(Received for publication, September 10, 1996, and in revised form, October 30, 1996)
From the Department of Biochemistry and Molecular Biophysics, Washington University School of Medicine, St. Louis, Missouri 63110
Yeast replication factor C (RF-C) is a heteropentamer encoded by the RFC1-5 genes. RF-C activity in yeast extracts was overproduced about 80-fold after induction of a strain containing all five genes on a single plasmid, with expression of each gene placed under control of the galactose-inducible GAL1-10 promoter. This strongly indicates that overexpression of the five known RFC genes is sufficient for overproduction of RF-C. Overexpression of all five genes was also necessary to achieve overproduction of RF-C as omission of any single gene from the plasmid gave uninduced, i.e. normal cellular levels of RF-C. The interaction between RF-C and proliferating cell nuclear antigen (PCNA) was studied with PCNA-agarose beads. Binding of RF-C to PCNA-agarose beads is negligible in buffers containing 0.3 M NaCl. However, addition of Mg-ATP to the binding buffer caused strong binding of RF-C to the beads even at 0.8 M NaCl. Binding of ATP, but not its hydrolysis, was required for the strong binding mode as nonhydrolyzable analogs were also effective. The existence of two distinct binding modes between PCNA and RF-C was used as the key step in a greatly improved procedure for the purification of RF-C. RF-C from the overproduction strain purified by this procedure was essentially homogeneous and had a severalfold higher specific activity than RF-C preparations that had previously been purified through multicolumn procedures.
The elongation apparatus for DNA replication is functionally
conserved from bacteriophage T4 to mammalian cells. Processive DNA
replication by the viral or cellular DNA polymerase depends on its
interaction with a toroidal shaped protein, the replication clamp. This
clamp is loaded onto the template-primer junction by a protein complex,
the clamp loader (see Ref. 1 for a review). Replication factor C
(RF-C),1 the eukaryotic clamp loader, was
first identified and purified by Tsurimoto and Stillman (2) as an
essential component for SV40 DNA replication. It is a multipolypeptide
complex that loads the replication clamp PCNA (proliferating cell
nuclear antigen) onto the template-primer junction in an
ATP-dependent manner. PCNA is the processivity factor for
eukaryotic DNA polymerase (Pol
) and DNA polymerase
. The
complex of Pol
, RF-C, and PCNA is called Pol
holoenzyme. Yeast
RF-C consists of a large subunit of 94 kDa and four smaller subunits of
36-40 kDa (3, 4). All five known genes have been cloned using a
combination of complementation cloning, peptide sequence analysis,
genome data base searching, and homology-based polymerase chain
reaction. All are essential for yeast cell growth (3, 4, 5, 6, 7, 8). The four
small RFC genes share significant sequence identity
(20-34%). Human RF-C, also called Activator 1, has a similar subunit
structure, and each of the human genes shows extended sequence
similarity (38-56%) with a specific yeast RFC gene (3, 4,
9, 10).
Biochemical studies of RF-C have established that the complex has a preferential binding affinity for template-primer junctions and has a single-stranded DNA-dependent ATPase activity which is further activated by the presence of primer termini and PCNA (9, 11, 12, 13, 14). Unfortunately, more detailed biochemical studies of this complex have been hampered by its scarcity and the difficulty in isolating homogeneous and fully active preparations. Previously, from 1000 g of yeast we routinely obtained about 50-200 µg of RF-C after a seven-step purification protocol, with a purity of about 50-90%, and similar yields were obtained by others (13, 14). Biochemical studies have also been less informative and reproducible, because the different subunits were often present at above or below stoichiometric levels. As a result, its activity varied substantially between preparations. These various problems have precluded a thorough biochemical analysis until now.
