Deletion Analysis of the Large Subunit p140 in Human Replication Factor C Reveals Regions Required for Complex Formation and Replication Activities*

(Received for publication, December 12, 1996)

Frank Uhlmann Dagger , Jinsong Cai , Emma Gibbs , Mike O'Donnell § and Jerard Hurwitz

From the Program in Molecular Biology, Memorial Sloan-Kettering Cancer Center and § Microbiology Department and Howard Hughes Medical Institute, Cornell University Medical College, New York, New York 10021

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES


ABSTRACT

Replication factor C (RFC) and proliferating cell nuclear antigen (PCNA) are processivity factors for eukaryotic DNA polymerases delta  and epsilon . RFC contains multiple activities, including its ability to recognize and bind to a DNA primer end and load the ring-shaped PCNA onto DNA in an ATP-dependent reaction. PCNA then tethers the polymerase to the template allowing processive DNA chain elongation. Human RFC consists of five distinct subunits (p140, p40, p38, p37, and p36), and RFC activity can be reconstituted from the five cloned gene products. To characterize the role of the large subunit p140 in the function of the RFC complex, deletion mutants were created that defined a region within the p140 C terminus required for complex formation with the four small subunits. Deletion of the p140 N-terminal half, including the DNA ligase homology domain, resulted in the formation of an RFC complex with enhanced activity in replication and PCNA loading. Deletion of additional N-terminal amino acids, including those constituting the RFC homology box II that is conserved among all five RFC subunits, disrupted RFC replication function. DNA primer end recognition and PCNA binding activities, located in the p140 C-terminal half, were unaffected in this mutant, but PCNA loading was abolished.


INTRODUCTION

Replication factor C (RFC)1 is a component of processive eukaryotic DNA polymerase holoenzymes. The processive elongation of DNA chains by pol delta  and epsilon  requires the two accessory factors PCNA and RFC (1-7). PCNA is a ring-shaped homotrimeric protein that encircles DNA and interacts with DNA polymerases, ensuring that they maintain a high affinity interaction with the template until completion of DNA synthesis (8-10). RFC binds DNA at a primer end and loads PCNA onto the DNA in an ATP-dependent reaction. Subsequent RFC-catalyzed ATP hydrolysis is required for pol delta to join this complex prior to initiation of chain elongation (2-5). Human RFC, first isolated as a protein complex required for SV40 replication in vitro, consists of five subunits that migrate during SDS-PAGE as protein bands of 140, 40, 38, 37, and 36 kDa (2, 11). The genes encoding each of these five subunits have been cloned, and the five polypeptides encoded by these genes have been shown to reconstitute RFC activity (12-18).

The five RFC subunits show high homology to each other, and a cluster of seven conserved boxes, referred to as RFC boxes II-VIII, has been defined (16, 19). The RFC boxes contain conserved motifs of 3-16 amino acids in length, and the distances between these boxes are similar in all subunits. The RFC boxes III and V contain conserved sequences characteristic for nucleotide-binding proteins. The function of the other boxes are unknown. In the four small subunits, these boxes are located in the N-terminal half of the polypeptide while the C-terminal sequences are unique to each subunit. The large subunit p140 contains additional N-terminal sequences including another conserved domain, RFC box I, that shows homology to prokaryotic DNA ligases and poly(ADP-ribose) polymerase (14, 15, 19). (A summary of the relative positions of the RFC boxes present in the p140 subunit is shown in Fig. 8.) Despite the sequence redundancy between the subunits, all five are required to form a stable and active complex (17, 20).


Fig. 8. Summary of the p140 subunit deletions and their effects on complex formation and RFC activities. The RFC homology boxes are indicated and numbered in the uppermost bar, representing full-length p140. The names given for the deleted p140 variants indicate the first or last amino acid present at the N or C terminus, respectively. n.d., not determined; N/A, not applicable, since these fragments do not form RFC complexes; *, the DNA binding activity of p140C555 alone is presented.
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The functions of each of the five subunits are presently poorly understood due to the difficulties in isolating each subunit in a soluble and native state. Although all of the subunits contain conserved ATP binding motifs, only the p40 subunit has been shown to bind ATP (5, 12). The N-terminal half of the p140 subunit, containing the ligase homology domain, binds DNA (5, 15, 21, 22), while the p40 and p140 subunits have been shown to interact with PCNA (7, 22). However, the relevance of these observations to the function of the RFC complex remains unclear.

We have reported the expression of the five cloned human RFC genes using an in vitro transcription/translation system (17). A complex was formed containing all five subunits that was active in supporting RFC-dependent replication. Studies on the interactions between the five subunits indicated a cooperative mechanism in RFC assembly. A core complex consisting of the p36, p37, and p40 subunits was detected, and it was shown that the p38 and p140 subunits were dependent upon each other for interaction with the core complex.

We have exploited these findings to determine the role played by the individual subunits in the function of the RFC complex. For this purpose, we have deleted regions of each of the subunits in the five-subunit complex. Here we report studies with the p140 large subunit. We have defined a region in this subunit required for RFC complex formation and have examined RFC complexes containing deleted p140 variants for their ability to bind DNA primer ends, to bind PCNA, load PCNA onto nicked circular duplex DNA, and to support RFC-dependent elongation of singly primed M13 DNA by pol delta .


MATERIALS AND METHODS

Templates for in Vitro Transcription/Translation of RFC Subunits

The DNA templates for in vitro transcription/translation of the five subunits of hRFC were as described previously (17).

