From the Department of Molecular Medicine/Institute of Biotechnology, University of Texas Health Science Center at San Antonio, San Antonio, Texas 78245-3207
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ABSTRACT |
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Genetic studies in yeast have indicated a role of the RAD50 and MRE11 genes in homologous recombination, telomere length maintenance, and DNA repair processes. Here, we purify from nuclear extract of Raji cells a complex consisting of human Rad50, Mre11, and another protein factor with a size of about 95 kDa (p95), which is likely to be Nibrin, the protein encoded by the gene mutated in Nijmegen breakage syndrome. We show that the Rad50-Mre11-p95 complex possesses manganese-dependent single-stranded DNA endonuclease and 3' to 5' exonuclease activities. These nuclease activities are likely to be important for recombination, repair, and genomic stability.
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INTRODUCTION |
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Genetic studies on Saccharomyces cerevisiae mutants sensitive to ionizing radiation and to other agents that cause DNA double-stranded breaks have identified a large number of genetic loci required for the repair of such breaks. Many of these genes, including RAD50, RAD51, RAD52, RAD54, RAD55, RAD57, RAD59, RDH54, MRE11, and XRS2, show epistasis and are collectively known as the RAD52 epistasis group. Mutants of the RAD52 group also have defects of varying degrees in mitotic and meiotic recombination, which are initiated via DNA double-stranded break formation. Because meiotic recombination is essential for the proper segregation of homologous chromosomal pairs during meiosis I, the RAD52 group mutants often exhibit severe meiotic abnormalities, including inviability (see Refs. 1 and 2 for discussions and references).
Extensive genetic evidence in yeast indicates that DNA double-stranded breaks are processed exonucleolytically, yielding 3' overhanging single-stranded (ss)1 tails of about 600 bases in length (3, 4). According to the double-stranded break repair model for recombination (5), the 3' ssDNA tails formed as a result of break processing are bound by recombination proteins, which then mediate a search for the chromosomal homolog and heteroduplex DNA formation with the homolog (5). The RAD52 group genes may be divided into two categories. The first class consists of the RAD50, MRE11, and XRS2 genes, whose protein products are thought to be involved in the nucleolytic processing of DNA double-stranded breaks (6). Consistent with this classification, the Rad50 and Mre11 proteins have been shown to be homologous to the Escherichia coli SbcC and SbcD proteins, which combine to form a complex with endonuclease and exonuclease activities (7). The second category of the RAD52 group genes includes RAD51, RAD52, RAD54, RAD55, RAD57, and RDH54, whose products nucleate onto the ssDNA tails generated from break processing and then mediate the formation of heteroduplex DNA between the recombining chromosomes (1, 2). Whether the Rad59 protein, which is homologous to Rad52 (8), also has a role in heteroduplex DNA formation remains to be established.
Important insights concerning the mechanism by which the RAD52 group proteins form heteroduplex DNA have been garnered through biochemical studies of purified human and yeast proteins (9-11). However, no information as to the biochemical functions of the RAD50 and MRE11 encoded products is currently available. The Rad50 and Mre11 proteins are of special interest because genetic studies in yeast have indicated that they are also indispensable for nonhomologous DNA end joining (12) and for the maintenance of telomere length (13). The human homologs of RAD50 and MRE11 genes have been identified (14, 15). Here, we purify a complex of human Rad50, Mre11, and a protein species with an apparent size of 95 kDa from nuclear extract of Raji cells. This 95-kDa protein, or p95, is most likely the same protein found to co-immunoprecipitate with Rad50 and Mre11 proteins from HeLa cell extract (14) and recently identified to be Nibrin, the product of the gene mutated in Nijmegen breakage syndrome (16, 17). Our biochemical studies now reveal that the Rad50-Mre11-p95 complex possesses an endonuclease activity and a 3' to 5' exonuclease activity.
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MATERIALS AND METHODS |
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Antisera-- The cDNAs encoding a portion of the human Rad50 protein (amino acid residues 518-881) and a portion of the human Mre11 protein (amino acid residues 1-320) were obtained from a human B cell library using the polymerase chain reaction. These cDNAs were fused in frame to glutathione S-transferase (GST), and the GST-Rad50 and GST-Mre11 fusion proteins were expressed in E. coli XL1 strain. The GST fusion proteins were purified by affinity chromatography on glutathione-Sepharose and used as antigens to raise polyclonal antisera in mice.
