J Virol, January 1998, p. 420-427, Vol. 72, No. 1
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Role of the Adenovirus DNA-Binding Protein in In
Vitro Adeno-Associated Virus DNA Replication
Peter
Ward,1,*
Frank B.
Dean,1,2
Michael
E.
O'Donnell,1,2 and
Kenneth I.
Berns1
Department of Microbiology, Hearst
Microbiology Research Center, Cornell University Medical
College,1 and
Laboratory of DNA
Replication, Rockefeller University,2 New York,
New York 10021
Received 3 July 1997/Accepted 1 October 1997
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ABSTRACT |
A basic question in adeno-associated virus (AAV) biology has been
whether adenovirus (Ad) infection provided any function which directly
promoted replication of AAV DNA. Previously in vitro assays for AAV DNA
replication, using linear duplex AAV DNA as the template, uninfected or
Ad-infected HeLa cell extracts, and exogenous AAV Rep protein,
demonstrated that Ad infection provides a direct helper effect for AAV
DNA replication. It was shown that the nature of this helper effect was
to increase the processivity of AAV DNA replication. Left unanswered
was the question of whether this effect was the result of cellular
factors whose activity was enhanced by Ad infection or was the result
of direct participation of Ad proteins in AAV DNA replication. In this
report, we show that in the in vitro assay, enhancement of processivity occurs with the addition of either the Ad DNA-binding protein (Ad-DBP)
or the human single-stranded DNA-binding protein (replication protein A
[RPA]). Clearly Ad-DBP is present after Ad infection but not before,
whereas the cellular level of RPA is not apparently affected by Ad
infection. However, we have not measured possible modifications of RPA
which might occur after Ad infection and affect AAV DNA replication.
When the substrate for replication was an AAV genome inserted into a
plasmid vector, RPA was not an effective substitute for Ad-DBP.
Extracts supplemented with Ad-DBP preferentially replicated AAV
sequences rather than adjacent vector sequences; in contrast, extracts
supplemented with RPA preferentially replicated vector sequences.
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INTRODUCTION |
A central feature of
adeno-associated virus (AAV) biology is that productive infection in
cell culture requires coinfection by a helper virus (either adenovirus
[Ad] or herpesvirus) (reviewed in reference 3).
The requirement for Ad or herpesvirus is not absolute, however, since
treatment of cells with genotoxic agents will render the cells
permissive for the production of small amounts of AAV
(51-53). Presumably, therefore, Ad and herpesvirus do not provide any unique functions which cannot be provided, under some conditions, by the cell infected with AAV alone. AAV gene expression is
enhanced by Ad infection (39), and open reading frame 6 of the E4 region of Ad is important for the conversion of the
single-stranded AAV genome into a double-stranded form which is the
substrate for subsequent steps in DNA replication (12a,
12b). It has been unknown whether Ad infection makes a further,
direct contribution to AAV DNA replication.
Ni et al. (34) developed an in vitro AAV DNA replication
assay in which a double-stranded AAV substrate with both ends in a
closed hairpin configuration replicated in an extract from Ad-infected cells which had been supplemented with the AAV Rep protein. They saw
little or no replication in an extract from uninfected HeLa cells. We
have reported an assay using open-ended linear duplex DNA in which an
extract from uninfected HeLa cells supplemented with Rep protein did
replicate AAV DNA (47). However, if an extract from
Ad-infected cells was substituted for the uninfected cell extract,
full-length replication was substantially enhanced and there was
significantly less defective product (46). There are two
conclusions from these reports. The first is that if the need for AAV
gene expression and the conversion of single-stranded to
double-stranded DNA are bypassed, AAV DNA replication can occur in
vitro. The second conclusion is that Ad infection makes an additional
direct contribution to AAV DNA replication which substantially increases the production of full-length AAV DNA. We have further demonstrated that the difference between the two extracts was that the
Ad-infected extract provided a helper function related to elongation
during replication (46).
This enhanced elongation could be from either stimulation of cellular
factors or the direct contribution of an Ad-encoded protein. With
respect to the latter possibility, it has been shown previously, in
vivo, that among the Ad proteins required for Ad DNA replication, the
DNA polymerase and the terminal protein make no contribution to AAV DNA
replication. The data on the Ad DNA-binding protein (Ad-DBP) have been
ambiguous (reviewed in reference 5). AAV DNA
replication is thought to occur by a single-stranded displacement mechanism. The AAV genome contains an inverted terminal repeat which
can form a hairpin and thereby serve as the primer to initiate synthesis. At the end of each round of replication, the newly made
strand hairpins on itself to initiate a subsequent round of replication
(reviewed in reference 3). Since the viral genome is
single stranded, the first round of replication produces a matching
second strand but all subsequent rounds involve the genome-length displacement of the nontemplate strand. This is a feature not shared by
the replication mechanism of the host cell, which is thought to involve
simultaneous replication of both strands. In our investigation of the
failure of processivity in in vitro AAV DNA replication in extracts
from uninfected cells, it appeared that the elongating strands were
dissociating prematurely from the template followed by template strand
switch to the displaced strand (46). Ad DNA replication also
occurs by a single-stranded displacement mechanism (reviewed in
reference 41). Thus, in its requirement to maintain
an extensive length of displaced single-stranded DNA in solution, AAV
DNA replication shares a basic similarity with Ad DNA replication. It
seems possible that the direct helper effect of Ad may be related to
this common feature.