Constructs for Expressing Deletion Mutants of p140

pET16p140C555 was derived from pET16ap140 by excising a BspMI-Bst BI fragment from the p140 coding sequence. The ends were filled in and religated. Expression from this vector results in a polypeptide spanning amino acids 1-555 of p140 plus three additional amino acids, TKK, at the C terminus. pET16p140N555 was obtained from pET16ap140 by removing a NcoI-BspMI fragment, filling in the ends, and religation. This vector expressed amino acids 555-1148 of p140 with an additional methionine for translational start at the N terminus. pET19p140N604, -N687, -N776, -N822, and -N877 were cloned from pET16ap140 by polymerase chain reaction (Expand High Fidelity, Boehringer Mannheim) using the following primers: p140N604 N terminus, 5'-CATGCCATGGACCAGAGCTGTGCCAACAAACTCC-3'; p140N687 N terminus, 5'-CATGCCATGGCGATTGTTGCTGAGTCACTGAAC-3'; p140N776 N terminus, 5'-CATGCCATGGTTGAACAGATTAAGGGTGCTATG-3'; p140N822 N terminus, 5'-CATGCCATGGCACGAAGTAAAGCATTAACCTATGAC-3'; p140N877 N terminus, CATGCCATGGATTATTCAATAGCACCCCCTCTTC-3'. The primer for the C terminus of all constructs was 5'-CGGGGTACCTCATTTCTTCGAACTTTTTCCTTTTCC-3'. Polymerase chain reaction products were cleaved with the restriction endonucleases NcoI and KpnI and ligated into the NcoI and KpnI sites of a modified pET19b vector (Novagen). This generated an artificial methionine in front of the p140 sequence starting at the respective amino acid indicated. Expression from these vectors ends at the C terminus of p140 (amino acid 1148). The validity of these constructs was confirmed by DNA sequencing. p140C1142 and p140C976 were generated by cutting pET16ap140 within the p140 coding sequence with the restriction endonucleases XmnI and AlwNI, respectively. The linearized vector fragments were used directly in in vitro transcription/translation reactions.

In Vitro Transcription/Translation

In vitro transcription/translation was performed as described (17). Linearized template DNA (0.4 µg) was added to a 10-µl transcription/translation reaction mixture. The translation products were quantitated by Western blotting of the p37 and p40 subunits and by comparing the level of [35S]methionine incorporated into these and other subunits.

Immunoprecipitation of Translation Products

Interactions between subunits were studied by coexpressing the subunits in question in the in vitro transcription/translation system. When a linearized template was used, each subunit was expressed individually, then mixed immediately after an 1 h incubation of the in vitro translation reactions, followed by further incubation for 30 min at 30 °C. Polyclonal antiserum (1 µl) against one of the subunits was prebound to a 5 µl suspension of protein A-Sepharose beads (Upstate Biotechnology Inc.) for 1 h on ice. Beads were washed with equilibration buffer (RIPA: 50 mM Tris/HCl, pH 8.0, 250 mM NaCl, 5 mM EDTA, 1 mM DTT, 0.5% Nonidet P-40, and 1% BSA). Aliquots of the in vitro translation reactions were added to the immunobeads and complexes were adsorbed for 1 h on ice with frequent shaking. The beads were then washed three times with 0.3 ml of RIPA and twice with 0.3 ml of RIPA without BSA and EDTA. Bound proteins were eluted with 25 µl of SDS-PAGE loading buffer and aliquots analyzed by SDS-10% PAGE. After separation, gels were fixed in 25% 2-propanol, 10% acetic acid, soaked in luminographic enhancer (Amplify, Amersham), dried, and exposed for autoradiography. The amount of RFC bound to the beads was quantitated after SDS-PAGE analysis by phosphorimager (Fuji), using known amounts of the p37 and p40 subunits as standards.

Isolation of Replication Proteins

The following proteins were prepared from HeLa cell extracts as described: HSSB (23), PCNA (24), pol delta , and RFC (25).

Replication Activity of in Vitro Formed RFC Complexes

RFC complexes formed from 25 µl of in vitro translation reactions were isolated with immunobeads as described for immunoprecipitation. In each case, the amount of RFC adsorbed to the beads was quantitated as described above. After the beads were washed, 14.5 µl of the following reaction mixture was added directly to the washed beads: 40 mM Tris/HCl, pH 7.5, 7 mM magnesium acetate, 0.5 mM DTT, 0.01% BSA, 2 mM ATP, 100 µM each of dATP, dGTP, and dTTP, 20 µM [alpha -32P]dCTP (10,000 cpm/pmol), 10 fmol of singly primed circular M13 DNA, 320 ng of HSSB, 50 ng of PCNA, and 50 fmol of pol delta . Reactions were incubated for 30 min at 37 °C with frequent shaking and stopped with 10 mM EDTA. Aliquots (2 µl) were withdrawn and added to 0.1 ml of solution containing 0.67 mg/ml salmon sperm DNA and 67 mM sodium pyrophosphate, and the mixture was precipitated with 1 ml of 5% trichloroacetic acid. After 15 min on ice, the precipitate was filtered through glass fiber filters (Whatman) and acid-insoluble replication products were quantitated by liquid scintillation counting. To 10 µl of the remaining replication products, loading dye was added, and the mixture was subjected to alkaline agarose gel electrophoresis. Gels were dried and exposed for autoradiography. The amount of full-length replication products formed was quantitated by phosphorimager analysis.

Reactions in which RFC isolated from HeLa cells was used were carried out under the above conditions either in the absence of, or after binding to immunobeads as described above. Products formed were analyzed as described above.

