Multiple Functional Elements Comprise a Mammalian Chromosomal Replicator

The structure of replication origins in metazoans is only nominallysimilar to that in model organisms, such as Saccharomyces cerevisiae.By contrast to the compact origins of budding yeast, in metazoansmultiple elements act as replication start sites or controlreplication efficiency. We first reported that replication forksdiverge from an origin 5' to the human c-myc gene and that a2.4-kb core fragment of the origin displays autonomous replicatingsequence activity in plasmids and replicator activity at anectopic chromosomal site. Here we have used clonal HeLa celllines containing mutated c-myc origin constructs integratedat the same chromosomal location to identify elements importantfor DNA replication. Replication activity was measured beforeor after integration of the wild-type or mutated origins usingPCR-based nascent DNA abundance assays. We find that deletionsof several segments of the c-myc origin, including the DNA unwindingelement and transcription factor binding sites, substantiallyreduced replicator activity, whereas deletion of the c-myc promoterP₁ had only a modest effect. Substitution mutagenesis indicatedthat the sequence of the DNA unwinding element, rather thanthe spacing of flanking sequences, is critical. These resultsidentify multiple functional elements essential for c-myc replicatoractivity.

INTRODUCTION

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Introduction

The initiation of eukaryotic DNA synthesis is precisely regulatedboth at the G₁/S phase checkpoint of the mitotic cycle and bymechanisms that control the order of replicon firing (reviewedin references 9, 18, and 21). For Escherichia coli, mammalianviruses, and the budding yeast Saccharomyces cerevisiae theinitiation of DNA replication is controlled by trans-actinginitiator proteins that interact with cis-acting DNA replicatorsequences. For S. cerevisiae, replicators encompass 100 to 200bp and include the major replication origin sites where DNAsynthesis begins (8). These replicators contain an essential $~$ 11-bp autonomous replicating sequence (ARS) consensus sequence(ACS) that binds the origin recognition complex (ORC) to nucleateformation of prereplication complexes. By comparison, the domainsthat control replication in the fission yeast Schizosaccharomycespombe are 500 to 1,500 bp in size and comprise multiple regionsthat add synergistically to origin activity (11, 22, 28, 48).The sequences that contribute to origin activity in S. pombeare heterogeneous, although A+T-rich potential binding sitesfor spORC have been found in several origins (10, 30, 36). Hence,despite notable differences in the structures of their respectiveORC orthologs, the dispersed replication origins of metazoancells more closely resemble those of S. pombe than those ofS. cerevisiae in that multiple elements distributed over largedistances act as replication start sites or control replication(3, 4, 13, 15, 16, 27, 40, 53, 56, 58, 62).

Replication begins in the 5' flanking region of the human c-mycgene, and a 2.4-kb core fragment of the c-myc origin displaysplasmid ARS activity in transfected cells and in cell extracts(7, 15, 41-43, 56-58, 62). At the germ line locus, in plasmids,or at an ectopic chromosomal locus, replication initiates atmultiple sites within the c-myc core origin and in the flankingDNA (15, 40, 58, 62). Thus, the c-myc core origin comprisesboth replicator elements and replication start sites. Amongthe structural elements of the 2.4-kb c-myc origin core arethe P₀ and P₁ promoters, a number of transcription factor consensusbinding sites, a DNA unwinding element (DUE) (also called thefar upstream element [44]) which contains three 10-of-11 matchesto the S. cerevisiae ARS consensus, a potential triplex- ornon-B DNA-forming region, a series of positioned nucleosomes(7, 33, 34, 54), and several DNA segments that adopt eitherbent or highly flexible conformations in vitro (7, 33, 34, 54).Similar sequences or structures are often found in the chromosomalreplicators of S. cerevisiae and S. pombe. Their presence inthe c-myc origin core raised the questions of which of theseelements might contribute to replicator activity and whetherthe multiple initiation sites within and flanking the core originare coordinately regulated.

In the present work we used the FLP recombinase system (40,46) to build a series of clonal cell lines, each containinga mutated c-myc origin construct integrated at the same chromosomallocation. Origin activity was defined by PCR quantitation ofthe abundance of short nascent DNA strands. Deletion of severaldifferent segments of the origin core, including the DNA unwindingelement and transcription factor binding sites, substantiallyreduced chromosomal origin activity, whereas deletion of thec-myc promoter P₁ had modest effect. Mutations that reducedorigin activity did so at each of four sequence-tagged sitestested near the c-myc DNA. The results indicate that multiplefunctional elements are essential for c-myc origin activityand are consistent with prior indications that initiation sitesflanking the core origin are subservient to the replicator activityof the core origin.

MATERIALS AND METHODS

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Materials and Methods

Plasmid construction. Mutants of the wild-type c-myc origin core were constructedfrom the plasmid pFRT.myc (40) by overlapping PCR and standardcloning techniques. Numbering of c-myc sequences begins at theupstream HindIII cleavage site. In pFRT.myc. ${Delta}$ DUE the DNA unwindingelement (nucleotides [nt] 747 to 828) was deleted. In plasmidpFRT.myc. ${Delta}$ 3' 1420, nt 931 to 2350 were deleted. In pFRT.myc. ${Delta}$ DUE, ${Delta}$ 3' 1420 both the DUE and the 3' 1,420 bp were deleted. A seriesof 12 $~$ 200-bp deletions was constructed covering the c-myc coreorigin (pFRT.myc. ${Delta}$ 1 through pFRT.myc. ${Delta}$ 12); the endpoints of thesedeletions are given in Fig. 2. Plasmid pFRT.myc.Sub2.4 was constructedby replacing the c-myc HindIII/NotI core fragment with the 3'flanking XhoI/EcoRV genomic c-myc fragment of nearly identicalsize. Plasmids pFRT.myc.Sub5AT and pFRT.myc.Sub5GC were constructedby replacing the 64% A+T 201 bp deletion DNA of pFRT.myc. ${Delta}$ 5 with201 bp containing 64% A+T or 64% G+C nucleotides, respectively(sequences available from the authors).

