(Received for publication, October 23, 1996, and in revised form, February 10, 1997)
From the Laboratory of Viral Oncology, Research Institute, Aichi Cancer Center, Chikusa-ku, Nagoya 464, Japan
The MCM protein family, which consists of at least six members, has been implicated in the regulatory machinery causing DNA to replicate once in the S phase. Mammalian MCM proteins are present in the nucleus in two different forms, one extractable by nonionic detergents and the other resistant to such extraction. The latter is assumed to be tightly associated with nuclear structures and released at the time of initiation of replication. However, details of the mode of binding remain unclear. In the present study, we found that, in nonionic detergent-permeabilized nuclei, the association of human MCM (hMCM) proteins with them could be stabilized by the addition of ATP. The hMCMs bound to the nuclei in the presence of ATP were released by digestion with nucleases, suggesting that they are chromatin-associated. The nuclease-directed solubilization of the chromatin-bound hMCMs thus provided a means to analyze them as well as soluble hMCMs by co-immunoprecipitation. The results indicate that the six hMCM members exist as heterocomplexes, whether bound or unbound. We therefore propose that hMCM proteins may function in DNA replication as heterohexamers associated with chromatin and that ATP is possibly involved in the association. Nuclease digestion-immunoprecipitation techniques of the type described here should facilitate further elucidation of the mode of interaction between hMCMs and chromatin.
Identification of DNA sequences able to act as origins of replication (autonomously replicating sequences; ARS)1 has allowed extensive analysis of the initiation step in the budding yeast. The MCM protein family, which consists of at least six members, was originally identified because of its involvement in the initiation of DNA replication at ARS (1-8) and later found to be conserved through eukaryotes (9-18). Although definite functions of the MCM proteins remain largely unknown, they have been implicated in the regulatory machinery allowing DNA to replicate only once during S phase (reviewed in Refs. 19 and 20).
In mammalian cells, MCM proteins are present in the nuclei in two different forms that can be differentiated by nonionic detergent extraction, one soluble and extractable and the other tightly associated with the nucleus, which is resistant to such extraction. The level of mammalian MCMs does not vary greatly during the cell cycle, but the nucleus-bound form gradually becomes dissociated from nuclear structures with progression through the S phase (21-25). It is now assumed that it is associated with prereplicative chromatin and released at the time of initiation of replication; the soluble form existing abundantly in G2 nuclei is considered inactive and no longer capable of binding to chromatin. Based on the finding that the nucleus-bound MCMs are liberated by nuclease treatment, they are thought to be linked to chromatin structures, but some controversy still remains in this regard (21, 22, 26). It has also been suggested that replication factories are connected with the nuclear matrix, which is not released by nuclease digestion (reviewed in Ref. 27; Ref. 28).
Whereas the MCM proteins share substantial homology, in budding yeast, each type functions in an ARS-specific manner to play indispensable roles in chromosomal replication (3-8). Similarly, in human cells the function of the hCDC47 form does not appear to be compensated for by other members (29). On the other hand, yeast MCMs exhibit genetic interactions (4, 7) and, just recently, have been shown to physically associate with one another (30). In Xenopus or Drosophila egg extracts, all of the MCM members appear to exist as heterocomplexes (15-17, 31, 32). In mammalian cells, interactions among MCMs have been studied mainly using nonionic detergent-extractable fractions, where CDC46 and MCM3 assemble into a complex (21, 23, 26), and CDC47, cdc21, and Mis5 form another complex, which relatively weakly associates with MCM2 (33, 34). Although such studies have provided useful information for understanding mammalian MCMs, it is very important that we analyze their nucleus-bound counterparts, whose biological and biochemical properties are presumably distinct. Indeed, the state of phosphorylation is known to be different between the two types, seemingly affecting nuclear association-dissociation (21, 22) and perhaps also influencing protein-protein interactions. In the present study, we therefore investigated the properties of the nucleus-bound form of human MCM (hMCM) proteins.
HeLa cells were grown in Dulbecco's modified Eagle's medium with 5% fetal calf serum.