DNA Binding Assay

The substrate used for DNA binding was a hair-pinned DNA structure, which was described previously and used to measure the binding of RFC to a DNA primer end (5, 26). The hairpin was formed from a synthetic 96-mer oligonucleotide after annealing in 20 mM Tris/HCl, pH 7.4, 50 mM NaCl, 2 mM MgCl2. The DNA contained a biotin moiety at the 5'-end. Oligo(dA-dC)26, also biotinylated at its 5'-end, was used as a single-stranded DNA substrate. Supercoiled pBlueBac II plasmid DNA was used as the double-stranded DNA competitor, where indicated. To a reaction mixture containing about 25 fmol of in vitro translated RFC subunits or RFC complexes, 10 pmol of the DNA substrate was added and the mixture was incubated at 30 °C for 10 min. Avidin agarose beads (5 µl, Vector) in 10 µl of equilibration buffer (20 mM Tris/HCl, pH 7.5, 100 mM NaCl, 2 mM MgCl2, 1 mM ATP, 2 mM DTT, 0.1% Nonidet P-40, and 1% BSA) was added to the reaction. Biotinylated DNA was bound to the avidin beads by incubating the mixture for 20 min on ice, with shaking. The beads were then washed three times with 0.3 ml of wash buffer (50 mM Tris/HCl, pH 7.5, 200 mM NaCl, 2 mM MgCl2, 1 mM ATP, 2 mM DTT, 0.5% Nonidet P-40, and 1% BSA) and once with wash buffer without BSA. Bound protein was eluted with 25 µl of SDS-PAGE loading buffer. Elution could also be performed with 0.2 M NaOH or less efficiently by treatment with nuclease S1. Aliquots of the eluate were separated on SDS-PAGE and the gels processed as described under immunoprecipitation.

PCNA Binding of in Vitro Translated RFC

PCNA was overexpressed in Escherichia coli (24). Purified PCNA was covalently bound to activated Affi-Gel-15 (Bio-Rad) at a concentration of 10 mg/ml resin according to the manufacturer's protocol. For control experiments, BSA was bound to the resin in the same way. Aliquots of translation reactions expressing RFC complexes were added to 5 µl of the affinity beads in 10 µl equilibration buffer (50 mM Tris/HCl, pH 8.0, 200 mM NaCl, 5 mM MgCl2, 2 mM ATP, 2 mM DTT, 0.25% Nonidet P-40, 10% glycerol, and 2.5% BSA). Binding was carried out on ice for 4 h. The beads were then washed twice with 0.3 ml of equilibration buffer containing 1% BSA and once with equilibration buffer without BSA. Bound protein was eluted with 25 µl of SDS-PAGE loading buffer, and aliquots were separated on SDS-PAGE. The gels were processed as described under immunoprecipitation.

Loading of PCNA onto Nicked Circular DNA

RFC complexes formed from in vitro translation reactions were isolated with immunobeads as described for immunoprecipitation. After the beads were washed, the following reaction mixture was added to the washed beads: 0.5 pmol of singly nicked pBluescript DNA and 2.6 pmol of 32P-labeled PCNA trimers (500-800 cpm/fmol) in 50 µl of incubation buffer (20 mM Tris/HCl, pH 7.5, 100 mM NaCl, 8 mM MgCl2, 0.5 mM ATP, 4% glycerol, 5 mM DTT, and 40 µg/ml BSA) (27, 28). The reaction was incubated for 15 min at 37 °C, stopped on ice and applied to a 5-ml gel filtration column (Bio-Gel A15m, Bio-Rad) equilibrated with incubation buffer. Fractions of 160 µl were collected at 4 °C, and 32P was quantitated by Cerenkov counting.


RESULTS

Identification of a Region within p140 Required for Complex formation

To identify regions in the subunit p140 that are required for complex formation, p140 deletion mutants were constructed, expressed in vitro, and assayed for their ability to assemble an RFC complex with the four small subunits. Fig. 1 shows the products obtained after in vitro transcription and translation of cDNAs encoding full-length p140 (lane 1) and deleted variants of this subunit (lanes 2-5). Each reaction mixture yielded a labeled protein of the expected size, although a substantial number of smaller products were formed. These products are most likely due to aberrant translational starts at internal methionine codons present in the transcribed RNA.


Fig. 1. Influence of p140 deletions on formation of the RFC complex. Full-length p140 and deletion mutants, labeled with [35S]methionine after in vitro transcription/translation, were separated on SDS-PAGE, and are shown in lanes 1-5. Complex formation of p140 with the small subunits was detected by immunoprecipitation of a mixture of all five subunits (lane 6, 10% of the input material; lane 7, immunoprecipitate with antibodies against p37; lane 8, immunoprecipitate using preimmune serum). Requirements for complex formation were studied by replacing p140 with the respective deletion mutant as indicated (lanes 9, 11, 13, and 15, 10% of the input material; lanes 10, 12, 14, and 16, immunoprecipitate). An experiment omitting p140 is shown as a control (lanes 17 and 18). Under the conditions used, the p36 and p37 subunits were not resolved and are jointly labeled p36, p37.
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An immunoprecipitation assay employing anti-p37 antibodies was used to analyze the formation of the five-subunit complex with the p140 deletion mutants described in Fig. 1. Deletion analysis of the p140 subunit revealed a region close to the C terminus that was required for complex formation with the small subunits of RFC. A C-terminal deletion of the p140 subunit that ended at amino acid 1142 (p140C1142; Fig. 1, lane 2) supported complex formation (lanes 9 and 10), as did full-length p140 (amino acids 1-1148, lanes 1, 6, and 7). However, p140C976, with another 166 C-terminal amino acids deleted, did not support RFC complex formation (Fig. 1, lanes 3, 11, and 12). Consistent with this, the N-terminal half of the p140 subunit (p140C555), spanning amino acids 1-555 that included the DNA ligase homology domain, was also unable to form the five-subunit RFC complex (Fig. 1, lanes 4, 13, and 14). These experiments were carried out with antibodies against the p37 subunit, so that immunoprecipitation of p140 variants incapable of supporting reconstitution of the five-subunit complex resulted in coprecipitation of the p36·p37·p40 core complex but not the p38 subunit or the p140 variant (Fig. 1, lanes 12 and 14; and control, omitting p140, lanes 17 and 18). p140C555 migrates through SDS-polyacrylamide gels as a band of 75 kDa although the calculated molecular mass of this fragment is 62 kDa. This aberrant migration is also observed with the full-length p140, a polypeptide of calculated molecular mass of 128 kDa that migrates through gels as a band of 140 kDa.

