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J. Biol. Chem., Vol. 277, Issue 18, 16096-16101, May 3, 2002
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From the Department of Biochemistry and Molecular Biology, Wright State University School of Medicine, Dayton, Ohio 45435
Received for publication, January 25, 2002, and in revised form, February 20, 2002
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ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Replication protein A (RPA) participates in many
cellular functions including DNA replication and nucleotide excision
repair. A direct interaction between RPA and the xeroderma pigmentosum group A protein (XPA) facilitates the assembly of a preincision complex
during the processing of DNA damage by the nucleotide excision
repair pathway. We demonstrate here the formation of a ternary
RPA, XPA, and duplex cisplatin-damaged DNA complex as is evident by
electrophoretic supershift analysis. The RPA-XPA complex displays
modest specificity for damaged versus undamaged duplex DNA,
and the RPA-XPA complex displays a greater affinity for binding duplex
cisplatin-damaged DNA when compared with the RPA or XPA proteins alone,
consistent with previous results. Using DNA denaturation assays, we
demonstrate that the role of XPA is in the stabilization of the duplex
DNA structure via inhibition of the strand separation activity of RPA.
Rapid kinetic analysis indicates that the bimolecular
kon of the RPA-XPA complex is 2.5-fold faster
than RPA alone for binding a duplex cisplatin-damaged DNA. The
dissociation rate, koff, of the RPA-XPA complex
is slower than that of the RPA protein alone, suggesting that the XPA
protein stabilizes the initial binding of RPA to duplex DNA as well as maintaining the integrity of the duplex DNA. Interestingly, XPA has no
effect on the kon of RPA for a single-stranded
40-mer DNA.
Nucleotide excision repair
(NER)1 is the major pathway
responsible for the removal of a wide array of bulky DNA adducts from the genome (1, 2). A defect in this pathway can result in genomic
instability and also results in a predisposition to skin cancer, as is
evident by the xeroderma pigmentosum (XP) disorder (3). Although the
protein components have been identified and the NER reaction has been
reconstituted in vitro (4, 5), the biochemical
process through which the global genomic repair pathway is initiated
and recognizes damaged DNA is still poorly understood. The
heterotrimeric replication protein A (RPA) is required for NER and has
been suggested to play a role in the damage recognition process (6-8).
The XPA protein is also required for NER and is involved in the DNA
damage recognition process (4, 5, 9). Both RPA and XPA preferentially
bind damaged DNA, and because RPA and XPA directly interact in the
absence of DNA, the RPA-XPA complex has been implicated as a key
component in the earliest stage of damage recognition (9-14). There is
also evidence that the XPC-hHR23B protein complex may initiate
recognition of DNA damage for the global genomic repair pathway of NER
(15). Recent evidence also implicates the DDB heterodimer in
damage recognition because the complex binds damaged DNA with high
affinity (16) and can dramatically increase the repair rate of certain DNA adducts, including cyclobutane pyrimidine dimers in conjunction with XPA and RPA (17). In addition, the p48 subunit of DDB has been
demonstrated to localize to the sites of UV-induced DNA damage independent of XPA and XPC (18).