In this paper we describe two important improvements to obtaining relatively large quantities of pure RF-C, which should make a thorough study of this loading factor feasible. The first improvement is the simultaneous overexpression of all five RFC genes in yeast, which provides an almost 100-fold higher level of RF-C. Second, a novel purification step has been developed which depends on the strong binding of RF-C to PCNA-agarose beads in the presence of Mg-ATP and weak binding in the absence of the nucleotide. This step allows the rapid purification of RF-C essentially to homogeneity. Because PCNA can be overproduced in Escherichia coli in large quantities, this affinity purification procedure should also be useful for the purification of RF-C from other organisms for which the PCNA gene is available.
The yeast strain used in this work is the protease-deficient galactose-inducible strain BJ2168 (MATa, ura3-52, trp1-289, leu2-3, 112, prb1-1122, prc1-407, pep4-3).
The overproduction plasmids used in this study are based upon the
pRS420 series plasmids into which the GAL1-10 upstream
activating sequence (GAL1-10 UAS), including the transcriptional start
sites for the GAL1 and GAL10 genes, as a 678-nt
BamHI-EcoRI fragment, was inserted into the
corresponding plasmid polylinker sites, resulting into vectors
pRS424-GAL (TRP1), pRS425-GAL (LEU2), and pRS426-GAL (URA3) (15, 16). All vectors have in addition the yeast 2 µM origin for high copy maintenance in yeast and
the Bluescript SKII+ backbone for propagation in E. coli (16). The transcriptional start site of the GAL1
gene is 60 nucleotides upstream of the BamHI cloning site
and the transcriptional start site of the GAL10 gene is 10 nucleotides upstream of the EcoRI cloning site. Both promoters are of similar strength. Using conventional subcloning procedures, all five RFC genes were cloned under control of
the GAL UAS, such that the translational start sites are between 35 nucleotides (for RFC5) and 200 nucleotides (for
RFC4) downstream of the relevant transcriptional start
sites. Upstream cloning sites used were Fnu4HI for
RFC1, BsmAI for RFC2,
HindIII for RFC3, MluI for
RFC4, and MslI for RFC5. These
restriction sites are 90, 60, 50, 135, and 10 nucleotides,
respectively, upstream of the translational start sites. Recombinant
RFC plasmids are listed in Fig. 1. pMTL4 is a centromere
plasmid with LEU2 as selectable marker and with the
GAL4 gene placed under control of the GAL1 UAS (a
gift of Mark Johnston, Washington University).
Media and Buffers
SCGL medium contains per liter: 1.7 g of yeast nitrogen base without amino acids and ammonium sulfate, 5 g of ammonium sulfate, 30 ml of glycerol, 20 ml of lactic acid, 1 g of glucose, 20 g of agar for solid media, 20 mg each of adenine, uracil, histidine, tryptophan, proline, arginine, and methionine, 30 mg each of isoleucine, tyrosine, and lysine, 50 mg of phenylalanine, and 100 mg each of leucine, glutamic acid, aspartic acid, valine, threonine, and serine. Uracil, tryptophan, and/or leucine were omitted when appropriate to ensure the selective maintenance of plasmids. Prior to autoclaving, the pH of the media was adjusted to 5-6 with concentrated sodium hydroxide. YPGL contains per liter: 10 g of yeast extract, 20 g of peptone, 30 ml of glycerol, 20 ml of lactic acid, 2 g of glucose, and 20 mg of adenine. Prior to autoclaving, the pH of the medium was adjusted to 5-6 with concentrated sodium hydroxide.
Buffer A contains: 50 mM Tris-HCl, pH 7.8, 5% (v/v) glycerol, 2 mM EDTA, 3 mM DTT, 5 µM pepstatin A, 5 µM leupeptin, 0.5 mM p-methylphenylsulfonyl fluoride, 10 mM NaHSO3. Buffer B contains: 50 mM Tris-HCl, pH 7.7, 0.5 mM EDTA, 10% glycerol, 8 mM magnesium acetate, 1 mM ATP, 3 mM DTT, 5 µM pepstatin A, 5 µM leupeptin, 5 mM NaHSO3. Buffer C contains: 30 mM Tris-HCl, pH 7.7, 2 mM EDTA, 10% glycerol, 3 mM DTT, 5 µM pepstatin A, 5 µM leupeptin, 5 mM NaHSO3. Buffer D contains: 30 mM HEPES-NaOH, pH 7.4, 0.5 mM EDTA, 10% glycerol, 0.01% Nonidet P-40, 3 mM DTT, 1 µM pepstatin A, 1 µM leupeptin. Salt concentrations (as NaCl) are indicated by a suffix, e.g. Buffer A500 = Buffer A + 500 mM NaCl.
