Mammalian nuclei become licensed for DNA replication during late telophase

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Journal of Cell Science 115, 51-59 (2002)
© 2002 The Company of Biologists Limited

Research Article

Mammalian nuclei become licensed for DNA replication during late telophase

Daniela S. Dimitrova¹^,*^,, Tatyana A. Prokhorova²^,, J. Julian Blow², Ivan T. Todorov³ and David M. Gilbert¹

¹ Department of Biochemistry and Molecular Biology, SUNY Upstate Medical University, 750 East Adams Street, Syracuse, NY 13210, USA
² CRC Chromosome Replication Research Group, The Wellcome Trust Building, University of Dundee, Dundee, DD1 5EH, UK
³ Department of Diabetes, Endocrinology and Metabolism, City of Hope National Medical Center, 1500 Duarte Road, Duarte, CA 91010, USA
^* Present address: Department of Biological Sciences, Cooke Hall, North Campus, SUNY at Buffalo, Buffalo, NY 14260
Present address: Department of Biological Chemistry and Molecular Pharmacology, Harvard Medical School, Boston, MA 02115

$§$ Author for correspondence (e-mail: dsd7{at}acsu.buffalo.edu)

Accepted October 3, 2001

SUMMARY

Top
SUMMARY
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Mcm 2-7 are essential replication proteins that bind to chromatinin mammalian nuclei during late telophase. Here, we have investigatedthe relationship between Mcm binding, licensing of chromatinfor replication, and specification of the dihydrofolate reductase(DHFR) replication origin. Approximately 20% of total Mcm3 proteinwas bound to chromatin in Chinese hamster ovary (CHO) cellsduring telophase, while an additional 25% bound gradually andcumulatively throughout G1-phase. To investigate the functionalsignificance of this binding, nuclei prepared from CHO cellssynchronized at various times after metaphase were introducedinto Xenopus egg extracts, which were either immunodepletedof Mcm proteins or supplemented with geminin, an inhibitor ofthe Mcm-loading protein Cdt1. Within 1 hour after metaphase,coincident with completion of nuclear envelope formation, CHOnuclei were fully competent to replicate in both of these licensing-defectiveextracts. However, sites of initiation of replication in eachof these extracts were found to be dispersed throughout theDHFR locus within nuclei isolated between 1 to 5 hours aftermetaphase, but became focused to the DHFR origin within nucleiisolated after 5 hours post-metaphase. Importantly, introductionof permeabilized post-ODP, but not pre-ODP, CHO nuclei intolicensing-deficient Xenopus egg extracts resulted in the preservationof a significant degree of DHFR origin specificity, implyingthat the previously documented lack of specific origin selectionin permeabilized nuclei is at least partially due to the licensingof new initiation sites by proteins in the Xenopus egg extracts.We conclude that the functional association of Mcm proteinswith chromatin (i.e. replication licensing) in CHO cells takesplace during telophase, several hours prior to the specificationof replication origins at the DHFR locus.

Key words: Mammalian nuclei, Mcm proteins, Replication licensing, ODP, Cell cycle

Introduction

Top
SUMMARY
Introduction
Materials and Methods
Results
Discussion
REFERENCES

The minichromosome maintenance proteins (Mcm 2-7) have beenshown to be key participants in the mechanism that limits eukaryoticreplication to once-per-cell-cycle (Tye, 1999). In particular,the association of Mcm proteins with chromatin appears to bethe final step in the formation of pre-replication complexes(pre-RCs) in a process referred to as replication licensing(Rowles and Blow, 1997). The molecular details of pre-RC assemblyare beginning to emerge (Kelly and Brown, 2000; Leatherwood, 1998).The origin recognition complex (ORC) recruits Cdc6 which,along with Cdt1 (Maiorano et al., 2000b; Nishitani et al., 2000;Tada et al., 2001), is required for the subsequent loading ofthe Mcm 2-7 complex (Coleman et al., 1996; Romanowski et al., 1996;Rowles et al., 1996; Tanaka et al., 1997). The formationof pre-RCs takes place during late mitosis and early G1-phaseand is prevented by the presence of cyclin-dependent kinase(CDK) activity (Coverley et al., 1996; Noton and Diffley, 2000)and geminin, a protein that binds to and inhibits Cdt1 (McGarry and Kirschner, 1998;Tada et al., 2001; Wohlschlegel et al., 2000).No activities have been identified that are requiredfor the formation of pre-RCs after the binding of Mcm proteins.Hence, the binding of Mcm 2-7 to chromatin likely representsfunctional licensing and the culmination of pre-RC assembly.In late G1-phase, CDK levels rise sharply, resulting in theinitiation of replication and the conversion of the pre-RC intoan active replication complex. CDK activity and geminin levelsrise throughout S-phase, until their destruction during thefollowing metaphase-anaphase transition. Thus, once-per-cell-cyclereplication is ensured by the sequential and mutually exclusiveconditions necessary for the assembly of pre-RCs and their conversionto active replication complexes.