Purification of Rad50-Mre11-p95 Complex-- Clarified nuclear extract from 80 ml of human Burkitt's lymphoma cell pellet (Raji cells; purchased from the National Cell Culture Center in Minneapolis) obtained from 50 liters of culture was treated with ammonium sulfate at 0.28 g/ml and then subjected to fractionation in columns of Source Q, Hydroxyapatite, Sepharose 6B, Phenyl-Superose, Sepharose 6B, and Mini S. The full purification details will be described elsewhere.2
DNA Substrates--
The X174 circular ssDNA and replicative
form DNA (95% supercoiled form) were purchased from New England
Biolabs and Life Technologies, Inc., respectively. For preparing
substrates for exonuclease reactions, pUC18 DNA was digested with
ScaI or EcoRI to linearize the DNA. To obtain the
3' end-labeled species, the EcoRI-linearized pUC18 DNA was
treated with a mixture of [
-32P]dATP and unlabeled
dCTP, dGTP, and TTP and E. coli Klenow polymerase. For 5'
end labeling, the pUC18 DNA linearized with ScaI was first treated with calf intestinal alkaline phosphatase to remove the preexisting 5' phosphate group, purified by phenol extraction and
ethanol precipitation, and then treated with polynucleotide kinase and
[
-32P]ATP to label the 5' end. Both the 3' and 5'
end-labeled DNA substrates were purified from the labeling reaction
mixtures using a GeneClean kit.
Nuclease Reactions--
DNA was mixed with the indicated amounts
of the Rad50-Mre11-p95 complex in reaction buffer (30 mM
potassium-MOPS, pH 7.2, 1 mM dithiothreitol, 1 mM ATP, 25 mM KCl, and 2 mM
MnCl2). After incubation at 37 °C, the nuclease reaction
was terminated by adding volume of 3% SDS and
volumes of loading buffer (0.1% orange G in 50 mM
Tris-HCl, pH 7.5, 50% glycerol, and 1 mM EDTA). Reaction
samples were run in 0.8% agarose gels at 100 mA and at room
temperature for 3 h in TAE buffer (50 mM Tris acetate,
pH 7.4, 1 mM EDTA). The DNA species were stained with
ethidium bromide (1 µg/ml) and photographed with Polaroid type 55 films. Photographic negatives were subjected to image analysis in a
Molecular Dynamics model SI densitometer to obtain data points for
graphical representation of the results. In the case of radiolabeled
DNA substrates, after photography, the gels were dried onto DEAE paper
and then subjected to PhosphorImager analysis and autoradiography.
Determination of Nature of DNA Termini in Nucleolytic
Product--
One µg of X ssDNA was treated for 60 min at 37 °C
in the presence or absence of 1 µg of Rad50-Mre11-p95 complex and
then purified by phenol extraction and ethanol precipitation. The DNA was dissolved in 50 µl of TE (10 mM Tris-HCl, pH 7.5, 0.2 mM EDTA); 12.5 µl of the DNA solution was analyzed in an
agarose gel to check for the extent of the nucleolytic action, and the
remainder of the solution was divided into three 12.5-µl aliquots.
The DNA in one of the aliquots was treated with calf thymus terminal
transferase in the presence of 2.5 µCi of
[
-32P]ddATP. One of the remaining aliquots was treated
with calf intestinal alkaline phosphatase, and the other was incubated
in buffer without the phosphatase, followed by phenol extraction and
ethanol precipitation of both. The two DNA samples were redissolved in
10 µl of TE and then treated with T4 polynucleotide kinase in
the presence of 3.5 µCi of [
-32P]ATP. DNA was
purified from labeling reactions using a GeneClean kit to remove any
unincorporated isotope, before being run in a 0.8% agarose gel. The
gel was then dried and subjected to autoradiography.
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RESULTS AND DISCUSSION |
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For identifying the Rad50 and Mre11 proteins in human cells, polyclonal antisera were raised in mice against GST-Rad50 and GST-Mre11 fusion proteins produced in and purified from E. coli. As shown in Fig. 1A, in the left panel, the anti-Rad50 serum detected in nuclear extract of Raji cells a protein band with an apparent size of about 150 kDa, which was in excellent agreement with the predicted size of 153 kDa for Rad50 protein (15). The anti-Mre11 serum detected a band with an apparent size of about 80 kDa (Fig. 1A, right panel) in the Raji nuclear extract, which was in excellent agreement with the predicted size of 81 kDa for Mre11 protein (14).