PCNA-Agarose BeadsAll steps were carried out at 0-4 °C. PCNA was purified to about 95% purity from E. coli cells containing the overexpression plasmid pBL228 as described (17). 800 mg of PCNA (10 mg/ml in a triethanolamine-HCl buffer) were dialyzed against 4 × 500 ml of coupling buffer (100 mM MOPS, pH 7.1, 80 mM CaCl2), with 4-8 h between buffer changes. 100 ml of Affi-Gel 10 beads (Bio-Rad) were rapidly washed with 400 ml of 10 mM sodium acetate, pH 5, followed by 300 ml of coupling buffer. The PCNA solution was added to the beads and the slurry gently mixed by continuous rotary inversion. Coupling to the beads was followed by monitoring the decrease in protein concentration in the supernatant. After 4 h, when no further coupling occurred (about 40% of the protein remained in the supernatant), unreacted sites were blocked by addition of 10 ml of 1 M ethanolamine-HCl, pH 8, and the slurry was mixed overnight. The beads were loaded in a column and washed with 500 ml of 40 mM HEPES-NaOH, pH 7.4, 0.5 M NaCl, 1 mM EDTA, followed by 500 ml of 40 mM HEPES-NaOH, pH 7.4, 0.15 M NaCl, 1 mM EDTA, 0.05% sodium azide, and stored in the latter buffer. For comparative purposes, BSA was similarly coupled to 10 ml of Affi-Gel 10. The coupling efficiency, determined from unbound protein, was 4 mg of PCNA/ml of beads and 5 mg of BSA/ml of beads. Incubation of the PCNA-agarose beads with 1% SDS released 1.5 mg of PCNA/ml of beads, indicating that a large fraction of the PCNA is bound to the beads via noncovalent monomer-monomer interactions. As expected, virtually no protein was released from the BSA-beads upon incubation with SDS.
Cell Growth and Extract Preparation for RF-C AnalysisA single colony of a plasmid-containing strain from a selective SCGL plate was grown in an air shaker at 30 °C in 100 ml of selective SCGL medium. After 2-3 days when the OD660 had reached 0.8-1, 100 ml of YPGL was added and growth continued for 3 h. Solid galactose (2% final concentration) was then added to the cultures and shaking continued for another 4 h. The cells (about 1-1.5 g) were harvested, resuspended in a minimal volume of water and frozen on dry ice. Large scale cell growth was carried out similarly, except that the 100-ml yeast culture in SCGL medium was used to inoculate 1200 ml of SCGL media. After overnight growth, when the OD660 was about 1, 1200 ml of YPGL were added. The culture was equally divided over two 4-liter flasks and grown at 30 °C for 3 h. Solid galactose (2% final concentration) was then added to each flask and after 4 h of continuous shaking the cells were harvested.
All further steps were at 0-4 °C. Thawed cells (500 µl) were shaken together with 500 µl of 2 × A500 buffer and 500 µl of glass beads in a 1.5 ml microfuge tube at top speed on a vortexer for 45 s, followed by a 90-s cooling period on ice water, for a total shaking period of 4 min. The lysate was taken off and the beads washed with 200 µl of buffer A500. The combined lysate was spun in a microcentrifuge for 15 min. The supernatants from three tubes were combined and diluted with 1.5 volumes of buffer A0, and 0.7 ml of Affi-Gel blue, equilibrated in buffer A200, were added. After 1 h of mixing by continuous rotation, the Affi-Gel blue was poured into a small column, the beads were washed with 4 ml of buffer A200, followed by 0.5 ml of A1000, and bound protein eluted with another 1.5 ml of A1000. Relative protein levels of RF-C subunits in the cleared lysate and the Affi-Gel blue fractions were determined by a Western analysis. RF-C activity was determined in the Affi-Gel blue eluate.