In cultured mammalian cells, replication initiates at specificsites (Aladjem et al., 1998; Giacca et al., 1994), however,no specific DNA sequences have been identified that direct theassembly of pre-RCs. We have shown that site-specific initiationof replication within the Chinese hamster ovary (CHO) dihydrofolatereductase (DHFR) locus can be achieved in Xenopus egg extractsusing intact, late-G1-phase nuclei as a substrate (Gilbert et al., 1995).With late-G1-phase nuclei that have been permeabilizedduring preparation, or with intact, early-G1-phase nuclei, replicationinitiates at random sites (Dimitrova and Gilbert, 1998). Ata distinct point during G1-phase, CHO nuclei experience a transition(origin decision point, ODP) that selects which of many potentialchromosomal sites will function as an origin of replicationin the upcoming S-phase (Wu and Gilbert, 1996). The ODP is unlikelyto represent the association of hamster ORC with chromatin,since pre-ODP nuclei replicate efficiently and at random siteswhen introduced into Xenopus egg extracts that lack ORC proteins(Yu et al., 1998), indicating that non-specific origin selectionis mediated by hamster ORC. Since the binding of Mcm proteinsprobably represents the culmination of pre-RC formation at replicationorigins, we were interested in determining whether the ODP representsthe completed assembly of pre-RCs at specific sites. We havepreviously shown that the Chinese hamster homologue of Mcm2is loaded gradually and cumulatively throughout G1-phase, beginningas soon as nuclei have formed during late telophase (Dimitrova et al., 1999).Thus, it remained possible that different originscould become licensed throughout G1-phase, as Mcm proteins boundto an increasing fraction of the chromatin. Alternatively, itwas possible that the initial association of Mcm proteins withchromatin prior to the ODP could be non-functional, with functionalMcm complexes being formed only at the ODP. For example, partialMcm complexes have been shown to associate with chromatin, butonly the complete heterohexamer forms a functional pre-RC (Maiorano et al., 2000a;Prokhorova and Blow, 2000). This possibilityseems to be supported by recent evidence that replication ofG1-phase CHO nuclei in Xenopus egg extracts depends on the presenceof Xenopus ORC and Mcm proteins if nuclei are isolated earlierthan 2 hours post-metaphase (Natale et al., 2000).

Here, we have evaluated the capacity of licensing-deficientXenopus egg extracts to replicate genomic DNA and to initiatereplication specifically at the DHFR origin within CHO nucleiprepared at different times during G1-phase. We found that extractsthat have been immunodepleted of Mcm proteins or supplementedwith geminin are unable to replicate chromatin from CHO cellssynchronized in metaphase, prior to Mcm binding. However, CHOnuclei prepared at all stages of G1-phase, including those fromtelophase cells, in which the first fraction of Mcm proteinshad bound to chromatin, were replicated with similar efficiency.Furthermore, replication at the DHFR locus initiated at randomsites with intact pre-ODP nuclei and at specific sites withinpost-ODP nuclei, regardless of the presence of Mcm proteinsin the Xenopus egg extract. We conclude that Mcm proteins areincorporated into functional pre-RCs during late telophase andthat a sufficient quantity of Mcm proteins have associated withchromatin at that time to support efficient genome replication.However, the licensing of mammalian chromatin is not sufficientto dictate which of many potential origins of replication willbe selected for initiation in the upcoming S-phase.

Materials and Methods

Top
SUMMARY
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Cell culture and synchronization
CHOC 400 is a CHO cell derivative, in which a 243 kb segmentof DNA containing the DHFR gene has been amplified $~$ 500-foldby stepwise selection in methotrexate (Milbrandt et al., 1981).Cells were cultured and synchronized as described (Dimitrova and Gilbert, 1998;Dimitrova et al., 1999).

Cell fractionation and immunoblotting
Cell fractionation and immunoblotting were performed as described(Dimitrova et al., 1999). For the immunoblots displayed in Fig. 3,the cells were permeabilized with 80 µg/ml digitoninand incubated in Xenopus egg extracts at a concentration of10,000 nuclei/µl for 1 hour at 21°C. The extractswere supplemented with 100 µg/ml aphidicolin (CalBiochem)to prevent DNA replication and release of Mcm proteins. Thenuclei were then washed with cold cytoskeleton buffer (CSK),extracted for 5 minutes on ice with CSK containing 0.5% TritonX-100 (Sigma), washed twice with CSK buffer and processed forwestern blotting as described (Dimitrova et al., 1999). Mcm2proteins (Xenopus and hamster) were detected with an affinity-purifiedrabbit polyclonal anti-human Mcm2 antibody (Todorov et al., 1995),Mcm3 proteins (Xenopus and hamster) – with a rabbitpolyclonal serum raised against Xenopus Mcm3 (Prokhorova and Blow, 2000)and Xenopus ORC2 – with an affinity-purifiedrabbit polyclonal antibody (Yu et al., 1998).

