Hypoxia Blocks In Vivo Initiation of Simian Virus 40 Replication at a Stage Preceding Origin Unwinding

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Journal of Virology, March 1999, p. 2243-2252, Vol. 73, No. 3
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Hypoxia Blocks In Vivo Initiation of Simian Virus 40 Replication at a Stage Preceding Origin Unwinding

Hans-Jörg Riedinger,^* Maria van Betteraey, and Hans Probst

Physiologisch-chemisches Institut der Universität Tübingen, D-72076 Tübingen, Germany

Received 28 May 1998/Accepted 2 December 1998

	ABSTRACT

Top Abstract Introduction Materials and methods Results Discussion References

Simian virus 40 (SV40)-infected CV1 cells transiently exposed to hypoxia show a burst of viral replication immediately afterreoxygenation. DNA precursor incorporation and analysis of growingdaughter strands by alkaline sedimentation demonstrated that SV40DNA synthesis began with a lag of about 3 to 5 min after reoxygenationfollowed by a largely synchronous viral replication round. ViralRNA-DNA primers complementary to the SV40 origin region were notdetectable before 3 min upon reoxygenation. A distinct form ofcircular closed, supercoiled SV40 DNA was detectable as soon as3 min after reoxygenation but not under hypoxia. Sensitivity tothe DNA nuclease Bal 31 and migration behavior in chloroquine-containingagarose gels suggested that this DNA species was highly underwoundcompared to other SV40 topoisomers and was probably related tothe highly underwound form U DNA first described by Dean et al.(F. B. Dean, P. Bullock, Y. Murakami, C. R. Wobbe, L. Weissbach,and J. Hurwitz, Proc. Natl. Acad. Sci. USA 84:16-20, 1987), invitro. 3'-OH ends of presumed RNA-DNA primers could be detectedin form U by 3' end labeling with T7 polymerase. Addition of aphidicolinto the cells before reoxygenation led to a pronounced accumulationof form U DNA containing RNA-DNA primers. In vivo pulse-chasekinetic studies performed with aphidicolin-treated SV40-infectedcells showed that form U is an initial intermediate of SV40 DNAreplication which matures into higher-molecular-weight replicationintermediates and into SV40 form I DNA after removal of the inhibitor.These results suggest that in vivo initiation of SV40 replicationis arrested by hypoxia before origin unwinding and primersynthesis.

	INTRODUCTION

Top Abstract Introduction Materials and methods Results Discussion References

Reversible suppression of cellular replicon initiation in hypoxic mammalian cells seems to be a general mechanism adaptingthe intensity of DNA replication to the supply of O₂ (and othernutrients) in the cellular environment (49, 50, 52, 54).The potential importance of this regulatory phenomenon in embryonicgrowth, tumor cell propagation, and wound healing has been mentionedpreviously (27, 28, 50, 52). A prominent feature of theO₂-dependent regulation of replication is the short time spanbetween reelevation of the pO₂ to 20% (reoxygenation) and theemergence of a burst of new replicon initiations. This suggeststhat a signal depending on the actual pO₂ exerts relatively directcontrol over a crucial step of replicon initiation. Examinationof the molecular events leading from reoxygenation to repliconinitiation in the mammalian cellular genome is, however, impededby the great diversity of mammalian replicons, their poorly characterizedorigins, and a poor knowledge of the proteins involved in cellularinitiation of DNAreplication.

As we have shown previously (21), simian virus 40 (SV40) replication in virus-infected CV1 cells is also subjected to O₂-dependentregulation of replicon initiation. Reduction of the pO₂ to 0.02to 0.2% in the culture medium results in reversible suppressionof viral DNA replication. Reoxygenation after several hours ofhypoxia triggers, within a few minutes, a burst of initiationsfollowed by a nearly synchronous round of viral replication beginningat the viral origin of replication (21).

The initiation of SV40 DNA replication has been relatively well investigated, rendering this virus a useful model system toexamine the reversible shutdown of replicon initiation byhypoxia.

Initiation of SV40 DNA replication requires the binding of a double hexamer of SV40 large T antigen to the viral origin inthe presence of ATP, leading to structural distortions of theorigin region (2, 3, 14, 15, 17, 41, 48; for arecent review about initiation of SV40 DNA, replication see reference6). After binding of replication protein A (RPA), further localunwinding by the helicase activity of T antigen occurs (4,33). The T antigen-RPA complex then binds polymerase $alpha$ -primase,which synthesizes RNA-DNA primers at the unwound template (13,20, 26). Succeeding processive elongation of RNA-DNA primersinvolves replication factor C, proliferating-cell nuclear antigen,and DNA polymerase $delta$ (60, 61).

In principle, each of the mentioned steps could be prevented under hypoxia. However, comparing the time needed to constituteactive initiation in SV40 replication systems in vitro (10 to15 min) (59, 62, 64-66) with the time needed to activate theprocessive state of replication after reoxygenation ( $<=$ 5 min) (21)suggests that part of the preinitiation and initiation processhas already occurred underhypoxia.

In the present communication, we show that initiation of viral DNA replication under hypoxia is interrupted before unwindingof the origin region. We demonstrate the emergence of an earlyreplicative form of SV40 DNA in vivo about 3 min after reoxygenationof host cells. We show that this replication intermediate is highlynegatively supercoiled and probably related to the unwound formU SV40 DNA species that has been demonstrated by Dean et al. (16)to be formed in the course of SV40 initiation of replication invitro. We further demonstrate that form U probably contains RNA-DNAprimers in vivo and that it matures into SV40 Cairns intermediatesand SV40 form IDNA.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and methods Results Discussion References

Transient hypoxia, reoxygenation, and radioactive labeling. Monkey CV1 cells (ATCC CCL70) were infected with SV40 as described previously (58). Transient hypoxia was started 24 h laterby gassing with 0.02% O₂-5% CO₂-Ar to 100% for 10 h (21). Forreoxygenation, 0.25 volume of medium equilibrated with 95% O₂-5%CO₂ was added and gassing was continued with artificial air (21).For radioactive labeling, [methyl-³H]deoxythymidine was added to the cells either directly or, forhypoxic labeling, by plunging a spatula carrying the appropriatequantity of [methyl-³H]deoxythymidine in dried form into the culture medium withoutinterruption of thehypoxia.