Binding of RF-C to PCNA-AgaroseAll steps were carried out at 0-4 °C. 10,000 units of RF-C in 200 µl binding buffer (50 mM Tris, 7.8, 10% glycerol, 5 mM DTT, 1 mg/ml of BSA) and EDTA, magnesium acetate, ATP, and NaCl as indicated, was gently agitated with 10 µl of PCNA-agarose beads in a 0.5-ml thin-walled microcentrifuge tube (polymerase chain reaction tube). When extracts or Affi-Gel blue fractions were incubated with the beads, protease inhibitors (0.5 mM p-methylphenylsulfonyl fluoride, 5 µM pepstatin A, 5 µM leupeptin, and 10 mM NaHSO3) were also added. After 1 h at 0-4 °C, the bottom of the tube was pierced with a 27-gauge needle and the solution spun through at 500 rpm for a few seconds, taking care not to let the beads become dry. 50 µl of the same buffer was layered onto the beads, and after an equilibration time of 5 min, spun through. This washing was repeated one more time. Bound RF-C was eluted with 2 × 30 µl of binding buffer containing 2 mM EDTA and 1 M NaCl. RF-C activity was measured in the 1 M NaCl eluate and the percent of activity recovered in comparison with starting activity taken to represent percent of bound RF-C. Control assays showed that when RF-C was not bound to the beads by this criterion, activity was recovered in the unbound fraction. In general, total recoverable activity (bound + unbound) was 80-90%.
RF-C Activity AssayThe standard 30-µl reaction contained
40 mM Tris-HCl, pH 7.8, 8 mM MgCl2,
0.2 mg/ml BSA, 1 mM DTT, 100 µM each of dATP,
dCTP, and dGTP, and 25 µM of [3H] dTTP (100 cpm/pmol dNTP), 0.5 mM ATP, 100 ng of singly primed single-stranded mp18 DNA (0.04 pmol of circles), 850 ng of E. coli single-stranded DNA-binding protein, 50 mM NaCl,
100 ng of PCNA, 10 ng of Pol , and RF-C. Incubations were at
37 °C for 4 min. The reactions were stopped by the addition of 100 µl of 50 mM sodium pyrophosphate, 25 mM EDTA,
and 50 µg/ml of calf thymus DNA as carrier, and acid-insoluble
radioactivity was determined. One unit of RF-C stimulates the
incorporation of 1 pmol of nucleotide into acid-precipitable
radioactivity by Pol
under the standard assay conditions,
i.e. using primed single-stranded mp18 DNA. During the time
period of the assay, Pol
, PCNA, and RF-C form a holoenzyme complex
on a primed circle, and the holoenzyme completely replicates the viral
circle. However, turnover to a new template circle is minimal. For this
reason, the unit definition depends on the length of replicable
template available (about 7210 nucleotides for the primed mp18
template).
Strain BJ2168 containing plasmids pBL420 and pMTL4 was grown and induced with galactose as described above. The preparation was carried out with a total of 120 g of frozen cells. All steps were carried out at 0-4 °C. The cells were thawed and mixed with an equal volume of 2 × A500 buffer. The suspension was loaded into the large chamber of a bead-beater (Biospec products) containing 175 ml of glass beads (0.4-0.5 mm), and the chamber was filled to the top with additional buffer A500 and immersed in a container filled with ice water. The cells were blended 45 s on, 90 s off, for a total blending time of 6 min. The lysate was poured off, and the beads were washed with 2 × 50 ml of buffer A500. The combined lysate was spun at 13,000 rpm for 30 min and the supernatant diluted with an equal volume of buffer A0. This is fraction I (520 ml) (Table I).