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Fig. 3. Geminin prevents binding of Xenopus Mcm proteins to hamster chromatin. Anti-HsMcm2 and anti-XMcm3 antibodies recognize both Xenopus (lane 1, Xenopus egg cytosol) and hamster (lane 2, Triton-extracted CHOC 400 G1-phase nuclei) Mcm proteins, which can be distinguished by their slightly different electrophoretic mobility. The anti-XORC2 antibody does not crossreact with hamster ORC2. (lanes 3-6) CHOC 400 metaphase cells were permeabilized with 80 µg/ml digitonin and incubated for 1 hour at 21°C in LSS (lanes 4,5) or HSS (lane 6) Xenopus egg extracts (supplemented with 100 µg/ml aphidicolin). Soluble or loosely bound proteins were removed by Triton extraction as described in Materials and Methods and the washed chromatin was subjected to immunoblotting analysis with antibodies specific for Mcm2, Mcm3 and ORC2. In lane 5, the LSS extract was supplemented with 2 µg/ml of purified Xenopus geminin. Aliquots of Xenopus egg extract (lane 1) or Triton-extracted CHOC 400 G1 nuclei (lane 2) were run in parallel and served as markers for the mobility of the respective proteins of hamster or frog origin.

Analysis of DNA replication in Xenopus egg extracts
Activated low speed (LSS) and high speed (HSS) Xenopus egg extractswere prepared as described (Chong et al., 1995; Goldberg et al., 1995).Extract depletions were carried out by a modification(T.A.P., unpublished) of the previously described procedure(Chong et al., 1997). Briefly, prior to the immunodepletion,the anti-Mcm3 antibody-coupled Protein A beads were pre-equilibratedin previously depleted extract. This decreased the extract dilutionfactor and helped to preserve better the nuclear assembly andDNA replication activity of the depleted extracts. PurifiedXenopus geminin (McGarry and Kirschner, 1998) was used at finalconcentrations between 0.2-2 µg/ml. This destruction box-negativevariant of geminin was stable during long incubation periods.Rates and extent of DNA replication with CHOC 400 nuclei wereevaluated by measuring the amount of acid-precipitable [ ${alpha}$ -³²P]dATP(Dimitrova and Gilbert, 1998; Gilbert et al., 1995). Specificityof initiation within the DHFR locus in CHO G1 nuclei was measuredby the early-labeled fragment hybridization (ELFH) assay (Dimitrova and Gilbert, 1998;Gilbert et al., 1995). Each batch of G1 cellswas tested for origin specificity before use in other experiments.Typically, the ODP transition occurred between 5-6 hours post-metaphase.

Results

Top
SUMMARY
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Mcm3 binds to CHO chromatin gradually and cumulatively throughout G1-phase, beginning in telophase
We have previously shown that approximately 20% of the totalMcm2 proteins in CHO cells are loaded onto chromatin duringtelophase, and that an additional 25% is loaded gradually andcumulatively throughout the remainder of G1-phase (Dimitrova et al., 1999).To determine whether this was true for anotherMcm subunit, Mcm3, CHO (CHOC 400) cells were synchronized inmetaphase with nocodazole and released into G1-phase. Immunoblottingexperiments were performed with either whole cell extracts,intact nuclei, permeabilized nuclei or detergent-extracted nuclei.Our anti-Mcm3 antibody detected a single band with an apparentmolecular mass of $~$ 100 kDa (Fig. 1A), consistent with the predictedsize of mammalian Mcm3. The total amount of Mcm3 per cell didnot vary significantly throughout the cell cycle and remainedexclusively nuclear during interphase, however, the majorityof Mcm3 was released from nuclei by Triton extraction (Fig. 1).Exit from mitosis is not synchronous for all cells and overa period of $~$ 1 hour after removal of nocodazole there is a mixedpopulation of cells at various stages of mitosis and early-G1.We used classical morphological criteria for their distinction:mitotic figures, degree of chromosome decondensation and dispersal,nuclear morphology, extent of nuclear lamina reassembly, completionof cytokinesis. Detergent-resistant association of Mcm3 proteinswith chromatin was first observed 40 minutes after metaphase,coincident with the appearance of telophase cells in the population(Fig. 1B). Within 1 hour post-metaphase most of the cells havecompleted mitosis and are already in G1-phase. By this time,approximately 20% of total Mcm3 was loaded onto chromatin. Additionalamounts of Mcm3 were loaded as cells proceeded through G1-phase(Fig. 1C). Later, as cells traversed S-phase, Mcm3 was releasedfrom chromatin. These results closely resemble previous resultsobtained for Mcm2 in CHO cells (Dimitrova et al., 1999). Weconclude that Mcm2 and Mcm3 associate with chromatin with similarkinetics, consistent with their participation in a multi-subunitpre-RC complex.