Aphidicolin, dissolved in dimethyl sulfoxide, was applicated to hypoxic cell cultures on a spatula after gassing within thehypoxic chamber for 15 min. The cells were reoxygenated 10 minafter application of the inhibitor. To stop incubations, the culturesupernatant was removed by aspiration and cells were washed oncewith ice-cold phosphate-buffered saline (150 mM NaCl, 10 mM NaHPO₄[pH 7.0]). Determination of incorporated radioactivity was describedpreviously (53).

Alkaline sedimentation analysis of labeled SV40 DNA. SV40-infected cells were pulse-labeled for 6 min before or after reoxygenation with 20 µCi of [methyl-³H]deoxythymidine. After being washed, the cells were lysed in0.25 M NaOH for 1 h and layered onto a 5 to 40% linear sucrosegradient in 0.25 M NaOH-0.6 M NaCl-1 mM EDTA-0.1% sodium lauroylsarcosinate.After centrifugation in a Beckman SW40 rotor at 36,000 rpm at23°C for 16 h, 0.6-ml fractions were collected from the top ofthe gradient and analyzed for acid-insoluble radioactivity (53).

Isolation of RNA-DNA primers and correlation with the SV40 genome. For separation of RNA-DNA primers from cellular and viral bulk DNA, an improved version of a hydroxyapatite thermochromatographymethod was used, as described previously (53), to separate short-chainreplication intermediates from bulk DNA in Ehrlich ascites cells.The procedure consists of two main steps: (i) preparation of acrude cell lysate under conditions partially destabilizing theDNA double helix in order to melt out all single chains shorterthan about 200 nucleotides, and (ii) elimination of all double-strandedDNA from the lysate by passage through a hydroxyapatite column.The details are as follows. Four SV40-infected cell cultures werecultivated hypoxically for 10 h. One of the cultivations was stoppedbefore reoxygenation. The others were reoxygenated and the reactionswere stopped 3, 5, or 10 min after reoxygenation. Labeling with[methyl-³H]deoxythymidine (50 µCi/ml) was performed as described in thelegend of Fig. 2. The cells were lysed for 5 min in 4 M guanidiniumthiocyanate-0.12 M guanidinium phosphate (pH 6)-0.2% sodium lauroylsarcosinate-1mM EDTA (1 ml), and DNA was sheared by 10 passages through a 26-gaugeinjection needle. The lysate was prewarmed to 37°C for 10 minand loaded onto a hydroxyapatite column (10 by 45 mm) that hadbeen equilibrated with 4 M guanidinium thiocyanate-0.12 M guanidiniumphosphate (pH 6) and prewarmed to 37°C. The flowthrough and theeluates obtained after washing the column twice with 0.5 ml of4 M guanidinium thiocyanate-0.12 M guanidinium phosphate at 37°Cwere combined and dialyzed overnight against 10 mM NaCl-0.1 mMTris-0.01 mM EDTA-0.2% sodium lauroylsarcosinate (pH 7.5).

The dialysate was subsequently hybridized against membrane-fixed, single-stranded M13mp18 DNA containing segments of the SV40genome (see Fig. 2A) cloned in either direction into the plasmidSmaI site by standard procedures (57). For fixation of the single-strandedSV40 probes onto a nylon membrane, 400 ng of DNA was dissolvedin 200 µl of SSC (0.3 M NaCl, 0.03 M sodium citrate [pH 7.0]),heated to 65°C for 10 min, and chilled on ice. The DNA was thentransferred to the membrane (2 cm in diameter), dried at 37°C,and fixed by UV irradiation. Hybridization was performed at 37°Cas described previously (19). After hybridization, the radioactivitybound to each of 14 probes was quantified and normalized for thesize of the respective SV40segment.

DNA isolation, chloroquine gel electrophoresis, Southern blotting, and hybridization. Washed cells were lysed and digested (0.25 M EDTA [pH 8.0], 1% sodium lauroylsarcosinate, 100 µg of proteinase K per ml) for3 h at 55°C. The lysate was extracted twice with phenol-CHCl₃and dialyzed against 0.1× Tris-EDTA (TE; pH 8.0) at 4°C overnight.After digestion with RNase A (100 µg/ml at 37°C for 1 h), 100ng of isolated DNA per slot was loaded onto a 25- by 20-cm agarosegel containing 70 µg of chloroquine per ml of gel buffer (30 mMNaH₂PO₄, 36 mM Tris, 1 mM EDTA). Electrophoresis was carried outat 2 V/cm and 4°C for 20 h. Southern blotting was performed subsequentlyunder alkaline conditions as described previously (57). ³²P labeling of BamHI-linearized SV40 DNA was performed with theBoehringer random-primed DNA-labeling kit (Boehringer, Mannheim,Germany). Hybridization was performed as described previously(19).

Distribution of SV40 DNA labeled in vivo by [methyl-³H]deoxythymidine and separated by chloroquine electrophoresis was determinedby cutting single lanes of the gel into 0.8-cm slices, which weredissolved in 0.5 M HCl (1 ml) by heating to 80°C for 2 h and countedafter addition of 10 ml of Ultima gold scintillator (AmershamBuchler, Braunschweig,Germany).