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FIG. 2. Maps of mutant c-myc origin constructs. Mutants of the c-myc origin were made between the HindIII and NotI sites in pFRT.myc. Solid boxes, wild-type (WT) c-myc core origin sequences; unfilled areas, deleted sequences; stippled box, non-origin substituted sequences. The rightmost 46 bp (NotI/XhoI segment) of c-myc DNA are not shown but are retained in all constructs. The ranges of the mutated sequences are shown to the left, alongside the abbreviation of the plasmid containing the construct (e.g., ${Delta}$ 1 is pFRT.myc. ${Delta}$ 1).

Cell culture, transfection, and selection. Acceptor 406 cells were derived from HeLa cells by integrationof an FLP recombinase target (FRT) site (40) and maintainedin Dulbecco's modified Eagle medium with 10% newborn calf serum(Gibco-BRL) and 50 µg of gentamicin/ml in a humidified5% CO₂ atmosphere at 37°C. 406 cells were periodically reselectedwith hygromycin (400 µg/ml) to maintain Hyg-TK expressionat the acceptor site. Transfections were performed using Lipofectamine2000 (Gibco-BRL) following the procedure recommended by themanufacturer. For each transfection the total amount of DNAwas 1 µg, and the molar ratio of the donor plasmid andcotransfected FLP recombinase-expressing plasmid, pOG44, was1:8. Approximately 24- to 48-h posttransfection, selection forG418 resistance (500 µg of active component/ml) was initiatedand continued for 15 days. Single colonies were picked and exposedto 20 µM ganciclovir for 2 to 3 days. Colonies resistantto hygromycin, G418, and ganciclovir were used for further analysis.

Nascent DNA. Nascent DNA was isolated by denaturing gel electrophoresis (27,40). Briefly, approximately 7.5 x 10⁷ cells were trypsinized24 h after seeding and washed twice in cold phosphate-bufferedsaline. The cell pellet was resuspended in 240 µl of coldphosphate-buffered saline with 10% glycerol. Seventy-five microlitersof cell suspension was loaded into one well of a 1.25% alkalinelow-melting-point agarose gel (SeaPlaque GTG) prechilled to4°C. Cells were lysed in the well for 10 min before theDNA marker was loaded and the current applied. The gel was runfor 12 h at 40 V, neutralized in 1x Tris-acetate-EDTA (TAE)buffer (51), and stained in 1x TAE-0.5 µg of ethidiumbromide/ml. The 1- to 2-kb nascent DNA was excised and purified(Qiagen).

Diagnostic PCR. Fifty nanograms of genomic DNA was used for PCR with primersets diagnostic for either the unoccupied chromosomal acceptorsite or the acceptor site after integration of the donor plasmid(Table 1). PCRs contained 10 mM Tris-Cl (pH 8.0), 50 mM KCl,1.5 mM MgCl₂, 0.2 mM each of dGTP, dCTP, dATP, and dTTP, 1.25U of Hotstar Taq DNA polymerase (Qiagen), and 25 pmol of eachprimer for the following amplification regimen after an initialdwell at 94°C for 15 min: 94°C for 30 s, 55°C for30 s, and 72°C for 30 s, for a total of 30 cycles.

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TABLE 1. Primers used in this work^a

Southern blot hybridization. Analysis was performed using standard methods with 10 µgof genomic DNA and hybridizing with either the 756-bp EcoRI/XbaIfragment of the Hyg gene from plasmid pFRT.Hyg.TK or the 405-bpNcoI/SmaI fragment of the Neo gene from pFRT.myc, as previouslydescribed (40).

Slot blot quantitation. Nascent DNA or known quantities of genomic DNA were appliedto Hybond N⁺ membranes (Amersham) using a slot blot apparatus(Schleicher and Schuell) (40) and UV cross-linked. Prehybridizationand hybridization washes were done as described for Southernblot hybridization, with 30 ng of [ ${alpha}$ -³²P]dCMP randomly labeledgenomic DNA used as a probe. The signals of the nascent samplesand the genomic standards were quantified by PhosphorImager(Molecular Dynamics).

Quantitative PCR. Short (1 to 2 kb) nascent DNA was quantitated by competitivePCR (27, 40) using the primers and competitors shown in Table1. The log of the ratio of signal intensity for the competitorand nascent template PCR products was plotted against the logof the competitor amount added to each reaction. GraphPad Prismwas used to fit a straight line to the points, and the equationof this line was used to quantitate the amounts of nascent DNAtemplate (12, 17, 40). Reaction conditions were selected toavoid heteroduplex formation between competitor and nascentPCR products, as evidenced by r² values near unity (29). Toallow comparison of the results from PCRs of different nascentDNA preparations, the primary data from all reactions were normalizedto an equivalent amount of input nascent DNA, based on slotblot quantitation of the total nascent DNA in each preparation(12, 17, 40). The data shown are representative of at leastthree independent nascent DNA preparations. Alternatively, quantitativereal-time PCR (Q-PCR) was performed on an Applied BiosystemsGeneAmp 5700 sequence detection system with amplification monitoredby SYBR Green fluorescence. The Q-PCR primers specific for theFLP acceptor site did not amplify HeLa genomic DNA. For Q-PCRthe data were normalized against the signal from the low-nascent-strandabundance site STS-54.8 in the human ß-globin locus(15, 27) amplified from an equal amount of the same nascentDNA in the same 96-well tray using the same reagents. The abundanceof 1- to 2-kb nascent strands at STS-54.8 was roughly 40 copies/ng(based on Molecular Probes OliGreen quantitation of total 1-to 2-kb nascent DNA). Standard curves were developed for allprimer sets using known amounts of the same preparation of 406/pFRT.myccell genomic DNA. The data presented are the means (and standarddeviation) of triplicate analysis on at least three independentpreparations of nascent DNA from each cell line.