The exact role that these protein components play in recognizing
damaged DNA in the vast background of undamaged DNA to initiate NER
remains to be determined. The affinity of these individual protein
components for damaged DNA cannot account for the specificity and
selectivity required for distinguishing the damaged DNA from the
background of undamaged DNA to initiate NER (1, 2). In light of recent
results demonstrating that in vitro NER catalyzed incision
of undamaged DNA can be detected, the degree of NER specificity for
damaged DNA may be less than originally thought (19). The protein components may work in a synergistic manner to account for the
damage-specific preference required, and/or the transcription machinery
may alleviate some of the selectivity required by stalling at DNA
lesions and recruiting the NER factors in a transcription-coupled repair mechanism. The question still remains as to what factor(s) initiates and acts as a nucleation point for NER in the absence of a
stalled transcription complex. A possibility is that the NER
initiator(s) could be a preformed complex of damage recognition proteins that synergistically function to selectively bind to a
damaged-DNA site. This initial complex of damage recognition proteins
could then recruit the other repair factors to initiate NER. Both
in vitro (20) and recent in vivo evidence (21)
suggests that recognition of DNA damage proceeds via a stepwise
assembly of NER
It has been unclear whether the RPA protein and the XPA protein remain
in a complex when bound to DNA and to what extent the protein-protein
interaction has on the ability to recognize damaged DNA. This is
evidenced by the difficulty in observing this complex or obtaining a
distinct footprint on damaged DNA (14). In an attempt to better
understand DNA damage recognition and the synergistic effects between
protein components, we have assessed the effect of the RPA-XPA
interaction on cisplatin-damaged DNA binding. We show the formation of
an RPA-XPA complex bound to duplex cisplatin-damaged DNA as evident by
supershift analysis by antibodies to both proteins. The RPA-XPA complex
binds synergistically to duplex cisplatin-damaged DNA compared with RPA
or XPA alone, and there is a specificity of the complex for duplex
cisplatin-damaged DNA versus duplex undamaged DNA. The XPA
protein stabilizes the duplex DNA structure and inhibits the strand
separation induced by RPA. Stopped-flow kinetic analyses reveal a
synergistic effect on the rate constants for binding duplex
cisplatin-damaged DNA and support the hypothesis that the RPA and XPA
proteins may be in complex prior to binding a damaged DNA site. These
results are discussed with respect to DNA damage recognition and the
regulation of nucleotide excision repair.
Materials--
All DNA oligonucleotides were purchased
from Integrated DNA Technologies, Inc. (Coralville, IA). Cisplatin was
purchased from Sigma, mung bean nuclease and T4 polynucleotide kinase
were purchased from New England Biolabs (Beverly, MA), and sequenase
(version 2.0) was purchased from U.S. Biochemical Corp. (Cleveland,
OH). Radiolabeled nucleotides were from PerkinElmer Life Sciences, and
unlabeled nucleotides were from Amersham Biosciences. The anti-p34 RPA monoclonal antibody (RPA/p34 Ab-1) was purchased from NeoMarkers (Fremont, CA), and the anti-Xpress Ab, which recognizes the amino acid linker sequence between the His6 tag and the
N terminus of the XPA protein, was purchased from Invitrogen. All other
reagents, enzymes, and chemicals were from standard suppliers. The 40 and 41-mer DNA sequences used to prepare the duplex DNA substrates are
5'-TCATTACTACTCACTCTGTCGGCCATCGCTCTCTATTCCC-3' and
5'-GGGGAATAGAGAGCGATGGCCGACAGAGTGAGTAGTAATGA-3', respectively.
Protein Purification--
Recombinant RPA was purified as
described using the expression vector kindly provided by Marc Wold
(22). The His6-XPA fusion protein was purified as
previously described (23).
Platination and DNA Purification--
The DNA substrates used
for electrophoretic mobility shift assay (EMSA) analysis were treated
with cisplatin, labeled with 32P, and purified as
previously described (11). Following gel purification, the DNA
substrates were treated with mung bean nuclease to reduce the
single-stranded DNA contamination to less than 1% (data not shown).
Electrophoretic Mobility Shift and Denaturation
Assays--
EMSAs were performed using 50 fmol of either undamaged or
cisplatin-treated duplex 41-bp DNA in a reaction buffer containing 20 mM HEPES (pH 7.8), 2 mM dithiothreitol, 0.001%
Nonidet P-40, and 50 mM NaCl (11, 24). The presence or
absence of 2 mM MgCl2 and the indicated amount
of each protein is shown in the figure legends. The proteins, a 4:1
molar ratio of XPA to RPA, were preincubated on ice for 15 min and then
added to the DNA and incubated for an additional 15 min at room
temperature. The specific antibodies were added, where indicated after
the RPA or RPA-XPA proteins were incubated with the DNA and incubated
for 15 additional minutes at room temperature. Gel loading buffer was
added, and the products were separated on 4% native polyacrylamide
gels as previously described (11, 24). For the EMSA and denaturation
assays, the reactions were split in half and analyzed separately (24). The products were then analyzed on 15% native gels to allow the separation of duplex and single-stranded DNA and quantified by phosphorimaging analysis.
