(Received for publication, November 11, 1996)
From the Sections of Microbiology and of Molecular and Cellular Biology, University of California, Davis, California 95616-8665
Protein-promoted DNA strand exchange requires
formation of an active presynaptic complex between the DNA-pairing
protein and single-stranded DNA (ssDNA). Formation of such a contiguous
filament is stimulated by a ssDNA-binding protein. Here, the effects of replication protein A (RPA) on presynaptic complex formation and DNA
strand exchange activities of Rad51 protein were examined. Presynaptic
complex formation was assessed by measuring ATP hydrolysis. With
X174 ssDNA, the ATPase activity of Rad51 protein is stimulated ~1.4-fold by RPA, provided that Rad51 protein is in excess of the
ssDNA concentration; otherwise, RPA inhibits ATPase activity. In
contrast, with ssDNA devoid of secondary structure (poly(dT), poly(dA),
poly(dI), and etheno-M13 DNA), RPA does not stimulate the already
elevated ATPase activity of Rad51 protein, but inhibits activity at low
Rad51 protein concentrations. These results suggest that Rad51 protein
and RPA exclude one another from ssDNA by competing for the same
binding sites and that RPA exerts its effect on presynaptic complex
formation by eliminating secondary structure to which Rad51 protein is
bound nonproductively. DNA strand exchange catalyzed by Rad51 protein
is also greatly stimulated by RPA. The optimal stoichiometry for
stimulation is ~20-30 nucleotides of ssDNA/RPA heterotrimer. The
ssDNA-binding protein of Escherichia coli can substitute
for RPA, showing that the role of RPA is not specific. We conclude that
RPA affects both presynaptic complex formation and DNA strand exchange
via changes in DNA structure, employing the same mechanism used by the
ssDNA-binding protein to effect change in E. coli RecA
protein activity.
The RAD51 gene of Saccharomyces cerevisiae, a member of the RAD52 epistasis group, is required for mitotic and meiotic recombination (for a review, see Ref. 1). Cells deficient in RAD51 function are sensitive to x-ray irradiation or DNA-alkylating agents, suggesting that this gene is required for repair of double-strand DNA breaks (2). Since formation of meiosis-specific double-strand DNA breaks is not inhibited in rad51 cells, RAD51 seems to function after formation of the break in meiotic recombination. The RAD51 sequence is conserved in a wide variety of eucaryotic organisms, suggesting that it is important to cellular function in eucaryotes (3). Rad51 protein has homology to Escherichia coli RecA protein (2, 4, 5). Furthermore, image reconstruction from electron micrographs of complexes of Rad51 protein and double-stranded DNA (dsDNA)1 confirmed this similarity and showed that the three-dimensional structure of the Rad51 protein-DNA filament is similar to the equivalent RecA protein-dsDNA complex (6). Finally, Rad51 protein from S. cerevisiae has single-stranded DNA (ssDNA)-dependent ATPase activity and promotes ATP-dependent DNA strand exchange (7, 8).
RecA protein plays a central role in genetic recombination in E. coli (for reviews, see Refs. 9-13). In vitro analyses have revealed that in the presence of ATP, RecA protein binds to ssDNA to form a nucleoprotein filament, referred to as the presynaptic complex, which is the active species in homologous DNA pairing. Pairing between the presynaptic filament and homologous dsDNA results in formation of the synaptic complex and is followed by DNA strand exchange, the process whereby one strand in the dsDNA is replaced by the homologous ssDNA (postsynaptic stage). The single-stranded DNA-binding protein (SSB protein) of E. coli stimulates RecA protein-mediated DNA strand exchange by acting at both the presynaptic and postsynaptic stages. At the presynaptic step, SSB protein disrupts secondary structure within the ssDNA to facilitate formation of a continuous RecA protein-ssDNA nucleoprotein filament. At the postsynaptic step, SSB protein facilitates DNA strand exchange by binding to the displaced ssDNA strand produced by DNA heteroduplex formation (14, 15). In both steps, physical interaction between RecA and SSB proteins is not required for stimulation (16-18).