Helical stability. Free energy values of wild-type c-myc DNA (nt 734 to 934) andthe pFRT.myc.Sub5 substitution DNAs were calculated using WEBTHER-MODYNsoftware (http://wings.buffalo.edu/gsa/dna/dk/WEBTHERMODYN)(45) over 100-bp windows (1 bp per step, 10 mM monovalent ion,37°C), and 20-bp windows (1 bp per step, 140 mM monovalention, 37°C).

RESULTS

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Results

Selectivity of replicator activity. The chromatin around c-myc exon I comprises several nuclease-hypersensitivesites that are stable to translocation (33, 34), a DNA unwindingelement that is susceptible in vivo to single-stranded-DNA-directedreagents (44), and a site of potential non-B DNA structure (Fig.1a) (49). DNA replication initiates at the endogenous c-myclocus in the 5' flanking region of the gene corresponding tothe 2.4-kb HindIII/XhoI fragment and in the neighboring XhoI/EcoRVfragment (15, 56, 58, 62). The 2.4-kb c-myc origin HindIII/XhoIfragment displayed replicator activity when moved to the ectopicchromosomal acceptor site in the HeLa-derived cell line 406,but a bacterial sequence did not act as a replicator at thesame site (40). To address the question of whether another eukaryoticsequence placed at this acceptor site would act as a replicator,the XhoI/EcoRV fragment of c-myc DNA downstream of the origincore was substituted for the wild-type c-myc origin core inpFRT.myc to produce pFRT.myc.Sub2.4 and integrated into thesame ectopic location in 406 cells using FLP recombinase (Fig.1b) (40, 46). The targeted integration of all constructs wasconfirmed by analytical PCR using primers that generated diagnosticproducts from the empty or occupied acceptor sites and by Southernblot hybridization using probes complementary to the acceptorsite (Hyg probe) or origin donor plasmid (Neo probe). As seenin Fig. 1c, diagnostic primers 1 and 2 yielded amplified productonly with 406 cell DNA containing the unoccupied acceptor site,but not with DNA from 406/pFRT.myc or 406/pFRT.myc.Sub2.4 cellsin which the acceptor site was occupied. Conversely, primers1 and 3 yielded the expected amplified product only with DNAfrom 406/pFRT.myc or 406/pFRT.myc.Sub2.4 cells but not with406 cell DNA. Hybridization with the Hyg probe confirmed thatintegration occurred at the intended chromosomal location, andhybridization with the Neo probe yielded a single hybridizingband, excluding the possibility that integration might alsohave taken place in a chromosomal location other than the acceptorFRT site (Fig. 1d).

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FIG. 1. Selectivity of c-myc origin replicator activity. (a) Map of the HindIII/EcoRV fragment of the human c-myc locus. The first c-myc exon and the 5' part of the second exon are indicated by filled boxes. The HindIII/XhoI fragment contains the wild-type c-myc origin core. The neighboring XhoI/EcoRV fragment used in pSub2.4 is also indicated. H, HindIII; N, NotI; Xh, XhoI; Ev, EcoRv. Downward-pointing arrowheads represent replication initiation sites previously mapped in vivo (15, 56, 58, 62). Filled squares and upward-pointing arrowheads designate sites hypersensitive to micrococcal nuclease or DNase I, respectively (6, 33, 34, 49, 54). A region of potential non-B, triplex structure is indicated by three horizontal bars. The diamond refers to a region of helical instability in vivo (DUE). (b) FLP recombinase integration system. 406 cells are the HeLa acceptor cell subline containing a single chromosomal copy of the plasmid pHyg.FRT.TK (linearized at its BglII sites), representing an unoccupiedchromosomal acceptor site. Hyg, hygromycin resistance gene; FRT, FLP recombinase target site; TK, herpes simplex virus thymidine kinase gene. Unfilled rectangles are vector sequences. The Hyg-FRT-TK fusion protein renders cells resistant to hygromycin and sensitive to ganciclovir. pFRT.myc (shown linearized) contains the 2.4-kb HindIII/XhoI fragment of the c-myc origin or its derivatives. pFRT.myc.Sub2.4 contains the XhoI/EcoRV fragment of c-myc DNA in place of the HindIII/NotI fragment; the 3' 46-bp NotI/XhoI segment of the 2.4-kb HindIII/XhoI fragment is retained in pFRT.myc.Sub2.4. Neo, G418 resistance gene with promoter replaced by FRT. pOG44 is an FLP recombinase expression plasmid, cotransfected with pFRT.myc. Accurately targeted cells are resistant to hygromycin, G418, and ganciclovir. PCR primers 1, 2, and 3 (horizontal arrowheads) give products diagnostic for the unoccupied acceptor site (primers 1 and 2) or the occupied acceptor site (primers 1 and 3). Sequence-tagged sites Hyg, pVU, pML, and TK used in Q-PCR quantitation are also indicated. The positions of restriction sites (E, EcoRI) and probes (solid bars; Hyg, 756-bp EcoRI/XbaI fragment of pHyg.FRT.TK; Neo, 405-bp NcoI/SmaI fragment of pFRT.myc) relevant to Southern analyses are shown. Plasmids are described in detail in reference 40. (c) Diagnostic PCR using primers 1 and 2 or 1 and 3 with DNA from 406 acceptor cells (A) with an unoccupied FRT acceptor site and DNA from cells containing the wild type c-myc origin fragment (pFRT.myc) (W) or pFRT.myc.Sub2.4 c-myc DNA (Sub2.4) at the acceptor site. (d) Hybridization with the Hyg or Neo probe to EcoRI-digested DNA from 406 acceptor cells (A) or from 406 cells containing the wild-type c-myc origin fragment (W) or pFRT.myc.Sub2.4 (Sub2.4) at the acceptor site. (e) Relative nascent strand abundance by Q-PCR at sequence-tagged sites STS-Hyg and STS-TK in 406 cells (A) or STS-Hyg, STS-pVU, STS-pML, and STS-TK in 406 cells containing the wild-type c-myc origin fragment (W) or pFRT.myc.Sub2.4 (Sub2.4) at the acceptor site. See the text for details.