Stopped-flow Kinetic Experiments and Data
Analysis--
Stopped-flow kinetic traces were obtained using a
SX.18MV stopped-flow reaction analyzer (Applied Photophysics) as
previously described (22). Equal volumes of protein and DNA in reaction buffer supplemented with 2 mM MgCl2 from
separate syringes were rapidly mixed at 24 °C. Fluorescence was
measured following excitation at 290 nm (0.5-mm slit width) using a
350-nm longpass cut-on filter (LG-350 from Corion, Franklin, MA).
Constant protein (6.25 nM RPA final reaction concentration
alone or preincubated with 25 nM XPA) and varying DNA
concentrations (62.5-125 nM final concentrations when
mixed) starting at a 10-fold molar excess of DNA to RPA were used to
achieve pseudo-first order kinetics. The RPA and XPA proteins were
preincubated on ice for 15 min prior to the stopped-flow reactions. The
kinetic data were fit using Pro-K software (Applied Photophysics) to
calculate the observed rate, kobs. The results obtained for RPA and the RPA-XPA complex binding duplex DNA were obtained modeling a double exponential decay. The
kobs was plotted versus DNA
concentration, which results in a linear relationship with the slope as
the kon and the y intercept as the
koff. The traces depicted for each concentration
of DNA represents the average of 8-12 individual shots, and each point
on the graph for determining rate constants are the average of at least
three experiments with the error bars representing the
S.D.
RPA-XPA Complex Formation on Duplex Cisplatin-damaged DNA--
It
has previously been shown that RPA and XPA interact in the absence of
DNA and that both proteins are required for NER. However, there has
been considerable difficulty in observing a trimeric RPA-XPA-DNA
complex because of the small change in the mobility of RPA-DNA compared
with RPA-XPA-DNA, and no DNA footprint has been observed for the
RPA-XPA complex bound to DNA. To determine whether the complex of
RPA-XPA binds to duplex cisplatin-damaged DNA, we employed an EMSA
using specific antibodies to RPA and XPA (Fig.
1). The XPA protein demonstrates weak
binding to the duplex cisplatin-damaged 41-bp DNA under the
experimental conditions employed (lane 2). The presence of
the anti-Xpress antibody (XPA Ab) supershifts the bound XPA protein and
enhances the binding of the XPA protein, possibly by stabilizing the
protein (lane 3). The monoclonal Ab to the p34 subunit of
RPA displays no cross-reactivity with the XPA protein (lane
4). The RPA protein-DNA complex is supershifted with a mAb to the
p34 subunit, and there is no cross-reactivity of the anti-Xpress
antibody for the RPA protein (lanes 6 and 7, respectively). The RPA-XPA complex resulted in a shifted complex that
migrated slightly slower than the RPA protein alone (lane 8 versus lane 7), although this difference was variable (data not shown). Supershift analysis using either the anti-Xpress or anti-p34 antibody of RPA shifted the band and confirmed that both XPA
and RPA were bound to the duplex cisplatin-damaged DNA (lanes 9 and 10, respectively). These data indicate that a
preformed RPA-XPA complex can bind duplex cisplatin-damaged DNA and
that both proteins are present in the bound DNA complex. Previous
studies suggested the existence of an RPA-XPA-DNA complex; however, the inability to footprint the complex and inefficient supershifting of the
complex with specific antibodies raised doubt as to the stability of
the complex (14). The data presented in Fig. 1 demonstrate conclusively
that XPA is present in the complex of RPA bound to DNA.
Damage-specific and Synergistic Binding of RPA-XPA to Duplex
Cisplatin-damaged DNA--
To determine the specificity of the RPA-XPA
complex for duplex cisplatin-damaged DNA, competition mobility shift
assays were performed using nonspecific competitor poly(dI-dC) DNA
(Fig. 2A). Increasing
concentrations of poly(dI-dC) were incubated in reactions with either
constant RPA or RPA-XPA complex using duplex cisplatin-damaged DNA
(lanes 2-5 and 6-9, respectively).