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Fraction I was gently agitated for 45 min with 50 ml of Affi-Gel blue beads (Bio-Rad) equilibrated in buffer A250. The beads were spun down at 100 × g and the supernatant poured off and discarded. The beads were loaded into a column and washed with 200 ml of buffer A250. Protein was eluted with buffer A1000 (with EDTA lowered to 0.5 mM). 40-ml fractions were collected and RF-C activity determined. The bulk of RF-C eluted in fractions 2 through 5 (Fraction II, 160 ml).
ATP and magnesium acetate were added to Fraction II to 1 and 7 mM, respectively, and the enzyme fraction was dialyzed against 500 ml of buffer B0 until the conductivity had reached that of buffer B300. The dialyzed fraction was loaded, at a rate of 1 ml/min, onto a 15-ml PCNA-agarose column, equilibrated in buffer B300. The column was washed with 30 ml of buffer B300, followed by 30 ml of buffer B400. The flow direction was then reversed and the column eluted with buffer C400. Fractions of 8 ml were collected and RF-C analyzed enzymatically and by SDS-PAGE. Fractions 2 through 4 contained RF-C (Fraction III, 24 ml).
Fraction III was dialyzed against 100 ml of buffer D0 until the conductivity reached that of D100, injected onto a 1-ml Mono S column, equilibrated in buffer D100, and eluted with a 20-ml linear gradient from D100 to D500. Fractions of 0.4 ml were collected and frozen individually. RF-C eluted at about 0.35 M NaCl.
An inducible system for the overexpression of RFC genes was chosen to allow normal cell growth prior to induction, in case overproduction of any or all of the subunits would be deleterious to cell growth. The strain used in this study is the protease-deficient strain BJ2168. In this strain, the expression of genes placed under control of the GAL1-10 UAS is appropriately induced by addition of galactose to the medium, but the strain grows very poorly on galactose as the sole carbon source. Adequate cell growth was obtained on media containing as carbon source 3% glycerol, 2% lactate, and a nonrepressing concentration of glucose (0.1%). Galactose was added to this medium to induce expression. All five RFC genes were cloned under control of the bidirectional GAL1-10 UAS, either alone or in various combinations as described under "Material and Methods" and outlined in Fig. 1.
Strains carrying plasmids containing one single RFC gene
under galactose control greatly overproduced the appropriate RF-C subunit after galactose induction as shown by Western analysis (results
not shown). A 4-h incubation in galactose medium was optimal. The
consequence of overproduction of a single RF-C subunit on cell growth
was monitored by growing cells under selective conditions on
glycerol-lactate medium, followed by plating on selection plates
containing either raffinose or galactose. Both are fermentable carbon
sources, but raffinose does not induce genes placed behind the
GAL1-10 UAS. The plating efficiency on galactose plates
versus raffinose plates was reduced about 10-fold when the
strain contained the RFC1 overproducing plasmid, pBL409 (Fig. 2A). In addition, the colonies that did
appear on the galactose plate were very small, whereas the colonies on
the raffinose plate were normal in size (Fig. 2B),
indicating that overproduction of Rfc1p is detrimental. The reduction
in plating efficiency and colony size is largely due to increased
plasmid loss and slow growth of overproducing cells, but not to a
specific cell cycle arrest in these cells (results not shown).