The C-terminal half of the p140 subunit (p140N555), spanning amino acids 555-1147, migrates at its calculated mass of 66 kDa. RFCp140N555 includes the RFC homology boxes II-VIII and was sufficient for complex formation with the small subunits (Fig. 1, lanes 5, 15, and 16).

To further delineate the region within the C terminus critical for complex formation, N-terminal deletions of the p140 subunit were examined starting at amino acids 604 after RFC box II, 687 after box IV, 776 after box VI, 822 after box VIII and 877 in the C terminus (p140N604, -N687, -N776, -N822, and -N877, respectively; Fig. 2, lanes 1-6). As shown, the large subunit derivative p140N822 supported formation of the five-subunit RFC complex, while p140N877 did not (Fig. 2, lanes 16-19). This indicated that a region between amino acids 822 and 1142, within the p140 C-terminal region that is not conserved among the RFC subunits, is necessary and sufficient for RFC complex formation.


Fig. 2. Influence of sequential deletions of p140 from the N terminus on RFC complex formation. Products formed in in vitro transcription/translation reactions are shown using templates for p140 deletion mutants starting from amino acids 555, 604, 687, 776, 822, and 877, respectively (lanes 1-6). These deletion mutants were coexpressed with the four small subunits (lanes 7, 10, 12, 14, 16, and 18, respectively) and complexes immunoprecipitated with antibodies against p37 (lanes 8, 11, 13, 15, 17, and 19). A control immunoprecipitation reaction using preimmune serum is shown in lane 9.
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Removal of the N-terminal Half of p140 Increases RFC Replication Activity

The replication activity of RFC complexes formed with the N-terminally deleted variants of p140 was examined. Complexes, assembled from in vitro translation reactions, were isolated on immunobeads, and their ability to support RFC-dependent DNA elongation was measured. The efficiency of the replication reaction with RFC bound to immunobeads was markedly reduced (approximately 6-fold) compared with reactions with soluble RFC (Fig. 3A, compare lanes 1 and 2), which was partly due to the limited efficiency of immunoprecipitation (25-35%). The elongation of singly primed single-stranded M13 DNA with immobilized RFC, catalyzed by pol delta , is dependent upon RFC, PCNA, and HSSB (Fig. 3A, lanes 1-8). The RFC complex formed with p140N555 (RFCp140N555) appeared to support replication more efficiently than the complex formed with full-length p140 (Fig. 3A, compare lanes 4 and 9). To quantitate this apparent difference, the RFC complexes formed with full-length p140 (RFCp140) or p140N555 were titrated by varying the amount of complex bound to immunobeads in the assay reaction (Fig. 3B). The efficiency of immunoprecipitation of RFCp140N555 was reproducibly twice the efficiency observed with RFCp140 (compare Fig. 1, lanes 7 and 16) and the input material for the reactions was adjusted accordingly. The activity of RFCp140N555 was approximately 2-fold greater than the activity of RFCp140 as measured by nucleotide incorporation, and 5-fold when formation of full-length replication products (7.2 kilobase pairs) in the singly primed M13 elongation reaction was measured (Fig. 3B, lanes 4-6 and 7-9). These differences were reproducibly observed in three additional experiments.


Fig. 3.

Replication activity of RFC complexes formed with N-terminally deleted variants of p140. A, assay for activity of RFC immobilized on immunobeads. Elongation of a single primer on single-stranded circular M13 DNA was performed as described under "Materials and Methods"; the replication products were separated by denaturing gel electrophoresis. A reaction in which 30 fmol of RFC, isolated from HeLa cells (hRFC), was added in lieu of immunobeads is shown (C, lane 1). hRFC bound to immunobeads (100 fmol input) with antibodies against p37 or the immunobeads alone was used in place of RFC in the reaction (lanes 2 and 3). The products of an in vitro translation reaction (25 µl), coexpressing the five RFC subunits (ivtRFC), were bound to a 5-µl suspension of protein A-Sepharose beads containing antibodies against the p37 subunit. After washing, the immunobeads were used in a complete reaction (lane 4), or in reactions without PCNA, pol delta , or HSSB (lanes 5-7). A mock in vitro translation reaction (25 µl), using template DNAs without the T7 RNA polymerase promotor (lane 8), and a reaction coexpressing the five subunits of RFCp140N555 (25 µl, lane 9) were bound to immunobeads. B, comparison of the activities of the RFC complexes containing full-length p140 or p140N555. Lanes 1-3 are controls as in A. Products contained in 50, 10, and 2 µl of the in vitro translation reaction (IVT) coexpressing RFCp140 (lanes 4-6), and 25, 5, and 1 µl of coexpressing RFCp140N555 (lanes 7-9) were bound to immunobeads and used in the replication reaction. The amount of RFC complex isolated on the beads in each case is indicated. An autoradiograph of the alkaline agarose gel in which the replication products were resolved is shown, and the quantitation of [alpha -32P]dCTP incorporated into replication products is given, as well as relative numbers for the amount of full-length (7.2 kilobase pairs) replication products formed (normalized against full-length products present in lane 6).