Quantification of the results (Fig. 2B) reveals a dramatic
decrease in bound RPA (filled circles) with increasing
concentrations of competitor dI-dC while having only a modest decrease
in bound RPA-XPA complex (open circles) with increasing
competitor DNA. A 3-4-fold difference in bound DNA for RPA alone
compared with the RPA-XPA complex was observed with the highest
concentration of competitor DNA (open circles versus filled circles). The presence of 2 mM MgCl2 in the binding reaction increases the
preference of the RPA-XPA complex for the DNA substrate compared with
RPA alone even in the absence of competitor DNA (data not shown). This
results in about a 1.5-fold better DNA binding for the RPA-XPA complex
compared with RPA alone. The data, however, are presented as a percent
of the maximum DNA bound for the RPA-XPA complex and for RPA with no
competitor DNA. In addition, the RPA-XPA complex preferentially binds
duplex cisplatin-damaged DNA compared with the undamaged duplex DNA
(data not shown). The RPA-preferential DNA binding results for
cisplatin-damaged versus undamaged duplex DNA are consistent
with previously published data (11, 22, 24). Interestingly, the XPA
protein also enhanced the binding of RPA to undamaged duplex DNA (data
not shown). These results reveal damage-specific binding as well as
synergistic binding of the RPA-XPA complex to duplex cisplatin-damaged
DNA when compared with the binding of the RPA or XPA proteins
alone.
XPA Inhibits RPA-induced DNA Denaturation--
We have previously
demonstrated that the ability of RPA to bind duplex DNA correlates with
the ability to denature duplex DNA (24). To assess the effect of XPA on
the ability of RPA to unwind or denature DNA, we performed
binding/denaturation assays (Fig. 3). The
EMSA reveals an increase in DNA binding with increasing concentrations
of either RPA or RPA-XPA (Fig. 3A, lanes 2-5 and 6-9, respectively). The presence of the anti-Xpress
antibody demonstrated by the supershifted complex that XPA is present
in the bound complex (Fig. 3A, lane 10). The
denaturation analysis (Fig. 3B) reveals an increase in
single-stranded DNA with increasing RPA (lanes 2-5) similar
to our previous report (24). Single-stranded DNA is also generated with
increasing concentrations of the RPA-XPA complex, but the level of
single-stranded DNA is reduced in the presence of the XPA protein
(lanes 6-9). The quantification (Fig. 3C)
reveals a correlation between RPA binding/denaturation, consistent with
previously published data (filled symbols). The presence of
the XPA protein stabilizes the duplex DNA structure and results in
about a 60-70% reduction in single-stranded DNA generation (open symbols). Considering the 41-bp DNA substrate is near
the minimal size DNA to support RPA-XPA complex formation, the lack of
complete inhibition is not surprising. These results as well as our
previously published data support a model for the recognition of
damaged DNA in which the RPA-XPA complex first binds duplex-damaged DNA
followed by DNA strand melting and the positioning of RPA to the
undamaged single-stranded DNA opposite the lesion (25). The XPA
protein, via contacts with both DNA strands, inhibits further DNA
denaturation and positions the protein complex near the DNA lesion
(25).
Stopped-flow Kinetic Analysis of the RPA-XPA Complex Binding Duplex
Cisplatin-damaged DNA--
To better understand the DNA binding
kinetics and to obtain rate constants for binding duplex DNA, we
performed stopped-flow kinetic analysis for RPA and the RPA-XPA
complex. We have previously published the stopped-flow kinetic analysis
of RPA binding DNA using the intrinsic fluorescence properties of RPA
and the quenching of fluorescence when RPA binds DNA. Here we
demonstrate the effect of the XPA protein on the kinetic rates of RPA
binding a duplex 41-bp cisplatin-damaged DNA (Fig.