Isolation of SV40 topoisomers, Bal 31 digestion, and chloroquine gradient gel-electrophoresis. Whole-cell DNA of SV40-infected CV1 cells was isolated 5 min after reoxygenation and electrophoresed on a preparative low-melting-pointagarose gel (NuSieve GTG agarose; Biozym, Hessisch Oldendorf,Germany) containing 70 µg of chloroquine/ml as described above.For localization of SV40 topoisomers, one lane of the gel wasSouthern blotted and hybridized against ³²P-labeled SV40 DNA. DNA from bands representing separated topoisomerswas then prepared from the rest of the gel as described previously(57). For preparation of relaxed closed circular double-strandedSV40 DNA, virus-infected cells were grown euoxically in the presenceof camptothecin (10 µM) for 30 min. After separation of whole-cellDNA on a chloroquine-containing low-melting-point agarose gel(70 µg/ml), the additional fast-migrating band which turned outto be relaxed closed circular SV40 DNA was isolated as describedabove. Digestion with nuclease Bal 31 was performed at 30°C for30 min as described previously (57).

For evaluation of negative supercoiling, SV40 topoisomers were separated on gradient gels prepared by successively gelling11 agarose lanes containing increasing chloroquine concentrationsbetween two glass plates (11 by 14 cm). The conditions of electrophoresiswere the same as described above, but the buffer contained nochloroquine and the running time was only 4 h. Topoisomers weredetected by Southern blotting and hybridization against ³²P-labeled SV40 DNA as describedabove.

Labeling of 3'-OH ends in replicative SV40 DNA molecules. Washed CV1 cells were lysed and digested (0.25 M EDTA [pH 8.0], 1% sodium lauroylsarcosinate, 100 µg of proteinase K/ml) for3 h at 37°C. The lysate (200 µl) was extracted twice with phenol-CHCl₃and loaded onto a 15 to 30% linear neutral sucrose gradient (10mM Tris [pH 7.5], 1 mM EDTA, 200 mM NaCl, 15 to 30% sucrose).After centrifugation in a Beckman SW60 rotor for 15 h at 30,000rpm and 4°C, 0.5-ml fractions were taken and aliquots of 20 µlwere analyzed for SV40 DNA on an agarose gel. Positive fractionswere pooled, and DNA was sedimented by centrifugation for 4 hin a Beckman TLA 100.2 rotor at 100,000 rpm and 4°C. After therun, the supernatant was rapidly removed by aspiration and theSV40 DNA was dissolved in 10 µl of TE (pH 7.5) containing 50 mMNaCl.

To label the 3'-OH ends of base-paired DNA chains, 50 to 250 ng of the dissolved SV40 DNA was elongated with Sequenase version2.0 (3 U) (United States Biochemicals, Braunschweig, Germany)in the presence of dCTP, dGTP, and dTTP (300 nM each) and [ $alpha$ -³²P]ddATP (10 µCi, 3,000 Ci/mmol) in 7.5 mM dithiothreitol-30 mMNaCl-30 mM Tris (pH 7.5)-15 mM MgCl₂ in a volume of 10 µl for10 min at room temperature and another 5 min at 37°C.

After being end labeled, the DNA was analyzed by separation on chloroquine-containing gels, capillary blotting to a nylonmembrane, and direct autoradiography. For determination of thesize of labeled single strands, the end-labeling mixture was broughtto 50% (vol/vol) formamide, 2.5 mM EDTA, and 0.05% (wt/vol) bromophenolblue and DNA was denatured by heating to 80°C for 10 min. TheDNA was then separated at 600 V for 3 h on a 20% polyacrylamide-Tris-borate-EDTA(TBE) gel containing 6 M urea. After the run, the gel was directlyautoradiographed.

	RESULTS

Top Abstract Introduction Materials and methods Results Discussion References

DNA replication begins after a short lag upon reoxygenation. As we have shown previously (21), initiation of SV40 DNA replication very closely succeeds reoxygenation of hypoxicallycultivated virus-infected CV1 cells. Incorporation of [methyl-³H]deoxythymidine added shortly before reoxygenation into viralDNA first started 2 to 3 min after reoxygenation (curve not shown).A similar lag between reoxygenation and the onset of DNA replicationwas observed in Ehrlich ascites cells (54). To examine the chainlengths of the DNA synthesized after reoxygenation, SV40-infectedcells were labeled with [methyl-³H]deoxythymidine by 6-min pulses staggered around the time ofreoxygenation. The labeled DNA was then analyzed for size by alkalinesucrose gradient centrifugation. Previous experiments (resultsnot shown) revealed that more than 90% of the acid-precipitableradioactivity was incorporated into viral DNA. Therefore, we generallydid not prepare Hirt supernatants, in which different but generallylarge portions of replicative viral DNA arelost.

Significant incorporation of [methyl-³H]deoxythymidine into newly initiated growing chains (fractions 4 to 9) occurred notearlier than 3 min after reoxygenation but did not occur underhypoxia (Fig. 1A). Some radioactivity was recovered as nearlyfull-length SV40 DNA (fractions 10 and 11) when the labeling by[methyl-³H]deoxythymidine included the first 2 min after reoxygenation.This radioactivity probably represented DNA molecules engagedin replication when the preceding hypoxia became effective (21).At 3 to 5 min after reoxygenation, a nearly synchronous roundof viral replication started, indicated by the increasing shiftof labeled molecules to higher S values with increasing time (Fig.1B). Covalently closed SV40 DNA, accumulating in the bottom fractionsof the gradients, was first detected when the end of the labelingperiod was shifted to 16 min after reoxygenation.