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Fig. 1. Cell cycle-regulated association of hamster Mcm3 with chromatin. (A) Western blot of total CHOC 400 cellular protein extract probed with an Mcm3-specific antibody. Positions of molecular weight standards (indicated in kDa) are marked on the left. (B,C) Variations in the amount of chromatin-bound Mcm3 during different stages of the cell cycle in CHOC 400 cells. Synchronized cell populations were resuspended in cytoskeleton buffer (for Triton extractions) or transport buffer (for digitonin permeabilization) and incubated for 5 minutes on ice with or without addition of permeabilizing agents as described in Materials and Methods. The cellular or nuclear pellets (P) were separated from the soluble fractions (S) by centrifugation. The proteins from each fraction (only the pellets were analyzed in the case of digitonin extractions) were separated by electrophoresis in 10% SDS-polyacrylamide gels (amounts corresponding to 5x10⁵ cells were loaded in each lane), transferred to nylon membranes and probed with an anti-Mcm3 antibody. In B, the percentages of cells in different stages of mitosis, determined microscopically after staining aliquots of the synchronized cells with 0.1 µg/ml 4', 6-diamidino-2-phenylindole (DAPI), are indicated on the right for each time point. In C, the relative amounts of chromatin-bound Mcm3 proteins at each time point analyzed were estimated by comparing serial dilutions of the soluble fractions run in parallel to an aliquot of the Triton-resistant fraction and are indicated on the right.

Functional significance of Mcm chromatin association
We next wished to distinguish between three possible explanationsfor the continued loading of Mcm proteins during G1. First,Mcm proteins loaded during telophase might not be functional:incompletely assembled and non-functional Mcm complexes havebeen observed to associate with chromatin (Maiorano et al., 2000a;Prokhorova and Blow, 2000). Second, continued Mcm loadingcould reflect the staggered assembly of functional pre-RCs ontoan increasing number of origins during G1-phase. Third, theinitial loading of Mcm proteins may be sufficient to licenseall origins for a new round of replication and the additionalloading of Mcm-s during G1-phase may be superfluous (Mahbubani et al., 1997).To distinguish between these possibilities, weevaluated the efficiency of Mcm-depleted Xenopus egg extractsto initiate replication within nuclei prepared from cells synchronizedat various times during early G1-phase. If early G1-phase hamsterchromatin does not contain functional pre-RCs, then it shouldrequire the presence of Xenopus Mcm proteins in order to initiatereplication. Likewise, an increase in the number of functionalpre-RCs, assembled onto hamster chromatin during G1-phase, shouldresult in a quantitative increase in the rate of replicationin Mcm-deficient extracts. Results (Fig. 2) revealed that bothintact nuclei and nuclei that had been permeabilized with digitoninto release the soluble pool of unbound Mcm proteins, replicatedwith similar efficiency when prepared from cells at all timesduring G1-phase, both in Mcm-depleted and mock-depleted extract.By contrast, Xenopus sperm chromatin (not shown) and CHO metaphasechromatin (Fig. 2), which are not associated with Mcm proteins,cannot be replicated by Mcm-depleted extracts. Our attemptsto examine Triton-extracted nuclei were not successful (D.S.D.,unpublished) as they are extremely poor substrates for DNA replicationeven in complete Xenopus egg extracts (Dimitrova and Gilbert, 1998).

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Fig. 2. The replication capacity of CHOC 400 G1-phase nuclei is independent of the presence of XMcm3 in Xenopus egg extracts. Synchronized CHOC400 cells were permeabilized with 80 µg/ml (A,B) or 400 µg/ml (C,D) digitonin to prepare cells with intact or permeabilized nuclei, respectively. Permeabilized cells were introduced in mock-depleted (A,C) or XMcm3-depleted (B,D) Xenopus egg extracts supplemented with [ ${alpha}$ -³²P]dATP. Aliquots were removed at the indicated times and the percentage of input DNA replicated was determined by acid precipitation as described (Dimitrova and Gilbert, 1998). Similar results were obtained in three independent experiments. Filled squares represent metaphase cells; diamonds, 1 hour; filled circles, 2 hours; triangles, 4 hours; hatched squares, 6-hour G1-phase nuclei; and hatched circles, G1/S-phase nuclei.

Recently, it has been shown that the protein geminin binds toCdt1 and inhibits its ability to load Mcm proteins onto Xenopussperm chromatin (McGarry and Kirschner, 1998; Tada et al., 2001;Wohlschlegel et al., 2000). We reasoned that, if geminin alsoprevented Xenopus Mcm proteins from being assembled onto hamsterchromatin upon the introduction of permeabilized CHO cells intogeminin-supplemented extracts, this would provide a simple meansto study replication in the absence of licensing activity. Inaddition, the process of immunodepletion inevitably reducesthe efficiency of replication in extracts due to the lengthymanipulations and the dilution of extract. To determine whethergeminin can prevent the association of Xenopus Mcm proteinswith hamster chromatin, CHO metaphase chromatin lacking hamsterMcm proteins (Fig. 3, lane 3) was introduced into a Xenopusegg extract in the presence or absence of geminin. After a 45minute incubation, chromatin was washed with Triton X-100 andthe association of XMcm2 and XMcm3 with chromatin was evaluatedby immunoblotting. To exclude the possibility that Mcm proteinswere loaded onto hamster chromatin and then released upon replicationof that chromatin, the egg extracts were supplemented with aphidicolin,which blocks DNA synthesis and prevents the release of Mcm proteins(Dimitrova and Gilbert, 2000; Kubota et al., 1997). As a control,the binding of XORC2, which is not inhibited by geminin (Walter, 2000;Wohlschlegel et al., 2000), was also evaluated. Althoughplenty of XORC2, XMcm2 and XMcm3 were loaded onto metaphasechromatin in control Xenopus egg extract, only XORC2 associatedwith chromatin in geminin-supplemented extracts. In fact, consistentwith results obtained previously with Xenopus sperm chromatinas a substrate (McGarry and Kirschner, 1998; Walter, 2000),the binding of XORC2 to metaphase chromatin was moderately enhancedby geminin (Fig. 3, lane 5). To verify that the concentrationsof geminin employed in this study were sufficient to block DNAreplication with unlicensed chromatin, either Xenopus spermchromatin (Fig. 4A) or hamster metaphase chromatin (Fig. 4B)were introduced into a Xenopus egg extract supplemented withvarious concentrations of geminin. Whereas the replication ofboth these substrates was completely inhibited by 0.2 µg/mlof geminin, replication proceeded efficiently within controlG1 nuclei (Fig. 4C) at concentrations up to 20 µg/ml ofgeminin. Again, CHO nuclei prepared at various times duringG1-phase replicated with similar efficiency in geminin-supplementedXenopus egg extracts (Fig. 4D-G). We conclude that functionalpre-RCs are present in CHO nuclei from the very beginning ofG1-phase.