Five plasmids were constructed which contained four RFC genes each, all genes being under galactose control (Fig. 1). Of those, only the strain with the plasmid lacking RFC3 (pBL425) had a low plating efficiency and produced small colonies when grown on galactose (Fig. 2A). When the appropriate one-subunit and four-subunit plasmids were combined in yeast, poor growth was in general observed, except for the combinations pBL412 + pBL424 (RFC1, RFC3, RFC4, RFC5 + RFC2) and pBL419 + pBL417 (RFC1, RFC2, RFC3, RFC4 + RFC5), which showed normal growth (Fig. 2A). Coincidentally, these two combinations of plasmids gave the lowest overproduction of RF-C activity, suggesting that overproduction of the complex is deleterious to cell growth (Fig. 1 and below). As with overproduction of Rfc1p, the reduction in plating efficiency and colony size is largely due to plasmid loss and cell death and not to specific cell cycle arrest in the cells overproducing RF-C. As expected from these previous results, when a plasmid containing all five RFC genes (pBL420) was transformed into yeast, the strain also grew poorly on galactose media (Fig. 2).
Overproduction of RF-CBecause of interfering nuclease and
polymerase activities, it is not possible to determine RF-C activity
from wild-type cells in crude extracts. However, its activity can be
determined quite accurately after Affi-Gel blue chromatography of the
extracts. A 50-fold overproduction of RF-C was detected when extracts
were made from induced cells carrying the five-subunit plasmid pBL420 (Fig. 3). Because there might be insufficient Gal4p in
the cell to saturate all Gal4p binding sites on the multicopy plasmid, we also introduced a Gal4p overproduction plasmid in the strain. The
strain with both plasmids overproduced RF-C activity about 80-fold
(Fig. 3). These expression studies show that the five known
RFC genes are sufficient for forming an active RF-C
complex.
Subunit Requirement of RF-C
All five RFC genes are
essential for yeast growth (3, 4, 5, 6, 7, 8). From these observations it does not necessarily follow that all five subunits are necessary for forming a
functional RF-C complex as defined by our assay, i.e.
loading of PCNA on singly primed mp18 DNA to allow processive DNA
synthesis by Pol . To test whether one of the subunits could be
omitted, we systematically designed overexpression plasmids lacking one of the genes at a time (Fig. 1). Strain BJ2168 was then transformed with a four-subunit plasmid together with a second plasmid containing the gene for the fifth subunit or the analogous vector. Extracts were
made from induced cells and passed over an Affi-Gel blue column as
described under "Materials and Methods." A Western analysis showed
that all immunoreactive material bound to the Affi-Gel blue matrix
under loading conditions (0.2 M NaCl) and eluted with the
elution buffer (1 M NaCl). In the strains lacking
RFC2, RFC3, or RFC5 on the
overexpression plasmids, no significant increase in RF-C activity over
that of the strain containing control plasmids was detected. In the
strain lacking RFC4 on the overexpression plasmid, the level
of RF-C was about 50% over background whereas in the strain lacking
RFC1 on the overexpression plasmid, the level of RF-C was
three times that of the control strain. The increased RF-C activity
from the strain carrying plasmid pBL422 (pRFC2,
pRFC3, pRFC4, pRFC5) could either be
due to the presence of a 3-fold higher level of Rfc1p in the cell than
of the other subunits or to a feeble RF-C activity by a subcomplex
lacking Rfc1p. The former is a likely possibility as previously we have isolated a form of RF-C with overstoichiometric levels of Rfc1p (13).
In all cases, addition of the missing fifth gene restored overproduction of RF-C to varying levels (Fig. 1). The variation in
RF-C levels in the strains with two RFC plasmids may be due to plasmid copy number effects and has been observed previously for the
combination RFC1, RFC2, RFC3, RFC4 + RFC5 (4).
This series of experiments allows the conclusions that (i) with the possible exception of Rfc1p, all subunits are present in yeast at
comparable levels, and (ii) all subunits are necessary for a fully
functional RF-C. Again, these experiments do not exclude the
possibility that a subcomplex of RF-C may be formed with a very weak
activity, which is at least 1 order of magnitude lower than that of
normal RF-C.