In this report, we show that the component of the Ad-infected cell
extract which supports processive replication of AAV DNA is Ad-DBP,
which has been shown to be necessary for the processive replication of
Ad DNA (25). Additionally we show that addition of excessive
amounts of the human single-stranded DNA-binding protein (replication
protein A [RPA]) to an extract from uninfected cells can also support
processive replication. Presumably it is RPA which supports AAV DNA
replication in the absence of Ad-DBP.
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MATERIALS AND METHODS |
Cell extracts.
Replication extracts from uninfected HeLa
cells and from HeLa cells infected with Ad were prepared as described
previously (16, 45) in a modification of a procedure
originally described by Wobbe et al. (50). Whole-cell
lysates were made by spinning down cells and freezing, thawing, then
mixing them with an equal volume of buffer L (100 mM Tris [pH 6.8],
200 mM dithiothreitol, 4% sodium dodecyl sulfate, 0.2% bromophenol
blue, 20% glycerol, 200 µg of phenylmethylsulfonyl fluoride per ml).
The mixture was boiled for 5 min and spun for 10 min at 12,000 × g, and the supernatant was analyzed by polyacrylamide gel
electrophoresis and Western blotting.
Proteins.
Ad-DBP purified from infected cells was a kind
gift of G. Droguette and M. Horwitz. Ad-DBP made in a baculovirus
expression system was a generous gift of R. Hay (29).
Escherichia coli single-stranded DNA-binding protein (SSB)
(48) and human proliferating cell nuclear antigen (3,000 U/mg of protein [17]) were purified as described
previously. RPA was purified as described previously (19)
both from HeLa cells and from E. coli expressing p11d-tRPA (15). DNA polymerase delta (phosphocellulose pool, 40 U/mg
of protein; heparin-Sepharose pool, 850 U/mg of protein) and DNA replication factor C (phosphocellulose pool, 320 U/mg of protein; final
fraction, 5,400 U/mg of protein) were purified by a modification of the
method of Lee et al. (23).
In vitro DNA replication.
In vitro DNA replication and
analysis of radioactively labeled replication products by gel
electrophoresis were performed as described previously (47).
Reactions were performed with approximately 100 µg of cellular
protein except where noted otherwise. Substrate was a BglII
digest of plasmid pAV2, except in one experiment where it was
undigested pAV2, as noted. pAV2 has been described elsewhere
(22). It consists of the entire genome of AAV2 inserted into
a pBR322 derivative by means of BglII linkers. AAV Rep68 was
expressed in and purified from E. coli either as a
maltose-binding protein-Rep fusion protein (8) or as a
His-tagged Rep68 fusion (consisting of the entire Rep68 peptide
sequence with six histidine residues fused to the amino terminus
[23a]). PhosphorImager (Molecular Dynamics) scanning
of dried gels was performed with ImageQuant version 3.0 software.
Antibodies.
Monoclonal antibody (MAb) 37-3, a MAb to Ad-DBP,
was a generous gift of Doug Brough (9). MAb RPA34-19 was
purchased from Oncogene Research Products (catalog no. NA18).
Immunodepletions.
Equal volumes of cellular extract (20 mg/ml) and MAb 37-3 (0.9 mg/ml in 10 mM NaPO4 with 0.02%
sodium azide) were mixed. The mixture was made 50 mM in NaCl and shaken
at 0°C for 1 h. Protein G-agarose beads (2.5 mg of protein per
ml; Calbiochem catalog no. 539207) were added to 10% of the volume.
The mixture was shaken at 0°C for an additional hour and spun for 3 min at 12,000 × g, and the supernatant was brought to
10% glycerol and stored at 
80°C.
Western blots.
Proteins were separated by sodium dodecyl
sulfate-polyacrylamide gel electrophoresis on 12% gels and transferred
to nitrocellulose. Filters were blocked by incubation in 50 mM Tris (pH
7.6)-0.2 M NaCl-5% Carnation nonfat dry milk-0.05% Tween 20 and
then incubated with 10 µg of MAb RPA34-19 in 10 ml of the same
buffer. The second antibody was anti-mouse immunoglobulin G (IgG)
conjugated to alkaline phosphatase (Sigma A-4312) used at 1:10,000
dilution.
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RESULTS |
Supplementation of AAV DNA replication in uninfected cell extracts
with extracts from Ad-infected cells.
Previously we had shown that
extracts from Ad-infected cells were able to replicate AAV DNA with
much greater processivity than extracts from uninfected cells. To
identify the components of the Ad extract responsible for this helper
activity, extracts from Ad-infected cells were mixed with extracts from
uninfected cells. As the ratio of uninfected to infected extract was
increased, there was an increase in full-length replication (Fig.
