector genome. AAV-mediated gene targeting increases with time and
multiplicity of infection, similar to AAV-mediated gene addition.
However, in contrast to gene addition, genotoxic stress did not affect
gene targeting rates, suggesting that different cellular factors are
involved. In the course of these studies, we found that (i) vector
genomes less than half of wild-type size could be packaged as monomers or dimers and (ii) packaged dimers consist of inverted repeats with
covalently closed hairpins at either end. These studies should prove
helpful in designing AAV gene targeting vectors for basic research or
gene therapy.
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INTRODUCTION |
Adeno-associated virus (AAV) is a
dependent parvovirus with a 4.7-kb single-stranded linear DNA genome.
Vectors based on AAV have been developed by replacing the viral genes
with foreign DNA between the cis-acting terminal repeats.
Typically, the foreign DNA encodes a transgene cassette with promoter
and polyadenylation signals designed to express from an ectopic
location. These vectors can transduce cells by a variety of mechanisms,
including random chromosomal integration of the vector genome (29,
38) or episomal transgene expression (2, 7, 18). If
transduction is performed in the presence of the AAV rep
gene, vectors can also be designed to integrate at the site-specific
integration locus of wild-type AAV located on human chromosome 19 (3, 24, 25, 33). In addition to these transduction
mechanisms (which can be defined as gene addition strategies), we have
shown that AAV vectors can be used to introduce specific genetic
modifications at homologous chromosomal sequences in a gene targeting
process (16, 27). The gene targeting rates produced by AAV
vectors approach 1% at the single-copy hypoxanthine phosphoribosyl
transferase (HPRT) locus in normal human cells, which is 3 to 4 logs higher than can typically be achieved in human cells with
conventional gene targeting methods (27). Possible
explanations for the high rates of AAV-mediated gene targeting include
efficient nuclear delivery of vector genomes, homologous pairing
promoted by the single-stranded vector genome, or effects of the vector
inverted terminal repeats.
To simplify studies of AAV-mediated gene targeting, we recently
developed an assay based on the correction of mutant neomycin phosphotransferase (neo) genes introduced by retroviral
vectors at random chromosomal locations (16). This approach
allowed us to control the structure of the targeted locus and compare correction rates of a variety of mutations in the neo gene.
We found that AAV vectors could be used to correct substitution, insertion, and deletion mutations with high fidelity at multiple chromosomal positions. Here we have developed a similar approach in
which mutant alkaline phosphatase (AP) genes introduced by retroviral
vectors are corrected by AAV vectors, allowing us to measure gene
targeting rates by histochemical staining in the absence of selection.
We used this simplified assay to study vector design parameters and the
effects of different transduction conditions on AAV-mediated gene
targeting rates. We also observed effects on AAV packaging due to
vector genome size.
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MATERIALS AND METHODS |
Vectors.
Plasmid pLAPSN (20) and its derivatives
were used to generate retroviral vector stocks by transient
transfection of PG13 cells (19), collection of conditioned
medium 2 days later, and passage through 0.45-µm-pore-size filters.
The various AP mutations shown in Fig. 1A
were introduced into pLAPSN by standard techniques (31) and
confirmed by DNA sequencing.
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FIG. 1.
AP gene targeting vectors. (A) Diagrams of retroviral
and AAV vectors used for AP gene targeting. The murine leukemia virus
(MLV) retroviral vector pLAPSN is shown, with the positions of the
LTRs, AP gene, SV40 promoter (SV), and neo gene indicated.
The AP mutations used in this study are shown above the AP gene along
with the corresponding wild-type (wt) sequences, with numbering
starting at nucleotide position 1 of the AP reading frame. Differences
between the wild-type and mutant sequences are shown in bold lowercase
letters. Maps of five AAV vectors containing wild-type portions of the
AP gene are shown below the pLAPSN map, with regions of homology and
the restriction enzymes used to generate these AP fragments indicated.
(B and C) Examples of AP+ foci produced in fibroblasts
containing the 375 4 mutation by gene targeting with the AAV-5'AP-Bss
vector in our standard assay (see Materials and Methods).
Photomicrographs obtained with a dissecting microscope of clonal foci
containing several AP+ cells are shown.
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AAV vector stocks were made by transient transfection of TtetA2
packaging cells or 293T cells with AAV vector plasmids as described
elsewhere (17). All stocks were treated with nuclease and
purified on CsCl gradients. Any residual adenovirus was heat inactivated at 56°C for 1 h. Unless otherwise stated, AAV vector stock particle numbers were based on the amount of full-length, single-stranded vector DNA genomes detected by alkaline Southern blot
analysis (17). AAV vector plasmids pA2-5'AP-Psh,
pA2-5'AP-Bss, pA2-3'AP-Bam, pA2-3'AP-(B/A), and pA2-3'AP-(E/A) were
made by inserting the restriction fragments from pLAPSN shown in Fig. 1A into the BglII site of pTR (30) and used to
generate the corresponding vectors AAV-5'AP-Psh, AAV-5'AP-Bss,
AAV-3'AP-Bam, AAV-3'AP-(B/A), and AAV-3'AP-(E/A), respectively. When
necessary, these fragments were first given compatible cohesive ends by
attaching BclI linkers (31). The AAV gene
addition vector AAV-LAPSN (28) used in the experiments in
Fig. 3c contains the murine leukemia virus long terminal repeat (LTR)
driving expression of a functional AP gene, as well as a simian virus
40 (SV40) promoter driving neo, and thus is analogous to the
retroviral vector pLAPSN.