Replication protein A (RPA), also referred to as replication factor A, is a single-stranded DNA-binding protein of S. cerevisiae (19-21). RPA is a heterotrimeric protein, consisting of polypeptides with molecular masses of 70.4, 29.9, and 13.8 kDa, and each subunit is essential for cell viability. RPA enhances DNA strand exchange promoted by Rad51 protein (7). Due to the superficial similarities of Rad51 and RPA to RecA and SSB proteins, respectively, it is reasonable to hypothesize that the role of RPA in DNA strand exchange catalyzed by Rad51 protein is similar to that of SSB protein in RecA protein-catalyzed DNA strand exchange. However, it is equally possible that RPA functions differently from SSB protein, to accommodate specific requirements of the eucaryotic recombination process. To address these issues, we measured presynaptic complex and DNA strand exchange activities of Rad51 protein and assessed the effects of both RPA and SSB protein on these reactions. While we find many parallels between the eucaryotic and procaryotic systems, significant differences exist. In particular, active presynaptic complex formation by Rad51 protein has a more stringent requirement for a ssDNA-binding protein. We suggest that this requirement stems from the stable and nonproductive binding of Rad51 protein to regions of dsDNA (secondary structure) within native ssDNA.
Both replicative form and viral (+)-strand X174 DNAs
were purchased from New England Biolabs Inc. For DNA strand exchange, the replicative form of
X174 DNA was linearized with
PstI. Etheno-M13 DNA was prepared as described (22).
Poly(dT) and poly(dA) were purchased from Pharmacia Biotech Inc.
Poly(dI) was purchased from P-L Biochemicals. The concentrations of
X174 dsDNA,
X174 ssDNA, poly(dT), and poly(dA) were determined
using molar (nucleotide) extinction coefficients of 6500, 8125, 7300, and 8600 at 260 nm, respectively, and the concentration of poly(dI) was
determined using a molar (nucleotide) extinction coefficient of 9400 at
246 nm. DNA was stored in 10 mM Tris-HCl (pH 7.5), 1 mM EDTA. All DNA concentrations are expressed in
nucleotides unless otherwise noted.
The three subunits of RPA, cloned on three separate plasmids (a generous gift from Dr. Richard Kolodner), were coinduced in yeast, and the RPA heterotrimer was prepared as described (23). Rad51 protein was overproduced in yeast using the plasmid and strain kindly provided by Dr. Patrick Sung and was purified as described (7), except that Cibacron blue column fractionation was used as the first step. SSB protein was overproduced and purified as described (24). The concentrations of RPA, Rad51 protein, and SSB protein were determined using extinction coefficients (determined, for Rad51 protein and RPA, from amino acid composition) of 8.8 × 104, 1.29 × 104, and 3.0 × 104 at 280 nm, respectively. Pyruvate kinase and lactate dehydrogenase were purchased from Sigma. The restriction endonuclease PstI was purchased from New England Biolabs Inc.
ATP Hydrolysis AssaysATPase activity was measured at
37 °C essentially as described (25). Rad51 protein and a
single-stranded DNA-binding protein (when indicated) were added in the
indicated order to ssDNA in 120 µl of buffer containing 2.5 mM ATP, 10 units/ml pyruvate kinase, 10 units/ml lactate
dehydrogenase, 0.3 mM phosphoenolpyruvate, 256 µM NADH, 50 µg/ml bovine serum albumin, 1 mM dithiothreitol, 20 mM magnesium acetate, 50 mM KCl, and 30 mM Tris acetate (pH 7.5). The
oxidation of NADH resulted in a decrease in absorbance at 340 nm, which
was continuously monitored by a Hewlett-Packard Model 8452A diode array
spectrophotometer. The rate of ATP hydrolysis was calculated from the
rate of change in absorbance using the following formula: rate of
A340 decrease (s1) × 9880 = rate of ATP hydrolysis (µM/min).