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Fig. 4. Hamster chromatin becomes licensed for replication at the end of mitosis. (A-C) Geminin prevents replication of Xenopus sperm (A; 1,000 nuclei/µl) and CHO metaphase chromatin (B; 10,000 nuclei/µl), but has no effect on hamster G1 nuclei (C; 6 hours in G1, 10,000 nuclei/µl). The indicated substrates were incubated in Xenopus egg extracts with (diamonds, 0.2 µg/ml; circles, 2 µg/ml; and triangles, 20 µg/ml) or without (squares) the addition of purified geminin. Aliquots were removed at the indicated times and the amount of replicated DNA was determined by acid precipitation as in Fig. 2. (D-G) Synchronized CHOC 400 cells were permeabilized as in Fig. 2 and incubated in control (D,F) or geminin-supplemented (E,G; 2 µg/ml) Xenopus egg extracts. The percentage of replicated DNA at various time points was determined as in Fig. 2. Similar results were obtained in four independent experiments.

Dispersed initiation within pre-ODP nuclei and site-specific intitiation within post-ODP nuclei are independent of Xenopus Mcm or Cdt1 proteins
When CHO nuclei are introduced into Xenopus egg extracts, replicationinitiates at the same specific sites used in cultured CHO cells,providing that nuclei are prepared with intact nuclear envelopesfrom cells that have passed a specific time point during G1-phase,termed the ODP. With nuclei isolated prior to the ODP, Xenopusegg extracts initiate replication at sites dispersed throughoutthe DHFR locus. It has been proposed that the ODP transitionmay represent the assembly of Mcm-containing pre-replicationcomplexes on hamster chromatin (Natale et al., 2000). This proposalwas based on data suggesting that pre-ODP nuclei cannot replicatein ORC- and Mcm-depleted extracts. However, our findings presentedin Figs. 1-4 indicate that nuclei isolated from cells as earlyas 1 hour after metaphase are fully competent to replicate inlicensing-defective extracts. This implies that replicationlicensing and the ODP are independent G1 events. Since thisprevious study did not directly measure the specificity of initiationin depleted extracts, we examined whether the pattern of initiationsites within the DHFR locus was influenced by the loading ofXenopus Mcm proteins. CHOC 400 cells were synchronized at 2hours and 6 hours after metaphase, representative of the pre-ODPand post-ODP stages of G1-phase. Intact nuclei from these cellswere introduced into either Mcm-depleted or geminin-supplementedextracts and the sites of in vitro initiation of replicationin the DHFR locus were mapped. These results (Fig. 5) demonstrateclearly that efficient initiation of replication at dispersedsites throughout the DHFR locus within pre-ODP nuclei was notmediated by the loading of Xenopus Mcm proteins. Random initiationbefore the ODP is a property of the CHO nuclei and is mediatedby hamster pre-RC proteins. Similarly, site-specific initiationwithin post-ODP nuclei was independent of Xenopus Mcm loading.

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Fig. 5. Replication origin selection in the DHFR locus in CHOC 400 G1 nuclei is independent of Xenopus Mcm proteins. Intact CHOC 400 pre-ODP (2 hours in G1; squares and diamonds) or post-ODP (6 hours in G1; circles and triangles) nuclei were introduced into mock-depleted (A; squares and circles), Mcm3-depleted (A; diamonds and triangles), control untreated (B; squares and circles) or geminin-supplemented (B; diamonds and triangles) Xenopus egg extracts. Specificity of initiation in the DHFR locus was determined by the ELFH assay as described in Materials and Methods.