Previously, we have shown by kinetic studies that the most
favorable pathway of loading PCNA at a primer terminus requires the
DNA-independent formation of a complex between PCNA and RF-C (18). In a
separate study we are investigating the parameters that govern the
interaction between PCNA and RF-C using several techniques, including
PCNA-agarose beads. Using PCNA-agarose beads, a stable complex between
PCNA and RF-C was detected, but only in the presence of
Mg-ATP.2 The data in Fig. 4
show that binding of RF-C to the PCNA beads is unstable at 200 mM NaCl when carried out in a buffer containing either
magnesium (without ATP) or ATP (with EDTA). In contrast, when both
magnesium and ATP are present in the binding buffer, stable binding is
observed at 400 mM NaCl, and substantial binding is still
observed at 700 mM NaCl (Fig. 4). ATP supported complex formation with half-maximal binding observed at about 1 µM. This defines an apparent KD value
for ATP of about 1 µM. The formation of such a stable
complex required ATP binding, but not its hydrolysis. Both ATPS and
AMP-PNP supported strong complex formation with apparent
KD values of 2 µM and 300 µM, respectively (Fig. 5). These values
compare well with the relative strength of ATP
S and AMP-PNP as
competitive inhibitors of the ATPase activity of RF-C with
Ki values of 1.8 and 130 µM,
respectively (13). GTP at 100 µM and CTP near 1 mM concentration also supported strong complex formation,
whereas ADP was ineffective (Fig. 5). However, none of these four
nucleotides can stimulate the loading of PCNA by RF-C onto a primed
template as determined in a Pol
holoenyme assay, indicating that
the hydrolysis of the bound nucleotide during the loading reaction is a
distinct step which shows both base and phosphate specificity and can
only be carried out by ATP (Refs. 9 and 13 and data not
shown).3
Affinity Purification of RF-C
The great difference in
interaction strength between PCNA and RF-C in the presence or absence
of Mg-ATP was exploited in an improved purification scheme for RF-C. To
test the possible value of this purification step, extracts from a
protease-deficient yeast strain were incubated with PCNA beads in a
buffer containing magnesium acetate and 0.4 M NaCl, with or
without 1 mM ATP. After washing the beads with the same
buffer, again with or without ATP, protein was eluted with 1 M NaCl in EDTA buffer and analyzed by SDS-PAGE. A large
number of proteins, which bind to the PCNA-agarose, beads can be
detected. Strikingly, the only difference between the two lanes is the
clear presence of the RF-C polypeptides in the Mg-ATP lane, indicative
that this complex can be specifically bound to the beads from crude
extracts (Fig. 6). The PCNA-agarose step purified RF-C
to a purity of about 1-5% from crude extracts. This corresponds to a
1000-5000-fold purification in this one step.
Together with the overproduction of RF-C in yeast, the affinity
purification step was applied to obtain homogeneous RF-C in high
quantity and yield. Affi-Gel blue batch chromatography was used as a
first step in the purification procedure to remove endogenous PCNA and
to allow for a cleaner handling of the PCNA beads so they could be
re-used. After the Affi-Gel blue step, the RF-C-containing fraction was
loaded onto the PCNA-agarose bead column in a buffer containing Mg-ATP
and 0.3 M NaCl. The column was washed with 0.4 M NaCl in the same buffer, and RF-C was quantitatively
eluted from the column by switching from Mg-ATP to 2 mM
EDTA in the same buffer (Fig. 7). RF-C eluting from this
column contained trace amounts of PCNA and was therefore passed over a
small Mono S FPLC column which removed PCNA and also served to
concentrate the complex. The yield from 120 g of cells was about 3 mg of pure RF-C (Table I). Unlike previous preparations
of RF-C, no DNA helicase activity could be detected after the
PCNA-agarose step (19).
RF-C activity is measured in a DNA polymerase holoenzyme assay.
Loading of PCNA by RF-C on singly primed single-stranded mp18 DNA
allows processive DNA synthesis by Pol
. One unit of RF-C activity
has been defined as that amount which stimulates 1 pmol of DNA
synthesis by Pol
when PCNA and ATP are also present. During this
assay, which is for 4 min at 37 °C, holoenzyme complex formation and
complete replication of the phage DNA is easily achieved, but turnover
of the holoenzyme to another phage DNA molecule is slow (18).