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FIG. 1. Alkaline sucrose gradient centrifugation of viral DNA from hypoxically cultivated and reoxygenated SV40-infected CV1 cells. Cells were cultivated hypoxically for 10 h and incubated with [methyl-³H]deoxythymidine (20 µCi/ml) either before or after reoxygenation between the points of time indicated (0 = time of reoxygenation). (A)

, $-$ 6 to 0 min (hypoxic); $open circle$ , $-$ 4 to +2 min; $triangle$ , $-$ 3 to +3 min; (B)

, $-$ 1 to +5 min; $open circle$ , +2 to +8 min; $triangle$ , +10 to +16 min; $down-triangle$ , +20 to +26 min. Sedimentation was from left to right. Supercoiled viral DNA is collected in the bottom fractions (fractions 17 to 19).

Synthesis of RNA-DNA primers is not detectable under hypoxia. The very first nucleic acid polymerized after completion of the preinitiation phase consists of short RNA-DNA primers formedby polymerase $alpha$ -primase (6, 13, 20, 26). Subsequent processiveprimer elongation requires loading of replication factor C andproliferating-cell nuclear antigen and switching to polymerase $delta$ (6, 46, 60, 61). We asked whether hypoxia preventedeither primer formation or switching to processive DNA synthesis.In the first case, primers would first emerge after reoxygenation;in the second, primers would accumulate under hypoxia. To distinguishbetween the possibilities, [methyl-³H]deoxythymidine was added to SV40-infected CV1 cells concurrentlywith the start of hypoxic gassing or shortly before or after reoxygenation.Primer-sized DNA (i.e., DNA smaller than 200 bp melted out fromhydroxyapatite-bound bulk DNA in the form of small, single-strandedchains, as described in Materials and Methods) was isolated fromhypoxic or reoxygenated cell cultures and hybridized to a setof membrane-fixed single-stranded SV40 probes. As shown in Fig.2A, this set covers the complete SV40 genome and differentiatesbetween the respective complementary strands. Primer-sized labeledDNA isolated from hypoxic cells and from cells whose reactionwas stopped 3 min after reoxygenation carried minimal radioactivity,which was bound more or less uniformly to all probes in the set(Fig. 2B to D).

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FIG. 2. Hybridization of RNA-DNA primers, labeled with [methyl-³H]deoxythymidine in vivo, to a set of membrane-fixed single-stranded, SV40-specific probes. Preparation of the RNA-DNA primers fraction from hypoxic or reoxygenated SV40 infected cells was performed as described in Materials and Methods. Designations and labeling schedules of analyzed samples: hypox, [methyl-³H]deoxythymidine (50 µCi/ml) was added at the start of hypoxia and incubation was stopped after 10 h; reox3, reox5, [methyl-³H]deoxythymidine (50 µCi/ml) was added after 9.5 h of hypoxic incubation to the cells, and incubation was continued for 30 min, and the cells were then reoxygenated and incubated with artificial air for 3 or 5 min; reox10, cells were reoxygenated after 10 h of hypoxia and labeled 2 min later with [methyl-³H]deoxythymidine (50 µCi/ml) for 8 min. (A) Cleavage sites of restriction enzymes used to generate a set of SV40-specific single-stranded DNA probes. Restriction fragments 1 and 1a harbor the origin of replication. The other fragments are either situated rightward (2r, 3r, and 4r) or leftward (2l, 3l) with respect to the viral origin. After subcloning, each restriction fragment yields two complementary single-stranded probes which recognize either sense sequences (probes marked by <) or antisense sequences (probes marked by >) of late viral mRNAs. (B) Sum of radioactivity hybridized to the respective < and > probes. (C) Radioactivity hybridized to the < probes alone. (D). Radioactivity hybridized to the > probes alone.

RNA-DNA primers isolated from cells labeled until 5 min after reoxygenation preferentially hybridized to probes containingthe viral origin (Fig. 2, probes 1 and 1a). When the incubationlasted until 10 min after reoxygenation, a large amount of RNA-DNAprimers was still bound to probes 1 and 1a but also to probescontaining SV40 regions more distant from the viral origin (probes2r, 2l, 3r, and 3l). The primer fractions isolated from the cellslabeled until 10 min after reoxygenation exhibited the expectedleading- versus lagging-strand differences of binding to the differentprobes of the set (Fig. 2C andD).

Primer-sized labeled DNA isolated from uninfected CV1 cells was not bound at all to the SV40 probes (data notshown).

The results presented show that primer synthesis is not detectable before 3 min after reoxygenation. This indicates that initiationof SV40 replication in hypoxic cells is not interrupted at primerelongation but rather at primer synthesis or at a preceding initiationstep (e.g., assembly of initiation proteins at the SV40 originor unwinding of the originregion).

A highly underwound SV40 DNA species appears within 3 min after reoxygenation. Since RNA-DNA primers were not detectable before or shortly after reoxygenation, we next examined how origin unwinding wasinfluenced by hypoxia and reoxygenation. As shown for SV40 origin-containingplasmids in vitro (7, 16, 66), unwinding generates topologicalDNA isomers which, after deproteinization, are detectable in chloroquine-containingagarose gels due to their enhanced degree of negative supercoilingcompared to the nonreplicative SV40topoisomers.

Whole-cell DNA of hypoxic or reoxygenated SV40-infected cells whose incubation was stopped at different times after reapplicationof O₂ was isolated and electrophoresed on a chloroquine-containingagarose gel. After Southern blotting, the DNA was hybridized toa ³²P-labeled SV40 probe. An additional, fast-migrating SV40 topoisomer(termed form U in the nomenclature of 16) was detectable between3 and 8 min after reoxygenation (Fig. 3). Form U was not detectableunder hypoxia or beyond 8 min after reoxygenation (Fig. 3). Furtherexperiments (results not shown) revealed that form U DNA did notemerge before 2 min after reoxygenation. Addition of camptothecin(10 µM) to the cells just before reoxygenation suppressed theappearance of form U, suggesting that topoisomerase I is involvedin its formation (data not shown). Cairns intermediates, runningthrough a nearly synchronous round of replication, were detectableafter 5 to 6 min of reoxygenation as an increasingly slower-migratingband emerging out of the bulk of nonreplicative topoisomers. After20 to 30 min, late Cairns intermediates with a defined low electrophoreticmobility developed. The fact that form U disappeared as increasinglylater replication intermediates began to dominate further indicatedits significance as an initial intermediate of SV40 replication.