The buffer used for preparation of cell lysates and the
immunoprecipitation procedure was modified CSK buffer (35) (10 mM Pipes, pH 6.8, 100 mM NaCl, 300 mM sucrose, 1 mM MgCl2, 1 mM EGTA, 1 mM dithiothreitol, 1 mM
phenylmethylsulfonyl fluoride, 10 µg/ml aprotinin) containing 0.1 or
0.5% Triton X-100 (0.1%TX-100mCSK or 0.5%TX-100mCSK, respectively).
ATP, GTP, CTP, and UTP were purchased from Sigma; ATPS and AMP-PNP
were from Calbiochem.
The preparation, purification, and specificity of rabbit anti-hCDC47 (human CDC47) antibodies were described previously (24). Rabbit anti-murine MCM3 (mMCM3) antiserum or antibodies affinity-purified with full-length mMCM3, anti-mcdc21 antiserum, and anti-mCDC46 antiserum were kindly provided by Dr. H. Kimura (Hokkaido University, Sapporo, Japan). Rabbit anti-Xenopus MCM2 (XMCM2) antiserum was kindly provided by Dr. S. Miyake (Toho University, Tokyo, Japan). All of these antibodies recognize not only the authentic target antigens but also their corresponding human homologues on Western blotting (21, 23, 36).
Analysis of the Nuclear Association of hMCM ProteinsTriton X-100-extracted nuclei were prepared as follows. Cells cultured in 100-mm plates were washed three times with ice-cold phosphate-buffered saline and lysed for 10 min on ice with 1 ml of ice-cold 0.5%TX-100mCSK. After low speed centrifugation (3000 rpm, 3 min at 4 °C), the nuclei were once more extracted with 1 ml of ice-cold 0.5%TX-100mCSK for 10 min on ice, recentrifuged, and resuspended in 1 ml of ice-cold 0.5%TX-100mCSK.
Aliquots (100 µl) were incubated at the indicated temperature for the
indicated period. Nucleotides, EDTA, or MgCl2 were added to
the samples before incubation as necessary. After incubation, the
pellet fractions and the soluble supernatants were separated by low
speed centrifugation. The pellet fractions were resuspended in 100 µl
of the buffer, and the supernatants were clarified by centrifugation at
15000 rpm for 5 min. The samples were then added to the same volumes of
2 × SDS-sample buffer (1 × solution; 62.5 mM
Tris-HCl, pH 6.8, 2% SDS, 5% -mercaptoethanol, 10% glycerol, 0.01% bromphenol blue), boiled, and analyzed by Western blotting or
SDS-polyacrylamide gel electrophoresis (SDS-PAGE) followed by Coomassie
Blue staining.
Nuclease digestion of Triton X-100-extracted nuclei was performed as follows. Triton X-100-extracted nucleus suspensions were prepared as described above. If not stated otherwise, 1 mM ATP was added to the buffer throughout the procedure. For DNase I digestion, the samples (100 µl) were supplemented with 250 or 1000 units/ml DNase I (10 units/µl, RNase-free, Boehringer Mannheim), followed by incubation. For HaeIII digestion, the MgCl2 concentration was increased to 2 mM, and the samples were incubated at 33 °C for 40 min with 1200 units/ml HaeIII (12 units/µl, Boehringer Mannheim). Subsequently, the pellet fractions and the soluble supernatants were separated by low speed centrifugation, and the samples were processed as described above.
To examine the extent of chromatin solubilization by nuclease digestion, DNA was isolated from the pellet and soluble fractions as follows. Samples (100 µl) were supplemented with 20 mM EDTA, 0.5% SDS, and 100 µg/ml RNase A and incubated at 37 °C for 10 min. Proteinase K (200 µg/ml) was then added, and incubation was continued for a further 2 h. After extraction with phenol-chloroform and precipitation with ethanol in the presence of 2.5 M ammonium acetate, the pellets were dissolved in 80 µl of 10 mM Tris-HCl, 1 mM EDTA. The amounts of DNA were then spectrophotometrically determined at a wavelength of 260 nm.
