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Molecular and Cellular Biology, November 1998, p. 6399-6407, Vol. 18, No. 11
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
The Middle Subunit of Replication Protein A
Contacts Growing RNA-DNA Primers in Replicating Simian Virus 40 Chromosomes
Gilad
Mass,
Tamar
Nethanel, and
Gabriel
Kaufmann*
Department of Biochemistry, Tel Aviv
University, Ramat Aviv 69978, Israel
Received 27 March 1998/Returned for modification 26 May
1998/Accepted 6 August 1998
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ABSTRACT |
The eukaryotic single-stranded DNA binding protein replication
protein A (RPA) participates in major DNA transactions. RPA also
interacts through its middle subunit (Rpa2) with regulators of the cell
division cycle and of the response to DNA damage. A specific contact
between Rpa2 and nascent simian virus 40 DNA was revealed by in situ UV
cross-linking. The dynamic attributes of the cross-linked DNA, namely,
its size distribution, RNA primer content, and replication fork
polarity, were determined. These data suggest that Rpa2 contacts the
early DNA chain intermediates synthesized by DNA polymerase 
-primase
(RNA-DNA primers) but not more advanced products. Possible signaling
functions of Rpa2 are discussed, and current models of eukaryotic
lagging-strand DNA synthesis are evaluated in view of our results.
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INTRODUCTION |
The single-stranded DNA (ssDNA)
binding protein (SSB) replication protein A (RPA) participates in
eukaryotic DNA replication (16, 58-60), DNA excision repair
(12), and homologous recombination (22, 32). In
addition, RPA communicates with regulators of the cell division cycle
and of the response to DNA damage (9, 30, 41, 42). RPA is a
heterotrimer, containing subunits of 70, 29 to 34, and 11 to 14 kDa
(Rpa1, -2, and -3, respectively), all of which are conserved among
eukaryotes and essential for viability in Saccharomyces
cerevisiae (6, 7, 16, 34, 58, 59). Although
functionally analogous to prokaryotic SSBs (31), RPA differs
from them in its subunit complexity, in being modified by cellular
regulators, and in its mode of template binding (59).
RPA's roles in DNA replication are inferred primarily from studying
simian virus 40 (SV40) DNA replication in systems reconstituted in
vitro and its binding interactions with defined ssDNA templates and
other replication proteins (13). Such data portray RPA as a
component of a ternary primosome complex whose other members are a
replication initiator-helicase (the viral large T antigen) and DNA
polymerase (Pol) -primase. The primosome assembles at the SV40
replication origin (ori), melts ori duplex DNA,
and primes the leading DNA strands at this site. However, it also
continues to unwind parental DNA and to prime lagging-strand
intermediates throughout the replication cycle (11, 14, 33, 35,
36, 44, 47, 52, 56). In these processes, RPA facilitates parental DNA unwinding, stabilizes the exposed template, and attracts other replication proteins.
The relevant functions of individual RPA subunits are understood in
part. SSB activity has been localized to a central, ~300-amino-acid region of Rpa1 fit to anchor RPA to the template strand (3, 19,
21, 43, 48). The ssDNA portion in direct contact with Rpa1 may be
as small as 8 nucleotides (nt), although the stable, occluded binding
site for RPA has been estimated to be closer to 30 nt (1-3,
26). Rpa2 and -3 form a stable complex that binds Rpa1, probably
via Rpa3 (21, 25, 48). Each of the two smaller subunits
features a single SSB motif found twice in Rpa1. Hence, the subunits
may also bind ssDNA (43). In fact, within RPA, Rpa2
interacts with the primer end of a synthetic primed template
(28). Conceivably, the weak DNA binding potential of the
smaller subunits is bolstered at the replication fork by additional
protein-DNA as well as protein-protein interactions of the primosome.
DNA damage-responsive and cell cycle-regulated protein kinases
phosphorylate the N-terminal domain of Rpa2 (4, 8, 15, 20, 40,
61). DNA damage-induced phosphorylation occurs neither in human
ataxia telangiectasia cells lacking ATM (30) nor in S. cerevisiae with a mutation in the ATM homologue MEC1
(9). Since MEC1 halts S-phase progression in response to
replicative lesions (41, 42), the attendant phosphorylation
of Rpa2 likely mediates the requisite switch between replicative and
repair modes of DNA synthesis. Likewise, phosphorylation of Rpa2 by the
G1/S checkpoint cyclin-dependent kinase 2 may be related to
entry into S phase (46). Investigating the function of Rpa2
at the replication fork may provide clues to the relation between the
phosphorylation of this subunit and the modulation of DNA synthesis.
To address this issue, Rpa2's interaction with nascent DNA was
monitored within replicating SV40 chromosomes by protein-DNA UV
cross-linking. The data indicate that Rpa2 contacts an early intermediate produced by Pol -primase (RNA-DNA primer [10, 37, 39, 53], henceforth RDP) but does not contact
more-advanced products. This observation suggests a link between the
replicative and signaling functions of RPA and provides a new vantage
point from which to evaluate current models of eukaryotic
lagging-DNA-strand synthesis.
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MATERIALS AND METHODS |
Materials.