For Fig. 4, fractions were collected directly from CsCl gradients,
their densities were determined by refractometry, and the vector DNA
within each fraction was released, separated on alkaline agarose gels,
and quantitated by PhosphorImager (Molecular Dynamics, Sunnyvale,
Calif.) analysis of Southern blots as described elsewhere (17). For Fig. 5, AAV vector DNA was purified from dialyzed CsCl fractions as described elsewhere (32). The light DNA
samples were purified from the monomer peak fractions of AAV-3'AP-Bam and AAV-5'AP-Psh shown in Fig. 4 (densities of 1.367 and 1.366 g/ml,
respectively). The heavy DNA samples were purified from fractions with
higher densities than the dimer peaks shown in Fig. 4 to minimize
copurifying monomer vector DNA (densities of 1.401 g/ml for
AAV-3'AP-Bam and 1.404 g/ml for AAV-5'AP-Psh).
Cell culture and transduction.
PG13 cells (19)
and MHF2 normal human fibroblasts (repository no. GM05387; Coriell
Institute for Medical Research, Camden, N.J.) (27) were
propagated in Dulbecco's modified Eagle's medium supplemented with
heat-inactivated 10% fetal bovine serum at 37°C. Proviral target
sites were introduced into MHF2 cells by transduction with
pLAPSN-derived retroviral vector stocks, followed by selection in G418
(0.6 mg of active compound per ml). The polyclonal, transduced cell
populations were all derived from >104 independent
transduction events, as determined by plating dilutions of the
transduced cells for selection 1 day after exposure to retroviral
vector stocks and counting the number of G418-resistant colonies.
Multiplicities of infection (MOIs) of 
0.1 retroviral transducing
units per cell were used to ensure that most cells contained a single
retroviral vector provirus.
To measure AP gene correction rates in our standard assay, MHF2-derived
target cells were seeded on day 1 at 105 cells/well in
48-well plates, infected with AAV vectors on day 2 at an MOI of 2,000 vector particles/cell (assuming no increase in cell number), treated
with trypsin, and plated in two 6-cm-diameter dishes on day 3 (0.25 or
99.75% of cells). The 0.25% plating was stained on day 4 and used to
calculate the total number of viable cells per well (values ranged from
5 × 104 to 1.5 × 105 viable
cells/original well, and exposure to AAV vector stocks had no effect on
plating efficiencies). The 99.75% plating was cultured until day 9 and
then stained histochemically for AP expression as described previously
(9). Gene correction rates were calculated as the number of
AP+ foci/105 viable cells. In some experiments,
the day of AP staining was varied (Fig. 3A), the MOI was varied (Fig.
3B and Table 1), or the cells were treated for 20 h immediately
prior to the addition of vector with etoposide or hydroxyurea (Fig.
3C). Experiments included a control for each target cell population
that did not receive vector and always failed to produce
AP+ foci. In addition, each AAV vector used for gene
targeting failed to produce AP+ foci when used to infect
cells without target loci. These controls confirmed that all
AP+ foci represented gene targeting events rather than
reversion of target loci or targeting vector AP mutations.
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RESULTS |
AP gene correction strategy.
We used bicistronic retroviral
vectors to introduce mutant AP genes into normal human fibroblasts and
then corrected these mutations by gene targeting with AAV vectors (Fig.
1A). The retroviral vectors were based on pLAPSN (20), which
expresses (i) AP from the murine leukemia virus LTR promoter and (ii)
neomycin phosphotransferase from an internal SV40 promoter that served
as a selectable marker. Four different mutations (2- and 4-bp
deletions, as well as 5- and 8-bp insertions) were placed into the AP
gene of pLAPSN, and polyclonal G418-resistant fibroblast populations
containing >104 independent proviral insertions were
generated for each of these mutations. The high complexity of these
polyclonal populations allowed us to avoid position effects that might
otherwise influence gene targeting rates if individual clones were compared.
Five different AAV vectors were constructed, each of which contained an
incomplete portion of the wild-type AP gene (Fig. 1A). These vectors
were all homologous to the retroviral target loci except for the
mutation to be corrected, and they varied in length of homology to the
target site as well as positioning of the mutations to be corrected.
All of the AAV targeting vectors and retroviral target loci except
AAV-3'AP-(E/A) contained nonfunctional AP genes, and so correction of
the retroviral target mutations by AAV targeting vectors could be
scored histochemically as foci of AP+ purple cells (Fig. 1B
and C). The AAV-3'AP-(E/A) vector contained a partially functional AP
fragment, and so this vector was used only in vector packaging
experiments, not in gene targeting studies. We used this simple and
convenient AP targeting assay to study several parameters relevant to
gene targeting.
Effects of homology length and mutation type on gene correction
rates.
Fibroblast cell populations containing each of the four AP
mutations shown in Fig. 1A were infected with four different AAV targeting vectors, for a total of 16 possible combinations. We used our
standard AP correction assay, which consisted of infection with an AAV
targeting vector at an MOI of 2,000 particles/cell and then staining
for AP expression 7 days later (see Materials and Methods). Figure
2A shows the gene correction rates from
these experiments plotted for each AAV targeting vector. The total
homology between the targeting vectors and the target loci varied from 1,693 to 2,988 bp, and increasing homology length appeared to increase
targeting rates. However, even the shortest homology vector,
AAV-3'AP-Bam, was able to correct all four mutations, with targeting
rates only two- to fivefold lower than that of the longest homology
vector, AAV-3'AP-(B/A).