4). The quenching of the intrinsic tryptophan fluorescence of constant amounts of RPA or RPA-XPA complex
was monitored over time at a variety of DNA concentrations. Control
traces with buffer (used to zero the fluorescence) or DNA mixed with
buffer were performed and resulted in minimal differences in
fluorescence (data not shown). The traces presented in each figure
represent the fluorescence above the buffer baseline value. Control
traces obtained using RPA or the RPA-XPA complex mixed with buffer,
which provides the initial fluorescence from which quenching was
monitored, resulted in no change in fluorescence over time (data not
shown). The increase in the initial intrinsic fluorescence at
time 0 for the RPA-XPA complex compared with RPA alone is due to the
intrinsic fluorescence properties of the XPA protein (Fig.
4A). The intrinsic fluorescence of the XPA protein is not
quenched when mixed with DNA similar to traces obtained with the buffer
control (data not shown). In addition, when the anti-Xpress antibody
was preincubated with the XPA protein, which results in enhanced DNA
binding as judged by EMSA (Fig. 1), upon mixing with DNA, no change in
intrinsic fluorescence was observed (data not shown). Each trace was
fit to a double exponential decay (thick line), and the
residual values for each fit are presented below the traces. The data
were not consistent with a single exponential decay but were consistent
with the slow phase of the biphasic reaction correlating with the
denaturation of the duplex DNA followed by the binding of RPA to
single-stranded DNA, consistent with our previously published data
(22).
The observed rate of quenching (kobs) for the
fast phase of the reaction was plotted versus DNA
concentration for RPA (filled circles) and the RPA-XPA
complex (open circles). The results revealed a linear
relationship where the slope is equal to the kon
and the y intercept equal to the koff
(Fig. 4B). The kon of RPA for the
duplex cisplatin-damaged 41-mer DNA was 0.045 ± 0.006 nM XPA Has No Effect on RPA Single-strand DNA Binding
Kinetics--
Considering the major role of RPA is single-strand DNA
binding, stopped-flow kinetic analysis of RPA and the RPA-XPA
complex binding single-stranded 40-mer DNA was performed (Fig.
5) to determine whether XPA had any
effect on RPA single-strand DNA binding. The plot of
kobs versus DNA concentration for RPA
(filled circles) yielded a kon of
1.87 ± 0.154 nM The process of eukaryotic NER has been well studied and
reconstituted in vitro, but the initiation of the pathway
including the recognition of the damaged DNA remains poorly understood
(4, 5). Two proteins that are required for NER and that play an important role in the preincision NER complex are RPA and XPA (6, 14,
26). It has previously been shown that the RPA and XPA proteins
interact in the absence of DNA and that both proteins are required
before incision can occur (6, 12, 14), but little is known how the
RPA-XPA interaction affects DNA binding and DNA damage recognition. In
this study, we show a ternary complex of RPA and XPA bound to duplex
cisplatin-damaged DNA, with the complex resulting in synergistic
binding when compared with RPA or XPA alone. This suggests that the RPA
and XPA proteins may form a complex prior to binding to DNA to enhance
the specificity for damaged versus undamaged duplex DNA.
Considering the low concentration of XPA relative to RPA, it is likely
that a large portion of XPA is complexed with RPA, while a relatively
small percentage of the cellular RPA is complexed with XPA. Clearly, it
will be of interest to ascertain how the kinetics of the interaction of
XPA with damaged DNA compare with the kinetics of the interaction of
XPA with RPA bound to damaged DNA.