Therefore, in practice this is a single turnover assay. If we assume
that RF-C consists of a monomer of each subunit in the heteropentamer,
its molecular weight would be 249,000, close to the previously measured
value of 240,000 (13). The maximum theoretical specific activity
obtainable by this assay would be 109/240,000 (picomoles of
RF-C/mg of protein) × 7210 (nucleotides per mp18 circle) = 29 × 106 units/mg. Previous preparations of RF-C typically had a
specific activity of about 5 × 106 units/mg (13). The
affinity-purified material had a specific activity of 20 × 106 units/mg.
Apart from the technical advances described in this study, two conceptual conclusions can also be drawn: (i) overexpression of the five RFC genes is both necessary and sufficient for overproduction of RF-C, and (ii) PCNA forms a distinct, salt-resistant complex with RF-C in the presence of Mg-ATP.
Interactions between the clamp and the clamp loader proceed
similarly in prokaryotes and in eukaryotes. Using a gel filtration technique to detect stable complexes, Naktinis et al. (20)
determined that co-migration on the gel filtration column of the
E. coli subunit (clamp) with the
-
complex (clamp
loader) required the presence of Mg-ATP. The same conclusion follows
from the PCNA-agarose bead studies in this paper. The sensitivity of
the PCNA·RF-C complex to even moderate salt levels, and the
resistance of the PCNA·RF-C·ATP complex to high levels of salt
suggest that non-ionic interactions contribute very strongly to the
latter complex. Possibly, in the ternary complex, the PCNA ring may
already be opened up in advance of loading around the template-primer
junction, with the subunit-subunit interface of PCNA stabilized by
hydrophobic interactions with RF-C. After loading, hydrolysis of the
bound ATP would be required in a subsequent step, either for closing of
the clamp around the DNA or for altering the interaction of PCNA with
RF-C to allow a proper interaction with Pol
. ATP
S, which
supports formation of the strong ternary complex (Fig. 5), does not
stimulate processive replication by Pol
holoenzyme under normal
assay conditions. However, when RF-C and PCNA are incubated with primed
DNA in the presence of ATP
S, and then excess ATP
S removed by
filtration over a Biogel A5 m column, the isolated complex contains
bound PCNA and RF-C and supports processive DNA replication upon
addition of Pol
(18, 21). However, this complex is different from the analogous complex made with ATP. It binds Pol
more weakly than
the ATP-derived complex. Furthermore, both the PCNA·RF-C complex and
the Pol
holoenzyme complex, as well as DNA synthesis by these
complexes, are sensitive to added ATP
S, whereas elongation of a
holoenzyme complex formed with ATP is resistant to ATP
S (18). This
is summarized in Fig. 8. Distinct ATP
S-mediated complexes of the clamp and the clamp loader with DNA have also been
documented in the phage T4 and the mammalian systems (12, 22, 23).
Together, these results indicate that ATP binding to PCNA·RF-C is
sufficient to load PCNA onto the DNA, but its hydrolysis is required to
stabilize the clamp.
The unique properties ATP in stabilizing interactions between PCNA and RF-C allowed us to design an efficient purification step for RF-C. The affinity chromatography step purified RF-C 1000-5000-fold from crude extracts. If preceded by an Affi-Gel blue batch chromatography step, which gives approximately a 10-fold purification of RF-C, it should be possible to obtain relatively pure RF-C by a two-column procedure, even when the complex has not been overproduced. The PCNA gene has been cloned from a large number of organisms, and so far the large scale expression of the protein in E. coli has been simple. Therefore, the utility of the affinity purification step should make the isolation and purification of RF-C from those organisms very feasible.
We thank John Majors and Tim Lohman for critical discussions during the progress of this work.