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FIG. 2.
Correction of AP mutations with different AAV targeting
vectors. Standard AP gene correction assays were performed on
polyclonal fibroblast populations containing each of the indicated AP
target mutations with AAV-3'AP-Bam, AAV-5'AP-Psh, AAV-5'AP-Bss, and
AAV-3'AP-(B/A). Each value represents the average from at least two
independent experiments. (A) Correction rates were plotted for each AAV
targeting vector, with the total length of homology each AAV vector
shared with the target locus indicated. The data are arranged with
increasing total homology length from left to right. (B) The data in
panel A are plotted relative to the short end homology extension for
each correction assay. The short end homology extension is the distance
of the corrected mutation from the end of the short side flanking
homology.
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A more dramatic effect of homology on gene targeting occurred when the
mutation being corrected was positioned near one end of the AAV vector
genome. Figure 2B plots the same gene correction values as in Fig. 2A
versus the distance of the corrected mutation from the end of the short
side flanking homology (called the short end homology extension). In
the case of the AAV-5'AP-Psh vector, two of the mutations had small
short end homology extensions of 0 or 37 bp, which resulted in
significantly lower targeting rates. All other data points had short
end homology extensions of >150 bp, and although there appeared to be
some increase in gene correction rates with longer extensions, these
effects were not consistent.
All four mutations could be corrected by AAV-mediated gene targeting.
If one excludes the two data points with short end homology extensions
below 150 bp, then the average gene correction rates were 13.8, 24.3, 33.4, and 41.1 (AP+ foci/105 cells) for
mutations 491+5, 1002+8, 3754, and 9612, respectively. Although
these correction rates are all within threefold of each other, it is
worth noting that both insertion mutations were corrected at lower
rates. A similar result was obtained when AAV vectors were used to
correct mutations in the neo gene, and a 1-bp insertion was
corrected less efficiently than a 1-bp deletion or several substitution
mutations (16). More controlled experiments with defined
insertions and deletions placed at the same position in target loci
will be required to determine if a true bias exists against correcting
insertion mutations.
Effects of different transduction conditions on AAV-mediated gene
targeting.
We studied the effects of time, MOI, and genotoxic
stress on gene targeting rates. As shown in Fig.
3A and B, correction of the AP3754
mutation by AAV-mediated gene targeting increased with longer times
after vector exposure and higher MOIs. In Fig. 3C, etoposide and
hydroxyurea were used to induce genotoxic stress prior to vector
exposure. Etoposide is an inhibitor of topoisomerase II which can
enhance enzyme-mediated DNA cleavage, and hydroxyurea prevents DNA
synthesis by inhibiting ribonucleotide reductase and depleting
deoxynucleotide pools. A transient exposure to these agents prior to
the addition of AAV vectors induces cellular functions involved in DNA
repair and/or synthesis that result in higher gene addition rates by
AAV vectors (26). Since some of these same cellular
functions might be involved in AAV-mediated gene targeting, we tested
their effects on correction of the AP3754 mutation. No effect on
gene targeting was observed with either drug, although parallel
experiments demonstrated a significant increase in gene addition rates
with the same treatments. In Fig. 3C, we adjusted MOIs to produce
similar numbers of AP+ foci in untreated gene addition and
gene targeting samples. At an MOI of 2,000 particles/cell, gene
addition still increased with genotoxic stress (14.8-fold increase for
etoposide treatment and 59-fold increase for hydroxyurea treatment).
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FIG. 3.
Effects of MOI, time, and genotoxic stress on gene
targeting. AP gene correction assays were performed on MHF2 fibroblasts
containing the AP3754 target mutation with the vector AAV-5'AP-Bss.
Experimental conditions were the same as our standard assay except for
the modifications noted below. (A) The length of time before
histochemical staining for AP expression was varied from 2 to 9 days
after exposure to the AAV vector. Each point represents the mean of
three independent measurements with standard error bars shown. (B) The
MOI was varied as indicated, and the experiment was performed with two
different AAV-5'AP-Bss stocks. (C) The cells were treated for 20 h
with medium containing etoposide (3 µM), hydroxyurea (40 mM), or no
drug immediately prior to exposure to the AAV vector. Parallel gene
addition transduction experiments were performed with the AAV-LAPSN
vector (28) under the same conditions except at an MOI of
100 instead of 2,000 vector genomes per cell (to generate similar
numbers of AP+ foci in untreated samples). Values shown are
the mean of three independent measurements with standard error bars
shown.
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Small vector genomes can be packaged as dimers.
We routinely
analyzed the genome content of AAV vector stocks by alkaline gel
electrophoresis of each CsCl gradient fraction and observed that in
some cases a dimer-sized vector genome band was present (see Materials
and Methods). Because these stocks were digested extensively with
micrococcal nuclease before being loaded on the gradients, these bands
represent encapsidated genomes. Packaged dimers appeared only when the
vector genome size was less than half the size of wild-type AAV (<2.5
kb). The dimer-sized genomes are clearly present in the gradients from
stocks of AAV-3'AP-Bam and AAV-5'AP-Psh, with genome sizes of 2,042 and
2,338 nucleotides, respectively, but were missing from stocks of
AAV-5'AP-Bss and AAV-3'AP(E/A), with genome sizes of 2,845 and 3,493 nucleotides, respectively (Fig. 4).