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The human Rad50 and Mre11 proteins are associated in a tight complex (14). To purify the Rad50-Mre11 complex, a scheme involving ammonium sulfate precipitation of nuclear extract, followed by chromatographic steps in columns of Source Q, Hydroxyapatite, Sepharose 6B, Phenyl-Superose, a second Sepharose 6B step, and Mini S was used, and the elution of the Rad50-Mre11 complex from the columns was monitored by immunoblot analysis. Interestingly, during the second gel filtration step on Sepharose 6B, we found a 95-kDa protein species coeluting precisely with the Rad50 and Mre11 proteins. When the protein pool consisting of Rad50, Mre11, and p95 was further fractionated in either Mini S or Mini Q, precise coelution of p95 with Rad50 and Mre11 proteins was again observed. The final protein pool used for the biochemical studies described below contained Rad50, Mre11, and p95 in nearly homogeneous form (Fig. 1B). The yield of this complex of Rad50, Mre11, and p95 from 80 ml of packed volume of Raji cell pellet was about 50 µg. Two independent preparations of the Rad50-Mre11-p95 complex obtained using Mini S as the final step of purification and one preparation of this complex purified using Mini Q as the final column gave the same results when used in the biochemical studies described below. We believe that p95 is identical to the protein species with the same size which in immunoprecipitation studies (14) was found to be associated with Rad50 and Mre11 proteins in HeLa cell extract. Interestingly, the p95 species appears to be substoichiometric in regard to Rad50 and Mre11 (Fig. 1B), suggesting that either p95 is associated with a fraction of the Rad50-Mre11 complex or p95 is of a lower stoichiometry in the protein complex.
The Rad50 and Mre11 proteins are structurally related to the SbcC-SbcD
complex, which possesses a ssDNA endonuclease activity (7). For this
reason, it was of great interest to test whether the Rad50-Mre11-p95
complex has a ssDNA endonuclease activity. To do this, purified
Rad50-Mre11-p95 complex was incubated with X circular ssDNA, and at
different times, SDS was added to 0.3% to terminate the reaction. The
reaction mixtures were run in an agarose gel and stained with ethidium
bromide to visualize the DNA species. As shown in Fig.
2A, with increasing reaction
time, the Rad50-Mre11-p95 complex converted the ssDNA into forms with progressively faster gel mobility, indicating that the Rad50-Mre11-p95 complex indeed has an associated ssDNA endonuclease activity.
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To examine whether the Rad50-Mre11-p95 nuclease would also act on
double-stranded DNA, the nuclease reaction was repeated, substituting the X ssDNA with the double-stranded supercoiled form.
Incision of the
X supercoiled DNA by Rad50-Mre11-p95 would generate
a nicked circular duplex DNA molecule. As shown in Fig. 2B,
the Rad50-Mre11-p95 complex converted some of the supercoiled DNA into
the nicked circular form, but the incision of the supercoiled DNA
clearly occurred at a much slower rate than the incision of ssDNA (Fig.
2C). For instance, at the reaction end point of 70 min, only
about 15% of the supercoiled DNA had been incised, as compared with
about 80% incision of the circular ssDNA by 30 min (Fig.
2C).
The addition of SDS at the beginning of the reaction abolished nuclease activity (Fig. 2D). Interestingly, the nuclease function was dependent on manganese, which could not be at all substituted by magnesium (Fig. 2D). In this regard, the Rad50-Mre11-p95 nuclease activity resembles the SbcC-SbcD nuclease complex, which is also specifically dependent on manganese for activity (7).
To confirm that the nuclease activity is intrinsic to the
Rad50-Mre11-p95 complex, we subjected fractions from the last step of
protein purification in Mini S to immunoblot analysis to determine their content of the Rad50-Mre11-p95 complex, and the same fractions were also used in nuclease assays with X ssDNA as substrate. As
shown in Fig. 3A, the level of
nuclease activity paralleled the amount of Rad50-Mre11-p95 complex in
the Mini S fractions. When a Mini Q column was used instead of Mini S
as the final purification step, we again observed co-elution of the
nuclease activity with the Rad50-Mre11-p95 complex (Fig.
3B).