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The measurement of RFC activity of complexes linked to immunobeads showed poor linearity as a function of RFC concentration in the M13 elongation assay (Fig. 3B). For this reason, these experiments were repeated using poly(dA)4000·oligo(dT)12-18 as the template in an RFC-dependent replication reaction. RFCp140N555 supported poly(dT) synthesis 5 times more effectively than RFCp140 (data not shown). In this assay, the synthesis of poly(dT) showed a more linear response to RFC linked to immunobeads (10-40 fmol). Similar observations were made with these complexes isolated from in vitro translation mixtures by phosphocellulose chromatography (data not shown). Thus assays using different DNA substrates and different isolation procedures indicated that the RFC complex containing the N-terminally deleted p140 was more active than the full-length p140 RFC complex.

A Region Including RFC Box II of p140 Is Indispensable for Replication Activity

To further identify regions within the p140 subunit required for replication, the N-terminally deleted variants of p140, p140N604 to p140N822, which lack some of the conserved RFC boxes but still form the five-subunit RFC complex, were examined for their ability to support DNA synthesis in the elongation reaction. As shown in Fig. 4, deletion of RFC box II from the p140 subunit (RFCp140N604) resulted in loss of replication activity, delineating a domain between amino acids 555 and 604 that is essential for replication activity.


Fig. 4. Replication activity of RFC complexes formed with progressively increasing N-terminally deleted p140 variants. Replication reactions with RFC complexes (40 fmol), isolated from in vitro translation reactions, were performed as described in Fig. 3A. dCTP incorporation was quantitated and is shown for reactions with RFCp140N555, RFCp140N604, RFCp140N687, RFCp140N776, RFCp140N822, and for a reaction without RFC.
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Deletion of the last six amino acids of p140 (p140C1142) did not affect the activity of the RFC complex formed with this subunit (data not shown).

Binding of RFC Complexes Containing Deleted p140 to Primer Ends

For its function in replication, RFC must possess at least three activities: the ability to bind to DNA primer ends, to interact with PCNA, and to load PCNA onto DNA in an ATP-dependent reaction. To determine why the RFCp140N604 complex is inactive in DNA synthesis, we examined which of these functions is disrupted.

First, DNA binding properties of the RFC subunits and complexes were studied. p140, formed in the in vitro translation reaction, bound to a DNA primer end formed by a hair-pinned DNA containing a recessed 3'-end (Fig. 5A, lanes 1 and 2). p140 specifically interacted with the primer end of this DNA substrate, since the binding was not competed by double-stranded DNA (lane 3), and p140 weakly bound to single-stranded DNA (lane 4). p140C555, containing the DNA ligase homology domain, bound to the primer end with the same efficiency as full-length p140 (lanes 6 and 7). p140N555, lacking this domain, still contained DNA binding activity, although the efficiency of binding was reduced (lanes 8 and 9). The four small subunits of RFC did not bind to DNA under the conditions used (lanes 10-17).


Fig. 5. DNA binding activity of RFC subunits and complexes. A, DNA binding properties of the single subunits. 5 µl of in vitro translation reactions, expressing about 25 fmol of the respective subunits or different regions of p140, were incubated with the indicated DNA substrates. The abbreviation hp refers to the addition of 10 pmol of biotinylated hair-pinned DNA containing a primer end, ss refers to addition of 10 pmol of biotinylated single-stranded oligo(dA-dC)26, and ds refers to the addition of a 6-fold molar excess (in nucleotides) of double-stranded plasmid DNA (2 µg). Biotinylated substrates were bound to avidin beads, and bound protein was eluted and analyzed on SDS-PAGE. 10% of the material added to the binding reaction is shown (lanes 1, 6, 8, 10, 12, 14, and 16), and the percentage of input material bound to avidin beads was quantitated and is indicated as % bound. B, DNA binding activity of RFC complexes formed with full-length and N-terminally deleted p140. Translation reaction mixtures in which the four small RFC subunits were coexpressed with p140 (lanes 1-5) or deleted p140 variants (lanes 6-13) were used in the binding reactions. Reactions were carried out as described in A. In lanes 1, 6, 8, 10, and 12, 10% of the material added to the binding reaction is shown. The elution of proteins bound to avidin beads and autoradiography were described under "Materials and Methods" under DNA binding assay.
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DNA binding by RFC complexes is shown in Fig. 5B. The complex containing full-length p140 bound specifically to the primer end (Fig. 5B, lanes 1-5). RFCp140N555 bound with reduced efficiency (lanes 6 and 7), as expected from the observed behavior of free p140N555 (see Fig. 5A). RFCp140N604, the complex inactive in replication, bound with equal efficiency as RFCp140N555 (lanes 8 and 9). DNA binding of the RFC complex was lost only after the p140 deletion extended to amino acid 776 (lanes 10-13). Likewise, p140N687 alone, rather than in the RFC complex, bound to primer ends, while p140N776 did not, suggesting that stable DNA binding of the RFC complex is mediated mainly by the large subunit. C-terminal deletion of p140N555 to amino acid 976 resulted in the loss of DNA binding by the subunit (data not shown). This localizes the region critical for DNA binding activity in the C-terminal half of p140 between amino acids 687 and the C terminus.

These results indicated that the inability of RFCp140N604 to support DNA synthesis was not due to its deficiency in binding DNA primer ends.