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FIG. 4.
Monomer and dimer vector genome forms are packaged in
particles with different densities. Vector stocks of AAV-3'AP-Bam,
AAV-5'AP-Psh, AAV-5'AP-Bss, and AAV-3'AP-(E/A) were purified on CsCl
gradients, fractions were collected, and the encapsidated DNA present
in each fraction was isolated, separated as single-stranded molecules
on alkaline agarose gels, transferred to nylon membranes, and probed
for vector sequences as described elsewhere (17). The sizes
in nucleotides (nt) of full-length, monomer vector genomes of each
vector are shown above the blots. The density of each fraction was
determined by refractometry. The results of this alkaline Southern blot
analysis are shown for each vector stock, with fractions increasing in
density from left to right. The first two lanes of blots A and B
represent 1.0 ng and 100 pg of standards consisting of the same DNA
fragment present in each vector genome but lacking the inverted
terminal repeats. The first lanes of blots C and D represent analogous
1.0-ng standards. These standards were mixed with lightest gradient
fraction before loading on the gel to adjust for salt concentrations.
The positions of vector genome dimers (d), monomers (m), and standards
(s) are indicated at the left of each blot. In the graphs below, the
amounts of monomer forms (squares) and dimer forms (circles) present in
each fraction were determined and plotted as a percentage of the total
genome content of the gradient (dimers and monomers) versus the density
(grams per milliliter of each fraction). Density values of the
fractions containing peak values of monomer and dimer forms are
indicated.
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The stocks containing dimer-sized genomes also contained monomer-sized
genomes, which were present across a broader range of densities. At low
densities, only monomers were present, while at high densities a second
peak containing both monomer- and dimer-sized genomes occurred. These
results demonstrate that the amount of encapsidated DNA contributes to
the density of vector virions, with a greater DNA content producing a
higher density particle. Similar results were noted previously in
wild-type AAV stocks containing variant genomes of different sizes
(4). Presumably the denser peak contained virions with
either one dimer-sized genome or two monomer-sized genomes, which would
produce very similar total DNA contents. A faint smear could typically
be seen extending from the lighter monomer peak to the denser dimer
peak in these gradients (Fig. 4A and B). This signal corresponds to vector DNA molecules with sizes between one and two complete genome lengths, with the sizes approaching that of a complete dimer as the
density increased. A similar phenomenon can be seen in Fig. 4C, where a
smear extends above the monomer peak and increases in size at higher
densities. No true dimer band is observed here, since full-length
dimers of AAV-5'AP-Bss would be larger than the wild-type viral genome
and exceed the packaging capacity of AAV.
Packaged vector dimers are inverted repeats with hairpins at either
end.
The most likely structure of the dimer-sized genomes present
in vector stocks would be head-to-head or tail-to-tail inverted dimers
formed by DNA replication extending from the 3'-terminal repeat
(13, 35). These molecules should base pair along most of
their length and contain a covalently closed hairpin at the terminal
repeat where DNA synthesis began. Analogous molecules may also be
present in wild-type AAV stocks that contain small, "snap-back"
variant genomes (4). Because the dimers form double-stranded molecules, they can be efficiently digested with restriction
endonucleases, allowing a more detailed analysis.
We isolated encapsidated DNA from heavy and light CsCl gradient
fractions of AAV-3'AP-Bam and AAV-5'AP-Psh vector stocks. The heavy
fractions contained dimer-sized genomes as well as monomer-sized genomes, and the light fractions contained only monomer-sized genomes
(Fig. 4A and B). The DNA molecules present in these fractions were
digested under neutral conditions with restriction endonucleases that
have sites located asymmetrically in the vector genome. The resulting
restriction fragments were separated as single strands on alkaline
agarose gels, transferred to nylon membranes, and probed for internal
vector sequences. In each case the presence of head-to-head or
tail-to-tail dimers should produce characteristic restriction
fragments, both for dimers containing a closed hairpin at the left
terminal repeat (left dimer) and for dimers containing a closed hairpin
at the right terminal repeat (right dimer). Complementary monomer
molecules could also hybridize to some extent under these conditions
and produce specific restriction fragments.
The results of this analysis, including the structures of the left and
right dimers and their predicted restriction digestion products, are
shown in Fig. 5. The heavy gradient
fractions of AAV-3'AP-Bam and AAV-5'AP-Psh produced the expected
restriction fragments of left and/or right dimers for each set of
enzymes, as well as the fragments expected from paired monomers. The
dimer digestion products were absent from the light gradient fractions, while the paired monomer restriction fragments were still present. Because the restriction sites were located asymmetrically in the vector
genome, each enzyme produced a large fragment for only one dimer
orientation (left or right) and a small fragment for the other
orientation. In most cases, only the larger fragment could be detected
due to preferential hybridization with the probe. However, the use of
different enzymes allowed us to demonstrate the presence of both left
and right dimer forms in each vector stock. For example, in the case of
AAV-3'AP-Bam, the 2,781-nucleotide fragment produced by
AvrII was due to the right dimer, while the 3,383-nucleotide
fragment produced by PstI was from the left dimer. Digestion
of the AAV-3'AP-Bam heavy gradient fraction with EagI produced fragments due to both left (2,291-nucleotide) and right (1,543-nucleotide) dimer forms in the same reaction. It is also possible that some dimers have closed hairpins at both ends, since these molecules have been shown to arise during AAV replication (23, 37).