Monoclonal antibodies (MAbs) specific to Rpa1 and
Rpa2, namely, anti-SSB70A, anti-SSB70B, anti-SSB70C, and anti-SSB34A
(25), as well as rabbit polyclonal antibodies raised against
Rpa3, were received from Jerard Hurwitz, Memorial Sloan-Kettering
Cancer Center, New York, N.Y. Sara Lavi, Tel Aviv University, also
provided the anti-Rpa1 and anti-Rpa2 MAbs. Protease inhibitor cocktail tablets (Complete Mini) were purchased from Boehringer Mannheim. Other
materials were as described previously (62).
DNA-protein UV cross-linking in replicating SV40
chromosomes.
Nuclear monolayers from SV40-infected CV-1 cells were
prepared essentially as described previously (62). However,
Complete Mini tablets, used according to the manufacturer's
instructions, replaced the protease inhibitor cocktail. The nuclear
monolayers were gently agitated at 30°C for the times indicated in
the figures with, per 100-mm-diameter plate, 600 to 1,200 µl of the
replication mixture (50 mM K-acetate, 5 mM MgCl2, 2 mM
dithiothreitol [DTT], 100 µg of leupeptin per ml, 0.05% Nonidet
P-40, 2 µM [each] dGTP and dCTP, 20 µM bromodeoxyuridine
triphosphate [BrdUTP], 0.5 µM [-32P]dATP [500
Ci/mmol], 2 mM ATP, and 20 µM concentrations of other radioactive
nucleoside triphosphates [rNTPs]). In the chase mixtures, 100 µM
dATP and 1 mM dTTP replaced the radioactive and photoreactive deoxyNTPs
(dNTPs) and the nuclear monolayers were further incubated as indicated
in the figures. When nascent DNA was labeled in the RNA primer moiety,
the corresponding replication mixture contained 0.5 µM
[-32P]UTP (3,000 Ci/mmol), 2 mM ATP, 20 µM
concentrations of the three other rNTPs, 20 µM BrdUTP, 2 µM
concentrations of the other dNTPs, and 200 µg of -amanitin per ml.
To end the reaction, the overlaying mixture was removed and the plates
were chilled on ice. The plates were then placed on a model TFX-20M
transilluminator (Vilber-Lourmat), providing a radiation spectrum with
a peak at 312 nm. After irradiation for 6 to 10 min at 4°C, the
nuclear monolayers were washed with 1 ml of 5 mM K-acetate-0.5 mM
MgCl2-2 mM DTT-30 mM K-HEPES buffer (pH 7.4). Viral DNA
and cross-linked proteins were extracted from the nuclei with sodium
dodecyl sulfate (SDS)-NaCl buffer (23). Subsequently, the
photolabeled proteins were extracted with phenol and precipitated from
the phenol phase and interphase with acetone (62). Where
indicated below, the acetone precipitate was resuspended in 250 µl of
DNase buffer (40 mM Tris-HCl [pH 8.0], 6 mM MgCl2, 1.5 mM
CaCl2) containing 0.4 mg of bovine serum albumin (BSA) per
ml, the protease inhibitors, and 10 U of DNase I. Following incubation
for 30 min at 37°C, an equal volume of 2× denaturation buffer (100 mM Tris-HCl [pH 7.5], 1% SDS, 140 mM 
-mercaptoethanol) was added
and the mixture was boiled for 10 min. Proteins and covalently linked
nascent DNA were separated from free DNA by a second extraction with
aqueous phenol and precipitated as described above. When
characterization of the cross-linked DNA was intended, the first
acetone precipitate was dissolved in 500 µl of 1× denaturation buffer without prior DNase I digestion. The photolabeled proteins were
dissociated from the replicating viral DNA by boiling for 10 min,
phenol extracted, and precipitated with acetone as described above.
Reference protein markers for Western blot analysis were provided by
DNase I-digested nonradioactive nuclear extracts prepared essentially
as described above but without cross-linking.
To isolate photolabeled RPA heterotrimer, pulse-labeling of nascent DNA
and UV cross-linking were performed with isolated replicating SV40
chromatin, essentially as described previously (62) but with
some modifications. Complete Mini tablets replaced protease inhibitors
in all solutions used for tagging and processing the cross-linked
chromatin. The concentration and specific activity of
[-32P]dATP were as described above. Following
pulse-labeling, the mixtures were transferred into a polystyrene
culture plate and irradiated as described above. The plate was then
washed twice with 300 µl of ice-cold low-salt buffer (20 mM HEPES-Na
[pH 7.8], 5 mM K-acetate, 0.5 mM MgCl2, 0.5 mM DTT)
followed by centrifugation at 220,000 × g for 90 min
through a 200-µl 10% glycerol cushion in low-salt buffer. The
chromatin pellet was suspended in 250 µl of DNase buffer, digested as
described above with DNase I, and prepared for native
immunoprecipitation by dilution with 5 volumes of 50 mM Tris-HCl (pH
7.5)-150 mM NaCl-1% Nonidet P-40. The resultant suspension was
clarified by centrifugation at 4°C and 10,000 × g
for 30 min.
Immunochemical detection of photolabeled RPA subunits.
The
photolabeled proteins of the acetone precipitate were dissolved in 100 µl of 1× denaturation buffer and denatured by boiling for 10 min.
They were then partially renatured by diluting the samples with 9 volumes of ice-cold washing buffer (50 mM Tris-HCl, [pH 7.5], 150 mM
NaCl) containing 0.5% Nonidet P-40 and the protease inhibitors.