1). Addition of increasing amounts of the
extract from Ad-infected cells led to a geometric increase in synthesis
of full-length DNA, which was suggestive of either an inhibitor in the
uninfected extract or a positive factor(s) in the extract from
Ad-infected cells which acts cooperatively. An inhibitor seemed less
likely because addition of uninfected cell extract to a final fraction
of 0.25 did not decrease the level of replication below that seen using extracts from Ad-infected cells (data not shown). This result suggested
it would be reasonable to search for helper functions by adding
purified known replication components or fractionated Ad extract to the
uninfected cell extract and assaying for an increase in full-length
replication.
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FIG. 1.
Mixing extracts from uninfected and Ad-infected cells.
Reactions were performed and analyzed as described in Materials and
Methods. DNA replications were performed with various amounts of
extract protein from either Ad-infected or uninfected cells. Shown are
relative amounts of protein from each extract versus relative amounts
of incorporation into full-length DNA.
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Supplementation of AAV DNA replication in uninfected cell extracts
with purified human DNA replication proteins.
Since the only
nonstructural proteins supplied by AAV are the Rep proteins, AAV DNA
replication must involve cellular and/or adenovirus replication
proteins. AAV DNA replication is thought to proceed by a
single-stranded displacement mechanism (reviewed in reference
3). The major cellular proteins which participate in
the leading-strand component of cellular DNA synthesis (which may be
similar to replication by single-stranded displacement) have been
identified and cloned. Purified RPA, replication factor C,
proliferating cell nuclear antigen and polymerase delta were added to
an extract from uninfected HeLa cells in the replication assay (Fig.
2A). Reactions were performed as
described in Materials and Methods, using linear duplex AAV DNA as the
template and 20 µg of extract from uninfected cells. A substantial
enhancement was seen only in reactions to which RPA (also known as
human single-stranded DNA-binding protein) had been added (lanes 6 and
7). The enhancement with the protein which had been produced in an
E. coli expression system was indistinguishable from the
enhancement using RPA which had been purified from HeLa cells.
Interestingly, E. coli single-stranded binding protein (SSB)
(lane 5) gave only a very slight enhancement of full-length
replication. Assays performed with suboptimal amounts of added RPA
which were then supplemented with added E. coli SSB also
demonstrated the inability of E. coli SSB to enhance
replication in this system (data not shown).
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FIG. 2.
(A) Replication of AAV DNA in an uninfected extract to
which purified human DNA replication proteins were added. Reactions
were performed as described in Materials and Methods, using an extract
from uninfected HeLa cells except that only 20 µg of cellular protein
was included in the reaction. Reactions were supplemented with various
replication proteins: lane 1, 0.04 µg of replication factor C (final
pool); lane 2, 1.0 µg of replication factor C (phosphocellulose
pool); lane 3, 0.2 µg of polymerase delta (heparin-Sepharose pool);
lane 4, 1.25 µg of polymerase delta (phosphocellulose pool); lane 5, 0.8 µg of E. coli SSB; lane 6, 1.0 µg of RPA expresseed
in E. coli; lane 7, 0.25 µg of RPA from HeLa cells; lane
8, 0.1 µg of proliferating cell nuclear antigen; lane 9, no added
protein. (B) MboI susceptibility of replication products.
Lanes 1 and 2, ad-infected cell extract; lanes 3 and 4, uninfected cell
extract; lanes 5 and 6, uninfected cell extract supplemented with RPA;
lanes 1, 3, and 5, undigested replication products; lanes 2, 4, and 6, reaction products digested with MboI. A, position of
full-length duplex AAV; M, position of the largest MboI
digestion product of AAV. Size markers shown on the left in nucleotides
are from a HindIII and EcoRI digestion of
lambda DNA.
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Previously we had shown that the fundamental block in replication with
extracts from uninfected cells involved processivity and that
replication was much more processive when an Ad-infected extract was
used. If replication can proceed completely through two rounds, the
duplex AAV molecule will contain two unmethylated strands and therefore
be digestible by MboI. As shown previously, replication with
an extract from Ad-infected cells leads to the production of labeled
DNA which is largely MboI susceptible, whereas replication
with an extract from uninfected cells leads to the production of only a
small amount of labeled DNA which is MboI susceptible (Fig.
2B). Replication in an extract from uninfected cells supplemented with
RPA leads to an increase in MboI-susceptible full-length DNA
compared to the unsupplemented, uninfected extract, demonstrating an
increase in processivity with the addition of RPA.
In contrast, when RPA was added to an extract from Ad-infected cells,
no enhancement of replication was seen (data not shown). Rather, there
was a slight decrease (30%) in full-length replication.
Supplementation of AAV DNA replication in uninfected extracts with
Ad-DBP.
Ad codes for a single-stranded DNA-binding protein
(Ad-DBP) which has been shown to play an essential role in the
processivity of Ad DNA replication (25). Because both Ad and
AAV apparently replicate by a single-stranded displacement mechanism,
it seemed possible that Ad-DBP might be playing a similar role in AAV
replication in Ad-infected cells. To test this possibility, the
standard replication reaction was performed with and without the
addition of Ad-DBP purified from Ad-infected cells. Addition of Ad-DBP
led to an increase in full-length product (Fig.
3A; compare lanes 1 and 2 with lane 3).