DNA strand exchange was
performed as follows (all concentrations are those in the final
reaction mixtures). 33 µM (nucleotides) X174 viral
(+)-strand DNA was incubated with 9.8 µM Rad51 protein in
a total volume of 8.5 µl of 2.5 mM ATP, 50 µg/ml bovine
serum albumin, 1.0 mM dithiothreitol, 20 mM
magnesium acetate, 50 mM KCl, and 30 mM Tris
acetate (pH 7.5) at 37 °C. After 5 min, RPA or SSB protein was added
to the indicated concentration, and incubation was continued for 30 min. PstI-linearized
X174 dsDNA (1 µl) was added to a
final concentration of 33 µM (base pairs) and incubated for an additional 90 min. Samples were deproteinized for 15 min by the
addition of SDS and proteinase K to final concentrations of 0.5% and 1 mg/ml, respectively. Reaction products were separated by
electrophoresis through a 1.0% agarose gel run in 40 mM
Tris acetate and 2 mM EDTA (pH 8.5) at 40 V for 13 h
and were visualized by staining afterward with ethidium bromide.
We first examined the effect of RPA on
the ssDNA-dependent ATPase activity of Rad51 protein (Fig.
1). ATP hydrolysis was measured using a
spectrophotometric assay that couples ADP production to oxidation of
NADH, which results in a decrease in absorbance (25). In the presence
of X174 ssDNA, Rad51 protein displayed a linear rate of ATP
hydrolysis. Subsequent addition of RPA increased the rate of ATP
hydrolysis, showing that the ssDNA-dependent ATPase activity of Rad51 protein is stimulated by RPA. In the presence of
X174 dsDNA, ATP hydrolysis was also increased, but to only ~40%
of the level achieved with ssDNA; RPA did not stimulate this activity
(Fig. 2). In the absence of DNA, ATP hydrolysis by Rad51 protein was observed above the background level, but the rate was
~10-15-fold lower than in the presence of ssDNA. The addition of RPA
had no effect on ATPase activity when ssDNA was absent. Also, the RPA
preparation had no ATP hydrolysis activity in either the presence or
absence of ssDNA (data not shown; Fig. 2).
In Rad51 protein-catalyzed DNA strand exchange, optimal product
formation occurs at ~3 nucleotides of ssDNA/Rad51 protein monomer;
exceeding this amount of protein results in a strong inhibition (8). To
determine the optimal ratio of Rad51 protein to ssDNA for ATPase
activity, a Rad51 protein titration at a fixed concentration of X174
ssDNA (6.87 µM) was performed (Fig. 2). The ATP
hydrolysis rate reached a plateau value at 4-5 µM Rad51 protein (1.4-1.7 nucleotides of ssDNA/Rad51 protein monomer), irrespective of the presence or absence of RPA; a similar plateau was
obtained with dsDNA. This optimal activity requires approximately twice
the amount of protein that is required for optimal DNA strand exchange.
RPA (222 nM) stimulated ssDNA-dependent, but
not dsDNA-dependent, ATP hydrolysis at the higher Rad51
protein concentrations; interestingly, at the lower Rad51 protein
concentrations (0.5 and 1.0 µM), RPA either had no effect
or slightly decreased the ATP hydrolysis rate. Similar behavior was
obtained previously for RecA and SSB proteins: when RecA protein was in
excess over ssDNA, SSB protein stimulated formation of the RecA
protein-ssDNA complex; but when ssDNA was in excess, SSB protein
inhibited complex formation (18). Our findings suggest that a
comparable relationship exists for Rad51 protein and RPA.
To further quantify the effects of RPA on ATPase
activity, reactions containing various concentrations of Rad51 protein
and a fixed concentration of ssDNA (6.87 µM) were
titrated with RPA. The ATP hydrolysis rate obtained in the presence of
RPA relative to that in the absence of RPA was plotted against RPA
concentration (Fig. 3). When the Rad51 protein
concentration was equal to or higher than 2.5 µM (2.75
nucleotides/Rad51 protein), RPA increased the ATP hydrolysis rate as
expected. When the Rad51 protein concentration was 0.5 µM
(13.7 nucleotides/Rad51 protein), ATPase activity was clearly decreased
by RPA in a concentration-dependent manner. Therefore, RPA
can have either a stimulatory or an inhibitory effect on the
ssDNA-dependent ATPase activity of Rad51 protein, depending
on the Rad51 protein concentration. This behavior is strikingly similar
to the effect of SSB protein on the ATPase activity of RecA protein
(18) and suggests that, as for RecA and SSB proteins, Rad51 protein and
RPA are competing for ssDNA-binding sites.