Myeloma immunoglobulin G (IgG; 10 µg) used for preclearing was
adsorbed to 4 µg of protein A-Sepharose via 20 µg of rabbit anti-mouse IgG in 300 µl of PBS (10 mM potassium phosphate buffer, [pH 7.4], 0.15 M NaCl) containing 1% BSA. The washed beads were incubated with the photolabeled protein mixtures for 3 h at 4°C on a rotator. Rabbit anti-mouse IgG was also used to enhance binding to
protein A-Sepharose of the anti-RPA MAbs except anti-SSB70B and the
polyclonal anti-Rpa3 antibodies that were adsorbed as such.
Anti-SSB34A, anti-SSB70A, and anti-SSB70B hybridoma supernatants were
used in amounts of 1, 2, and 2 ml, respectively. Purified anti SSB70C
was used at 12 µg, the anti-Rpa3 antiserum was used at 4 to 10 µl,
and both were adsorbed to protein A-Sepharose in 300 µl of PBS-BSA as
described above. The precleared preparation was supplemented with, as
the carrier, 1 mM dATP or UTP and 100 µg of denatured salmon sperm
DNA per ml. This mixture was added to the protein A-antibody beads, and
the suspension was rotated for 6 to 16 h at 4°C. The beads were
rinsed four times with washing buffer containing 0.2% Nonidet P-40.
Antibody-antigen conjugates were released by heating the suspension at
95°C for 10 min in 20 µl of 2× SDS-polyacrylamide gel
electrophoresis (PAGE) sample buffer and separated on SDS-10% (if not
otherwise indicated) polyacrylamide gels. The gels were blotted on a
nitrocellulose membrane or dried. Radioactivity was monitored and
quantified by phosphorimaging (Fujix Bas 1000; Fuji) or autoradiography
and densitometry (ScanJet 3p; Hewlett-Packard). TINA software (Raytest
Isotopenmessgeräte GmbH), compatible with the TINA-PCBAS and TIFF
files of the phosphorimager and scanner, respectively, was applied in
both cases. These tools were also used for the densitometry of the
enhanced-chemiluminescence (ECL) autoradiograms. The cross-linking
intensity (CI) is the densitometric signal of the photolabeled protein
normalized to the ECL signal of the immunoprecipitated counterpart. The
relative labeling of RDP is the radioactivity in the 10- to 35-nt
region divided by that in the 10- to 250-nt region representing the
entire spectrum of Okazaki fragments and their precursors.
Photolabeled RPA heterotrimer was immunopurified from the cross-linked
and DNase I-digested replicating SV40 chromatin. Following
preclearing
with a nonspecific antibody, as described above, native
immunoprecipitation was performed with each of the three anti-Rpa1
MAbs
(anti-SSB70A, anti-SSB70B, and anti-SSB70C) as well as with
anti-SSB34A. The immunoprecipitates were released from protein
A beads
by heating the beads in 2× sample buffer as described
above followed
by washing in 200 µl of denaturation buffer. The
supernatants were
combined and extracted with phenol, and the
proteins were precipitated
from the phenol phase and interphase
with acetone, as described above.
The precipitates were denatured
at 100°C for 10 min in 20 µl of
SDS-PAGE sample buffer and separated
on a gradient gel of SDS-8 to
15% polyacrylamide. Positions of
RPA subunits were determined by
sequential probing of an immunoblot
with antibodies directed against
each subunit. Photolabeled derivatives
were detected by
autoradiography.
Sizing cross-linked DNA chains.
Gel portions containing
photolabeled proteins of interest were excised, swollen in 10 mM
Tris-HCl (pH 7.5)-0.1 mM EDTA, and ground. The slurry was suspended in
300 µl of a similar buffer containing 1% SDS and 100 µg of
proteinase K per ml and incubated for 2 h at 37°C. A comparable
gel portion was extracted without protease to detect any free DNA
migrating with the photolabeled conjugate on the SDS-polyacrylamide
gel. The released DNA was mixed with 5 µg of carrier plasmid DNA or
yeast tRNA and extracted with phenol, precipitated with ethanol,
dissolved in formamide, and separated on a denaturing 12%
polyacrylamide-7 M urea gel in 25 mM Tris-borate buffer, pH 8.3. After
autoradiography and densitometric scanning, the profile of the
unproteolyzed control was subtracted from that of the proteolyzed
sample to yield the net profile of DNA released from the photolabeled
protein.
Determination of replication fork polarity.
Replication fork
polarity was determined by gel mobility retardation of the Rpa2
conjugate and by dot blot hybridization of the DNA released from it. In
the first analysis, immunoprecipitated, photolabeled Rpa2, taken from
half of a 100-mm-diameter plate, was dissolved in 25 µl of SDS-PAGE
sample buffer containing 3 µg of either ssDNAs of pairs of M13mp10
clones encoding the lagging or leading SV40 template strands
(38) or vector DNA. Following heating to 100°C for 1 min
and slow cooling to 30°C, the mixtures were separated by SDS-PAGE.
The radioactive species were detected by autoradiography. In the second
analysis, DNA was released from the Rpa2 conjugate and purified as
described above. It, along with an isolated RDP control, was then
hybridized to dot blots, each containing 1 µg of ssDNA of one of the
four template clones described above or of the vector DNA.