Binding of PCNA by RFCp140N604

We compared the abilities of RFC complexes containing full-length or N-terminally deleted p140 to bind PCNA. The RFCp140N604 complex interacted with PCNA but not with BSA covalently linked to a solid phase, as did the RFC complexes containing the full-length large subunit and p140N555 (Fig. 6). This suggests that the replication defect in RFCp140N604 is not solely due to its inability to interact with PCNA. However, it cannot be excluded that multiple contact sites between PCNA and RFC are required and that one of these sites may be absent in the RFCp140N604 complex.


Fig. 6. Interaction of RFC complexes containing full-length or N-terminally deleted p140 with PCNA. In vitro translation reactions expressing the small RFC subunits and either p140, p140N555, or p140N604 (RFC, N555, and N604 in the figure) were incubated with PCNA- or BSA-affinity beads as described under "Materials and Methods." 10% of the translation reaction mixture (lanes 1, 4, and 7), the material that eluted from the PCNA beads (lanes 2, 5, and 8), and the material that eluted from the BSA beads (lanes 3, 6, and 9) were analyzed on SDS-PAGE.
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p140 and the deleted variants p140N555 and p140N604 alone interacted with PCNA as did the single subunits p36 and p38 (data not shown), suggesting that the interactions between PCNA and RFC are likely to be complex, involving more than one subunit of RFC.

RFCp140N604 Cannot Load PCNA onto DNA

We determined whether the RFC complex formed with the p140N604 subunit that was inactive in replication was able to load PCNA onto DNA. The loading of 32P-labeled PCNA onto nicked circular DNA was assayed by separating the [32P]PCNA-DNA complex from free [32P]PCNA after the loading reaction by filtration through a sizing column. As shown in Fig. 7, RFCp140N604 was inactive in loading PCNA, whereas the RFCp140N555 complex catalytically loaded PCNA onto DNA. RFCp140N555 immobilized on beads (40 fmol) loaded 1.1 pmol of PCNA onto DNA, and the reaction was dependent on the addition of ATP (data not shown). A similar amount of RFCp140 loaded 0.2 pmol of PCNA. This indicated that the RFCp140N555 complex was 5 times more active in the PCNA loading reaction than RFC containing the full-length p140 subunit, consistent with the differences observed in the elongation reaction of primed DNA substrates (Fig. 3). Similarly, the unloading reaction, in which [32P]PCNA is released from the [32P]PCNA-DNA complex, was catalyzed more efficiently by RFC containing p140N555 than full-length p140 (data not shown).


Fig. 7. Loading of PCNA onto nicked circular DNA by RFC containing full-length or deleted p140 variants. Loading reactions with RFCp140, RFCp140N555, and RFCp140N604 (designated RFC, N555, and N604 in the figure), isolated from in vitro translation reactions, were carried out as described under "Materials and Methods." The elution profile of [32P]PCNA from the sizing column is shown and represents the amount of PCNA present in each fraction. Fractions 7-16 correspond to the excluded volume containing PCNA bound to DNA. Fractions from the included region, containing free [32P]PCNA and [gamma -32P]ATP, are not shown.
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These results suggest that the loss of replication activity observed with RFCp140N604, which possessed DNA and PCNA binding activities, was most likely due to its inability to load PCNA onto DNA.


DISCUSSION

Deletion analysis of the large subunit p140 of human RFC presented in this report provides a step toward the functional characterization of this polypeptide. A summary of the p140 variants constructed, as well as the activity of RFC complexes containing these variants, is presented in Fig. 8. A region was defined within amino acids 822-1142 that is required for the formation of the RFC complex. All of the small subunits also require sequences close to their C termini for complex formation (29), suggesting that the unique sequences in these regions govern the interactions between the five subunits. This might explain why all five subunits are required to form the RFC complex despite the redundancy in their conserved regions. The only other stable complex formed by the RFC subunits consists of the three subunits p36, p37, and p40. This core complex is inactive in replication, although it contains some of the enzymatic properties of RFC.2

In the yeast Saccharomyces cerevisiae, the genes coding for the homologous RFC complex have been identified (3, 19, 20, 31-36). The genes for the corresponding subunits of yeast and human include highly homologous RFC boxes as well as several conserved C-terminal regions. These homologous C-terminal sequences may include sites critical for subunit interactions that have been conserved through evolution.

The p140 subunit was shown to contain two independent DNA binding domains. Apart from a DNA binding activity that has been mapped to the ligase homology domain (15, 21, 22), a separate region located in the C-terminal half of the subunit was found to recognize primer ends. This confirms previous observations that different nonoverlapping parts of this protein can bind DNA (37). Both the p37 subunit and the p36·p37·p40 core complex have been shown to bind specifically to DNA primer ends under conditions less stringent than those used to bind p140 (7).2 However, further studies will be necessary to establish the significance of these DNA binding activities.

When RFC complexes were formed with N-terminally deleted variants of the p140 subunit, it was found that the N-terminal half (amino acids 1-555) of p140 was not required for RFC to load PCNA onto DNA and to support elongation of primed DNA templates. The resulting complex (RFCp140N555) was 2-5 times more active than wild-type RFC in catalyzing PCNA loading and the elongation reaction. Two hypothetical explanations for this effect should be mentioned. The N-terminal half of p140 contains a strong DNA binding activity, whereas the C-terminal half binds DNA less effectively, but sufficiently to support RFC activity. The catalytic turnover of RFC may be enhanced by the absence of the strong but dispensable N-terminal DNA binding activity. The p140 N-terminal half also contains two potential CDC2 kinase sites (15) whose phosphorylation status may regulate RFC activity. RFCp140N555 lacks these sites and thus might escape this regulation. A similar mechanism has been described for mammalian DNA ligase I (38), where the enzymatic activity, located in the C terminus, is blocked by interaction with the N terminus. This blockage was released after phophorylation or alternatively by deletion of the N terminus. Further studies with RFCp140N555 purified from baculovirus-infected insect cells will be necessary to examine this effect in more detail.