Geminin prevents the licensing of illegitimate replication origins that are activated when post-ODP nuclei are permeabilized
We have previously shown that, even under conditions that preserveoverall replication efficiency, permeabilization of the nuclearenvelope of post-ODP CHO nuclei results in a complete loss oforigin specificity when these nuclei are introduced into Xenopusegg extracts (Dimitrova and Gilbert, 1998). This loss in specificitycould be due to the loss from CHO nuclei of soluble proteinsrequired for origin specification, the disruption of a multiproteincomplex within nuclei, or to the inappropriate entry of a Xenopusfactor(s) that can license illegitimate origins. To distinguishbetween these possibilities, intact and permeabilized nucleiwere prepared from the same population of post-ODP cells andintroduced into either complete extracts or the same extractssupplemented with geminin to prevent loading of Xenopus Mcm-sand unauthorized assembly of Xenopus pre-RCs on CHO chromatin.Consistent with the results presented in Fig. 5B, geminin hadno effect on the site-specific pattern of initiation withinintact nuclei (not shown). However, whereas initiation withinpermeabilized post-ODP nuclei was dispersed throughout the DHFRlocus in control extracts, a significant degree of specificitywas retained when these extracts were supplemented with geminin.Hence, an intact nuclear envelope is required to prevent theentry of a Xenopus activity that can license illegitimate originsites. Importantly, the parallel examination of permeabilizednuclei prepared at 2 hours in G1-phase (pre-ODP) revealed thatinhibition of the origin licensing potential of Xenopus eggextracts by geminin was not sufficient to create prematurelya specific initiation pattern within pre-ODP nuclei (Fig. 6,triangles and hatched circles). This result once again confirmsthat the licensing of CHO chromatin for replication is independentof the selection of specific origin sites. We expect that theintroduction of permeabilized mammalian nuclei or chromatinpreparations into geminin-supplemented Xenopus egg cytosol wouldprovide a valuable in vitro system for dissection of the componentsof mammalian pre-RCs.

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Fig. 6. Replication initiates with a significant degree of specificity within permeabilized CHO post-ODP nuclei incubated in licensing-deficient Xenopus egg extracts. Digitonin-permeabilized pre-ODP (2 hours in G1; triangles and hatched circles) or post-ODP (6 hours in G1; diamonds and circles) nuclei were incubated in control untreated (diamonds and triangles) or geminin-supplemented (filled circles and hatched circles) Xenopus egg extracts and the specificity of initiation within the DHFR locus was measured by the ELFH assay. Squares represent intact post-ODP nuclei incubated in control untreated egg extracts. Similar results were obtained in three independent experiments. The relative specificity of initiation at ori-ß within permeabilized post-ODP nuclei (measured as the average specificity of probes C, D, E and R, mapping to the region of peak initiation activity) varied in different experiments between 25 to 60-70% of that within intact post-ODP nuclei.

	Discussion

Top SUMMARY Introduction Materials and Methods Results Discussion REFERENCES

We demonstrate for the first time that functional pre-RCs areassembled in CHO cells at the onset of G1-phase, several hoursprior to the specification of the DHFR replication origin atthe ODP. Mcm proteins bind to chromatin during late telophaseand, coincident with this binding, nuclei become competent toreplicate in licensing-defective Xenopus egg extracts. Thisindicates that the initial amount of Mcm-s loaded during telophaseis sufficient for licensing of CHO nuclei. Similar to our previousobservations with Mcm2, we found that additional amounts ofhamster Mcm3 proteins are loaded throughout G1-phase. Interestingly,a similar gradual loading of XMcm2 and XMcm3 proteins onto chromatinwas observed during incubation of demembranated Xenopus spermnuclei in Xenopus egg extracts (Coue et al., 1998; Thommes et al., 1997).Increase in the amount of chromatin-bound Mcm proteinshas been documented in S. cerevisiae (Zou and Stillman, 2000),S. pombe (Ogawa et al., 1999) and human nuclei (Mendez and Stillman, 2000).The additional Mcm-s loaded on chromatin during G1-phasemay represent backup copies that can take over should replicationforks become stalled. The Mcm hexamers may function as a replicativehelicase (You et al., 1999) and the excess of chromatin-loadedproteins may serve to increase the replicative fidelity, notthe replication rates. Consistent with this idea, although 10-20copies of Mcm 2-7 were loaded onto each replication origin onsperm nuclei incubated in Xenopus extracts, maximal replicationrates were still observed when this was reduced to only $~$ 2 copiesper origin (Mahbubani et al., 1997). Alternatively, these couldbe Mcm complexes assembled on origins that do not fire. It hasbeen demonstrated that in S. cerevisiae pre-RC proteins arebound to both active and silent chromosomal replication origins(Santocanale and Diffley, 1996). It is possible that eukaryoticnuclei assemble more origins than necessary as a means to ensurethat the whole genome would be replicated even if some originsfailed to fire. A third possibility is that a fraction of thechromatin-bound Mcm proteins are involved in genomic processesother than DNA replication. For example, Mcm proteins have beenshown to be associated with transcription factors (DaFonseca et al., 2001;Zhang et al., 1998) and with components of thegeneral transcription machinery (Yankulov et al., 1999) or tobind the promoters of several cell cycle-regulated genes (B.Tye et al., unpublished). Regardless of other potential functionsof the Mcm proteins, our study demonstrates that the initialamount of Mcm-s loaded during telophase is fully functionaland sufficient to license the CHO chromatin for replication.