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RESULTS |
Interaction of Rpa2 with nascent SV40 DNA.
Mammalian
replication proteins can be detected in situ by combining DNA-protein
UV cross-linking with immunopurification (62). This protocol
was adapted to monitor possible interactions between RPA and nascent
SV40 DNA and eventually characterize the cross-linked DNA. Briefly,
viral chromosomes replicating within nuclear monolayers or in a soluble
fraction were pulse-labeled from photoreactive DNA precursor (5-BrdUTP)
and radioactive dNTP or rNTP precursors. Following UV irradiation of
the replication mixture, SV40 DNA and any cross-linked proteins were
extracted. The photolabeled proteins were separated from the bulk
nascent DNA, before or after DNase I digestion, depending on whether
only their detection was intended (Fig. 1 to 3) or their detection as
well as a characterization of the cross-linked DNA was required (Fig. 4
to 6).
Rpa2 was immunopurified from the denatured photolabeled protein mixture
with the cognate MAb anti-SSB34A and then visualized
by Western
blotting with the same antibody (Fig.
1A). Photolabeled
derivatives were
detected by autoradiography (Fig.
1B). Autoradiography
revealed a
radioactive product migrating between the 32.5- and
47-kDa size markers
(lane 1), above the positions of the Rpa2
species detected by
immunoblotting in the original protein mixture
(Fig.
1A, lane 1) and
the immunoprecipitates (lanes 3 to 5). Similar
retardation, by the
equivalent of 6 to 8 kDa, has been observed
with a cross-linked 17-nt
adduct (
28). The radioactive Rpa2
derivative was seen
neither in the nonirradiated control (Fig.
1B, lane 2) nor in that
containing dTTP instead of BrdUTP (lane
3), indicating covalent linkage
of DNA and protein. To compare
the photolabeling potentials of the
three RPA subunits, the intact
RPA heterotrimer was precipitated under
native conditions from
the photolabeled protein mixture derived from
replicating SV40
chromatin. In this case, the three anti-Rpa1 MAbs
(anti-SSB70A,
anti-SSB70B, and anti-SSB70C) and anti-SSB34A were used
in separate
immunoprecipitation attempts. After resolution of the
individual
subunits by denaturing gel electrophoresis, they were
detected
by immunoblotting and autoradiography. This process indicated
that while all three subunits were precipitated, Rpa2 received
the bulk
of the photolabel; about 20% appeared in an Rpa1 derivative
and none
appeared in Rpa3 (Fig.
1C). The bias in favor of Rpa2
was observed
regardless of the subunit specificity of the immunoprecipitating
antibody (Fig.
1D).
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FIG. 1.
UV cross-linking of Rpa2 with nascent SV40 DNA. Proteins
were photolabeled with nascent DNA within replicating SV40 chromosomes
pulse-labeled by BrdUTP and [-32P]dATP for 90 s.
Following DNase I digestion, Rpa2 was immunopurified and detected by
immunoblotting and autoradiography, as described in Materials and
Methods. (A) Immunoblot probed with anti-SSB34A. Proteins extracted
from a nonlabeled control nuclear monolayer (lane 1), antibody alone
(lane 2), the immunoprecipitates of cross-linked proteins derived from
the standard reaction mixture (lane 3), a nonirradiated control (lane
4), or a control with dTTP instead of BrdUTP (lane 5) are shown. (B)
Autoradiogram of proteins immunoprecipitated from the standard mixture
(lane 1), a nonirradiated control (lane 2), or the control with dTTP
instead of BrdUTP (lane 3). (C) Immunoprecipitation of the photolabeled
RPA heterotrimer. RPA was immunoprecipitated under native conditions
from the photolabeled protein mixture derived from replicating SV40
chromatin with anti-SSB34. After separation by SDS-PAGE, individual RPA
subunits were detected by immunoblotting and photolabeled derivatives
were detected by autoradiography. (D) Densitometric tracings of
photolabeled RPA precipitated under native conditions by the indicated
MAbs and resolved by SDS-PAGE as described for panel C. H
and L indicate heavy and light Ig chains, respectively. The
arrows and arrowheads point to the ECL signal of Rpa2 and the
photolabeled derivative, respectively. Ctrl, control; Ipc,
immunoprecipitated cleared Rpa.
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Dynamics of the interaction between Rpa2 and nascent DNA.
The
maturation kinetics of the nascent-DNA chains and the dynamics of the
interaction between Rpa2 and nascent DNA were compared in
continuous-labeling and pulse-chase experiments. Rpa2's CI leveled off
within ~30 s (Fig. 2A, B, and D),
similar to the rate at which the absolute labeling of the RDP fraction
reached a steady-state value (Fig. 2C and D) (38). Moreover,
Rpa2's CI decayed with a half-life of ~1 min (Fig.
3A, B, and D), faster than the conversion of RDPs into larger products (Fig. 3C and D). These data suggest that
Rpa2 contacts RDPs and dissociates from them before further processing.
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FIG. 2.
Behavior of Rpa2's photolabel in continuous labeling.