The RPA protein alone has previously been shown to preferentially bind
duplex-damaged DNA compared with undamaged DNA, and the DNA binding
activity correlates with the ability to denature the duplex DNA
substrate (10, 11, 24). It has also been shown that RPA can unwind long
stretches of DNA which is dependent on the reaction conditions (27,
28). In this study, the XPA protein inhibits the ability of the RPA
protein to denature the duplex DNA substrate. This is an important
function of the XPA protein so that the recruitment of the other repair
factors can be localized to the damaged-DNA site. This would also
maintain a defined system in which incision occurs ~6 bases 3' of the
lesion and 22 bases 5', resulting in the release of a 24-32 nucleotide fragment (1, 2). Consistent with our previous model of RPA binding
duplex DNA, the RPA-XPA complex binds duplex-damaged DNA followed by a
defined denaturation such that RPA binds to the single-stranded DNA
opposite the DNA adduct (24, 25). Evidence demonstrating that the XPA
protein contacts both DNA strands enables the maintenance of a defined
unwound duplex DNA around the DNA adduct (25). This would allow for the
recruitment of the other repair factors including TFIIH, XPG (3'
incision), and XPF-ERCC1 (5' incision) (1, 2, 29). The previously
established protein interactions of the repair factors with RPA and XPA
would position the XPG protein 3' of the DNA adduct and the XPF-ERCC1
protein 5' of the lesion (8, 30-33). The positioning of RPA to the
bottom undamaged DNA strand of the duplex favors the stimulation of DNA synthesis following damaged strand displacement (24, 34, 35). Although
our data are consistent with RPA binding the undamaged strand of
duplex-damaged DNA, RPA has been suggested to bind both strands of
duplex-damaged DNA (36). The difference in binding in this case may
be lesion specific.
The kinetics of the binding reaction of the RPA-XPA complex is
consistent with an increase in DNA damage specificity. The data are
also consistent with the potential for shielding of cisplatin-damaged DNA by HMG-box proteins (37). These HMG-box proteins are highly abundant, and the A and B box domains of HMGB1 bind at rates to cisplatin-damaged duplex DNA substrates at near diffusion (38, 39). The
kinetic data obtained with the RPA-XPA complex reveal a considerably
slower rate of association, and considering the low cellular
concentration of the complex, the potential for HMG-box proteins
associating with the damaged sites before the NER machinery marks the
site for repair is high.
Numerous caveats, however, remain to be investigated, not the least of
which is the role of other proteins that can participate in the
recognition of damaged DNA. The XPC-hHR23B protein complex also plays a
role in the formation of the NER preincision complex (14, 15, 26).
Recent data have demonstrated preferential binding of this complex to
duplex-damaged DNA, and a series of repair kinetic reactions suggests
that the XPC-hHR23B protein could, in some cases, be responsible for
marking damaged sites and initiating repair (15, 40). More recently,
in vivo analysis suggested that in the absence of XPA,
XPC/hHR23B was still capable of relocating to the sites of DNA damage
(21). Although these results suggest that XPC/hHR23B can potentially
associate with damaged DNA, as assessed by immunofluorescence, the
experiment does not reveal how the complex forms in the presence of
XPA. Results were also presented suggesting that XPA was unable to associate with the sites of UV-induced DNA damage in XPC cells. However, the degree of relocation and association of XPA with the
damaged sites observed in wild type cells was minimal, and therefore
the results obtained monitoring XPA relocalization with the XPC cells
are difficult to interpret (21). In addition to XPC-hHR23B and the
XPA-RPA complex, the damaged DNA-binding protein DDB (heterodimer p127
and p48) also preferentially binds damaged DNA and is specifically
involved in the repair of DNA adducts that fail to cause a large change
in thermal stability of the duplex DNA (17, 41). Whether these protein
factors play a role prior to RPA-XPA binding or whether there is a
higher order recognition complex remains to be determined. It will be
interesting to see how XPC-hHR23B and DDB affect the RPA-XPA complex
association with duplex-damaged DNA.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (65K):
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Fig. 1.
EMSA analysis of RPA, XPA, and the RPA-XPA
complex binding a duplex cisplatin-damaged DNA. EMSAs were
performed using the following indicated amounts of RPA, XPA, or the
RPA-XPA complex and 50 fmol of duplex 41-bp DNA containing a single,
centrally located 1,2d(GpG) cisplatin-DNA adduct. The products were
separated on a 4% native polyacrylamide gel and visualized by
autoradiography. Lane 1, no protein; lane 2, 300 ng of XPA; lane 3, 300 ng of XPA plus anti-Xpress Ab;
lane 4, 300 ng of XPA plus anti-RPA p34 mAb; lane
5, 200 ng of RPA; lane 6, 200 ng of RPA plus anti-RPA
p34 mAb; lane 7, 200 ng of RPA plus anti-Xpress Ab;
lane 8, 200 ng XPA and 200 ng of RPA; lane 9, 200 ng of XPA and 200 ng of RPA plus anti-Xpress Ab; lane 10,
200 ng of XPA and 200 ng of RPA plus anti-RPA p34.