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FIG. 3. Demonstration of form U after reoxygenation. SV40 DNA was isolated from hypoxically cultivated and reoxygenated CV1 cells and separated on a chloroquine-containing agarose gel. After Southern blotting, the DNA was hybridized against ³²P-labeled linear SV40 DNA. Lanes: H, 10-h hypoxic; 3' to 30'; reoxygenated (times, in minutes, after reoxygenation are indicated). LC, late Cairns SV40 DNA; IC, intermediate Cairns SV40 DNA; T, topoisomers of mature SV40 DNA (form I); U, form U.

To demonstrate that form U is indeed a full-length, highly negatively supercoiled SV40 topoisomer, it was isolated from apreparative chloroquine-containing agarose gel. Portions (0.1to 0.2 ng) of form U DNA were digested with BamHI or BglI or withincreasing amounts of single-strand-specific nuclease Bal 31 andelectrophoresed on minigels. SV40 DNA was detected in the gelblots by hybridization as described above. Digestion with restrictionnucleases revealed that form U represents a full-length supercoiledSV40 topoisomer (Fig. 4A). Compared to another supercoiled SV40topoisomer (Fig. 4B) (the same topoisomer as analyzed in Fig.5D), form U was found to be 10 to 100 times more sensitive todigestion with Bal 31. This result suggests that form U exhibitsextensive single-strand-like character, as expected for highlynegatively supercoiled DNA. Moreover, cleavage of form U by Bal31 led directly to the linear form III SV40 DNA, and only a minoramount of circular nicked (form II) DNA was detectable. As describedpreviously (29, 38), this digestion pattern points to thepresence of a cruciform structure in form U, which is preferablycut in the loops by Bal 31, leading to linear SV40 DNA. This cruciformstructure may be extruded from the SV40 origin inverted repeatin case of high negative superhelical tension (38).

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FIG. 4. Digestion of form U (A) and a supercoiled SV40 DNA topoisomer (B) with endonucleases BglI and BamHI and sensitivity against the single-strand-specific DNase Bal 31. A total of 0.1 (BglI and BamHI) or 0.2 ng (Bal 31) of each topoisomer was digested. NC, nicked circular DNA; L, linear DNA; SC, supercoiled DNA; U, form U (also indicated by an arrowhead).

The negative supercoil densities of form U and selected bulk SV40 DNA topoisomers were also compared by determination of themigration behavior in agarose gels containing increasing amountsof chloroquine in neighboring lanes (Fig. 5).

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FIG. 5. Migration pattern of distinct SV40 topoisomers in chloroquine (Chq) gradient gel electrophoresis. Gradient gels consist of 11 layers of different chloroquine concentrations as indicated at the top of the photographs. Different topoisomers at 0.1 to 1 ng were loaded. NC, nicked circular DNA; OC, relaxed closed circular DNA; SC, supercoiled DNA; U, form U. (A) Relaxed, closed circular SV40 DNA; (B to E) SV40 DNA topoisomers with increasing preexisting negative superhelical tension; (F) form U.

Depending on the preexisting negative superhelical tension, the minima of electrophoretic mobility, indicating the point wherethe DNA circle is relaxed, were reached at different chloroquineconcentrations for each topoisomer (Fig. 5A to E). Note the differentmigration pattern of relaxed closed circular and relaxed nickedcircular SV40 DNA in Fig. 5A: upon intercalation, chloroquineintroduces positive supercoils in closed but not in nicked circles,causing increased versus decreased mobility, respectively, withrising chloroquineconcentrations.

The minimum electrophoretic mobility was not reached for form U at chloroquine concentrations up to 100 µg/ml (Fig. 5F), againconfirming a very high degree of preexisting negative supercoilingfor this SV40 topoisomer. Increasing the chloroquine concentrationto 300 µg/ml caused a significant reduction of form U mobility(data not shown); it was also found that form U migrated as asmear instead of a sharp band at this concentration, indicatingthat form U probably consists of many SV40 topoisomers with differentelevated degrees of negative supercoiling. The electrophoreticseparation was, however, poor at this and higher chloroquineconcentrations.

Aphidicolin induces the accumulation of form U. Aphidicolin, an inhibitor of polymerases $alpha$ and $delta$ , inhibits primer processing (47) and probably uncouples helicase and replicativepolymerase activities (22). When aphidicolin (2 µg/ml) was addedto hypoxic cells 10 min before reoxygenation, accumulation ofform U was detectable 4 and 7 min after reoxygenation (Fig. 6).Cairns intermediates were not observed in aphidicolin-treatedcells. These results again suggest that form U is a precursorof replicative SV40 DNA forms.

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FIG. 6. Accumulation of SV40 form U in reoxygenated cells treated with aphidicolin. Aphidicolin (2 µg/ml) was added to SV40-infected CV1 cells 10 min before reoxygenation. SV40 DNA was isolated, separated on a chloroquine-containing gel, Southern blotted, and hybridized as described in Materials and Methods. Lanes: 1, control, 4-min reoxygenated; 2, plus aphidicolin, 4-min reoxygenated; 3, control, 7-min reoxygenated; 4, plus aphidicolin, 7-min reoxygenated. LC, late Cairns SV40 DNA; IC, intermediate Cairns SV40 DNA; T, topoisomers of mature SV40 DNA (form I); U, form U.