Protein-DNA conjugates were prepared after the indicated pulse-labeling
times. Rpa2 was then immunopurified and detected by autoradiography and
Western blot analysis, essentially as described in Materials and
Methods and in the legend of Fig. 1. (A) Autoradiogram of photolabeled
Rpa2; (B) immunoblot; (C) pattern of nascent-SV40-DNA chains from
aliquots of the same replication mixtures; (D) Rpa2 CI (open squares)
and absolute labeling (A.L.) of the RDP fraction (filled triangles)
versus labeling time. H and L indicate heavy and
light Ig chains, respectively. The arrow points to the ECL signal of
Rpa2; the arrowhead points to the photolabeled derivative. Ctrl,
control. M, DNA size markers (in nucleotides).
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FIG. 3.
Pulse-chase kinetics of Rpa2's photolabel. SV40 DNA
pulse-labeled for 90 s with BrdUTP and [-32P]dATP
was chased with dTTP and nonlabeled dATP as indicated. After UV
cross-linking, Rpa2 was immunopurified and detected as described in
Materials and Methods and in the legend of Fig. 1. (A) Autoradiogram;
(B) immunoblot; (C) patterns of nascent SV40 DNA during chase; (D) Rpa2
CI (open squares) and relative labeling (R.L.) of the RDP fraction
(filled triangles) versus chase time. The photolabeled protein samples
shown in panel A were isolated from the bulk (90%) of the reaction
mixture, and the blot showing them was exposed for a week. The total
nascent DNA shown in panel C represents 10% of the reaction mixture,
and the gel containing it was exposed for 16 h. H and
L indicate heavy and light Ig chains, respectively. The
arrow points to the ECL signal of Rpa2; the arrowhead points to the
photolabeled derivative. M, DNA size markers (in nucleotides).
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Size distribution of nascent DNA cross-linked to Rpa2.
To size
the nascent-DNA chains cross-linked to Rpa2, a gel portion containing
the original conjugate not treated with DNase I (Fig.
4A, lane 3) was digested with proteinase
K. The released DNA was extracted with phenol and separated by
denaturing gel electrophoresis, which revealed a major group of
products ranging between ~10 and 35 nt and another group ranging
between ~120 and 140 nt (Fig. 4B, lane 7). The latter, also extracted
without proteolysis (Fig. 4B, lane 8), represented free DNA that was
not covalently linked to Rpa2 but that migrated with the photolabeled
protein in an SDS-polyacrylamide gel. The residual radioactivity seen in Fig. 4A, lane 3, between the well and the defined photolabeled Rpa2
band did not represent Rpa2 cross-linked to longer DNA chains. Blotting
onto nitrocellulose removed this residue (lane 4), showing it to be
free DNA not covalently bound to protein. Moreover, identical baseline
intensities of the clarified region were obtained whether or not the
Rpa2 conjugates had been subjected to digestion with DNase I (compare
lanes 4 and 5). Moreover, the DNase I treatment only slightly changed
the width, intensity, and position of the photolabeled Rpa2 band,
consistent with the shortness of the original cross-linked chains (Fig.
4B, lane 7). Figure 4C compares the net scanned profile of the DNA
released from Rpa2 (the difference between the densitometric tracings
of lanes 7 and 8) to the profile of the original nascent DNA (derived
from Fig. 4B, lane 9). While RDP-sized chains (area bordered by the
34-nt marker) constituted the bulk of DNA linked to Rpa2, they
exhibited about 20% of the radioactivity of the "Okazaki zone" of
total nascent DNA. We also determined the sizes of DNAs released from
anonymous proteins found in the original mixture of photolabeled
proteins (Fig. 4A, lane 1) or the preclearing precipitate (Fig. 4A,
lane 2). Inspection of the respective autoradiograms (Fig. 4B, lanes 1 to 6) and derived net profiles yielded distributions of approximately
15 to 200, 30 to 80, and 15 to 70 nt (Fig. 4C). Considered together,
these data indicated that selective binding of RDP-like chains is a distinctive property of Rpa2.
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FIG. 4.
Sizing of nascent-DNA chains cross-linked to Rpa2. (A)
Photolabeled Rpa2 not treated with DNase I was isolated from
replication mixtures that had been pulse-labeled for 90 s as
detailed in Materials and Methods. Crude photolabeled protein mixture
(Total; lane 1); photolabeled proteins of the preclearing precipitate
(Prcl; lane 2); immunoprecipitated cleared photolabeled Rpa2 (Ipc; lane
3); and nitrocellulose blots of the Rpa2 conjugate separated by
SDS-PAGE, before or after DNase I digestion (lanes 4 and 5, respectively), are shown. (B) Portions of the bracketed gel sections
a to c and Rpa2 (from panel A, lanes 1 to 3) were incubated with either proteinase K (Prot.K) (lanes 1, 3, 5, and 7) or buffer only (lanes 2, 4, 6, and 8). DNA was phenol extracted
from the gel sections and separated by denaturing polyacrylamide-urea
gel electrophoresis. Lane 9 contains an aliquot of nascent SV40 DNA
(Total nasc. DNA) of the same replication mixture. The arrow marks the
position of the ECL signal of Rpa2, and the arrowhead marks the
position of the photolabeled derivative M, DNA size markers (in
nucleotides). (C) Densitometric tracings of the total and released DNA
preparations of panel B. The profile of the total DNA is shown. Net
profiles of the DNA populations released from the indicated sections of
panel A were obtained by subtracting the profile of an unproteolyzed
sample (even-numbered lanes in panel B) from the original profile of
the matched proteolyzed sample (odd-numbered lanes). However, residual
spikes of large chains remained in the net profiles in sections
b and c. These spikes coincide with the free-DNA
contaminants and probably result from an excess of proteolyzed over
unproteolyzed sample in the paired samples. The size distributions of
chains in profiles a to c were estimated by
setting their half-maximal heights as lower and upper borders. A.U.,
arbitrary absorption units.