All the experiments reported above were performed by the addition of RPA to preformed presynaptic complexes of Rad51 protein and ssDNA. If, instead, Rad51 protein is added to the preformed complexes of RPA and ssDNA, then the ATP hydrolysis rate does not increase instantly, but rather displays a time-dependent increase before achieving a steady-state rate; at steady state, the ATP hydrolysis rate is similar to that obtained in the parallel reaction where RPA is added last.2 This result further supports the idea that RPA and Rad51 protein bind ssDNA competitively and that Rad51 protein can displace RPA that is bound to ssDNA.
In the Absence of DNA Secondary Structure, RPA Does Not Stimulate the ATPase Activity of Rad51 ProteinIn the E. coli
system, SSB protein stimulates presynaptic complex formation by
eliminating ssDNA secondary structure, which subsequently allows
complete RecA protein filament formation (18). However, when ssDNA
without secondary structure (e.g. poly(dT)) is used, SSB
protein does not stimulate, but instead inhibits ATPase activity due to
displacement of RecA protein from ssDNA. Therefore, it was of special
interest to examine the effect of RPA on the ATPase activity of Rad51
protein stimulated by ssDNA devoid of secondary structure (Fig.
4, A and B). As expected from the
analogy to the RecA and SSB protein system, RPA did not stimulate ATP
hydrolysis at any Rad51 protein concentration tested when poly(dT) was
used as a DNA cofactor (Fig. 4A). Furthermore, there was no
stimulation when another ssDNA devoid of secondary structure (poly(dA),
poly(dI), and etheno-M13 DNA) was used as the DNA cofactor (Fig.
4B). These results confirm the expectation that RPA acts in
these reactions by eliminating secondary structure within ssDNA. In
fact, RPA inhibited poly(dT)-dependent ATPase activity when the Rad51 protein concentration was low (1.3 µM; 6.15 nucleotides of ssDNA/Rad51 protein monomer), with less inhibition
occurring at higher Rad51 protein concentrations (Fig. 4A).
Similarly, RPA inhibited the reactions employing poly(dA), poly(dI),
and etheno-M13 DNA (Fig. 4B). These results are somewhat
different from the effect of SSB protein on RecA protein activity,
where saturating amounts of SSB protein fully inhibit the ATPase
activity of RecA protein irrespective of the RecA protein concentration
(18), and suggest that the stability of the Rad51 protein-ssDNA
filament relative to RPA is greater than that of the RecA protein
filament relative to SSB protein.
E. coli SSB Protein Can Stimulate the ATPase Activity of Rad51 Protein
The results presented so far strongly suggest that RPA
stimulates presynaptic complex formation of Rad51 protein by a
mechanism that is quite similar to that developed for SSB and RecA
proteins. Therefore, we examined whether SSB protein could substitute
for RPA in these reactions. The addition of SSB protein to reactions containing Rad51 protein and X174 ssDNA resulted in the changes shown in Fig. 5. SSB protein stimulated ATP hydrolysis
when the Rad51 protein concentration was 3.5 and 5.0 µM
(2.0 and 1.4 nucleotides/Rad51 protein, respectively) and inhibited it
at 1.0 and 0.5 µM (6.9 and 13.7 nucleotides/Rad51
protein, respectively). These data are similar to those obtained for
RPA shown in Fig. 3.
RPA and SSB Protein Can Stimulate DNA Strand Exchange by Rad51 Protein
Because SSB protein can substitute for RPA in presynaptic
complex formation, we expected that SSB protein could substitute for
RPA in DNA strand exchange mediated by Rad51 protein. Fig. 6A shows the effect of RPA on DNA strand
exchange. RPA extensively stimulated formation of nicked circular dsDNA
(OC; the final product of the DNA strand exchange reaction)
and the slower migrating joint molecules (JM; intermediates
of the exchange reaction), as reported (7, 8). Often we did not detect
any product in the absence of RPA; but in other experiments, we could
sometimes observe a trace amount (data not shown). This is in contrast
to RecA protein-mediated DNA strand exchange, where products can be
found in the absence of SSB protein (26). Quantitative analysis of the
gel (Fig. 6C) shows that stimulation by RPA reached its optimum (~30% of the total DNA) at a ratio of ~20-30 nucleotides of starting ssDNA/RPA heterotrimer.