ImmunoprecipitationCell extracts were prepared as follows. For the Triton X-100-extractable fractions, cells cultured in 100-mm plates were washed three times with ice-cold phosphate-buffered saline, lysed for 20 min on ice with 1 ml of ice-cold 0.1%TX-100mCSK with 1 mM ATP, and centrifuged. For the fractions released from nonionic detergent-extracted nuclei by heating in the absence of ATP, Triton X-100-extracted nuclei prepared from 100-mm culture plates as described above, except that 0.1%TX-100mCSK was used for second round of lysis, were incubated in 1 ml of 0.1%TX-100mCSK at 25 °C for 30 min and centrifuged to obtain the soluble supernatant. For the fractions released from Triton X-100-extracted nuclei by DNase I digestion (the DNase I-released fractions), Triton X-100-extracted nuclei prepared from 100-mm plates as described above, except that 0.1%TX-100mCSK with 1 mM ATP was used for second round of lysis, were digested with 1000 units/ml DNase I in 1 ml of 0.1%TX-100mCSK containing 1 mM ATP at 25 °C for 30 min and centrifuged to obtain the soluble supernatant.
Separate aliquots were then mixed with 3 µg of purified anti-hCDC47 antibodies, anti-mMCM3 antibodies or control rabbit immunoglobulin, and rocked for 1 h at 4 °C. The mixtures were further incubated for 1 h after the addition of 10 µl of protein G-agarose beads (Pharmacia Biotech Inc.), and then the beads were washed three times with 1 ml of 0.1%TX-100mCSK with or without 500 mM NaCl for 10 min each. ATP (1 mM) was also included in the washing buffer for the Triton X-100-extractable fraction or the DNase I-released fraction. The immunoprecipitates were eluted with elution buffer (0.1 M glycine-HCl, pH 2.5) and subjected to SDS-PAGE followed by silver staining or immunoblotting. The efficiency of precipitation averaged approximately 10% of the total for each protein.
ImmunoblottingImmunoblotting was performed as described previously (24). The protein blots were incubated with appropriate first antibodies for 1 h at room temperature, purified anti-hCDC47 antibodies at 1 µg/ml, rabbit anti-mMCM3 antiserum at a 1:1000 dilution, rabbit anti-mcdc21 antiserum at a 1:500 dilution, rabbit anti-mCDC46 antiserum at a 1:500 dilution, rabbit anti-XMCM2 antiserum at a 1:500 dilution, and anti-proliferating cell nuclear antigen (PCNA) mouse monoclonal antibody at 20 µg/ml (PC10, Boehringer Mannheim). The blots were then probed with peroxidase-labeled goat anti-rabbit IgG or anti-mouse IgG antibodies (Zymed) and visualized using the ECL system (Amersham Corp.). The intensity of signals visualized on films was measured with a CS-930 chromatoscanner (Shimadzu, Japan).
In Vitro Translation of hCDC47 and hMCM3 ProteinsPurified plasmids carrying hCDC47 cDNA or hMCM3 cDNA (kindly provided by Dr. H. Takisawa; Osaka University, Osaka, Japan) were expressed in a coupled transcription-translation system with [35S]cysteine according to the manufacturer's instructions (Promega). In vitro translated proteins were diluted with 0.1%TX-100mCSK containing 1 mM ATP and subjected to immunoprecipitation with either anti-hCDC47 or anti-mMCM3 antibodies. After washing with the same buffer, the beads were boiled in 1 × SDS-sample buffer, and the precipitates were separated by 10% SDS-PAGE and analyzed with a bioimaging analyzer BAS2000 (Fuji Film, Japan).
During the course of the present analyses, we found that the
nucleus-bound hMCM proteins were released from the extracted nuclei by
heating. Immunoblotting analysis of the levels of hCDC47 protein in the
nuclear pellets and the soluble supernatants separated after incubating
Triton X-100-extracted HeLa cell nuclei revealed that, by incubation at
25 °C for 40 min, about half of the nucleus-bound hCDC47 was
liberated into the supernatant, and at 33 °C for 40 min, almost all
was liberated (Fig. 1A). With parallel
immunoblotting using anti-mMCM3 antibodies, hMCM3 was also found to be
dissociated with similar kinetics (Fig. 1C). PCNA, the
auxiliary protein of DNA polymerase (37), is also known to have a
detergent extraction-resistant nucleus-bound form (38), the levels of
which are cell cycle-regulated during S phase but differently from hMCM
proteins (24). As shown in Fig. 1A, the nucleus-bound PCNA
was also found to be dissociated from the nuclei in a
temperature-dependent manner. For all three proteins,
neither detectable proteolytic products nor remarkable reduction in the
total amount were found after heating.