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FIG. 5.
Restriction analysis of vector dimer forms. Encapsidated
vector DNA molecules from light (L) and heavy (H) CsCl gradient
fractions of AAV-3'AP-Bam and AAV-5'AP-Psh vector stocks were purified,
digested with the indicated restriction endonucleases, and analyzed by
alkaline gel electrophoresis of denatured molecules. (A and C) Southern
blot analysis of these digests for AAV-3'AP-Bam and AAV-5'AP-Psh,
respectively. Undigested samples were also run on each gel. The sizes
of the major single-stranded digestion products and of full-length
monomer and dimer genome forms are shown in nucleotides at the left of
each blot. Denatured plasmid restriction fragments of known size were
run on each gel as size standards (not shown). (B and D) Each box shows
the predicted structure and size (in total nucleotides [nt] of
denatured molecules) of the predicted left dimer, right dimer, and
paired monomer forms present in undigested DNA samples and samples
digested with the indicated restriction endonucleases for AAV-3'AP-Bam
and AAV-5'AP-Psh, respectively. Left and right dimer forms differ in
the location of covalently closed hairpin ends.
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Full-length monomer genomes were present in both the light and heavy
gradient fractions, and only a portion of these could be digested with
restriction enzymes. The digested monomers presumably had hybridized
with complementary monomers during the restriction digestion, allowing
efficient cleavage of double-stranded molecules. In contrast, most of
the full-length dimer forms present in the untreated samples were
completely digested by restriction enzymes. This argues against the
presence of packaged head-to-tail dimers (direct repeats) in these
vector stocks, since these molecules are not self-complementary, and
based on the results of monomer digestion, only a portion of
single-stranded dimer genomes would be expected to hybridize with
complementary dimers during restriction digestion. Single-stranded,
head-to-tail dimer forms would therefore be expected to be largely
resistant to restriction digestion and remain as full length dimers.
Gene targeting rates correlate with monomer vector genome
levels.
We compared gene correction rates using different CsCl
gradient fractions of AAV-3'AP-Bam and AAV-5'AP-Psh to determine if dimer or monomer genomes were preferentially used for gene targeting (Table 1). Although the analysis was
complicated by the fact that all fractions contained monomer genomes,
no significant contribution to gene targeting could be attributed to
the presence of dimer genomes. This is most clearly demonstrated by
comparing the gene correction rates of AAV-3'AP-Bam light and heavy
fractions. An increase in the dimer MOI from 100 genomes/cell (light
fraction) to 1,500 genomes/cell (heavy fraction) in the presence of a
constant amount of monomer genomes did not increase gene correction
rates. The conclusion that monomers are the preferred substrates for gene targeting is also supported by the data in Fig. 2, since the
larger AAV-5'AP-Bss and AAV-3'AP-(B/A) vectors tended to produce higher
gene correction rates, despite the absence of dimer forms in these
stocks (the MOIs in Fig. 2 were all based on monomer forms).
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DISCUSSION |
In this report we have described an AP gene correction assay to
study several parameters that influence AAV-mediated gene targeting.
The assay is simple to perform, allows for sequence manipulations of
both the target locus and targeting vector, and in principle can be
applied to any cell line that can be transduced by retroviral vectors.
By assaying polyclonal cell populations with target loci at multiple
chromosomal locations, we were able to avoid position effects that
might influence gene targeting and compare correction rates of
different AP mutations. A major advantage of the AP system over a
similar approach that we recently described based on correction of
neo gene mutations (16) is that there is no
selective pressure for corrected loci, and gene targeting is assayed
instead by histochemical staining. A disadvantage of this system is
that clones containing corrected loci cannot easily be separated from
nontargeted cells and expanded for DNA analysis. However, our previous
HPRT and neo gene targeting experiments have
shown that >90% of targeted loci contain the expected genetic change
with no secondary mutations (16, 27), and so we assume that
most AP+ foci represent accurate gene correction events.
A comparison of AP gene correction rates obtained with different AAV
vectors suggests that central positioning of the modification being
introduced and increasing total homology with the target locus will
lead to optimal gene targeting rates. Although our data set does not
establish the ideal length of homology extension beyond the introduced
modification, there were dramatic decreases in AP gene correction rates
when this distance was 37 bp or less (Fig. 2B). The effects of total
homology length are best illustrated by comparing the AP correction
rates obtained with the smallest (AAV-3'AP-Bam; 1,693-bp homology) and
largest (AAV-3'AP-[B/A]; 2,988-bp homology) AAV vectors. In these
cases a 1.8-fold increase in total homology increased gene targeting
rates two- to fivefold (Fig. 2A). A dependence on homology length was
also observed with conventional gene targeting approaches based on
electroporation or transfection of plasmid constructs (5,
36). However, the absolute targeting frequencies obtained by
conventional methods were approximately 10
6 with 2- to
4-kb constructs (5), compared to 103 for
AAV-mediated gene targeting (16, 27) (Fig. 3B).