To ensure that the increased replication was due to the Ad-DBP and not
to another protein found in Ad-infected cells which might be copurified
with Ad-DBP, we repeated the assay using purified Ad-DBP made in a
baculovirus expression system. The baculovirus protein also gave
increased replication of full-length AAV substrate (Fig. 3B). The
effect was significantly better when 1.5 µg was used rather than 0.75 µg (a 7.2-fold increase over the unsupplemented extract, compared
with a 2.3-fold increase). This may reflect the cooperative nature of
the enhancement suggested by the extract mixing experiment shown in
Fig. 1. In addition, Fig. 3B shows a decrease in the intensity of the
smear of labeled DNA of approximately 300 to 1,000 nucleotides with the
addition of AD-DBP. This is also the case when an Ad-infected cell
extract is used in place of an uninfected cell extract. We previously characterized this heterogeneous collection of DNA as short inverted repeats which resulted from the lack of processivity in the in vitro
AAV DNA replication system using extracts from uninfected cells
(46). AAV DNA replicated in an Ad-DBP-supplemented extract from uninfected cells was also more susceptible to MboI than
AAV DNA replicated in the unsupplemented extract (Fig. 3C).
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FIG. 3.
Replication of AAV DNA in uninfected cell extracts
supplemented with Ad-DBP. (A) Replication in an extract from uninfected
cells supplemented with Ad-DBP purified from Ad-infected cells. Lane 1, 2.7 µg of Ad-DBP; lane 2, 1.3 µg of Ad-DBP, lane 3, unsupplemented.
(B) Replication in an extract from uninfected cells supplemented with
Ad-DBP made in a baculovirus expression system. Lane 1, 1.5 µg of
Ad-DBP; lane 2, 0.75 µg of Ad-DBP; lane 3, unsupplemented. (C)
MboI digest of replication products from assays performed in
an extract from uninfected cells supplemented either with RPA or
Ad-DBP. Lane 1, unsupplemented; lane 2, 1.0 µg of RPA; lane 3, 1.5 µg of Ad-DBP from a baculovirus expression system. M designates the
largest MboI digestion product of AAV. Bands labeled A and B
are observed if protein is not extracted from the reaction; both
represent full-length AAV DNA, but presumably of alternative
structures, as described previously (46).
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Immunodepletion of extracts from Ad-infected cells with an antibody
to the Ad-DBP.
We have demonstrated three ways in which the
replication in vitro of full-length duplex AAV DNA in an extract from
uninfected HeLa cells can be enhanced: supplementation with an extract
from Ad-infected cells, supplementation with RPA, and supplementation with Ad-DBP. Next we wanted to determine whether the enhanced replication seen with the Ad-infected extract was at least partly attributable to one or both of the two DNA-binding proteins.
Initially we immunodepleted Ad-DBP from the Ad-infected extract by
using a MAb to the N-terminal portion of Ad-DBP (MAb 37-3). The results
are shown in Fig. 4A. Lanes 1 and 2 show
the effects of depleting and mock depleting an extract from uninfected
cells, respectively. The MAb actually enhanced replication in the
uninfected extract. In the extract from Ad-infected cells, however, the
immunodepletion (lane 3) substantially reduced replication of the AAV
substrate compared with mock depletion (lane 4) (70% reduction). To
ensure that MAb 37-3 was not depleting or in some other way interfering with the activity of RPA, we repeated the experiment with an extract from uninfected cells to which RPA had been added before the
immunodepletion. A comparison of the effect of depletion on the
supplemented extract with the effect of depletion on the extract from
Ad-infected cells is shown in Fig. 4B. Lanes 1 and 2 show replication
in the mock-depleted and the immunodepleted supplemented extracts from
uninfected cells, respectively. Immunodepletion with MAb 37-3 did not
decrease replication with the supplemented extract, just as it did not
decrease replication with the unsupplemented extract. In fact,
replication is 16% higher in the immunodepleted extract. This result
shows that immunodepletion with MAb 37-3 does not interfere with the
activity of RPA and also does not interfere with some component of the
replication machinery which is functional only when activity is more
substantial than is seen with unsupplemented uninfected cell extract.
Immunodepletion of the extract from Ad-infected cells (lane 4) again
leads to a substantial reduction in AAV DNA replication (84%
reduction) compared to the mock-depleted extract (lane 3).
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FIG. 4.
(A) Replication performed with extracts immunodepleted
with MAb 37-3. Lanes 1 and 2, extracts from uninfected cells; lanes 3 and 4, extracts from Ad-infected cells; lanes 1 and 3, extracts which
had been immunodepleted with MAb 37-3; lanes 2 and 4, extracts which
had been mock depleted. (B) Replications performed with extracts from
Ad-infected cells and extracts from uninfected cells supplemented with
RPA. Lanes 1 and 2, extracts from uninfected cells which had been
supplemented with RPA prior to immunodepletion; lanes 3 and 4, extracts
from Ad-infected cells; lanes 1 and 3, mock depletion; lanes 2 and 4, immunodepletion with MAb 37-3. All reactions were performed with
approximately 50 µg of cellular protein. A and B designate two forms
of full-length AAV.
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We saw an increase in replication whenever we added the antibody to
assays in which the extract from uninfected cells was used and believe
that it is due to a slight nonspecific enhancement from some component
of the antibody buffer.