There are several possible reasons for the observed thermolability of the nuclear association of these proteins. Interestingly, for hMCM proteins, the addition of ATP to the reaction mixture inhibited their dissociation. In contrast to the control case, in the presence of 0.1 mM ATP, almost all hCDC47 protein was retained in the nuclear pellet even after incubation at 33 °C for 40 min (Fig. 1B). ATP-dependent retention was also observed for hMCM3 (Fig. 1C) and hcdc21 (data not shown). In contrast, the addition of ATP failed to inhibit the thermolability of the PCNA nuclear association (Fig. 1B), indicating that the effect of ATP is not nonspecific. In all of the cases described above, the core histones were detected only in the nuclear pellet fractions, irrespective of the incubation temperature or the presence of ATP (Fig. 1B).
To examine the specificity of the ATP requirement for the nuclear
association of hMCMs, the experiments were repeated in the presence of
three other ribonucleoside triphosphates. As shown in Fig.
2A, none of them could maintain the
association of hCDC47 as effectively as ATP. Similar results were also
obtained for hMCM3 (data not shown). To address the role of ATP, two
ATP analogs were tested for their ability to function in place of ATP.
At comparable concentrations, both ATPS and AMP-PNP, which has a nonhydrolyzable
-
bond, could maintain the association of hCDC47 (Fig. 2B) or hMCM3 (data not shown). This indicates that the
hydrolysis of ATP
-
bonds, required for protein phosphorylation
or ATPase reaction, is not required for the observed
ATP-dependent nuclear binding by hMCMs.
DNA-protein interactions frequently require divalent cations, especially Mg2+. Accordingly, we examined the effects of Mg2+ on the nuclear association of hMCMs as follows. To avoid undesired nuclear lysis by removal of divalent cations, Triton X-100-extracted nuclei were prepared as usual with 0.5%TX-100mCSK buffer, which contains 1 mM MgCl2, and before incubation, they were supplemented with excess EDTA (final 10 mM) or additional MgCl2. In the presence of EDTA, almost all of the nucleus-bound hCDC47 was liberated from the nuclei by incubation at 25 °C for 20 min (Fig. 2C). Increasing the concentration of MgCl2 inhibited the release (Fig. 2C). In all cases, the core histones were detected only in the nuclear pellet fractions (data not shown); thus, the release of the hCDC47 in the presence of EDTA may not be due to nonspecific nuclear lysis. These findings suggest that Mg2+ may play a role in the nuclear association of hMCMs. In the presence of ATP, however, EDTA did not appear to accelerate the dissociation; even after incubation at 33 °C for 40 min, almost all hCDC47 protein was retained in the nuclear pellet, irrespective of the presence or absence of EDTA (Fig. 2D). It is possible that, in the presence of ATP, the association of Mg2+ with putative target molecule(s) is stabilized and thus not interfered with by EDTA. Alternatively, Mg2+ might not be required in the presence of ATP. These points should be precisely reexamined when a reconstituted system for hMCM-DNA (or chromatin) binding is established.
hMCM Proteins Are Associated with ChromatinDetermination of
conditions to stabilize the association of hMCMs with nucleus enabled
us to more precisely examine whether they were released by nuclease
digestion. The Triton X-100-extracted HeLa cell nuclei were incubated
with 1 mM ATP at 25 °C for 30 min under the absence or
presence of DNase I, and thereafter the levels of hCDC47 protein in the
nuclear pellets and the soluble supernatants were examined by
immunoblotting. Without DNase I, almost all of the nucleus-bound hCDC47
remained in the pellet. In contrast, when incubation was with 250 units/ml DNase I, approximately two-thirds of the nucleus-bound hCDC47
was released, and with 1000 units/ml, by which the genomic DNA was
digested into less than 400-100 base pairs on average (data not
shown), almost all was released (Fig. 3A).