To date, we have used AAV vectors to introduce several different types
of genetic modifications, including substitutions (1 and 2 bp),
insertions (1, 2, and 4 bp), and deletions (1, 5, 8, and 14 bp) at
three different target loci (neo, HPRT, and AP
[references 16 and 27 and this
study]). The only modifications that were introduced at lower
frequencies were a 1-bp deletion in the neo gene at about
10-fold-lower rates (16) and 5- or 8-bp deletions in the AP
gene at 2- to 3-fold lower rates (Fig. 2). Thus, small insertion
mutations (which are corrected by introducing deletions) may be more
difficult to correct than other types of mutations. Although the basis
for these differences is not understood, our results suggest that many
of the mutations responsible for genetic diseases will be amenable to
gene correction by AAV vectors. We have not determined if larger
modifications can be efficiently introduced; however, the AAV packaging
capacity of <5 kb will ultimately limit the size of insertion
modifications, especially if substantial homology to the target locus
must be included in the vector genome.
Transduction conditions are known to have significant effects on gene
addition by AAV vectors, including time after vector exposure, MOI, and
genotoxic stress (1, 8, 11, 12, 14, 15, 26, 28, 34).
Similarly, we found that both longer times and higher MOIs also
increased gene targeting by AAV vectors. A clear dependence on MOI was
previously noted for HPRT and neo gene targeting
as well (16, 27). The increase over time is presumably
related to the persistence of AAV vector genomes as single-stranded,
episomal molecules in the nuclei of normal human fibroblasts
(28) and suggests that these genomes continue to participate
in gene targeting reactions long after the initial infection with
vector particles.
In contrast to its effects on gene addition, genotoxic stress induced
by etoposide or hydroxyurea had no effect on gene targeting by AAV
vectors. These treatments are thought to increase gene addition by
promoting integration and/or second-strand synthesis of the vector
genome (1, 8, 10, 26). Etoposide introduces chromosomal
breaks that could serve as vector integration sites, and the removal of
hydroxyurea allows nucleotide precursor pools to reaccumulate, which
may promote second-strand synthesis. Apparently neither of these
processes nor other cellular DNA repair and/or synthesis functions
induced by genotoxic stress are involved in gene targeting. This is
consistent with a model in which single-stranded, episomal vector
genomes, rather than integrated or double-stranded forms, participate
in the gene targeting reaction. The monomer and dimer data in Table 1
also support this model, since the double-stranded vector dimers did
not appear to contribute to gene targeting. Given that different
mechanisms are used, it may be possible to identify conditions that
favor gene targeting without increasing gene addition and thereby
increase the ratio of targeted to nontargeted transduction events. A
dependence on single-stranded vector genomes also suggests that
annealing of complementary input vector genomes may limit gene
targeting in some situations.
Our observation that small vector genomes can be packaged as dimers is
consistent with prior studies suggesting that the AAV packaging
capacity is approximately 5 kb of DNA (21). When vector genomes are greater than one-half wild-type size (>2.5 kb),
single-stranded, linear monomers are packaged, as with wild-type AAV.
Smaller vector genomes can be packaged in relatively light capsids as
single-stranded linear monomers or in heavier capsids as dimers or
pairs of linear monomers (based on the equivalent densities of these
types of particles). The encapsidated dimers are head-to-head or
tail-to-tail repeats with covalently closed hairpins present at a
terminus. These dimers are expected to form double-stranded molecules
throughout their length, except for the small loop regions of the
terminal repeats. However, this does not demonstrate that
single-stranded DNA is not required for packaging, since these dimers
may be encapsidated as unwound, single-stranded molecules. A previous
study also concluded that AAV vector particles may contain two copies
of small genomes, but no encapsidated dimer forms were described
(6).
The encapsidated genome dimers are expected to be produced as
replication intermediates in the presence of the AAV Rep proteins and
adenovirus helper functions (13, 35). Packaging of these dimers may be associated with replication, since AAV particle assembly
is linked to viral DNA synthesis (22, 39). In one model for
packaging, preassembled AAV capsids incorporate vector genomes that
sometimes exceed the packaging capacity, which results in portions of
the vector genome remaining outside the capsid, and these exposed
genome portions are subsequently removed by nucleases (6).
This may result in the smear seen on some alkaline gels of
intermediate-sized genomes packaged in particles of increasing density
(Fig. 4).
| |
ACKNOWLEDGMENTS |
We thank Rong Dong, John Weller, and Richard Newton for technical assistance.
This work was supported by grants from the March of Dimes Birth Defects
Foundation, Cystic Fibrosis Foundation, and National Institutes of Health.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Division of
Hematology and Markey Molecular Medicine Center, University of
Washington, Box 357720, Seattle, WA 98195. Phone: (206) 616-4562. Fax:
(206) 616-8298. E-mail: drussell{at}u.washington.edu.
| |
REFERENCES |
| 1.
|
Alexander, I. E.,
D. W. Russell, and A. D. Miller.
1994.
DNA-damaging agents greatly increase the transduction of nondividing cells by adeno-associated virus vectors.
J. Virol.
68:8282-8287[Abstract/Free Full Text].
|
| 2.
|
Bertran, J.,
J. L. Miller,
Y. Yang,
A. Fenimore Justman,
F. Rueda,
E. F. Vanin, and A. W. Nienhuis.
1996.
Recombinant adeno-associated virus-mediated high-efficiency, transient expression of the murine cationic amino acid transporter (ecotropic retroviral receptor) permits stable transduction of human HeLa cells by ecotropic retroviral vectors.
J. Virol.
70:6759-6766[Abstract/Free Full Text].
|
| 3.
|
Bertran, J.,
Y. Yang,
P. Hargrove,
E. F. Vanin, and A. W. Nienhuis.
1998.