Form U probably contains RNA-DNA primers. In a previous publication (47), Nethanel et al. showed that aphidicolin inhibits primer processing but not primer synthesisin isolated nuclei of SV40-infected cells. We therefore investigatedwhether RNA-DNA primers were also detectable in SV40 DNA of cellstreated with aphidicolin beforereoxygenation.

SV40 DNA was separated from the remainder of the DNA by neutral sucrose gradient centrifugation, and 3'-OH ends of base-pairedchains were labeled and elongated by a few nucleotides with T7-DNApolymerase (Sequenase), [ $alpha$ -³²P]-ddATP, dCTP, dGTP, and dTTP. Labeled DNA was subsequently separatedon a chloroquine-containing agarose gel, transferred to a nylonmembrane by capillary blotting, and autoradiographed. In untreatedcells (Fig. 7, lanes 1 to 3), form U was slightly labeled. Cairnsintermediates, again detectable as an increasingly slower migratingband, were more strongly labeled. As expected, essentially noradioactivity was found in the range of the nonreplicating SV40DNA topoisomers. Addition of aphidicolin (lanes 4 to 6) led tostrong labeling of form U, whereas essentially no radioactivitywas found in the range of the Cairns intermediates. Longer incubationtimes in the presence of the inhibitor resulted in a downwardbroadening of the form U signal. When aphidicolin was washed out6 min after reoxygenation (lanes 7 and 8), the label in the formU region disappeared and moved to the early Cairns intermediateregion. Again, the range of the bulk topoisomers remained essentiallyfree of radioactivity. The end-labeled DNA chains were also analyzedon a 20% polyacrylamide gel containing 6 M urea. In SV40 DNA isolatedfrom aphidicolin-treated cells, end-labeled chains in the rangeof 25 and about 50 nucleotides (nt) were found (Fig. 8). Whenend-labeled DNA was treated with NaOH (0.3 M) at 60°C for 40 minprior to electrophoresis, a size reduction of primer-sized DNAwas observed, suggesting that the end-labeled strands containedRNA synthesized by primase (initiator RNA [iRNA]) (Fig. 8). The3'-end-labeled DNA isolated from control cells 4 min after reoxygenationwas found to be up to 200 nt. Again, NaOH treatment led to sizereduction (data not shown). As expected, no shortening was seenwhen the isolated 67-bp band of the molecular weight marker wastreated with NaOH (data not shown).

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FIG. 7. Analysis of 3'-OH end-labeled SV40 DNA isolated from untreated and aphidicolin-treated CV1 cells. SV40-infected CV1 cells were reoxygenated in the absence (lanes 1 to 3) or presence (lanes 4 to 8) of aphidicolin (2 µg/ml). After reoxygenation, the cells were incubated for the indicated times or aphidicolin was washed out after 6 min (lanes 7 and 8). SV40 DNA was separated from cellular DNA and 3'-OH end labeled with [ $alpha$ -³²P]ddATP as described in Materials and Methods. End-labeled DNA was separated on a chloroquine-containing gel, capillary blotted, and autoradiographed. Lanes: 1, control, 4-min reoxygenated; 2, control, 7-min reoxygenated; 3: control, 16-min reoxygenated; 4 to 6, as lanes 1 to 3, with aphidicolin; 7, aphidicolin removed 6 min after reoxygenation, incubated for a further 2 min; 8, aphidicolin removed 6 min after reoxygenation, incubated for a further 6 min. LC, late Cairns SV40 DNA; IC, intermediate Cairns SV40 DNA; T, topoisomers of mature SV40 DNA (form I); U, form U.

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FIG. 8. Demonstration of RNA-DNA primers in SV40 DNA isolated from aphidicolin-treated CV1 cells. SV40 DNA from cells reoxygenated for 11 min in the presence of aphidicolin (2 µg/ml) was isolated and 3'-end labeled as described in Materials and Methods. The DNA was then separated on a 20% polyacrylamide-6 M urea gel. DNA from lane 2 was incubated with 0.3 M NaOH at 60°C for 40 min to hydrolyze iRNA before electrophoresis. M, 5'-end-labeled marker DNA (DNA molecular weight marker VIII [Boehringer]).

Form U matures into Cairns intermediates and full-length SV40 topoisomers. The disappearance of form U and the concomitant appearance of early Cairns intermediates after removal of aphidicolin, asshown in Fig. 8, is a strong hint that form U is a precursor ofreplicative SV40 DNA species. This was further confirmed by chasekinetics of a ³H label incorporated into form U in vivo. SV40-infected cellswere treated with aphidicolin (2 µg/ml) and [methyl-³H]deoxythymidine (80 µCi/ml) 10 min before reoxygenation. At 6min after reoxygenation, the medium was replaced by chase mediumcontaining 10 µM nonlabeled deoxythymidine and no aphidicolin,and incubation was continued for various times. DNA was isolatedand separated on a chloroquine-containing gel. After the run,the gel was cut into slices, which where analyzed for radioactivity.Figure 9A shows that 1 min after replacement of the aphidicolin-[methyl-³H]deoxythymidine-containing medium by the chase medium, most ofthe label was found at the position of form U, which was localizedby Southern blotting and hybridization of a separate lane of thegel. With increasing times, the label of form U was chased intoCairns intermediate DNA and finally into the mature topoisomersof SV40 DNA (Fig. 9B).

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FIG. 9. Chase kinetics of a radioactive label incorporated into SV40 form U in vivo. [methyl-³H]deoxythymidine (70 µCi/ml) and aphidicolin (2 µg/ml) were added to SV40-infected cells 10 min before reoxygenation. At 6 min after reoxygenation, the medium was replaced by chase medium containing 10 µM deoxythymidine and incubation was continued for the indicated times. SV40 DNA was isolated and separated on a chloroquine-containing gel. After electrophoresis, the gel was cut into slices, which were analyzed for containing ³H radioactivity. (A) Distribution of the ³H label after a chase of 1, 2, or 4 min. (B) Distribution of the ³H label after a chase of 6, 10, or 25 min. LC, late Cairns SV40 DNA; IC, intermediate Cairns SV40 DNA; T, topoisomers of mature SV40 DNA (form I); U, form U.