Parallel immunoblotting revealed that the nucleus-bound hMCM3 and
hcdc21 were also liberated by DNase I digestion like hCDC47 (Fig.
3A; data not shown for hcdc21). When nuclei were treated
with restriction endonuclease HaeIII instead of DNase I,
similar release of the nucleus-bound hCDC47 and hMCM3 resulted (Fig.
3B). In both cases, release of the hMCMs by nuclease
digestion was accompanied by liberation of core histones (Fig. 3,
A and B). We also examined whether the bound
hMCMs are released by nuclease digestion even in the absence of ATP at
low temperature. To facilitate the nuclear association of hMCMs in the
absence of ATP and DNase I activity at low temperature, the MgCl2 concentration was increased to 10 mM in
these experiments. Under such conditions, without DNase I, most of the
bound hCDC47 remained in the pellet even after incubation in the
absence of ATP at 4 °C for 60 min, but this was also released by the
addition of 1000 units/ml DNase I (Fig. 3C).
Temperature-dependent release of hCDC47, its suppression by
ATP, and DNase I-mediated release under the presence of ATP, were
observed not only for HeLa cells, as described above, but also for
untransformed WI38 human fibroblasts (data not shown). Together, these
data lead us to conclude that the nucleus-bound hMCMs are associated
with chromatin and that the binding is stabilized by ATP.
It has been suggested that replication factories are connected with the nuclear matrix and that they are relatively resistant to removal by nuclease treatment. For example, newly synthesized DNA appears to remain associated with nuclei even after most chromosomal DNA is removed (28). We therefore investigated the time course of the DNase I-directed solubilization of the nucleus-bound hMCMs, comparing it with that of genomic DNA. The Triton X-100-extracted nuclei were digested with 1000 units/ml DNase I in the presence of ATP at 25 °C, and after 5, 10, and 20 min, respectively, the nuclear pellets and the soluble supernatants were separated and examined for hCDC47 and DNA levels. As shown in Fig. 3D, the extent of release of the bound hCDC47 was almost proportional to that of chromosomal DNA throughout the time course. This was also the case for HaeIII digestion at 33 °C for 40 min (data not shown). Therefore, it seems unlikely that the bound hMCMs are more resistant to removal by nuclease digestion as compared with total chromatin.
Six hMCM Members Are Associated with Chromatin as HeterocomplexesAlthough biochemical analyses of mammalian MCM proteins have so far been accomplished mainly using nonionic detergent extractable forms, several lines of investigation of chromatin-bound forms have been attempted with high concentration salt extraction. Using such methods, for example, it has been shown that MCM3 and CDC46 form a complex in the chromatin-bound form as tight as in the soluble one (21, 23, 26). This salt extraction is useful in some instances but might be inappropriate for analyses of interactions among proteins, since only those strong enough to be resistant to high salt concentrations would be maintained. We consider that the above described DNase I-directed solubilization of chromatin-bound hMCMs in the presence of ATP was a viable alternative to salt extraction; it better preserves physical interactions among proteins or between proteins and DNA, although the effects of the DNA remaining after DNase I digestion should be taken into account in the interpretation of results. In the present study, as an initial trial, we focused on physical interactions among the chromatin-bound hMCMs, assessing them by co-immunoprecipitation.
As previously reported, our anti-hCDC47 antibodies specifically detect
authentic hCDC47 by immunoblotting and by immunoprecipitation under
stringent conditions with radioimmune precipitation buffer (24).
Although the part (amino acids 562-719) of the hCDC47 protein used for
antibody preparation is unique, the protein with a region most
homologous to this is hMCM3. On the other hand, the anti-mMCM3
antibodies specifically recognize not only the authentic mMCM3 but also
hMCM3 on Western blotting (21, 23). These antibodies, therefore, seemed
suitable for aimed co-precipitation analysis. However, to more
rigorously establish their specificities, especially with the
immunoprecipitation buffer adopted, we prepared in vitro
translated hCDC47 and hMCM3. As shown in Fig. 4,
reciprocal immunoprecipitation with the anti-hCDC47 or anti-mMCM3
antibodies under the same conditions as used for cellular hMCMs
revealed no evidence of any cross-reaction.