Origin activity, as reflected by the abundance of short (1-to 2-kb) nascent DNA, was measured by Q-PCR. Other laboratories,as well as our own, have shown that this size fraction comprisesnew, semiconservatively synthesized DNA derived from replicationorigins and excludes Okazaki fragments (20, 60, 62). Similarapproaches have been used previously to analyze the c-myc (40),DHFR (29), and ß-globin (3, 27) origins. Q-PCR wasperformed at four sequence-tagged sites, STS-Hyg, STS-pVU, STS-pML,and STS-TK (Fig. 1b and e). Consistent with previous resultsusing competitive PCR, integration of the wild-type c-myc coreorigin into the acceptor site of 406 cells significantly increasedthe nascent DNA abundance at all four sequence-tagged sites,with the greatest increases at the sites most closely flankingthe c-myc origin DNA, STS-pVU and STS-pML. STS-pML and STS-pVUare 3 kb apart, and STS-Hyg and STS-TK are more than 8 kb apart,while the electrophoretically size-fractionated nascent DNAfor these assays was no larger than 2 kb. Thus, the increasesin nascent strand abundance at sequence-tagged sites STS-Hyg,-pVU, -pML, and -TK are consistent with our previous observationsthat the wild-type origin core DNA promotes independent initiationsin the flanking chromosomal DNA. By contrast, pFRT.myc.Sub2.4did not induce appreciable origin activity at the same chromosomalacceptor site. The relative abundance of 1- to 2-kb nascentDNA at STS-pVU or STS-pML in 406/pFRT.myc cells was about 10to 15 times that in 406/pFRT.myc.Sub2.4 cells. These data confirmthat the c-myc origin core displays replicator activity andargue that it is not merely the size or the eukaryotic derivationof the origin fragment that endows it with this property. Significantly,at the endogenous c-myc locus, replication initiates at severalsites in the c-myc DNA contained in pFRT.myc.Sub2.4 (56, 58,62). The absence of replicator activity in the XhoI/EcoRV fragmentsuggests that these initiation sites are subservient to thecore origin.

cis-acting elements in the c-myc origin. The contribution to replicator activity of two regions of theorigin, containing the DUE and the 3' 1,420-bp transcriptionfactor binding domain, were of particular interest since analogouselements have been implicated in origin activity in eukaryoticviruses and yeast, yet these elements are thought not to befunctionally conserved in the replicators of higher eukaryotes.Plasmids were constructed to remove an 82-bp region containingthe DUE (pFRT.myc. ${Delta}$ DUE), or the 3' 1,420-bp region containingmultiple transcription factor consensus binding sites (pFRT.myc. ${Delta}$ 3'1420) and integrated at the 406 cell acceptor site (Fig. 2).Targeted integration was confirmed by diagnostic PCR and Southernblot hybridization (Fig. 3a to c).

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FIG. 3. Screening of constructed cell lines. (a) Maps of unoccupied (upper) and occupied (lower) acceptor sites. E, EcoRI; X, XbaI. Integrant structure was verified by PCR (b and d) and Southern hybridization to the Neo probe (c and e) or the Hyg probe (e). PCR primers (horizontal arrowheads) were designed to give diagnostic products from the empty acceptor site (upper map; primers 1 and 2) and from the occupied acceptor site (lower map; primers 1 and 3). The predicted sizes of restriction fragments from unoccupied and occupied FRT sites are indicated. Other notations are as in Fig. 1. (b and d) Diagnostic PCR. Genomic DNA from 406-derived cell lines was amplified with primer pairs 1 and 2 or 1 and 3. A, DNA from 406 acceptor cells; W, DNA from 406 cells with integrated wild-type c-myc DNA (406/pFRT.myc). DNA from the clonal cell lines 406/pFRT.myc. ${Delta}$ DUE ( ${Delta}$ DUE), 406/pFRT.myc. ${Delta}$ 3' 1420 ( ${Delta}$ 3' 1420), or 406/pFRT.myc. ${Delta}$ DUE, ${Delta}$ 3' 1420 ( ${Delta}$ DUE, ${Delta}$ 3' 1420) is shown. DNA from the clonal cell lines 406/pFRT.myc. ${Delta}$ 1 through 406/pFRT.myc. ${Delta}$ 12 is shown in lanes numbered 1 to 12. (c) Southern hybridization. Genomic DNA isolated from406 cells containing wild type c-myc DNA (406/pFRT.myc) (W) or from cell lines 406/pFRT.myc. ${Delta}$ DUE ( ${Delta}$ DUE), 406/pFRT.myc. ${Delta}$ 3' 1420 ( ${Delta}$ 3' 1420), or 406/pFRT.myc. ${Delta}$ DUE, ${Delta}$ 3' 1420 ( ${Delta}$ DUE, ${Delta}$ 3' 1420) was digested with XbaI, electrophoresed, and hybridized to the Neo probe. The 5.8-kb band arose from the removal of an additional 1,420 bp from the 7.2-kb wild-type band. (e) Southern hybridization. Genomic DNA was isolated from 406 cells containing an unoccupied FRT (A), wild-type c-myc DNA (406/pFRT.myc) (W), or from the clonal cell lines 406/pFRT.myc. ${Delta}$ 1 through 406/pFRT.myc. ${Delta}$ 12 (numbered 1 to 12). DNA was digested with EcoRI, electrophoresed, and hybridized with the Hyg probe (upper panel) or the Neo probe (lower panel).