Replication licensing is clearly insufficient to specify theDHFR origin of replication, as active replication forks wereefficiently assembled within CHO pre-ODP nuclei introduced intolicensing-deficient extracts. Initiation under these conditionstakes place at sites distributed throughout the DHFR locus andmust be mediated by functional pre-RCs assembled by CHO nucleiprior to nuclear isolation in order to initiate replicationwithin licensing-defective extracts. Interestingly, we observedincreased loading of XORC2 onto CHO metaphase chromatin in Xenopusegg extracts supplemented with geminin (Fig. 3, compare lanes4 and 5). Identical results have been reported when Xenopussperm chromatin was incubated in geminin-supplemented extracts(McGarry and Kirschner, 1998; Walter, 2000). These observationsraise the possibility that loading of increasing amounts ofMcm-s onto chromatin serves to prevent ORC binding to illegitimatesites or unwanted ‘sliding’ of ORC along chromatin.Alternatively, the increased loading of Mcm-s throughout G1-phasecould weaken the interaction of ORC proteins with chromatinand cause the dissociation of ORC from sites with low affinity,thus focusing initiation to more specific chromosomal siteswith high affinity for ORC. In support of this hypothesis, Rowleset al. found that licensing (i.e. loading of Mcm-s on chromatin)dramatically changed XORC1 affinity for Xenopus sperm chromatinso that it became sensitive to extraction with high salt (Rowles et al., 1999).The ODP could represent the culmination of thisprocess. Studies of ORC and Mcm interactions along the entirelength of defined replicons in mammalian nuclei during differentstages of G1-phase will be needed to further explore this hypothesis.

Two significant differences exist between our data, presentedhere, and those presented previously by another lab (Natale et al., 2000).The first issue is whether the replication licensingand the ODP are separate events. In contrast to previous measurementsof the ODP (Wu and Gilbert, 1996), Natale et al., concludedthat the ODP occurs at 2 hours in G1-phase, a timepoint at whichthey first detected the assembly of functional pre-RCs. Ourobservations indicate that the ODP can, indeed, occasionallyexhibit limited temporal shifts, depending on the cell cyclelength and/or growth conditions (D.S.D., unpublished). Thus,the ODP must be determined individually for each origin in differentcell lines, as well as for each batch of synchronized cellsusing the same cell line. We use aliquots of the same batchof synchronized cells to carry out all different types of experiments,which excludes variability due to batch-to-batch differencesin the kinetics of cell cycle progression. However, we havenever observed an ODP earlier than 4 hours in G1-phase. A closeexamination of the data published by Natale et al., providesan explanation for this apparent discrepancy. Whereas replicationwithin the CHO nuclei becomes independent of Xenopus ORC andMcm proteins at 2-3 hours post-metaphase [meaning that the licensingis completed within 2-3 hours, figures 1 and 8 in Natale etal. (Natale et al., 2000)], the selection of specific originsites has just begun at this time, but is not completed until4-5 hours post-metaphase [figure 2 in Natale et al. (Natale et al., 2000)],fairly close to the timing documented by us.This implies that in both studies the licensing of CHO nucleioccurred no less than 2 hours prior to the ODP transition. Weconclude that the replication licensing of mammalian nucleiand the selection of specific origin sites are uncoupled. Takentogether with our previous work on the establishment of a temporalprogram for replication of CHO chromosomal domains (Dimitrova and Gilbert, 1999)and the dynamics of replicon activation duringS-phase (Dimitrova and Gilbert, 1999; Dimitrova et al., 1999),we have now demonstrated that the four major regulatory steps(replication licensing, replication timing, selection of preferredorigin sites and firing of the origins) in the replication ofthe mammalian genome are temporally separated (Fig. 7).

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Fig. 7. Establishment of a program for replication of mammalian nuclei. When CHOC 400 cells, blocked in metaphase with nocodazole, are released into G1-phase, nuclear assembly is completed within 1 hour [(Dimitrova and Gilbert, 1999; Dimitrova et al., 1999) and this study], coincident with the reactivation of general transcription (D.S.D., unpublished) and the licensing of chromatin for replication (this study). Within the next hour, chromosomal domains are directed to distinct and reproducible nuclear locations and by 2 hours into G1-phase (TDP, timing decision point) the temporal order for their replication in the upcoming S-phase is established (Dimitrova and Gilbert, 1999). At the ODP (5-6 hours in G1), specific chromosomal sites, where replication will initiate, are selected within the DHFR locus [(Wu and Gilbert, 1996) and this study]. Several hours later, at the G1/S transition (12-14 hours post-metaphase) the rise in S-phase promoting factor activity (S-phase cyclin-dependent kinases and dbf4/cdc7 kinase) leads to the assembly of replication factories and the firing of the earliest replication origins (Dimitrova et al., 1999). The four major events, which prepare the genome for replication, are highlighted in red.