The in vivo function of the p140 N-terminal half remains speculative. Although the DNA binding activity of this region may not be essential for RFC function in replication, it might direct RFC to sites involved in other DNA transactions, such as DNA repair or recombination. Furthermore, while the studies presented here show that the p140 N-terminal half is dispensable for the elongation reaction, more elaborate interactions between the replication proteins probably take place at a replication fork, which might involve the N terminus of the p140 subunit.

In S. cerevisiae several mutations in the gene encoding the RFC large subunit (cdc44) have been identified that cause cold sensitivity, elevated levels of spontaneous mutations and increased sensitivity to DNA damaging agents. One such mutation was located in the DNA ligase homology domain (30, 39). Further studies in yeast will help to elucidate the in vivo function of the p140 N-terminal half.

Further deletion of the p140 N terminus into the RFC box II resulted in an RFC complex (RFCp140N604) devoid of replication activity. This loss in replication activity was shown to be due to the inability of RFCp140N604 to load PCNA onto DNA, although it cannot be excluded that interactions of RFC with other replication proteins (pol delta  or HSSB) are also affected. RFCp140N604 bound to DNA primer ends and to PCNA with the same efficiency as RFCp140N555.

PCNA loading onto DNA requires opening of the trimeric ring structure of PCNA and disruption of the contacts on at least one of the interfaces between the PCNA monomers. It is likely that more than one contact site between RFC and PCNA is necessary to accomplish the structural changes essential for this reaction. The small subunits p36, p38, and p40 have also been found to interact with PCNA (7),3 and it is possible that a site between amino acids 555 and 604 within p140 is critical for PCNA loading but was not revealed due to the presence of other interacting sites.

ATP binding and hydrolysis by RFC are essential for its function in PCNA loading and replication. These properties of the inactive RFCp140N604 complex could not be measured using in vitro translated material due to high background values, but are unlikely to be altered since the conserved putative ATP binding motifs of p140 were not affected in this variant.

Another possible explanation for the loss of replication function in RFCp140N604 is that the absence of amino acids 555-604 of p140 leads to a structural distortion in the RFC complex that renders it inactive. However, deletion of a similar fragment, containing RFC box II, from any of the small subunits (p36, p37, or p40) did not lead to a comparable inactivation of the RFC complex (29).

In summary, we have defined a region around RFC box II in the large subunit, which when deleted inactivated RFC in loading PCNA. However, the reasons for this loss of function and a general understanding of how the RFC complex works as a molecular machine assembling the PCNA ring around DNA await elucidation of its three-dimensional structure.


FOOTNOTES

*   These studies were supported by National Institutes of Health Grants GM 38559 (to J. H.) and GM 38839 (to M. O'D.).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.
Dagger    Enrolled in the graduate program at the Physiologisch-chemisches Institut, Universität Tübingen, and supported by the German Academic Exchange Service (DAAD) through funds of the Zweites Hochschulsonderprogramm.
   Professor of the American Cancer Society. To whom correspondence should be addressed: Program in Molecular Biology, Memorial Sloan-Kettering Cancer Center, 1275 York Ave., Box 97, New York, NY 10021.
1   The abbreviations used are: RFC, replication factor C, also called activator 1; PCNA, proliferating cell nuclear antigen; pol, DNA polymerase; HSSB, human single-stranded DNA-binding protein, also called RPA; BSA, bovine serum albumin; PAGE, polyacrylamide gel electrophoresis; DTT, dithiothreitol; RIPA, radioimmune precipitation buffer.
2   J. Cai, E. Gibbs, F. Uhlmann, B. Phillips, N. Yao, M. O'Donnell, and J. Hurwitz, submitted for publication.
3   F. Uhlmann and J. Hurwitz, unpublished results.

ACKNOWLEDGEMENTS

We thank Charles E. Stebbins for a preparation of PCNA used in this study and Dr. Z.-Q. Pan for continuous helpful discussions.