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Fig. 2.
Specificity of the RPA-XPA complex for duplex
cisplatin-damaged DNA. A, EMSAs were performed as
described in the legend to Fig. 1 using 50 fmol of duplex
cisplatin-damaged 41-mer with the addition of 2 mM
MgCl2. The products were separated on a 4% native
polyacrylamide gel and visualized by autoradiography. Lane
1, no added protein; lanes 2-5 contain 200 ng of RPA;
lanes 3, 4, and 5 contain increasing
amounts of dI-dC competitor DNA (4, 8, and 12 ng, respectively);
lanes 6-9 contain 200 ng of RPA and 200 ng of XPA
(preincubated on ice); lanes 7, 8, and
9 contain increasing amounts of dI-dC competitor DNA (4, 8, and 12 ng, respectively). B, quantification of RPA binding
duplex cisplatin-damaged DNA (filled circles) as well as the
RPA-XPA complex binding duplex cisplatin-damaged DNA (open
circles) with increasing competitor dI-dC DNA.
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Fig. 3.
RPA denaturation of duplex 41-bp
cisplatin-damaged DNA is inhibited by XPA. A, EMSAs
were performed as described in the legend to Fig. 1 using increasing
concentrations of RPA or the RPA-XPA complex. Lane 1, no
added protein; lanes 2-5, increasing concentrations of RPA
(50, 100, 200, and 300 ng, respectively); lanes 6-9,
increasing concentrations of RPA and XPA (50, 100, 200, and 300 ng,
respectively for each protein); lane 10, 300 ng of RPA and
300 ng of XPA supershifted with the anti-Xpress Ab. B,
denaturation experiments were performed as split reactions with the
binding experiments but the reaction stop buffer contained SDS and
proteinase K to disrupt the protein-DNA interaction as well as excess
cold unlabeled DNA to prevent the re-annealing of the labeled DNA after
the protein-DNA complex had been disrupted. The products were separated
on a 15% native polyacrylamide gel. The triangle symbol
represents the heat-denatured control. Lanes 1-10
correspond to the same lanes as in A. C,
quantification of increasing concentrations of RPA binding
(filled circles) and denaturing (filled squares)
duplex cisplatin-damaged 41-bp DNA as well as the RPA-XPA complex
binding (open circles) and denaturing (open
squares) the same DNA substrate.
View larger version (31K):
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Fig. 4.
Stopped-flow kinetic analysis of RPA and the
RPA-XPA complex binding duplex cisplatin-damaged 41-bp DNA.
Kinetic traces were measured at an RPA concentration of 6.25 nM, an XPA concentration of 25 nM, and a DNA
concentration of 62.5 nM under the same reaction conditions
as in the legend to Fig. 1. The buffer alone and DNA/buffer mix were
used as blank controls (not shown). The control trace of RPA and buffer
mixed is the intrinsic fluorescence that is observed at time 0 and in
the absence of DNA results in a straight trace (not shown). Upon the
mixing of RPA and DNA, there is a time- and DNA-dependent
decrease in RPA intrinsic fluorescence. Each trace is an average of
10-12 measurements at each DNA concentration, and the solid
black line represents the fit to a double exponential decay. The
top trace is the kinetic trace of the RPA-XPA complex, while
the bottom trace is the kinetic trace of RPA. The residual
values for each fit of the data are presented in the panels below the
kinetic traces. B, quantification of the rate constants for
RPA (filled circles) and the RPA-XPA complex (open
circles).