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Lagging-strand polarity of DNA chains cross-linked to Rpa2.
The fork polarity of the DNA cross-linked to Rpa2 was determined by
hybridization to SV40 ssDNA probes, representing the lagging or leading
template strands, cloned in the M13 phage vector (38). Photolabeled Rpa2 not treated with DNase I was incubated under hybridization conditions with either lagging- or leading-strand probes
or with the vector DNA, and the mixtures were resolved by SDS-PAGE. The
nonhybridized conjugate and the hybridized form, expected at the well,
were detected by autoradiography. As shown, the lagging-strand probes
retained a considerable fraction of the radioactivity at the well, with
the result that the intensity of the upper portion of photolabeled Rpa2
band was reduced (Fig. 5A, lane 4). The
reason for the preferential retention seems to be the presence of the
longer and better-hybridizing RDPs in this portion. In contrast, the
leading-strand template retained only a residual fraction of the
radioactivity at the well, about one-fifth of that seen with the
lagging-strand template, and hardly reduced the intensity of the Rpa2
band (lane 3). In a complementary experiment, DNA released from
photolabeled Rpa2 was hybridized to the individual probes on dot blots.
In this case, a three- to fourfold bias in favor of the lagging-strand
templates was found (Fig. 5B, lane 1). However, an RDP fraction
purified directly from the replication mixture (Fig. 2C) hybridized to
the same dots with a bias greater than 10-fold in favor of the
lagging-strand templates (Fig. 5B, lane 2). The smaller bias seen with
the Rpa2 conjugate and with the DNA released from it is attributed to
increased contamination by fragments of long nascent chains due to the
requisite higher specific radioactivity employed (500 versus 100 Ci/mmol) and longer isolation procedure. An alternative possibility,
that Rpa2 also contacted leading chains, seems less likely since
conjugates that were cross-linked to long nascent-DNA chains, expected
at the top of the original SDS-polyacrylamide gel, were not evident.
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FIG. 5.
Determination of fork polarity of DNA cross-linked to
Rpa2. (A) Rpa2 cross-linked to intact nascent-DNA chains was
immunopurified and hybridized to pairs of M13-SV40 ssDNA clones of
leading (LD)- or lagging (LG)-strand fork polarity. The mixtures were
resolved by SDS-PAGE and autoradiographed as described in Materials and
Methods and the legend of Fig. 4. Lanes: 1, not hybridized; 2, vector;
3, mSVBH10 and mSVTB10 (clockwise replication fork [CW] and
counterclockwise replication fork [CCW] leading-strand templates,
respectively); 4, mSVBH11 and mSVTB11 (CW and CCW lagging-strand
templates, respectively). (B) Nascent DNA was released by proteolysis
of photolabeled Rpa2 (from Fig. 4B, lane 7). Following extraction from
the gel, it was hybridized to dot blots containing the indicated
leading- and lagging-strand probes (blot 1), along with a purified RDP
fraction from Fig. 2C (blot 2) or vector DNA labeled by random priming
(blot 3). XDNA, DNA released from the cross-linked Rpa2-DNA conjugate;
RDP, RDP fraction; M13, vector DNA. The arrow indicates the position of
the ECL signal of Rpa2, and the arrowhead indicates the photolabeled
derivative.
|
|
Nascent DNA cross-linked to Rpa2 is covalently linked to RNA.
The presence of RNA primers in the nascent DNA cross-linked to Rpa2 was
established by pulse-labeling the replicating DNA from
[-32P]UTP. Subsequent UV cross-linking and
immunopurification revealed photolabeling of Rpa2 in the standard
mixture but not in a control containing dTTP instead of BrdUTP (Fig.
6A, compare lanes 2 and 3). Hence, the
radioactively labeled RNA was linked to Rpa2 through the cross-linked
DNA moiety. Photolabeled in this manner, Rpa2 was resolved into two
bands. The more intense, designated l, traveled near the
major ECL signal of free Rpa2. The slower and fainter band
(h) was retarded by the equivalent of ~8 kDa and resembled in this regard Rpa2 photolabeled with a radioactive DNA precursor (Fig.
4A). Exhaustive proteolysis released from bands h and
l chains of 20 to 30 and 10 to 15 nt, respectively (Fig. 6C,
lanes 2 and 4). This difference may account, at least in part, for the difference in the electrophoretic mobilities of the parental
photolabeled protein species h and l. Although
the cross-linked nascent-DNA chains radiolabeled in the RNA moiety were
also within the RDP size range, they appeared shorter, on average, than
those radiolabeled in the DNA moiety (Fig. 4B, lane 7). This
discrepancy is attributed to accentuation of the shorter chains in the
number distribution due to radiolabeling of the fixed-size RNA moiety
as opposed to enhancement of the longer chains in the weight
distribution due to radiolabeling of the variable DNA moiety. Moreover,
in the RNA radiolabeling mode, Rpa2 may be photolabeled as soon as the first photoreactive deoxynucleoside monophosphate (dNMP) residue is
incorporated into the growing RDP; in the DNA radiolabeling mode, both
the photoreactive and radioactive dNMPs are required.