Targeted integration of a recombinant globin gene adeno-associated viral vector into human chromosome 19.
Ann. N. Y. Acad. Sci.
850:163-177[Abstract/Free Full Text].
|
| 4.
|
de la Maza, L. M., and B. J. Carter.
1980.
Molecular structure of adeno-associated virus variant DNA.
J. Biol. Chem.
255:3194-3203[Abstract/Free Full Text].
|
| 5.
|
Deng, C., and M. R. Capecchi.
1992.
Reexamination of gene targeting frequency as a function of the extent of homology between the targeting vector and the target locus.
Mol. Cell. Biol.
12:3365-3371[Abstract/Free Full Text].
|
| 6.
|
Dong, J. Y.,
P. D. Fan, and R. A. Frizzell.
1996.
Quantitative analysis of the packaging capacity of recombinant adeno-associated virus.
Hum. Gene Ther.
7:2101-2112[Medline].
|
| 7.
|
Duan, D.,
P. Sharma,
J. Yang,
Y. Yue,
L. Dudus,
Y. Zhang,
K. J. Fisher, and J. F. Engelhardt.
1998.
Circular intermediates of recombinant adeno-associated virus have defined structural characteristics responsible for long-term episomal persistence in muscle tissue.
J. Virol.
72:8568-8577[Abstract/Free Full Text].
|
| 8.
|
Ferrari, F. K.,
T. Samulski,
T. Shenk, and R. J. Samulski.
1996.
Second-strand synthesis is a rate-limiting step for efficient transduction by recombinant adeno-associated virus vectors.
J. Virol.
70:3227-3234[Abstract].
|
| 9.
|
Fields Berry, S. C.,
A. L. Halliday, and C. L. Cepko.
1992.
A recombinant retrovirus encoding alkaline phosphatase confirms clonal boundary assignment in lineage analysis of murine retina.
Proc. Natl. Acad. Sci. USA
89:693-697[Abstract/Free Full Text].
|
| 10.
|
Fisher, K. J.,
G. P. Gao,
M. D. Weitzman,
R. DeMatteo,
J. F. Burda, and J. M. Wilson.
1996.
Transduction with recombinant adeno-associated virus for gene therapy is limited by leading-strand synthesis.
J. Virol.
70:520-532[Abstract].
|
| 11.
|
Fisher, K. J.,
K. Jooss,
J. Alston,
Y. Yang,
S. E. Haecker,
K. High,
R. Pathak,
S. E. Raper, and J. M. Wilson.
1997.
Recombinant adeno-associated virus for muscle directed gene therapy.
Nat. Med.
3:306-312[CrossRef][Medline].
|
| 12.
|
Flannery, J. G.,
S. Zolotukhin,
M. I. Vaquero,
M. M. LaVail,
N. Muzyczka, and W. W. Hauswirth.
1997.
Efficient photoreceptor-targeted gene expression in vivo by recombinant adeno-associated virus.
Proc. Natl. Acad. Sci. USA
94:6916-6921[Abstract/Free Full Text].
|
| 13.
|
Hauswirth, W. W., and K. I. Berns.
1977.
Origin and termination of adeno-associated virus DNA replication.
Virology
78:488-499[CrossRef][Medline].
|
| 14.
|
Hermonat, P. L., and N. Muzyczka.
1984.
Use of adeno-associated virus as a mammalian DNA cloning vector: transduction of neomycin resistance into mammalian tissue culture cells.
Proc. Natl. Acad. Sci. USA
81:6466-6470[Abstract/Free Full Text].
|
| 15.
|
Herzog, R. W.,
J. N. Hagstrom,
S. H. Kung,
S. J. Tai,
J. M. Wilson,
K. J. Fisher, and K. A. High.
1997.
Stable gene transfer and expression of human blood coagulation factor IX after intramuscular injection of recombinant adeno-associated virus.
Proc. Natl. Acad. Sci. USA
94:5804-5809[Abstract/Free Full Text].
|
| 16.
|
Inoue, N.,
R. K. Hirata, and D. W. Russell.
1999.
High-fidelity correction of mutations at multiple chromosomal positions by adeno-associated virus vectors.
J. Virol.
73:7376-7380[Abstract/Free Full Text].
|
| 17.
|
Inoue, N., and D. W. Russell.
1998.
Packaging cells based on inducible gene amplification for the production of adeno-associated virus vectors.
J. Virol.
72:7024-7031[Abstract/Free Full Text].
|
| 18.
|
Malik, P.,
S. A. McQuiston,
X. J. Yu,
K. A. Pepper,
W. J. Krall,
G. M. Podsakoff,
G. J. Kurtzman, and D. B. Kohn.
1997.
Recombinant adeno-associated virus mediates a high level of gene transfer but less efficient integration in the K562 human hematopoietic cell line.
J. Virol.
71:1776-1783[Abstract].
|
| 19.
|
Miller, A. D.,
J. V. Garcia,
N. von Suhr,
C. M. Lynch,
C. Wilson, and M. V. Eiden.
1991.
Construction and properties of retrovirus packaging cells based on gibbon ape leukemia virus.
J. Virol.
65:2220-2224[Abstract/Free Full Text].
|
| 20.
|
Miller, D. G.,
R. H. Edwards, and A. D. Miller.
1994.
Cloning of the cellular receptor for amphotropic murine retroviruses reveals homology to that for gibbon ape leukemia virus.