The second important difference concerns the timing of assemblyof functional pre-RCs. Natale et al. found that the competenceto replicate in ORC- and Mcm-depleted extracts was not acquireduntil 2-3 hours after metaphase, whereas we observed efficientreplication in Mcm-depleted or geminin-supplemented extractsas early as 1 hour after metaphase, when nuclear assembly hasjust been completed. One possibility is that this subtle differencecould be due to differences in the handling of synchronizedcells after mitotic shake-off. We have found that both the lengthof nocodazole treatment and the temperature at which mitoticcells are maintained between shake-off and re-plating are criticalto the timely resumption of mitosis and normal progression intoG1. Furthermore, we routinely monitor the exit of our mitoticcell preparations from mitosis and discard preparations thatdo not exhibit $>=$ 90% G1-phase cells within 1 hour (Fig. 1). Wehave also confirmed that Mcm proteins are loaded on chromatininvariantly during late telophase in mammalian cells of differentorigin (human, hamster, rat and mouse) by indirect immunofluorescentlabeling of Triton-extracted cells (D.S.D., unpublished). Thecharacteristic mitotic figures allow for an extremely precisedistinction of cells at different stages of mitosis even withinasynchronous cell populations (Dimitrova et al., 1999), thuseliminating any possibility that the use of mitotic synchronizationmight have created artefacts in our experiments. As Natale etal. also observed tight binding of the Mcm proteins to chromatinwithin 1 hour post-metaphase, the only actual difference inresults concerns the functional status of the pre-RCs assembledin late telophase. Despite our extensive efforts, we could notfind conclusive evidence to account for this puzzling discrepancy.However, we believe that it may, at least in part, be a consequenceof alterations introduced in the egg extract preparation protocolby these investigators (Li et al., 2000), resulting in unusualperformance of their extracts. In particular, Li et al. foundthat upon introduction of hamster G1 nuclei in Xenopus egg extractsthe radioactive label was incorporated into DNA strands 2-4kb in length that do not grow as would be expected of activereplication forks. By contrast, our extracts efficiently elongatenascent DNA (Dimitrova and Gilbert, 1998) (D.S.D. and D.M.G.,unpublished), suggesting that the extracts used in the previousstudies may have suffered a reduced replication competence.For unknown reasons, the earliest G1 nuclei might be more sensitiveto the egg extract deficiencies and fail to replicate altogether.Even late G1 nuclei replicate at reduced levels under thoseconditions [only 10-20% of the genome within intact nuclei replicatedNatale et al. (Natale et al., 2000) vs. 80-90% in our studies],once again pointing to suboptimal in vitro replication conditions.

Two observations suggest that our results are not due to deficienciesin our extracts: first, the Mcm-depleted extract can be rescuedby purified Mcm complexes (T.A.P. and J.J.B., unpublished);second, we obtain similar results by simply adding geminin tothe extract, which does not reduce extract activity or disruptefficient nuclear envelope assembly (with Xenopus sperm or CHOmetaphase chromatin). We conclude that licensing of mammalianchromatin takes place in late telophase, coincident with thestable association of Mcm proteins with chromatin, and is distinctfrom the specification of replication origin sites, which occursseveral hours later, at the ODP.

We have previously shown that the permeabilization of CHO post-ODPnuclei results in loss of origin specificity even under conditionsthat preserve high replication rates (Dimitrova and Gilbert, 1998).There are at least three possible explanations for thisobservation. First, permeabilization may result in loss of solublenuclear components, essential for specific origin activation.Second, the permeabilizing reagents affect the stability ofendogenous hamster pre-RC complexes, which leads to their disassembly.Third, CHO pre-RCs remain stable after permeabilization, butfactors in the Xenopus egg extracts gain access to the exposedCHO chromatin and re-arrange the existing pre-RCs or licenseillegitimate sites. The availability of licensing-defectiveextracts allowed us to address which of these possibilitieswere true. We found that a significant degree of DHFR originspecificity was preserved when digitonin-permeabilized post-ODPnuclei were allowed to initiate replication in geminin-supplementedextracts. The efficient site-specific initiation was supportedby endogenous pre-RC proteins stably associated with CHO chromatin.This result supports primarily the third possibility, althougha minor damage to endogenous hamster pre-RCs could not be ruledout, given the reduced degree of specificity, as compared tointact post-ODP nuclei. Our findings are consistent with a hostof previous studies that have demonstrated the essential roleof the intact nuclear envelope for properly regulated DNA replication.Importantly, the fact that initiation takes place at dispersedsites within pre-ODP nuclei, with or without the addition ofgeminin to the Xenopus egg extract, once again demonstratesthat events taking place within CHO nuclei at a discrete pointin G1-phase are responsible for focusing of initiation to specificorigin sequences. Finally, our findings open up new possibilitiesfor studies of the assembly of mammalian pre-RCs at specificchromosomal sites via the development of manipulatable systemsfor replication of mammalian chromatin. The role of individualpre-RC proteins can be evaluated by introducing chromatin preparations,from which specific pre-RC components have been removed, intogeminin-supplemented Xenopus cytosol, which can support efficientreplication without the unwanted licensing of additional initiationsites.

ACKNOWLEDGMENTS

This work was supported by a Cancer Research Campaign (CRC)grant SP2385/0101 to J.J.B. and by NIH grant GM57233-01 to D.M.G.

REFERENCES

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SUMMARY
Introduction
Materials and Methods
Results
Discussion
REFERENCES

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