Western blots of the extracts performed with MAb 37-3 showed the
presence of substantial amounts of the Ad-DBP in the extract from
Ad-infected cells but no detectable Ad-DBP in the extract from the
uninfected cells (data not shown).
Supplementation of immunodepleted extracts.
To ensure that the
reduced replication seen with immunodepleted extract was due to a
depletion only of a DNA-binding protein activity and to further ensure
that the DNA-binding protein which has been depleted was Ad-DBP and not
RPA, the following was done. Figure 5A
shows one series of assays performed with the mock-depleted (lane 1)
and depleted extracts from Ad-infected cells (lanes 2 to 4). Lane 2 shows the results of replication with the depleted extract alone. Lanes
3 and 4 show the results of replication with the depleted extract which
had been supplemented with 1.5 µg of Ad-DBP made in the baculovirus
expression system and 1.0 µg of RPA made in the E. coli
expression system, respectively. Immunodepletion reduced replication to
25% of the level of the undepleted extract. Addition of the Ad-DBP and
RPA restored replication to 51 and 90%, respectively, of the
undepleted level. In the case of RPA, replication was restored to
almost the same level as before immunodepletion, but restoration was
not as complete with Ad-DBP. We have noted that in this assay, if the
amounts of Rep protein and substrate DNA are kept constant, but the
amount of cellular protein is reduced as was the case in this assay,
the ability of Ad-DBP to supplement AAV replication is substantially
reduced for unknown reasons (data not shown). We think that this is why
added Ad-DBP does not restore replication as completely as does added
RPA. In contrast, Fig. 5B shows a replication assay performed with the
mock-depleted extract from Ad-infected cells alone and with the
mock-depleted extract supplemented with 1.0 µg of RPA. In the case of
the mock-depleted extract, the addition of the DNA-binding protein gave
no enhancement of replication. These results demonstrate that it was
the depletion of a DNA-binding protein activity which gave reduced
replication in the immunodepletion experiment.
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FIG. 5.
(A) Supplementation of immunodepleted extracts.
Replication assays of AAV were performed as described in Materials and
Methods in a mock-depleted extract from Ad-infected cells (lane 1) and
an MAb 37-3-depleted extract from Ad-infected cells (lanes 2 to 4).
After depletion, extracts were unsupplemented (lanes 1 and 2) or
supplemented with 1.5 µg of Ad-DBP (lane 3) or 1.0 µg of RPA (lane
4). (B) Supplementation of a mock-depleted extract. Replication of AAV
was performed as described in Materials and Methods in a mock-depleted
extract from Ad-infected cells. Lane 1, extract supplemented with RPA
after mock depletion; lane 2, extract not supplemented. (C) Western
blot of depleted and mock-depleted extracts from Ad-infected cells with
an antibody to the 34-kDa subunit of RPA. Lane 1, depleted extract;
lane 2, mock-depleted extract. Size markers, shown on the right, are in
kilodaltons. Additional bands in lane 1 are residual antibody from the
immunodepletion, detected by the secondary antibody in the detection
system (goat anti-mouse IgG).
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To further ensure that immunodepletion by MAb 37-3 did not
inadvertently bring down RPA, a Western blot was performed with the
mock-depleted and immunodepleted extract, using MAb RPA34-19, a MAb
which recognizes the 34-kDa subunit of RPA. From the Western blot shown
in Fig. 5C, it is apparent that the 34-kDa subunit of RPA has not been
decreased in quantity by immunodepletion with MAb 37-3. The two
additional bands seen in the depleted lane are presumably from MAb
37-3, which failed to bind the protein G beads in the immunodepletion.
Since these are mouse antibodies, they were detected by the detection
system which made use of an alkaline phosphatase-conjugated goat
antibody to mouse IgG.
Ad infection does not induce higher levels of RPA in infected
cells.
The data that we have presented show that Ad-DBP is
responsible for at least a significant portion of the higher levels of replication seen in extracts from Ad-infected cells. However, increased
levels of RPA might still be partly responsible for the higher levels
of replication. Either Ad infection could induce expression of RPA or
Ad infection could alter the nuclear membrane, leading to the
extraction of higher percentages of RPA in infected cells than in an
extract from uninfected cells. To test these possibilities, we
performed Western blotting on the replication extracts made from
infected and uninfected cells and used in all of the above-described
assays (Fig. 6A) and on a whole-cell
lysate made from infected and uninfected cells. In comparing equal
amounts of protein, MAb RPA34-19 detected no increase in RPA in
infected cells. Apparently Ad infection neither induces higher levels
of RPA nor alters the physiology of the cell such that RPA becomes more
easily extractable at the 28-h time point at which these extracts were
made.
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FIG. 6.
Western blots comparing levels of RPA from Ad-infected
and uninfected cells. (A) Western blot of extracts used for replication
assays. Lane 1, extract from uninfected cells; lane 2, extract from
Ad-infected cells. (B) Western blot of whole-cell lysate. Lane 1, lysate of Ad-infected cells; lane 2, lysate of uninfected cells. Size
markers, shown on the right, are in kilodaltons.
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Ad-DBP enhances AAV DNA replication in the context of a plasmid
substrate more efficiently than does RPA.