1 s1, and the
koff was 3.54 ± 0.6 s1,
consistent with the rate constants of RPA for a duplex 1,2d(GpG) cisplatin-damaged 30-mer DNA. The kon of the
RPA-XPA complex for the duplex cisplatin-damaged 41-mer DNA substrate
was 0.106 ± 0.01 nM1 s1
with a koff of 0.056 ± 0.95 s1. These results reveal a 2-3-fold difference in the
kon values, and even with the high error rate
for the koff value there is at least a 3-fold
difference in the koff of RPA versus
the RPA-XPA complex for the duplex cisplatin-damaged 41-mer. The
kon of the RPA-XPA complex for the duplex
undamaged 41-mer was 0.026 ± 0.006 nM1
s1 with a koff of 3.93 ± 0.806 s1 (Table I).
These data are consistent with the XPA protein stabilizing RPA binding
to duplex DNA and synergistically affecting the binding to
duplex-damaged DNA.
Kinetic analysis of DNA binding
1 s1, and
the kon for the RPA-XPA complex (open
circles) was 2.09 ± 0.145 nM1
s1. The y intercept value
(koff) for RPA was 0.06 ± 14.7 s1, and the y intercept for the RPA-XPA
complex resulted in a negative value with large errors, indicating a
slow dissociation. The negative value for the y intercept
(koff) is a characteristic feature with high
kobs values and a slow dissociation rate. A
small change in the slope (kon) can result in a
dramatic change in the y intercept, and thus large errors
associated with the koff determinations. These
results demonstrate minimal differences in the rate of association of
RPA in the presence or absence of XPA when binding single-stranded DNA,
and ultimately, XPA has no effect on RPA single-strand DNA binding
kinetics. Interestingly, contaminating single-stranded DNA in mobility
shift assays performed using duplex DNA results in less XPA protein
supershifted by the anti-Xpress antibody (data not shown). These
results suggest that the XPA protein may dissociate from the
RPA-ssDNA complex or RPA binding to single-stranded DNA results in a
conformational change that disrupts the XPA interaction. The RPA-XPA
complex remains intact, however, when the complex binds to duplex DNA,
suggesting a different mode of duplex DNA binding for the RPA-XPA
complex such that XPA can contact and stabilize the duplex DNA.
View larger version (13K):
[in a new window]
Fig. 5.
Stopped-flow kinetic analysis of RPA and the
RPA-XPA complex binding single-stranded 40-mer DNA. Kinetic traces
were measured at a constant RPA concentration of 6.25 nM,
in the absence or presence of 25 nM XPA (preincubated on
ice), and varying DNA concentration from 62.5 to 125 nM.
Each trace used was an average of 10-12 measurements, and the kinetic
traces were fit to a single exponential decay. The observed rate
constants (kobs) were then plotted
versus DNA concentration and fit to a straight line. Data
obtained for RPA binding (filled circles) and RPA-XPA
complex binding (open circles) the single-stranded 40-mer
DNA are presented. Each point represents the average of four separate
experiments, and the error bars represent the S.D. The
kon values for RPA and the RPA-XPA complex are
1.87 nM 1 s1 ± 0.154 and 2.09 nM1 s1 ± 0.145, respectively.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
| |
FOOTNOTES |
|---|
* This work was supported by National Institutes of Health Award CA82741 (to J. J. T.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
To whom correspondence should be addressed: Dept. of Biochemistry
and Molecular Biology, Wright State University, 3640 Colonel Glenn
Highway, Dayton, OH 45435. Tel.: 937-775-2853; Fax: 937-775-3730; E-mail: john.turchi@wright.edu.
Published, JBC Papers in Press, February 21, 2002, DOI 10.1074/jbc.M200816200
| |
ABBREVIATIONS |
|---|
The abbreviations used are: NER, nucleotide excision repair; RPA, human replication protein A; XPA, xeroderma pigmentosum group A protein; kon, association rate; koff, dissociation rate; EMSA, electrophoretic mobility shift assay; ssDNA, single-stranded DNA; Ab, antibody; mAb, monoclonal antibody; DDB, damaged-DNA-binding protein; HMG, high mobility group.
| |
REFERENCES |
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TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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