Proc. Natl. Acad. Sci. USA
91:78-82[Abstract/Free Full Text].
|
| 21.
|
Muzyczka, N.
1992.
Use of adeno-associated virus as a general transduction vector for mammalian cells.
Curr. Top. Microbiol. Immunol.
158:97-129[Medline].
|
| 22.
|
Myers, M. W., and B. J. Carter.
1980.
Assembly of adeno-associated virus.
Virology
102:71-82[CrossRef][Medline].
|
| 23.
|
Ni, T. H.,
W. F. McDonald,
I. Zolotukhin,
T. Melendy,
S. Waga,
B. Stillman, and N. Muzyczka.
1998.
Cellular proteins required for adeno-associated virus DNA replication in the absence of adenovirus coinfection.
J. Virol.
72:2777-2787[Abstract/Free Full Text].
|
| 24.
|
Palombo, F.,
A. Monciotti,
A. Recchia,
R. Cortese,
G. Ciliberto, and N. La Monica.
1998.
Site-specific integration in mammalian cells mediated by a new hybrid baculovirus-adeno-associated virus vector.
J. Virol.
72:5025-5034[Abstract/Free Full Text].
|
| 25.
|
Recchia, A.,
R. J. Parks,
S. Lamartina,
C. Toniatti,
L. Pieroni,
F. Palombo,
G. Ciliberto,
F. L. Graham,
R. Cortese,
N. La Monica, and S. Colloca.
1999.
Site-specific integration mediated by a hybrid adenovirus/adeno-associated virus vector.
Proc. Natl. Acad. Sci. USA
96:2615-2620[Abstract/Free Full Text].
|
| 26.
|
Russell, D. W.,
I. E. Alexander, and A. D. Miller.
1995.
DNA synthesis and topoisomerase inhibitors increase transduction by adeno-associated virus vectors.
Proc. Natl. Acad. Sci. USA
92:5719-5723[Abstract/Free Full Text].
|
| 27.
|
Russell, D. W., and R. K. Hirata.
1998.
Human gene targeting by viral vectors.
Nat. Genet.
18:325-330[CrossRef][Medline].
|
| 28.
|
Russell, D. W.,
A. D. Miller, and I. E. Alexander.
1994.
Adeno-associated virus vectors preferentially transduce cells in S phase.
Proc. Natl. Acad. Sci. USA
91:8915-8919[Abstract/Free Full Text].
|
| 29.
|
Rutledge, E. A., and D. W. Russell.
1997.
Adeno-associated virus vector integration junctions.
J. Virol.
71:8429-8436[Abstract].
|
| 30.
|
Ryan, J. H.,
S. Zolotukhin, and N. Muzyczka.
1996.
Sequence requirements for binding of Rep68 to the adeno-associated virus terminal repeats.
J. Virol.
70:1542-1553[Abstract].
|
| 31.
|
Sambrook, J.,
E. F. Fritsch, and T. Maniatis.
1989.
Molecular cloning: a laboratory manual, 2nd ed.
Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
|
| 32.
|
Samulski, R. J.,
L. S. Chang, and T. Shenk.
1989.
Helper-free stocks of recombinant adeno-associated viruses: normal integration does not require viral gene expression.
J. Virol.
63:3822-3828[Abstract/Free Full Text].
|
| 33.
|
Shelling, A. N., and M. G. Smith.
1994.
Targeted integration of transfected and infected adeno-associated virus vectors containing the neomycin resistance gene.
Gene Ther.
1:165-169[Medline].
|
| 34.
|
Snyder, R. O.,
C. H. Miao,
G. A. Patijn,
S. K. Spratt,
O. Danos,
D. Nagy,
A. M. Gown,
B. Winther,
L. Meuse,
L. K. Cohen,
A. R. Thompson, and M. A. Kay.
1997.
Persistent and therapeutic concentrations of human factor IX in mice after hepatic gene transfer of recombinant AAV vectors.
Nat. Genet.
16:270-276[CrossRef][Medline].
|
| 35.
|
Straus, S. E.,
E. D. Sebring, and J. A. Rose.
1976.
Concatemers of alternating plus and minus strands are intermediates in adeno-associated virus DNA synthesis.
Proc. Natl. Acad. Sci. USA
73:742-746[Abstract/Free Full Text].
|
| 36.
|
Thomas, K. R., and M. R. Capecchi.
1987.
Site-directed mutagenesis by gene targeting in mouse embryo-derived stem cells.
Cell
51:503-512[CrossRef][Medline].
|
| 37.
|
Ward, P., and K. I. Berns.
1991.
In vitro rescue of an integrated hybrid adeno-associated virus/simian virus 40 genome.
J. Mol. Biol.
218:791-804[CrossRef][Medline].
|
| 38.
|
Yang, C. C.,
X. Xiao,
X. Zhu,
D. C. Ansardi,
N. D. Epstein,
M. R. Frey,
A. G. Matera, and R. J. Samulski.
1997.
Cellular recombination pathways and viral terminal repeat hairpin structures are sufficient for adeno-associated virus integration in vivo and in vitro.
J. Virol.
71:9231-9247[Abstract].
|
| 39.
|
Zhou, X., and N. Muzyczka.
1998.
In vitro packaging of adeno-associated virus DNA.
J. Virol.
72:3241-3241[Abstract/Free Full Text].
|
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Abstract
Introduction