In vitro AAV DNA
replication using either RPA or Ad-DBP was substantially equivalent in
an assay measuring replication of linear duplex AAV. We have previously
reported a replication assay in which the substrate is a plasmid in
which the AAV genome is inserted into a plasmid vector (47).
Rep-dependent replication in this assay involves rescue of the AAV
sequences from the plasmid backbone as well as replication, and we
think that this combined rescue-replication is a useful model for
rescue-replication of the chromosomally integrated AAV genome. It was
noted that in this assay in which replication initiated at the AAV
origin in the context of a circular plasmid, replication of pBR
sequences rather than AAV sequences often occurred. This is not so
surprising since the initial direction of replication from a nick at
the AAV origin is necessarily outward through the inverted terminal repeat toward the contiguous vector sequences. In order for AAV sequences, rather than pBR sequences, to be replicated, the replication complex must reverse direction at the AAV/pBR boundary, perhaps by
template strand switching, for which we previously proposed a model
(47). Figure 7 is a schematic
illustrating the two possible directions for replication initiating at
the AAV terminal resolution site when the AAV genome is inserted into a
plasmid vector.
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FIG. 7.
Schematic showing initiation of replication at the
terminal resolution site (trs) of AAV when the AAV genome has been
inserted into a plasmid vector. Replication can be either back into AAV
sequences (1) or forward into vector sequences
(2). The shaded region denotes the 145-base inverted
terminal repeat of AAV DNA.
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When the intact plasmid pAV2 was used as the substrate for in vitro AAV
DNA replication, there was a fundamental difference between extracts
from uninfected cells and extracts from Ad-infected cells. Whereas
extracts from uninfected cells replicated pBR about as frequently as
AAV, extracts from Ad-infected cells preferentially replicated AAV. We
compared the effects of adding Ad-DBP or RPA to an uninfected extract
to those obtained with unsupplemented uninfected and Ad-infected
extracts when the substrate was the intact plasmid pAV2 (Table
1). As expected, the extract from Ad-infected cells gave a higher ratio of AAV to pBR replication than
did the extract from uninfected cells. As was found with the assay
using duplex AAV DNA as the substrate, both Ad-DBP and RPA induced a
substantial increase in replication. With the addition of Ad-DBP to an
assay using an intact plasmid as the substrate, there was an AAV-to-pBR
ratio which was similar to that from the Ad-infected cell extract;
however, the addition of RPA gave the opposite result. Addition of RPA
to the extract from uninfected cells gave an AAV-to-pBR ratio which was
substantially lower than the ratio for the uninfected extract alone.
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TABLE 1.
Relative incorporation into AAV and pBR sequences in
replication reactions using intact pAV2 as the substrate
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DISCUSSION |
A basic question in AAV biology has been the nature of the helper
effect provided by Ad in productive AAV replication, and a component of
this question has been whether Ad provided any function which directly
promoted replication of AAV DNA. Previously we demonstrated that
full-length replication of an open-ended, duplex AAV DNA substrate was
50-fold better in extracts made from Ad-infected cells supplemented
with the AAV Rep protein than in Rep-supplemented extracts made from
uninfected cells. A closer examination of replication in the two
extracts demonstrated that initiation in each was approximately
equivalent but that in the extract from uninfected cells, most
replication events led to the dissociation of the elongating strand
from the template strand after a few hundred bases. The goal of the
studies described in this report was to determine whether the
enhancement of processivity was the result of cellular factors whose
activity was stimulated by Ad infection or was the result of an Ad
protein(s) participating directly in AAV DNA replication.
The data presented demonstrate that the addition of either the human
RPA or the Ad-DBP to an extract from uninfected cells supports enhanced
AAV DNA replication. The enhancement in both cases was associated with
an increase in processivity as demonstrated by MboI
susceptibility and the disappearance of short replication products
characteristic of displacement of the elongating strand from the
template. Previously we had shown that replication of short substrate
molecules in extracts from uninfected cells gave almost as much
full-length product as replication of short substrates in extracts from
Ad-infected cells, which was consistent with the hypothesis that the
difference between the two extracts reflected a difference in
processivity. In agreement with these results, while RPA and Ad-DBP
each increased full-length replication of the short substrates, they
did so to a much lesser extent than for longer wild-type-length
substrates (data not shown). To show that the abundant single-stranded
binding activity which promotes more efficient replication was already
present in the extract from Ad-infected cells, we added RPA to this
extract and saw no enhancement. The finding that Ad DNA replication
takes place in an environment of increased single-stranded binding
activity and that AAV replication can be enhanced by supplying an
excess of this activity is not an unexpected result. In normal cellular replication, the displaced strand is believed to be incorporated immediately into the lagging-strand replication complex, while in both
Ad and AAV replication there presumably are significant lengths of
displaced, single-stranded DNA.