The DNase I-released fractions of HeLa cells were immunoprecipitated
with anti-hCDC47 antibodies, and the precipitates were washed with
0.1%TX-100mCSK containing 1 mM ATP, subjected to SDS-PAGE, and silver-stained. Anti-hCDC47 antibodies co-precipitated p125, p105,
p97, and p90 with p83 corresponding to hCDC47 in the presence of 100 mM NaCl (Fig. 5A). When the NaCl
concentration in washing buffer was raised to 500 mM, p125
and p90 were remarkably decreased, but p105 and p97 remained in the
anti-hCDC47 precipitates (Fig. 5A). With immunoblotting of
the precipitates, the p83 was recognized by anti-hCDC47 as expected,
p125 by anti-XMCM2, p97 by anti-mcdc21, and p90 by anti-mCDC46 (Fig.
5B). The results for p105 were somewhat complex. Anti-mMCM3
antibodies reacted with p105 in the precipitates after washing with 100 mM NaCl but not after washing with 500 mM NaCl
(Fig. 5B), indicating the presence of at least two different proteins, one hMCM3 and another, which is more tightly associated with
hCDC47. Recently, hCDC47 has been found to form tight complexes with
hcdc21 and a newly identified p105MCM in their soluble forms (33, 34).
It is now apparent that p105MCM is a mammalian homologue of Mis5 (39),
an MCM family member in fission yeast (11). Therefore, the p105
identified in our system may be hMis5.
To gain further information, the DNase I-released fractions were
reciprocally immunoprecipitated with anti-mMCM3 antibodies. As shown in
Fig. 6, comparison between anti-hCDC47 and anti-mMCM3 revealed essentially the same co-precipitation patterns for hMCMs, and
no significant enrichment of the corresponding antigen was found in the
reciprocal immunoprecipitates. As demonstrated by previous studies (21,
26), in the presence of 500 mM NaCl, only hCDC46 was
readily co-precipitated with hMCM3 (data not shown). These
immunoprecipitation data suggest that the six chromatin-bound hMCM
proteins essentially exist in a heterocomplex with the apparent stoichiometric ratio 1:1, in which hCDC47, hcdc21, and hMis5 form one
relatively tight complex and hMCM3 and hCDC46 form another. Since a
slight, but significantly higher level of DNA compared with the control
case was detected in anti-hCDC47 immunoprecipitates (data not shown),
we cannot completely eliminate the possibility that the interactions
are mediated by residual DNA. However, complexes were also detected in
the Triton X-100-extractable fraction and in the fraction released from
nonionic detergent-extracted nuclei by ATP-depletion, as described
below.
The hMCM Complex Is Dissociated from Chromatin by Heating in the Absence of ATP
We next examined physical interactions among the
hMCMs dissociated from chromatin by ATP depletion. The fraction
released from nonionic detergent-extracted HeLa cell nuclei by heating in the absence of ATP was immunoprecipitated with anti-hCDC47 or
anti-mMCM3 antibodies, and the precipitates were washed with 0.1%TX-100mCSK, subjected to SDS-PAGE, and silver-stained. Anti-hCDC47 antibodies co-precipitated p125, p105, p97, p90, with p83 (Fig. 7A). With immunoblot analyses of the
anti-hCDC47 precipitate, p125 was recognized by anti-XMCM2, p90 by
anti-mCDC46, and p105 by anti-mMCM3 (Fig. 7B). The relative
levels of the co-precipitated hMCM3 and hCDC46 to hCDC47 were slightly
decreased in this fraction as compared with the chromatin-bound case.