View larger version (28K):
[in this window]
[in a new window]
|
FIG. 6.
Cross-linking of Rpa2 to nascent DNA labeled in the RNA
primer moiety. Protein-DNA conjugates radiolabeled from
[-32P]UTP were prepared and detected by
autoradiography and Western blotting, and the cross-linked DNAs were
sized, as detailed in Materials and Methods. (A) Autoradiogram of a
preclearance (Prcl) immunoprecipitate (lane 1), an Rpa2
immunoprecipitate of a control replication mixture containing dTTP
instead of BrdUTP (lane 2), or the standard mixture (lane 3). (B)
Immunoblot probed with the anti-Rpa2 MAb. Shown are proteins extracted
from a nonlabeled control (Cntrl) nuclear monolayer (lane 1), antibody
alone (lane 2), a preclearance immunoprecipitate (lane 3), and Rpa2
immunoprecipitates from reaction mixtures without (lane 4) or with
(lane 5) BrdUTP. (C) Nascent RNA-DNA released by proteolysis from
photolabeled Rpa2 species of bands h and l (from
panel A, lane 3) was resolved by gel electrophoresis (lanes 2 [band
h] and 4 [band l]) along with respective
unproteolyzed controls (lanes 1 and 3). h and l
designate slow- and fast-migrating photolabeled Rpa2 species,
respectively. H and L indicate heavy and light Ig
chains, respectively. Prot.K proteinase K; M, protein size markers (in
thousands). The arrow indicates the ECL signal of Rpa2, and the
arrowhead indicates at the photolabeled derivative.
|
|
| |
DISCUSSION |
Within the replicating SV40 chromosome, Rpa2 contacts RDPs, the
products of Pol -primase but not more advanced intermediates. This
conclusion is based on the preferred cross-linking of Rpa2 (over Rpa1)
to nascent SV40 DNA, kinetic attributes of the nascent-DNA chains
cross-linked in situ to Rpa2, the size distribution of these
cross-linked nascent-DNA chains, RNA primer content, and lagging-strand
polarity (Fig. 1 to 6). These data also reinforce previous conclusions
about the potential of Rpa2 to interact with DNA (28, 43),
suggest a link between replicative and signaling functions of RPA, and
provide a new vantage point from which to examine lagging-DNA-strand
synthesis (45). Below, we elaborate on these issues.
Rpa2 may contact the growing ends of RDPs.
SSB activity was
originally localized to Rpa1 (59), but recent evidence
indicates that the smaller RPA subunits may also be endowed with this
property. Philipova et al. have detected in the essential domains of
Rpa2 and -3 a single copy of an SSB motif present twice in Rpa1
(43). They have also noted the weak SSB activity of Rpa2, as
have others with the Rpa2-Rpa3 complex (46a). What could
this SSB activity signify? Results of X-ray diffraction of a cocrystal
containing the DNA binding domain of Rpa1 and an octanucleotide ligand
indicate that the C-proximal domain of Rpa1 points toward the growing
end of the primer strand (3). Since the C domain binds Rpa2
and -3 (18), Rpa2 may itself be near the primer end. In
fact, Rpa2 has been cross-linked to the 3' end of the primer strand of
an RPA-primed template complex, and this reaction depended on the
ability of Rpa1 to bind the template (28).
In what follows, we try to integrate the above facts and various
attributes of the DNA cross-linked to Rpa2 (Fig.
2 to
6)
into a
preliminary viewpoint about the position and function of
this subunit
at the replication fork (Fig.
7).
Accordingly, Rpa2
is situated to bind with its SSB motif a few dNMP
residues at
the 3' end of the growing RDP. To maintain this position
during
RDP elongation, Rpa2 translocates with the growing end. Upon RDP
completion, the contact is disrupted and RPA recycles to a new
priming
site. Our observations that support this scheme are, first,
that the on
and off rates of the contact between Rpa2 and nascent
DNA matched the
turnover kinetics of RDP (Fig.
2 and
3) and, second,
that Rpa2
cross-linked with the entire spectrum of RDPs but not
more advanced
intermediates (Fig.
4 and
6).
The ability of Rpa2 to interact with the 3' end of the primer strand
justifies reevaluation of RPA's site size estimates (
1,
2,
26,
27). Namely, different parts of model oligonucleotides
used to
determine this parameter can mimic different parts of
a primed
template, especially when RPA is limiting and the ligand
is large
enough to accommodate more than one subunit. Related
to this may be the
enhanced hyperphosphorylation of Rpa2 by the
DNA-dependent protein
kinase when RPA binds its ligand in the
large-site mode (
1).
Presumably, contact of Rpa2 with a portion
of the ligand under these
conditions renders this subunit a better
substrate for the kinase.
How can the SSB motif of Rpa2 recognize the primer end if the latter
exists in duplex configuration? One possibility is that
such
recognition is enabled by spontaneous or RPA-assisted fraying
of the
duplex (
17,
49). Nucleotide misincorporation and stalling
of
the fork also induce unwinding of the primer end, shifting
it from the
Pol to the proofreading site in certain Pols (
54).