One possible mechanism for enhancement of single-stranded
binding activity upon Ad infection is an enhancement of cellular single-stranded binding activity. We looked for an increase in absolute
amounts of RPA both in the replication extract and in whole-cell
lysates of infected cells. By Western blot analysis, we saw no increase
after Ad infection. Also, the relative amount of RPA compared to total
protein was approximately the same in the replication extracts as in
the total-cell lysate. Recently it has been shown (31) that
the assembly of the intact RPA from its three components is a cell
cycle-dependent phenomenon. Assembly of the complete RPA is necessary
for RPA support of DNA replication (12, 15, 18). In
addition, phosphorylation of RPA has been shown to be a cell
cycle-dependent phenomenon (10, 11). The phosphorylation
state of RPA may play a role in the modulation of DNA replication in
cells (13). We have not measured what fraction of the
components is assembled into the complete RPA or the phosphorylation
status of the RPA in our extracts. We do not think, however, that an
Ad-induced assembly or phosphorylation of RPA plays a significant role
in AAV DNA replication in our assay, because the amount of added RPA
which achieved stimulation comparable to maximally effective amounts of
Ad-DBP or that seen in the infected cell extract was 10-fold that of
RPA naturally present in the extracts. Another possibility for
enhancement of single-stranded binding activity is Ad recruitment of
RPA into replication centers within the nucleus. It has been shown that during cellular DNA replication, RPA is found concentrated in replication foci (1, 4, 21, 31). It has also been shown that
during Ad DNA replication, Ad-DBP is concentrated at replication foci
(30, 37, 44). This of course raises the available
concentrations of these components in a way which is hard to mimic in a
soluble replication system. Additionally, it is possible the Ad
infection affects the level of activity of a single-stranded
DNA-binding protein other than RPA. It has been noted that a second
cellular single-stranded DNA-binding protein (PC4) is capable of
playing a role in the simian virus 40 in vitro replication system
(35).
The second possible mechanism for enhancement is Ad-DBP, which is
synthesized early in infection and is present in large amounts. This
protein has been shown to play several roles in Ad DNA replication (reviewed in references 14 and
43) and, in particular, is essential for the
elongation step (25). When it was added to an extract from
uninfected cells, there was a significant enhancement of AAV DNA
replication in our assay. As with RPA, both the Ad-DBP purified from
infected cells and that made in an expression system enhanced
replication, making it unlikely that the effect is due to a second
factor copurifying with Ad-DBP.
Immunodepletion of the infected cell extract with an antibody to Ad-DBP
substantially reduced the ability of these extracts to support AAV DNA
replication. The restoration of replication capacity by the addition of
either Ad-DBP or RPA (both produced in expression systems) to the
immunodepleted extract demonstrated that only a single-stranded binding
activity had been depleted. The controls showing that RPA was
unaffected by the immunodepletion demonstrated that whatever effect Ad
infection might have on endogenous RPA activity, the primary
single-stranded binding protein support for AAV DNA replication in the
Ad-infected extract is supplied by Ad-DBP. It is interesting that
Weitzman et al. (49) have shown that in Ad-AAV-coinfected
cells, AAV DNA is recruited into Ad replication foci. In particular,
they have shown colocalization between Ad-DBP and AAV DNA and between
Ad-DBP and the AAV Rep protein. Although our data do not absolutely
exclude a role for Ad-induced enhancement of endogenous single-stranded
binding protein activity, the presence of large amounts of Ad-DBP in
the infected cell (concentrated at the foci containing replicating AAV
DNA) and its ability to support AAV DNA replication make it likely that
this protein plays an important role in AAV DNA replication in the cell
as we have shown that it does in the extract made from these cells.
We noted one substantial difference between the two proteins with
regard to the ability to support in vitro AAV DNA replication. When the
substrate for replication was not the isolated duplex form of the AAV
genome but rather the AAV genome inserted into a plasmid vector,
extracts from uninfected cells supplemented with RPA preferentially
replicated adjacent vector sequences rather than AAV sequences. In
contrast, when the same extract was supplemented instead with Ad-DBP,
replication was now preferentially of AAV sequences. In this respect,
supplementation of the uninfected extract with Ad-DBP gave replication
quite similar to that seen with the extract from Ad-infected cells,
while supplementation of the uninfected extract with RPA was quite
dissimilar. This last result supports the tentative conclusion that
Ad-DBP plays a primary role in AAV DNA replication and suggests that
Ad-DBP may play an important role in the excision and replication of an
integrated genome upon Ad infection of latently infected cells.
It is interesting to speculate on what might be the source of this
difference. Previously (47) we suggested a model to explain how AAV replication turns back on itself in the plasmid context. In
that model, when the replication complex passes through the inverted
terminal repeat, the now separated DNA strands of the original template
may fold up into a hairpin conformation, thereby displacing the newly
synthesized strand and its associated replication complex. The newly
made strand is now free to fold on itself and replicate back into AAV.
This model suggests that replication back into AAV is dependent on
self-base pairing within each strand and that replication with Ad-DBP
allows self-pairing more readily than does replication with RPA.
There is an extensive and somewhat ambiguous literature on the possible
role of Ad-DBP on AAV replication (reviewed in reference 5). It was reported that temperature-sensitive
mutations in the E2A gene (which codes for Ad-DBP) caused two- to
fivefold-reduced synthesis of AAV DNA when this Ad was used as the
helper for AAV at the nonpermissive temperature (28). In
contrast, other reports characterized the same mutants as efficient
helpers (26, 42). Further investigation of the
best-characterized temperature-sensitive E2A mutant
(Adts125) seemed to show that synthesis of replicative-form AAV DNA was normal at the nonpermissive temperature, and the decrease in production of infectious particles was due only to other effects of
the E2A mutation (27).