The origin activity of the wild-type and mutant origin constructswas compared at three sequence-tagged sites by competitive PCR(Fig. 4). Deletion of the DUE decreased the nascent strand abundanceat STS-pML by approximately half and reduced the signals atthe flanking sites STS-Hyg and STS-TK to background levels.Removal of the large region containing the transcription factorbinding sites, in the presence or absence of the DUE, decreasedthe levels of nascent strands to background levels at all sequence-taggedsites, proximal and distal to the replicator.

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FIG. 4. Analysis of nascent DNA abundance by competitive PCR. (a) Representative polyacrylamide gels of competitive PCR products with nascent DNA from the indicated cell lines. The products of amplification of nascent DNA (N) and competitor DNA (C) are indicated. The copy number of competitor added to each reaction is indicated above each gel lane. (b) Relative abundance of nascent DNA at the sequence-tagged sites STS-Hyg, STS-pML, and STS-TK. The amounts of nascent DNA template were calculated as described in Materials and Methods. To allow comparison of the results from PCRs with different amounts of input nascent DNA, the primary data (panel a) from all reactions were normalized to an equivalent amount of input nascent DNA, based on slot blot hybridization. Solid bar, wild-type c-myc (406/pFRT.myc); shaded bar, 406/pFRT.myc. ${Delta}$ DUE; open bar, 406/pFRT.myc. ${Delta}$ 3' 1420; hatched bar, 406/pFRT.myc. ${Delta}$ DUE, ${Delta}$ 3' 1420; stippled bar, ${Delta}$ 1 (406/pFRT.myc. ${Delta}$ 1); segmented bar, ${Delta}$ 10 (406/pFRT.myc. ${Delta}$ 10). The positions of the sequence-tagged sites on a map of the origin integrants are indicated below.

These results raised the possibility that one or more transcriptionfactor binding sites in the 3' 1,420-bp region may contributeto origin activity. To assess the contribution of discrete subdomainswithin the c-myc origin to replicator activity, a set of 12mutants, pFRT.myc. ${Delta}$ 1-pFRT.myc. ${Delta}$ 12, was constructed with $~$ 200-bpdeletions spanning the c-myc origin core (Fig. 2). Each constructwas individually integrated into the same acceptor site in 406cells using FLP recombinase (Fig. 3d and e). For comparisonwith subsequent real-time PCR quantitation of origin activity,competitive PCR was used initially to measure the activity ofpFRT.myc. ${Delta}$ 1 ( ${Delta}$ 1) and pFRT.myc ${Delta}$ 10 ( ${Delta}$ 10) relative to that of the wild-typec-myc DNA in pFRT.myc. The DNA deletion in pFRT.myc ${Delta}$ 1 removedone match to the S. cerevisiae ACS and a site of putative bentDNA, while the deletion in pFRT.myc ${Delta}$ 10 removed the P₀ promoter(Fig. 5f). The data of Fig. 4b show that the pFRT.myc ${Delta}$ 1 deletionor the pFRT.myc ${Delta}$ 10 deletion reduced the abundance of nascentstrands at STS-pML by $~$ 70%. As in the case of the ${Delta}$ DUE and ${Delta}$ 3'1420 deletions, ${Delta}$ 1 and ${Delta}$ 10 showed a reproducible but lesser decreaseof nascent strand abundance in the flanking genome, with ${Delta}$ 1 reducingthe signals by $~$ 35% and $~$ 50%, respectively, at STS-Hyg and STS-TK,and ${Delta}$ 10 reducing these signals by $~$ 30 to 40%.

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FIG. 5. Origin activity of c-myc mutants at an ectopic chromosomal site. (a) Map of c-myc origin integrants showing sequence-tagged sites. (b to e) Q-PCR analysis of relative nascent DNA abundance at STS-Hyg (b), STS-TK (c), STS-pVU (d), and STS-pML (e). W, nascent strand abundance in cells containing wild-type c-myc DNA (pFRT.myc); 1 to 12, nascent strand abundance in cells containing mutant c-myc DNA (406/pFRT.myc. ${Delta}$ 1-406/pFRT.myc. ${Delta}$ 12). (f) Approximate location of structural features of the c-myc origin core DNA aligned with the positions of origin deletions ( ${Delta}$ 1 to ${Delta}$ 12) described in this study. Horizontal bars, predicted positions of bent and straight or flexible DNA (34). MNase hss, micrococcal nuclease hypersensitive sites; DNase hss, DNase hypersensitive sites (33, 34, 54). DUE, DNA unwinding element (7, 44). Triplex, region of predicted triple helix or non-B DNA formation. ACS, 10 of 11 matches to S. cerevisiae ARS consensus sequence. txn factor, matches to transcription factor consensus binding sites: p, PuF (49); m, c-Myb (65); n, NF1 (54); s, SP1 (14); a, AP-2 (26), e, E2F (24, 50); f, far upstream element binding protein (44). P₀ and P₁, c-myc promoters.