	DISCUSSION

Top Abstract Introduction Materials and methods Results Discussion References

The cellular replicons of Ehrlich ascites cells and the viral replicons in SV40-infected cells exhibit distinct analogieswith respect to their behavior in transient-hypoxia experiments.Like cellular replicons, SV40 replicons accumulate under hypoxiain a state ready to begin DNA synthesis immediately after reoxygenation(21). The present study was intended to elucidate, by meansof the SV40 model, some mechanistic aspects of these remarkablyfast responses. In particular, we investigated the state in whichreplicon initiation is blocked under hypoxia, ready to be reactivatedimmediately after O₂recovery.

The results presented suggest that hypoxia blocks initiation at a stage preceding origin unwinding and primer synthesis. Unwindingwas demonstrated by the appearance of a highly underwound SV40DNA species, termed form U (16), in chloroquine-containing agarosegels. Form U was detected between 3 and 8 min after reoxygenationbut was not detected under hypoxia (Fig. 3). Comparison of theelectrophoretic mobility of form U with that of other SV40 topoisomersin special agarose gels containing different chloroquine concentrationin neighboring lanes (Fig. 5) indicated that form U is highlyunderwound. This agrees with the in vitro results of Bullock etal. (7) and Dean et al. (16).

In vitro, origin unwinding was shown to depend on SV40 T antigen, RPA, a topoisomerase, and ATP (16, 33). Upon bindingof T antigen to the viral origin, local distortion occurs, resultingin one to five additional negative superhelical turns (55).Such small changes in overall superhelical density are, however,difficult to detect in vivo, since they will be masked by thenaturally occurring variations of negative supercoiling in thelarge excess of nonreplicative bulk SV40 DNA present (Fig. 3).It therefore remains uncertain whether this minor initial distortionoccurs before or afterreoxygenation.

Additional unwinding generates form U, which is detectable in chloroquine-containing gels (7, 16). In an in vitro replicationassay mixture containing T antigen, HeLa cytoplasmic extract,ATP, and an ATP-regenerating system, form U was detected 5 to10 min after mixing of the components (7). DNA synthesis wasdetectable not earlier than 15 min after the start of incubation.These results suggest that unwinding is not necessarily followedby an immediate start of DNA synthesis. In our in vivo experiments,form U appeared 3 min after reoxygenation (Fig. 3). This relativelyshort time suggests that part of the preinitiation process, mostprobably T-antigen binding to the viral origin, takes place despitethe presence of hypoxia. This suspicion is confirmed by recentdata which indicate that the T antigen is bound to the originprior to reoxygenation (to be published separately in anothercontext). RNA-DNA primers and subsequent processive DNA elongationwere detectable 3 to 5 min (Fig. 1 and 3) after reoxygenation,i.e., very shortly after or even at the same time as the generationof form U. The 3'-OH end labeling of SV40 DNA isolated from reoxygenatedcells (Fig. 7) showed that form U indeed contains RNA-DNA primers.This result was especially evident when the cells were treatedwith aphidicolin immediately before reoxygenation (Fig. 7). Previousanalysis by Dröge et al. (22) showed that aphidicolin inducesnegative supercoiling in SV40 DNA in vivo. It was concluded thathelicase and polymerase activities are uncoupled to some extentby aphidicolin. Nethanel et al. (47) showed that primer synthesisis not compromised by aphidicolin in isolated nuclei of SV40-infectedcells but, instead, primer processing is inhibited. Both statementsare supported by the results presented here. After aphidicolintreatment, RNA-DNA primers of the same size as described by Nethanelet al. (47) (i.e., 30 to 60 nt [Fig. 8]) were found in the isolatedSV40 DNA. Cairns intermediates, indicating normal processing ofRNA-DNA primers to higher-molecular-weight daughter strands, onthe other hand, were not observed even 16 min after reoxygenation.Primer loss, as reported by Nethanel et al. (47) to occur inisolated nuclei after prolonged aphidicolin treatment, was notdetectable.

Aphidicolin also led to an increase in the amount of form U DNA detectable by Southern hybridization (about a fivefold increasecompared to an untreated control, as judged by densitometric evaluationof Fig. 6). At the same time, the overall number of primer 3'-OHends detectable by end labeling increased from about 10-fold 4min after reoxygenation to >40-fold 16 min after reoxygenationcompared to the untreated control (Fig. 7). This result suggeststhat the number of free 3'-OH-ends per molecule of form U probablyincreased with increasing incubation times in presence of aphidicolin,indicating that unwinding and concomitant primer synthesis continuedin aphidicolin-treated cells whereas primer processing wasinhibited.

Prolonged treatment with aphidicolin resulted in a broadening of the form U band (Fig. 7). This may also be interpreted asa further unwinding of form U, leading, after deproteinization,to additional negative supercoiling and higher electrophoreticmobility in chloroquine gels. Downward broadening was also observedin vitro with a distinct species of form U (termed form U_R) whenRPA was added in excess to the reaction mixture (7). This wasalso interpreted as a further unwinding of form U_R.

When aphidicolin was removed from reoxygenated cells, form U disappeared and Cairns intermediates and mature SV40 topoisomersemerged (Fig. 7 and 9), indicating that form U is a precursorof replicative SV40 DNAforms.