Two sets of more definitive experiments have been done more recently.
Kitchingman and colleagues (33, 38) constructed a series of
point mutants in Ad-DBP, including several targeted to the putative
single-stranded DNA binding domain. When transfected into AAV-infected
Cos cells, several of these mutants, especially those targeted to the
putative DNA binding site, supported almost no synthesis of AAV DNA. In
the second set of experiments, Carter et al., making use of a cell line
which expresses the E2a gene (20), produced Ad which makes
no detectable Ad-DBP. With this mutant used as a helper, AAV DNA
replication was reduced severalfold (6). Both sets of
experiments imply a role for Ad-DBP in AAV DNA replication. The much
greater effect seen with several of the mutants in the first set of
experiments can probably best be explained by hypothesizing that these
mutants were demonstrating a dominant negative effect. There would of
course be no such effect in the second set of experiments, since there
was no Ad-DBP; in these experiments, the AAV DNA replication which was
seen was most likely supported by the cell's endogenous RPA. We think
that our results are not inconsistent with the last two sets of
experiments.
The requirement for single-stranded DNA-binding protein stimulation in
this assay seems specific since E. coli SSB gave no enhancement. If the requirement is specific, it is unexpected that two
proteins as dissimilar in sequence as the human and Ad single-stranded
binding proteins both support replication. Earlier experiments with
mutants in the Ad pol gene (reviewed in reference 5) demonstrated that a cellular polymerase
replicated AAV DNA, and in this work the supplemented extracts were
from uninfected cells; therefore, the replication machinery must have
been cellular. It is consequently not surprising that the human protein
RPA supported replication. What is somewhat unexpected is that Ad-DBP
supports elongation in what is essentially a cellular replication
system. Since Ad has its own polymerase and apparently does not utilize a helicase, there would be no selection for Ad-DBP to cooperate with
the cellular replication components. NF I and NF III are cellular
components involved in Ad DNA replication but only in initiation
(32, 36), while the enhancement described in this report is
due to elongation. Stimulation of polymerase delta replication by
Ad-DBP has been observed previously, but in an assay in which all
single-stranded DNA-binding proteins tested gave stimulation (18). Presumably, therefore, in that assay there was no
specific protein-protein interaction.
A possibility for further investigation, therefore, is that with
respect to the enhanced elongation that we have described, both Ad-DBP
and RPA interact with an AAV protein which remains a component of the
replication complex. The Rep protein might remain a continuous
component of the replication complex, in its role as a helicase. It is
reasonable that the AAV Rep protein might have become adapted to both
cellular and Ad replication components. The possible role of the Rep
protein as a helicase for AAV DNA replication is consistent with
previous characterization of Rep as a helicase (16b) and
with the data of this study which suggest that one of the components of
the replication complex must be able to interact specifically with both
Ad-DBP and RPA.
The conclusions of this work with regard to the role of
single-stranded DNA-binding proteins in AAV DNA replication
may help to reconcile two apparently paradoxical observations.
Exposure of cells to ionizing radiation and other genotoxic agents
renders them permissive for AAV DNA replication (without helper
virus) (51-53). Similar treatment also enhances AAV vector
transgene expression (2, 40). While this may in part be
caused by an increased amount of double-stranded transcriptional
template, it has also been suggested that prolonged transgene
expression may be a consequence of enhanced vector integration
(40). Perhaps DNA replication induced by radiation is, at
least initially, less processive than that induced by Ad coinfection.
As mentioned above, changes in the replicative capacity of cells have
been associated with changes in the phosphorylation and assembly of
RPA, and such changes can be induced by DNA-damaging agents. For
example, it has been shown that UV light-induced DNA synthesis arrest
is mediated at least in part through transient phosphorylation-related
alterations in RPA which also render the protein temporarily
nonfunctional in the simian virus 40 in vitro DNA replication assay
(7). Replication in the context of an inactive RPA might
involve frequent dissociation of the elongating strand, which could
foster integration. It might be informative to investigate whether
there is a correlation between those DNA-damaging and
synthesis-inhibiting agents which give higher transduction efficiencies
and those which change the functioning of RPA.
| |
ACKNOWLEDGMENTS |
This work was supported by Public Health Service grant GM50032.
We are greatly indebted to Douglas Brough for his kind gift of MAb 37-3 and to Gustavo Droguette, Marshall Horwitz, and Ron Hay for their kind
gifts of the Ad-DBP. We also thank A. LeGall and A. Muesch for advice
on the immunodepletion experiments; D. Brough, D. Klessig, J. Hurwitz,
C. H. Young, E. Falck-Pedersen, R. M. Linden, and E. Winocur
for helpful discussions; and N. Cortez for excellent technical
assistance.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Dept. of
Microbiology, Hearst Microbiology Research Center, Cornell University
Medical College, 1300 York Ave., New York, NY 10021. Phone: (212)
746-6519. Fax: (212) 746-8587. E-mail:
pjward{at}mail.med.cornell.edu.
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Replication of adeno-associated virus in cells irradiated with UV light at 254 nm.
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J Virol, January 1998, p. 420-427, Vol. 72, No. 1
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