The dynamic range of Q-PCR is substantially greater than thatof competitive PCR (2, 38). Thus, Q-PCR was used to assess theabundance of nascent strands at STS-Hyg, STS-pVU, STS-pML, andSTS-TK in each of the 12 $~$ 200-bp c-myc DNA deletion mutants,including ${Delta}$ 1 and ${Delta}$ 10 (Fig. 5). The results for different DNA preparationswere normalized against the signal at STS-54.8 in the ß-globinlocus (chromosome 11). Normalizing the data from different deletionmutant cell lines against the nascent strand abundance at thelamin B2 locus (chromosome 19) did not change the relative signalsat the four acceptor site sequence-tagged sites. Thus, integrationof c-myc DNA at the anonymous acceptor site in 406 cells doesnot appear to affect replication at these distal locations.

In 406 cells containing the wild-type c-myc origin DNA (406/pFRT.myc),Q-PCR revealed a difference of $~$ 50-fold at STS-pVU or STS-pMLversus STS-Hyg or STS-TK (Fig. 5b to e), whereas this differencewas at most 8- to 15-fold using competitive PCR assays (Fig.4). This difference in sensitivity may be because Q-PCR quantitationoccurs at the earliest stages of amplification while competitivePCR is an end-stage assay, possibly more susceptible to spuriousamplification products. As with the competitive PCR analyses,the results of the deletions are seen most clearly at thosesites closest to the c-myc DNA, STS-pVU and STS-pML. The effectsof the deletions in the cell lines 406/pFRT.myc. ${Delta}$ 1 and 406/pFRT.myc. ${Delta}$ 10on nascent strand abundance are similar to, but greater than,those seen by competitive PCR. The relative abundances of nascentstrands at the pVU and pML sequence-tagged sites in each deletioncell line are aligned above the position of that deletion inFig. 5f.

Deletion of nucleotides 384 to 533 ( ${Delta}$ 3) or nucleotides 1932 to2133 ( ${Delta}$ 11) had little or no effect on origin activity, whereasnascent strand abundance was most significantly decreased in ${Delta}$ 1 and ${Delta}$ 4- ${Delta}$ 10 and intermediate decreases were observed with the ${Delta}$ 2 and ${Delta}$ 12 cell lines. These data are consistent with the resultsobtained with the ${Delta}$ DUE and ${Delta}$ 3' 1420 cell lines, where removalof the DUE or multiple transcription factor binding sites reducedorigin activity. While the greatest decreases correlate withthe loss of specific structures in DNA or chromatin, the DUE,and matches to the ACS, there is no simple correlation withthe absolute presence or absence of transcription factor bindingsites. For example, ${Delta}$ 1 decreased origin activity but removedno known transcription factor consensus binding sites, while ${Delta}$ 3 removed a consensus binding site for c-Myb but did not decreaseorigin activity.

Since it was possible that the reduction of nascent strand abundanceby deletions across the broad region defined by ${Delta}$ 4- ${Delta}$ 10 was dueto a requirement for a particular spacing between segments 384to 533 ( ${Delta}$ 3) and 1932 to 2133 ( ${Delta}$ 11) rather than the specific sequencesin this region, two additional substitution cell lines wereconstructed that precisely restored the spacing of ${Delta}$ 5, whichhad removed the DUE and ARS consensus sites. The DNA deletedin 406/pFRT.myc. ${Delta}$ 5 is 64% A+T; this DNA was replaced with eukaryoticsequences of either 64% G+C or 64% A+T (Fig. 6a to c). As shownin Fig. 6d, substitution of either sequence did not restorethe replicator activity of the c-myc origin fragment. Thesedata indicate that the germ line spacing of the region between ${Delta}$ 3 and ${Delta}$ 11 is not sufficient for origin activity and further thatthe sequence of the DUE or ACS region is more important fororigin activity than its base composition.

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FIG.6. Sequence dependence of DUE region origin activity. (a) Maps of unoccupied (left) and occupied (right) acceptor sites. (b) Integration was verified by PCR. Diagnostic PCR using DNA from 406 acceptor cells (A) and DNA from cells containing a 201-bp A+T-rich (Sub5AT) or G+C-rich (Sub5GC) substitution in place of the wild-type 201-bp DUE/ACS region in pFRT.myc at the acceptor site. Other notations are as in Fig. 1. (c) Integrant structure was verified by Southern hybridization with the Hyg or Neo probe to EcoRI-digested DNA from 406 acceptor cells (A), from 406 cells containing the wild-type c-myc origin fragment (406/pFRT.myc) (W), pFRT.myc.Sub5AT (Sub5AT), or pFRT.myc.Sub5GC(Sub5GC) at the acceptor site. (d) Relative nascent strand abundance at sequence-tagged sites STS-Hyg, STS-pVU, STS-pML, and STS-TK in 406 cells containing the wild-type c-myc origin fragment pFRT.myc (W), pFRT.myc.Sub5AT (AT), or pFRT.myc.Sub5GC (GC) at the acceptor site. (e) Helical stability calculations for the 201-bp DNAs corresponding to the wild-type c-myc DNA removed in deletion 5 ( ${Delta}$ 5, nucleotides 734 to 934), Sub5AT DNA, and Sub5GC DNA. Left panel, 100-bp window. Horizontal gray bar, 98 kcal/mole. Right panel, 20-bp window. See Materials and Methods for details.