The results presented here suggest that form U is derived from an in vivo SV40 DNA species, which is unwound to a certaindegree and contains some RNA-DNA primers but also significantcomplementary single-stranded regions, probably coated by RPA.After deproteinization, the latter generate the additional negativesupercoils responsible for the high electrophoretic mobility ofform U in chloroquine-containinggels.

RNA-DNA primers of the size observed in Fig. 8 are expected to be thermally stably bound under the conditions used to isolateform U (57), and primer loss is energetically unfavorable becauseit further increases the existing negative supercoiling generatedby elimination of nucleosomes and RPA. Nevertheless, it cannotbe fully excluded that some primer loss during DNA isolation isinvolved in generation of the particular high degree of negativesupercoiling typical of form U. However, we do not believe thatthis is the case. It should be noted in this context that thereis a difference between primer loss in isolated nuclei as describedby Nethanel et al. (47), which may be compensated by topoisomeraseI action or RPA binding, and primer loss during DNA isolation,which necessarily results in additional negative superhelicaltension.

As mentioned above, form U generation in vitro is not necessarily accompanied by simultaneous primer synthesis. In vivo, unwindingand form U generation seems to be directly accompanied by primersynthesis. This may point to a tighter coupling of unwinding andprimer synthesis by DNA polymerase $alpha$ -primase compared to the invitroassay.

The differences mentioned raise the question of how far observations made in in vitro systems reflect the in vivo situation.Because a method for synchronizing SV40 replicon action withinliving cells had so far not been developed, the knowledge aboutthe temporal organization of replicon initiation exclusively reliedon experiments with in vitro systems. Such systems per se providea certain synchrony, since mixing of crucial system componentsdefines a temporal reference point. However, bringing togetherpreviously well-separated components of a complex macromolecularmachinery is by no means a physiological event. Transient-hypoxiaexperiments with cultivated cells, in contrast, provide a toolto synchronize cellular or viral replicon action. In cells exposedto "controlled-hypoxia" (5) conditions, cellular or viral repliconsaccumulate in a distinct, still uninitiated state, ready to bereleased into a synchronous round of replication by a physiologicalswitch.

The mechanism by which reoxygenation triggers the unwinding of the viral origin is unknown. Some possibilities seem unlikelyor even may be excluded, especially if it is assumed that eventsleading from reoxygenation to initiation are essentially the samefor mammalian and SV40 replicons. ATP was found not to be undershort supply in hypoxic Ehrlich ascites (51, 52) or SV40-infectedCV1 cells (unpublished data). Moreover, addition of KCN (10 mM)to hypoxic cells just before reoxygenation did not suppress theappearance of form U DNA (data notshown).

With respect to the replication of cellular DNA of Ehrlich ascites cells, it was already pointed out that the fast and reversibleresponse of the replication machinery to transient hypoxia cannotbe interpreted as a p53-dependent phenomenon mediated by changesin the expression of p21 (5). For SV40 replication in vivo,a p53-dependent pathway can be excluded a priori, since this proteinis bound and thus inactivated by the large T antigen (25, 35,36). Finally, synthesis of new proteins seems not to be possiblein the short period between reoxygenation and the beginning ofDNAsynthesis.

Among the remaining possibilities, changes in the phosphorylation patterns of proteins directly involved in origin unwindingor primer synthesis seem to be most likely. For SV40 T antigen,phosphorylation of Thr 124 (1, 8, 23, 24, 42-44), ordephosphorylation of Ser 120 and 123 (9-11, 63) was shown tostimulate unwinding. For RPA, it was suggested that hypoxia causeshyperphosphorylation of the p34 subunit, thus inhibiting the single-strandbinding activity of RPA which is necessary for replicon initiation(28). Since only minor amounts of these proteins may be actuallyengaged in SV40 initiation and elongation, such changes may escapedetection when the phosphorylation pattern of whole-cell proteinis analyzed. This may explain why we found no significant changesin whole-cell T-antigen phosphorylation before and after reoxygenation(21), although their occurrence cannot be excluded sofar.

Besides activation of origin unwinding via phosphorylation or dephosphorylation, other possibilities exist. Eucaryotic andviral origins of replication were shown to rely upon binding oftranscriptional activators for their function (12, 18, 32).Interaction of AP1 with T antigen was shown to stimulate originunwinding in polyomavirus (30). Unwinding may also be inducedby binding of AP1 or other transcription factors, like NF- $kappa$ B,to the viral enhancer (39, 40, 45) or to auxiliary sequencesflanking the SV40 core origin of replication (31). Activationand increased DNA binding capacity of AP1 and NF- $kappa$ B have beendemonstrated upon hypoxia and reoxygenation (34, 37, 56).

Final conclusions of how SV40 origin unwinding is blocked by hypoxia cannot be drawn at present. Determination of the phosphorylationpatterns of T antigen and RPA and identification of the proteinsbound to the SV40 minichromosome before and after reoxygenationwill help to elucidate the above-mentionedquestions.

	ACKNOWLEDGMENTS

We acknowledge G. Probst for critical reading of themanuscript.

This work was supported by the Deutsche Forschungsgesellschaft (grant Pr95/11-1).

	FOOTNOTES

^* Corresponding author. Mailing address: Physiologisch-chemisches Institut der Universität Tübingen, Hoppe-Seyler-Strasse4, D-72076 Tübingen, Germany. Phone: 49 7071 2972454. Fax: 497071 293361. E-mail: hans-joerg.riedinger{at}uni-tuebingen.de.

REFERENCES

Top
Abstract
Introduction
Materials and methods
Results
Discussion
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66. Wold, M. S., J. J. Li, and T. J. Kelly. 1987. Initiation of simian virus 40 DNA replication in vitro: large-tumor-antigen- and origin-dependent unwinding of the template. Proc. Natl. Acad. Sci. USA 84:3643-3647[Abstract/Free Full Text].

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