When SSB protein was used in place of RPA in otherwise identical reactions (Fig. 6B), SSB protein increased both joint molecule and nicked circular dsDNA formation. Stimulation by SSB protein reached its optimal level (~20% of the total DNA) at a ratio of ~7-10 nucleotides of starting ssDNA/SSB protein monomer (Fig. 6C), which is similar to that required for the RecA protein-mediated reaction (26). These results indicate that SSB protein can substitute for some of the functions of RPA required for DNA strand exchange mediated by Rad51 protein. They also suggest that no specific protein-protein interaction between Rad51 protein and RPA is required for stimulation of DNA strand exchange catalyzed by Rad51 protein alone. Although the maximum yield of the product formation supported by SSB protein appears to be lower than that supported by RPA, replicate experiments established that this difference was not significant (data not shown).
As reported by Sung (7), DNA strand exchange catalyzed by Rad51
protein is stimulated by RPA. Here, we show that presynaptic complex
formation, as measured by ssDNA-dependent ATP hydrolysis, is also stimulated by RPA. Stimulation of ATPase activity was observed
only when the concentration of Rad51 protein exceeded one-fifth of the
ssDNA nucleotide concentration and only when the ssDNA contained
secondary structure. Based on the assumption that the ATPase activity
of Rad51 protein is proportional to the amount of Rad51 protein bound
to ssDNA, this suggests that RPA functions by eliminating DNA secondary
structure, allowing more Rad51 protein to bind to ssDNA (Fig.
7, a-c). In the presence of a limited amount
of Rad51 protein, RPA inhibited rather than stimulated ATPase activity,
suggesting that RPA and Rad51 protein compete for the same binding
sites on ssDNA (Fig. 7, d-f); this interpretation is also
consistent with more direct physical assays of ssDNA
occupancy.3 The same conclusion was used to
explain the effects of SSB protein on the activities of RecA protein
(18). In agreement, SSB protein substitutes for the function of RPA in
both the DNA strand exchange and ATPase activities of Rad51 protein.
Therefore, we conclude that the mechanism of stimulation of Rad51
protein activity by RPA is very similar to that of RecA protein
activity by SSB protein.
The finding that SSB protein can substitute for some of the functions of RPA that are required for DNA strand exchange mediated by Rad51 protein argues against the need for a specific protein-protein interaction between Rad51 protein and RPA that is essential to this reaction. Although the genetic evidence for an important role for RPA is compelling (27, 28), these in vivo studies most strongly implicate Rad52 protein as the potential target for interaction with RPA. Thus, by virtue of an absence of a specific need for RPA in the reactions described here with Rad51 protein alone, our studies both support the conclusion and suggest further that RPA acts primarily via interaction with a different protein(s) of the RAD52 group, minimally, Rad52 protein (28).4
For all the similarities, there exist some notable differences between
the two systems. One obvious difference is the overall rate of
reaction. In our experiments, the kcat for
X174 ssDNA-dependent ATP hydrolysis by Rad51 protein is
0.40-0.44 min
1 under optimal conditions and ~0.5
min
1 for poly(dT). This value is ~50-fold lower than
for RecA protein (18). Also, DNA strand exchange promoted by Rad51
protein is 20-30-fold slower than for RecA protein, and the yield is
reduced (26). This difference may simply reflect an intrinsically
slower rate for eucaryotic recombination relative to procaryotic
recombination; alternatively, it may reflect the need for other
stimulatory factor(s) in presynaptic complex formation and/or a later
step of DNA strand exchange.