In S. cerevisiae a free energy of unwinding of less than 98kcal/mole is associated with functional origins (45), and S.pombe ARSs meet this criterion as well, probably as a resultof their A+T richness (28). As shown in Fig. 6e (100-bp window),both the 201-bp wild-type DNA corresponding to sequences missingfrom ${Delta}$ 5 and the Sub5AT DNA meet this criterion, while the Sub5GCDNA does not. A more obvious difference between wild-type andSub5AT DNA is evident if the helical stability of 20-bp windowsis considered (Fig. 6e, 20-bp window), where a local minimumappears between nucleotide positions 60 to 70 in wild-type DNA.

DISCUSSION

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Discussion

A 2.4-kb core fragment of the c-myc origin displays plasmidautonomous replicating sequence activity and replicator activityat an ectopic chromosomal location, while a bacterial DNA fragmentdid not (40). Together with the present results and data fromothers (4, 40), these results refute the contention that anysimilarly sized eukaryotic or prokaryotic DNA fragment willfunction as a replication origin in a chromosomal context. Thenotion that replication is sequence independent derives primarilyfrom the replication of many DNAs in Xenopus oocyte extractsand of plasmids transfected into mammalian cells. In Xenopusoocyte extracts, origin-independent replication (23, 25, 39,61) may be due to an elevated concentration of replication factorsor the absence of a template chromatin structure restrictiveto origin function (21, 35, 64).

It has been reported that any prokaryotic or eukaryotic DNAsequence of sufficient length can initiate replication in plasmidsthat bind the viral EBNA-1 protein (32). The present data argueagainst concluding from this that specific DNA sequences arenot involved in chromosomal replicator activity. In mammaliancells as in yeast, plasmid replication may be more permissivethan chromosomal replication. Thus, the 5' 930-bp of the c-myccore origin display autonomous replicating sequence activity(43), but not chromosomal replicator function (this work). Moreover,the nuclear retention function ascribed to EBNA-1 binding maybe related to the attachment of cellular origin recognitioncomplex proteins and prereplicative complexes (15, 52) thatact in cis to potentiate the initiation of replication in DNAsequences sufficiently long to unwind under superhelical strainthat otherwise would not function as chromosomal replicatorsor origins.

The c-myc 2.4-kb core origin fragment stimulates replicationin cis. When integrated into the same acceptor site, the originfragment acted as a replicator while the Sub2.4 fragment didnot, although replication initiates within the Sub2.4 fragmentat its endogenous chromosomal location. The simplest interpretationof these results is that the core origin stimulates replicationin the flanking DNA when moved to the ectopic acceptor siteand in the neighboring Sub2.4 XhoI/EcoRV DNA at the endogenousc-myc locus. Recent experiments with Drosophila (5) and S. pombe(31) predict that ORC binding to specific regions of DNA isinvolved in metazoan replicator function. Hence, it is reasonableto speculate that one or more of the regions deleted in ${Delta}$ 1- ${Delta}$ 12acts to recruit ORC or other replication proteins (e.g., MCMs)to the neighboring Sub2.4 DNA (5, 19) at the c-myc locus. However,at this time it is not known whether ORC is bound to the wild-typeor ${Delta}$ 1 to ${Delta}$ 12 deletion mutants.

The replicators of S. cerevisiae are compact, while those ofS. pombe are broad (11, 28, 48) and contain multiple consensussequences, ORC binding sites, and transcription factor bindingsites. In the present work several mutations of the c-myc coreorigin decreased c-myc replication initiation, including deletionof the ACS or DUE sequences, transcription factor consensusbinding sites, potential triplex or non-B DNA structures, andDNA bound as positioned nucleosomes. Nonetheless, deletion analysisby itself does not reveal the positive role in replication ofthose elements whose removal decreased the activity of the c-mycreplicator.

Alterations in nucleosome positioning are correlated with changesin the binding of replication proteins and origin activity (37,55). At the endogenous c-myc locus and at ectopic locationsthe $~$ 1.4-kb zone defined by pFRT.myc. ${Delta}$ 4-pFRT.myc. ${Delta}$ 10 contains severalspecific MNase/DNaseI cleavages indicative of a nonrandom chromatinorganization. This chromatin structure is stable to transductionto ectopic chromosomal sites (33, 34). The present results showthat any of the deletions within this zone substantially reducedorigin activity. To test whether the particular spacing of sequencesin this zone is essential, the DUE fragment deleted in ${Delta}$ 5 wasreplaced with A+T-rich or G+C-rich DNA of the same length. Althoughthese substitutions restored the spacing of the core origin,they did not restore replicator activity, suggesting that atleast in the case of the DUE or ACS element specific sequencesor structures may be important for replicator activity. Proofthat the decrease of nascent strand abundance in the remainingdeletions is due to the loss of specific sequences will requireanalysis of additional substitution mutant cell lines.