Therefore, most hMCMs dissociated from chromatin by ATP depletion
appeared to remain in complexes. Unlike the DNase I-released fraction,
however, different precipitation profiles were obtained with
anti-hCDC47 and anti-mMCM3 antibodies; namely, anti-mMCM3 antibodies
failed to precipitate the complex efficiently, co-precipitating only
p90, p125, and additional p126 with p105 hMCM3, with apparently
equivalent stoichiometry (Fig. 7A). Immunoblot analyses
demonstrated anti-mCDC46 antibodies to recognize p90 as expected, but
anti-XMCM2 recognized neither p125 nor p126 (Fig. 7B). The
nature and significance of these latter two is currently unknown. One
interpretation of the discrepancy between the two immunoprecipitates is
that the anti-mMCM3 antibodies contain those targeting epitopes on
hMCM3 contributing to binding between the hMCM3-hCDC46 complex and the
hCDC47-hcdc21-hMis5 complex, enhancing dissociation of the two
complexes. The possibility that the hMCM3-hCDC46 complex was
dissociated preferentially from nuclei by ATP depletion can be ruled
out, since the dissociation rate of hMCM3 was similar to that of hCDC47
(see Fig. 1). In the chromatin-bound form in the presence of ATP, the
epitopes might be masked conformationally or by other protein(s).
Alternatively, even after dissociation by the antibodies, the two
complexes might be linked together by factors such as other proteins or
DNA protected from DNase I.
The hMCM Complex in the Triton X-100-extractable Fraction
We
also examined complex formation by the nonionic detergent-extractable
hMCMs by immunoprecipitation. The Triton X-100-extractable fractions of
HeLa cells were immunoprecipitated with anti-hCDC47 antibodies, and the
precipitates were washed with 0.1%TX-100mCSK containing 100 mM or 500 mM NaCl. The precipitates were
subjected to SDS-PAGE followed by silver staining, showing similar
co-precipitation profiles as with the DNase I-released fraction (Fig.
8). The identity of each hMCM except hMis5 was confirmed
by immunoblotting (data not shown). The relative levels of higher
mobility forms of hMCM2 and retarded forms of hcdc21 in the precipitate
appeared increased in comparison with those in the chromatin-bound
form, in agreement with previous findings that these forms result from
hyperphosphorylation and can be readily extracted with nonionic
detergent (21, 22). These results indicate that soluble hMCMs also
exist, at least partly, as heterocomplexes, in which hCDC47, hcdc21,
and hMis5 similarly form a relatively tight complex. On the other hand, the anti-mMCM3 immunoprecipitates in the presence of 100 mM
NaCl contained hCDC46 but little of the other hMCMs (Fig. 8), similar to the situation with the fraction released from nonionic
detergent-extracted nuclei by ATP depletion. The same interpretation
might thus be applicable.
Since sequence requirements for replication origins appear to differ among budding yeast, egg extract, and mammalian somatic cells, MCMs might function in distinct ways in each case. Whereas biochemical studies of physical associations among mammalian MCMs have been so far carried out mainly using chromatin-unbound soluble forms (21, 23, 26, 33, 34), those playing a role in allowing the initiation of replication may more likely be the nucleus-bound forms. In the present study, we have therefore focused attention on chromatin-bound hMCMs solubilized by DNase I in the presence of ATP. Our newly devised approach is partly analogous to the UV or formaldehyde cross-linking-immunoprecipitation techniques applied for analyzing protein-DNA interactions in vivo (40, 41). The data obtained indicate that six hMCM family members associate with chromatin almost exclusively as a heterocomplex, in which hCDC47, hcdc21, and hMis5 form one relatively tight complex, while hMCM3 and hCDC46 form another.
It has been shown using gel filtration in the presence of glycerol or by glycerol gradient centrifugation that soluble fraction hMCMs reside in a 500-600-kDa complex (26, 33, 34). However, the exact composition of the complex remains to be elucidated. Interactions between MCM3-CDC46 and CDC47-cdc21-Mis5 complexes have so far not been detected with standard immunoprecipitation procedures (23, 26, 33, 34). In contrast, the present immunoprecipitation assay also demonstrated the heterocomplex consisting of six hMCMs in the Triton X-100-soluble chromatin-unbound fraction. Our conditions may thus be more stabilizing than those applied by the standard method. It has been reported that glycerol stabilizes the 500-600-kDa hMCM complex during gel filtration (33). Taking into account our findings and the above described previous findings, it seems likely that hMCMs play a role in DNA replication as heterohexamers associated with chromatin. Whether this is also the case for the egg extract or yeast systems is unclear, although a 500-600-kDa MCM heterocomplex has also been detected in the chromatin-unbound fraction in both cases (16, 30, 31, 32). It is furthermore conceivable that the hMCM complexes undergo cell cycle modifications such as association-dissociation with chromatin or phosphorylation, but the possibility still remains that there is a change in the complex formation profile during the cell cycle. This could be clarified by examining synchronized cell populations with the methods described here. On the other hand, it is clearly of interest that any association of chromatin-bound complexes with other protein(s) be clarified, and co-immunoprecipitation studies might be one fruitful approach to achieving this end.