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To determine the nature of the DNA termini generated as a result of
Rad50-Mre11-p95 nucleolytic action, X ssDNA was treated with the
Rad50-Mre11-p95 complex, and the nucleolytic product was purified. A
portion of the Rad50-Mre11-p95 digested DNA was run in an agarose gel
and stained with ethidium bromide to examine the extent of nucleolytic
action (Fig. 4A), and
other portions were incubated with terminal transferase and
[
-32P]ddATP and with polynucleotide kinase and
[
-32P]ATP, with or without prior treatment with
alkaline phosphatase. Fig. 4B shows that the product of
nucleolytic action was labeled readily by terminal transferase,
indicating the presence of a 3' hydroxyl group. Also, labeling of the
nucleolytic product by polynucleotide kinase was stimulated markedly by
prior phosphatase treatment of the digested DNA, indicating the
presence of a 5' phosphate (Fig. 4C). Thus, the
Rad50-Mre11-p95 nuclease generates 3' hydroxyl and 5' phosphate
termini.
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To test whether Rad50-Mre11-p95 nuclease complex would act exonucleolytically, we labeled restriction DNA fragments either at the 3' or 5' end with 32P and then treated the labeled DNA species with purified Rad50-Mre11-p95 complex, followed by electrophoresis of the reaction mixtures in an agarose gel. The gel was dried and subjected to autoradiography and PhosphorImager analysis to determine whether there was exonucleolytic digestion of the end-labeled species. As shown in Fig. 5A, we found that incubation of the 3' end-labeled species with the Rad50-Mre11-p95 complex for 10 min resulted in >70% loss of the 32P label, whereas little release of the 32P label was observed with the 5' end-labeled species even after 30 min, indicating that the Rad50-Mre11-p95 complex also acts exonucleolytically, in the 3' to 5' direction. The 3' to 5' exonuclease activity, like the endonuclease function, has a specific requirement for Mn2+ (Fig. 5B).
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We have presented evidence that the Rad50-Mre11-p95 complex has Mn2+-dependent endonuclease and 3' to 5' exonuclease activities. The Rad50-Mre11-p95 nuclease generates 3' hydroxyl and 5' phosphate termini, suggesting that when mediating DNA scission in vivo, the nuclease complex creates DNA termini that are suitable for priming DNA synthesis and for ligation. The nuclease activity in this protein complex likely resides in the Mre11 protein, because the S. cerevisiae Mre11 protein alone has been found to possess endonuclease activity.3 In the previous studies (14, 16), two additional protein species with sizes of 200 and 400 kDa were found to be co-immunoprecipitating with the Rad50-Mre11-p95 complex. The 200-kDa species was identified to be fatty acid synthase, whereas the identity of the 400-kDa species remains to be established (16). These two protein species are not present in our purified preparations of the Rad50-Mre11-p95 complex (Fig. 1B).
Cells derived from patients with Nijmegen breakage syndrome, which is characterized by elevated cellular sensitivity to ionizing radiation indicative of a DNA repair defect, fail to assemble Rad50-Mre11 containing nuclear repair foci (16). p95 (Nibrin) may regulate the nuclear localization of the Rad50-Mre11 complex. In addition, it is possible that p95 affects the nuclease activities of the Rad50-Mre11-p95 complex and could also have a role in linking the DNA repair machinery to cell cycle checkpoints (16, 17).
Genetic studies in yeast have implicated the Rad50 and Mre11 proteins in homologous recombination (6), recombinational repair (6), repair by nonhomologous DNA end joining (12), and in telomere length maintenance (13). Given the high degree of conservation of these proteins among eukaryotes, it seems reasonable to suggest that, in addition to DNA repair, the human Rad50-Mre11-p95 complex also plays an important role in recombination and telomere length homeostasis. In these chromosomal transactions, Rad50-Mre11-p95 nuclease activities may function alone or in combination with other novel protein factors. Among such novel protein factors there could be a DNA helicase, which would cooperate with the Rad50-Mre11-p95 endonuclease activity to create a 3' ssDNA tail (3, 4) for the nucleation of Rad51 and other proteins that function in heteroduplex DNA formation (9-11, 18).
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FOOTNOTES |
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* This work was supported by Grant ES07061 from the NIEHS, National Institutes of Health (to P. S.), a grant from the Ataxia Telangiectasia children's project, and Grant CA49649 from the National Cancer Institute (to E. L).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. Tel.: 210-567-7216;
Fax: 210-567-7277; E-mail: sung{at}uthscsa.edu.
The abbreviations used are: ss, single-stranded; GST, glutathione S-transferaseMOPS, 4-morpholinepropanesulfonic acid.
2 K. Trujillo and P. Sung, manuscript in preparation.
3 L. Symington, personal communication.
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REFERENCES |
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