However,
because Pol
lacks a proofreader (
55), it is tempting
to
speculate that associated Rpa2 compensates for this deficiency,
acting
as a potential sensor of the disabled primer end.
Rpa1 also cross-linked the primer strand, albeit more weakly than Rpa2.
This interaction was observed both in SV40 chromosomes
replicating in
solution (Fig.
1C and D) or in nuclear monolayers
(data not shown) and
within a complex of purified RPA and a synthetic
primed template
(
28). In contrast, when purified RPA interacts
with
single-stranded oligonucleotides, the affinity of Rpa1 to
the ligand is
orders of magnitude greater than that of Rpa2 (
59).
Therefore, the weaker binding of Rpa1 to the primer strand may
reflect
inadvertent interaction of RPA with traces of nascent
DNA dissociated
from the replicating chromosomes. Alternatively,
Rpa1 does interact
with the primer strand, either upstream or
downstream of the gap RPA
occupies, but this interaction is much
weaker than that with the
template strand. The apparent failure
of Rpa3 to cross-link nascent DNA
(Fig.
1C) may indicate that
its SSB motif is idle, at least in ongoing
replication. Alternatively,
Rpa3 interacts with the primer strand under
different circumstances
or interacts with the template strand. To
address these problems,
it will be necessary to characterize all
binding interactions
of the three subunits with model primed templates
and more complex
systems that support the DNA transactions in which RPA
partakes.
Possible signaling functions of Rpa2 within and beyond the
replication fork.
Interaction with the growing primer end may
qualify Rpa2 as a signal transducer within the replication apparatus,
adapting the RPA heterotrimer itself or associated replication proteins to changes induced by DNA chain growth. RPA may be adjusted in this
manner to the diminishing ssDNA template, being switched, perhaps,
between its different binding modes (2) and/or induced to
translocate to the next priming site. Rpa2 may also relay the growth
signal to the associated Pol -primase (5), permitting its
progress along the template (51, 57) and/or cycling to a new
priming site. Discontinuous translocation of the transcribing Escherichia coli RNA Pol has been proposed (inchworm model
[51]), and an analogous mechanism may also benefit DNA
Pol (57), allowing them to advance along rather than around
their template. The strong pause site in RDP synthesis, accentuated by
ATP depletion (39), hints that Pol -primase translocates
in such a manner.
Interaction of Rpa2 with the growing end of the primer and the reported
interactions of Rpa2 with regulatory protein kinases
(
40,
59) implicate this subunit also in transduction of signals
beyond
the replication apparatus. For example, Rpa2 may report
the condition
of a disabled primer end to DNA damage-responsive
checkpoints.
Alternatively, signals received from checkpoints
may be transmitted by
Rpa2 to an associated replicative or repair
protein and, in turn, shift
the synthetic apparatus between the
replicative and repair modes
(
29a). Although there is no evidence
that Rpa2
phosphorylation inhibits ongoing SV40 DNA replication
in experimental
systems reconstituted in vitro (
20,
29), this
possibility
remains to be explored under conditions closer to
the physiological.
The use of cellular replication systems, which
are more responsive to
checkpoints, may also be revealing. Such
studies should also address
the possible connection between the
status of the primer end and Rpa2
phosphorylation.
Evaluation of models for lagging-DNA-strand synthesis.
Models
of eukaryotic lagging-DNA-strand synthesis termed "initiation zone"
and "nested discontinuity" have been described previously (38,
39, 45). Their current versions share the notion that RDPs
produced by Pol -primase are further processed by PCNA-dependent Pol
. At ori, RDPs are extended into leading DNA strands.
Those synthesized later are incorporated into Okazaki fragments of up
to ~200 nt (10, 37-39, 44, 45, 50, 53). It is with regard
to the last step that the two models digress. In the first model, an
Okazaki fragment arises by continuous elongation of a single RDP; in
the second model, a contiguous array of RDPs matures into an Okazaki
fragment in a repair-like process (38, 39). Hence, each
model predicts a different population of nascent-DNA chains facing
Rpa2: the entire spectrum of Okazaki fragment intermediates in the
first model and only RDPs in the second. Selective cross-linking of
RDPs to Rpa2 (Fig. 2 to 4 and 6) is consistent with the second model.
Further support is lent to that model by the high intrinsic affinity
and low cooperativity of RPA binding to the ssDNA target (27). These binding properties, which distinguish RPA from
prokaryotic counterparts, hint that, in vivo, the eukaryotic protein
encounters templates comprising a single or only a few binding sites.
In fact, in nucleotide excision DNA repair, RPA interacts with a template of up to ~30 nt (24). A similar portion may be
available at the onset of the RDP cycle, according to the nested
discontinuity model.
| |
ACKNOWLEDGMENTS |
We thank Jerard Hurwitz and Sara Lavi for providing anti-RPA
antibodies, Marc Wold and Olga Lavrik for making results available prior to publication, and Mark Wold and Rolf Knippers for critical readings of the manuscript.
This work was supported by grants from the U.S.-Israel Binational
Science Foundation, the Israel Cancer Society, and the German-Israeli Foundation for Research and Development to G.K.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biochemistry, Tel Aviv University, Ramat Aviv 69978, Israel. Phone:
972-3-640-9067. Fax: 972-3-642-6213. E-mail:
kaufmann{at}post.tau.ac.il.
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0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