The hMCM Complex Chromatin AssociationIn the present study, we showed that under three different conditions, nucleus-bound hMCMs are released depending on nuclease digestion. To date, a number of authors have investigated the effects of DNase I treatment on the nuclear association of mammalian MCMs. Kimura et al. (21) reported no release of nucleus-bound mMCM3 under their conditions. Burkhart et al. (26) described approximately half of the bound hMCM3 as liberated, although details of their assay were not given. Todorov et al. (22) found that digestion of HeLa cell nuclei with DNase I released the bound hMCM2 without affecting the core histones, in direct contrast to our present results. Although it is difficult to directly compare findings obtained under different experimental conditions, a major advantage with our system was the stabilization of chromatin binding of the hMCM complex observed with ATP. However, it is still unclear whether the complex binds to DNA directly or requires the mediation of other protein(s) and, if directly, which hMCMs participate in the binding. Recently, it was reported that hMCMs can bind to histone H3 in vitro (42). However, in anti-hCDC47 immunoprecipitates from the DNase I-released fractions, core histones have not been detected in comparable stoichiometry with hMCMs as yet.2 On the other hand, it is also uncertain whether specific DNA sequences are involved in the binding. In this regard, we have observed that HaeIII-PvuII-digested DNA fragments can be co-precipitated by anti-hCDC47 only in the presence of ATP and not by control antibodies.2
Possible Involvement of ATP in the hMCM Complex Chromatin AssociationThe possibility that chromatin binding of hMCMs
is stabilized by ATP is intriguing. The ability of AMP-PNP to replace
ATP indicates that reactions requiring hydrolysis of the ATP -
bond like protein phosphorylation or ATPase dependent steps are not required for the observed effect. Rather, ATP might act like a co-factor that enhances DNA binding as is the case with several replication-related DNA-binding proteins such as SV40 or polyomavirus T-antigen; the binding of the T-antigen to the origin is enhanced not
only by ATP but also by AMP-PNP (43, 44). Since it is unclear whether
the hMCMs bind to DNA directly or via other DNA-binding protein(s), we
cannot even speculate as to the identity of candidate protein(s)
affected by ATP. One possibility, however, is that the hMCM complex
binds to DNA directly in an ATP-dependent manner. It is
known that hMCMs have putative ATP-binding and ATPase motifs in their
conserved regions (45), but we have yet failed to detect either in
immunoprecipitated hMCM complex preparations.2 Another
possibility is that the hMCM complex binding is through other
protein(s) that associate with DNA in an ATP-dependent
manner. One attractive candidate for such a protein(s) might be the
putative human homologue of budding yeast origin recognition complex
(46), since this multi-protein complex binds to ARS in an
ATP-dependent manner and interacts genetically with MCMs in
budding yeast (47, 48). In contrast to the case with the T-antigen,
however, origin recognition complex DNA binding is not stimulated by
AMP-PNP (47). In any case, our results do provide a strong indication
that the hMCM complex association with chromatin in vivo is
dependent to some extent on ATP. Although the exact role of ATP in the
chromatin association of hMCMs and its generality in other systems such as egg extracts or yeast remains to be determined, its
effect should be taken into account in future analyses of MCM-DNA
interactions.
We thank Dr. H. Kimura for generously providing antibodies and sharing unpublished results, Dr. S. Miyake for anti-XMCM2 antibody, and Dr. H. Takisawa for hMCM3 cDNA. We also thank T. Yoshida and Y. Matsumura for technical assistance.