REFERENCES

  1. Tsurimoto, T., and Stillman, B. (1989) EMBO J. 8, 3883-3889 [Abstract]
  2. Lee, S.-H., and Hurwitz, J. (1990) Proc. Natl. Acad. Sci. U. S. A. 87, 5672-5676 [Abstract]
  3. Burgers, P. M. J. (1991) J. Biol. Chem. 266, 22698-22706 [Abstract/Free Full Text]
  4. Lee, S.-H., Kwong, A. D., Pan, Z.-Q., and Hurwitz, J. (1991) J. Biol. Chem. 266, 594-602 [Abstract/Free Full Text]
  5. Tsurimoto, T., and Stillman, B. (1991) J. Biol. Chem. 266, 1950-1960 [Abstract/Free Full Text]
  6. Podust, V. N., Georgaki, A., Strack, B., and Hübscher, U. (1992) Nucleic Acids Res. 20, 4159-4165 [Abstract]
  7. Pan, Z.-Q., Chen, M., and Hurwitz, J. (1993) Proc. Natl. Acad. Sci. U. S. A. 90, 6-10 [Abstract]
  8. Burgers, P. M. J., and Yoder, B. L. (1993) J. Biol. Chem. 268, 19923-19926 [Abstract/Free Full Text]
  9. Krishna, T. S., Kong, X.-P., Gary, S., Burgers, P. M., and Kuriyan, J. (1994) Cell 79, 1233-1243 [Medline] [Order article via Infotrieve]
  10. Fukuda, K., Morioka, H., Imajou, S., Ikeda, S., Ohtsuka, E., and Tsurimoto, T. (1995) J. Biol. Chem. 270, 22527-22534 [Abstract/Free Full Text]
  11. Tsurimoto, T., and Stillman, B. (1989) Mol. Cell. Biol. 9, 609-619 [Medline] [Order article via Infotrieve]
  12. Chen, M., Pan, Z.-Q., and Hurwitz, J. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 2516-2520 [Abstract]
  13. Chen, M., Pan, Z.-Q., and Hurwitz, J. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 5211-5215 [Abstract]
  14. Bunz, F., Kobayashi, R., and Stillman, B. (1993) Proc. Natl. Acad. Sci. U. S. A. 90, 11014-11018 [Abstract]
  15. Burbelo, P. D., Utani, A., Pan, Z.-Q., and Yamada, Y. (1993) Proc. Natl. Acad. Sci. U. S. A. 90, 11543-11547 [Abstract]
  16. O'Donnell, M., Onrust, R., Dean, F. B., Chen, M., and Hurwitz, J. (1993) Nucleic Acids Res. 21, 1-3 [Medline] [Order article via Infotrieve]
  17. Uhlmann, F., Cai, J., Flores-Rozas, H., Dean, F., Finkelstein, J., O'Donnell, M., and Hurwitz, J. (1996) Proc. Natl. Acad. Sci. U. S. A. 93, 6521-6526 [Abstract/Free Full Text]
  18. Cai, J., Uhlmann, F., Gibbs, E., Flores-Rozas, H., Lee, C., Phillips, B., Finkelstein, J., Yao, N., O'Donnell, M., and Hurwitz, J. (1996) Proc. Natl. Acad. Sci. U. S. A. 93, 12896-12901 [Abstract/Free Full Text]
  19. Cullmann, G., Fien, K., Kobayashi, R., and Stillman, B. (1995) Mol. Cell. Biol. 15, 4661-4671 [Abstract]
  20. Gary, M., and Burgers, P. M. (1995) Nucleic Acids Res. 23, 4986-4991 [Abstract]
  21. Halligan, B. D., Ming, T., Guilliams, T. G., Nauert, J. B., and Halligan, N. L. N. (1995) Gene (Amst.) 11, 217-222
  22. Fotedar, R., Mossi, R., Fitzgerald, P., Rouselle, T., Maga, G., Brickner, H., Messier, H., Kasibhatla, S., Hübscher, U., and Fotedar, A. (1996) EMBO J. 15, 4423-4433 [Abstract]
  23. Kenny, M. K., Lee, S.-H., and Hurwitz, J. (1989) Proc. Natl. Acad. Sci. U. S. A. 86, 9757-9761 [Abstract]
  24. Tsurimoto, T., Melendy, T., and Stillman, B. (1990) Nature 346, 534-539 [CrossRef][Medline] [Order article via Infotrieve]
  25. Lee, S.-H., Eki, T., and Hurwitz, J. (1989) Proc. Natl. Acad. Sci. U. S. A. 86, 7361-7365 [Abstract]
  26. Munn, M. M., and Alberts, B. M. (1991) J. Biol. Chem. 266, 20024-20033 [Abstract/Free Full Text]
  27. Kelman, Z., Yao, N., and O'Donnell, M. (1995) Gene (Amst.) 166, 177-178 [CrossRef][Medline] [Order article via Infotrieve]
  28. Yao, N., Turner, J., Kelman, Z., Stukenberg, P. T., Dean, F., Shechter, D., Pan, Z.-Q., Hurwitz, J., and O'Donnell, M. (1996) Genes Cells 1, 101-113 [Abstract/Free Full Text]
  29. Uhlmann, F., Gibbs, E., Cai, J., O'Donnell, M., and Hurwitz, J. (1997) J. Biol. Chem. 272, 10065-10071 [Abstract/Free Full Text]
  30. McAlear, M. A., Tuffo, K. M., and Holm, C. (1996) Genetics 142, 65-78 [Abstract/Free Full Text]
  31. Yoder, B. L., and Burgers, P. M. J. (1991) J. Biol. Chem. 266, 22689-22697 [Abstract/Free Full Text]
  32. Fien, K., and Stillman, B. (1992) Mol. Cell. Biol. 12, 155-163 [Abstract]
  33. Li, X., and Burgers, P. M. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 868-872 [Abstract]
  34. Li, X., and Burgers, P. M. J. (1994) J. Biol. Chem. 269, 21880-21884 [Abstract/Free Full Text]
  35. Howell, E. A., McAlear, M. A., Rose, D., and Holm, C. (1994) Mol. Cell. Biol. 14, 255-267 [Abstract]
  36. Noskov, V., Maki, S., Kawasaki, Y., Leem, S.-H., Ono, B.-I., Araki, H., Pavlov, Y., and Sugino, A. (1994) Nucleic Acids Res. 22, 1527-1535 [Abstract]
  37. Luckow, B., Bunz, F., Stillman, B., Lichter, P., and Schütz, G. (1994) Mol. Cell. Biol. 14, 1626-1634 [Abstract]
  38. Prignet, C., Lasko, D. D., Kodama, K., Woodgett, J. R., and Lindahl, T. (1992) EMBO J. 11, 2925-2933 [Abstract]
  39. McAlear, M. A., Howell, E. A., Espenhalde, K. K., and Holm, C. (1994) Mol. Cell Biol. 14, 4390-4397 [Abstract]

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