Compared to the acceptor 406 cells or 406/pFRT.myc.Sub2.4 cells,integration of the wild-type c-myc origin core at the acceptorsite increased the abundance of 1- to 2-kb nascent strands atSTS-pVU and STS-pML, which are 3 kb apart, and at STS-Hyg andSTS-TK, which are more than 8 kb apart. Moreover, except forthe ${Delta}$ 2 and ${Delta}$ 3 cell lines, the effects of the remaining c-myc origindeletions on nascent strand abundance were qualitatively similarat all four sequence-tagged sites, although quantitatively greaterat the proximal STS-pVU and STS-pML than at the distal sequence-taggedsites. While it is formally possible that the nascent strandsdetected at the distal sites are 3- to 8-kb contaminants inthe 1- to 2-kb nascent fraction and therefore the same effectswill be seen at all four sequence-tagged sites, the resultsfrom ${Delta}$ 2 and ${Delta}$ 3 argue against this. The disparate effects of ${Delta}$ 2or ${Delta}$ 3 at the proximal versus distal sequence-tagged sites mayreflect different influences on individual initiation sites,albeit for unknown reasons. In control experiments (not shown),nascent DNA preparations were spiked with fluorescently labeledDNA of known size, prior to alkaline gel fractionation. Theseexperiments detected no cross-contamination between the 1- to2-kb and 3- to 8-kb fractions of DNA. Taken together, the resultsare consistent with previous observations that the c-myc replicatorpromotes initiation at multiple sites (40, 56, 58, 62). By contrast,for those S. pombe and human origins that have been examinedby replication initiation point mapping, a single site appearsto be preferred as the leading strand start in the locale ofthe replicator (1, 22, 31), with additional initiations in theflanking DNA revealed by two-dimensional electrophoresis (22).Therefore, it is possible that at the ectopic acceptor locusin 406 cells, the relative nascent strand abundance at STS-pVUor STS-pML versus that at STS-Hyg or STS-TK may reflect thedifference between the frequency of initiation at primary andflanking sites.

The ACS of S. cerevisiae origins is not functionally conservedin S. pombe, and a recent report showing that the function ofthe A+T-rich B2 element did not correlate with local helicalinstability (63) contests earlier results showing that originefficiency is related to the ease of origin unwinding (59).These data challenge the significance of the c-myc DUE regionas an unwinding element. Some form of DNA unwinding is an obligatorystep for initiation of replication, and the c-myc DUE regionexists in vivo in a non-base-paired conformation (44). Our experimentshave shown that replacing the easily unwound DUE with a sequenceof equivalent A+T content does not allow c-myc replicator function.At the same time, these results do not allow conclusions aboutthe role of an easily unwound region in the c-myc origin, sincethe Sub5AT replacement did not show the same local unwindingprofile as the wild-type DUE and because a potential proteinbinding site may have been eliminated by the substitutions.In this context it is of interest to note other work, in whichmembers of our group have used a yeast one-hybrid strategy toisolate a novel protein of the predicted molecular mass 24 kDa,which binds specifically to the DUE region in vivo and inhibitsreplication subsequent to the formation of prereplicative complexeson sperm chromatin in vitro in the Xenopus oocyte extract system(J. Casper, M. Ghosh, G. Randall, and M. Leffak, unpublisheddata). Experiments are under way to address the role of thec-myc DUE in replicator function by replacing it with othersequences of predicted low helical stability.

The pFRT.myc. ${Delta}$ 3' 1420 mutant removed several transcription factorbinding sites and eliminated origin activity, as did smallerdeletions of particular transcription factor consensus bindingsequences ( ${Delta}$ 4- ${Delta}$ 10), while deletion of other consensus bindingsites had a modest effect or no effect ( ${Delta}$ 2, ${Delta}$ 3, ${Delta}$ 12), raising thequestion of whether transcription factor binding sites contributeto origin activity. Possibly relevant to this question are experimentsby Ohba et al., who found that DNA replication from the c-myccore origin in vitro was stimulated by transcription (47). Experimentsare in progress to test the effect on replication of replacingthe c-myc transcription factor binding sites with heterologousprotein binding sites.

The human c-myc core origin shows incomplete similarity to theorigin of S. cerevisiae or S. pombe. While the c-myc origincontains a DUE, ARS consensus sequences, and transcription factorbinding sites, these elements occupy a broader region than thecompact origins of S. cerevisiae. Whereas the origins of S.pombe are broad and contain multiple asymmetric A+T-rich elementsthat contribute incrementally to plasmid ARS activity, severalessential elements of the c-myc origin do not contain asymmetricA+T sequences, and replacement of the A+T-rich DUE region withan equally A+T-rich DNA sequence did not restore c-myc chromosomalorigin activity. In summary, the present work shows that diverseDNA elements contribute to the activity of the human c-myc replicator.Although deletion of the DUE region and several transcriptionfactor consensus binding sites reduced nascent strand abundance,these experiments do not identify the roles of these elementsin replication initiation. Proof of how these elements contributeto replication will involve their replacement with other sequencesthat restore activity.

ACKNOWLEDGMENTS

Financial support from the National Institutes of Health (GM53819to M.L.) and the Wright State University School of Medicineis gratefully acknowledged.

We thank Yanlin Huang and David Kowalski (Department of CancerGenetics, Roswell Park Cancer Institute) for access to the WEBTHERMODYNprogram and Steven Berberich and John Turchi for their commentson the manuscript.

FOOTNOTES

* Corresponding author. Mailing address: Department of Biochemistry and Molecular Biology, Wright State University School of Medicine, Dayton, Ohio 45435. Phone: (937) 775-3125. Fax: (937) 775-3730. E-mail: michael.leffak{at}wright.edu.

REFERENCES

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