Another difference is the rather stringent requirement for a ssDNA-binding protein in the DNA strand exchange reaction. Rad51 protein catalyzes DNA strand exchange very poorly when a ssDNA-binding protein is absent. In contrast, RecA protein catalyzes the same reaction in the absence of SSB protein at approximately half the efficiency of the reaction in the presence of SSB protein (26). A possible explanation for this severe requirement for a ssDNA-binding protein may stem from the fact that Rad51 protein can bind to dsDNA as well as to ssDNA (2).5 In the absence of a ssDNA-binding protein, Rad51 protein will bind to both the single- and double-stranded regions of native ssDNA (Fig. 7a). The Rad51 protein filament formed on the base-paired regions of the DNA might inhibit DNA strand exchange. Therefore, removal of Rad51 protein from the double-stranded regions by RPA and its replacement by a uniform Rad51 protein-ssDNA complex might be critical for efficient DNA strand exchange in vitro. Thus, the nonproductive binding of Rad51 protein to these regions of DNA secondary structure, the stabilization of these dsDNA regions, or an instability of the resultant discontinuous presynaptic filament could explain the poor DNA strand exchange activity in the absence of a ssDNA-binding protein.
Our results also suggest a potential second function for RPA. Maximal ATPase activity (reflecting optimal presynaptic complex formation) required approximately one RPA heterotrimer/70 nucleotides of ssDNA; however, optimal DNA strand exchange requires twice as much RPA (one RPA heterotrimer/~20-30 nucleotides of ssDNA). This suggests that there is another role of RPA in DNA strand exchange other than to enhance formation of the presynaptic complex. This proposed additional function is unknown, but it might be a postsynaptic role similar to that established for SSB protein in RecA protein-promoted DNA strand exchange (14, 15). In this second capacity, SSB protein binds to and prevents reinvasion of the displaced DNA strand in RecA protein-catalyzed DNA strand exchange.
Alani et al. (23) reported that the DNA binding stoichiometry of RPA to ssDNA (or "site size") is 80-100 nucleotides/RPA heterotrimer. Based on this value, more RPA than is needed to saturate the ssDNA is required for optimal stimulation of both ATPase and DNA strand exchange activities. We also analyzed the ssDNA binding characteristics of our RPA preparation by fluorescence quenching, under the conditions of both our DNA strand exchange reactions and the previously reported RPA-ssDNA binding reaction (23). Under both conditions, the site size of our RPA preparation was 20-30 nucleotides, and the magnitude of the quenching indicated that at least 70% of our RPA was active in DNA binding.2 We cannot specify the reason for the different observed site size of RPA; post-translational modification related to phosphorylation of RPA subunits could provide an explanation (29).
Finally, the facile binding of Rad51 protein to dsDNA differentiates it from RecA protein and offers an explanation for its relatively poor DNA strand exchange activity. Optimal ATPase activity occurs at ~1.5 nucleotides of ssDNA/Rad51 protein monomer; this ratio is essentially the same at different RPA concentrations (Fig. 2).2 However, optimal DNA strand exchange occurred at a lower Rad51 protein concentration, corresponding to ~3 nucleotides of ssDNA/protein monomer (8).2 At the ratio of Rad51 protein to ssDNA optimal for ATP hydrolysis, DNA strand exchange is strongly inhibited. One way to reconcile these different optima is to propose that because of the relatively strong binding of Rad51 protein to dsDNA, Rad51 protein partitions between both the ssDNA and dsDNA present in DNA strand exchange reactions. Consequently, optimal DNA strand exchange is a compromise between the inhibitory consequences of incomplete presynaptic complex formation relative to inhibition due to dsDNA binding. Incomplete presynaptic complex formation would also explain why product formation in the DNA strand exchange reaction is limited to only 30% of starting DNA. An alternative explanation for the differing optimal ratios is to suggest that the active complex for DNA strand exchange has a structure different from that needed for ATP hydrolysis. Further analysis of this system and of the effects of other Rad proteins should help elucidate the precise function of these proteins in recombination.
We thank members of our laboratory, particularly Jim New, for useful discussions throughout this work; Piero Bianco, Frank Harmon, Bob Tracy, Bill Rehrauer, Alex Mazin, Dan Anderson, Deana Haddox, Noriko Kantake, Jason Churchill, and Erica Seitz for comments on the manuscript; Dr. Richard Kolodner for the RPA-overproducing strain; and Dr. Patrick Sung for the plasmid and strain for overproduction of Rad51 protein.