Retrotransposon Suicide: Formation of Ty1 Circles and Autointegration via a Central DNA Flap

Despite their evolutionary distance, the Saccharomyces cerevisiaeretrotransposon Ty1 and retroviruses use similar strategiesfor replication, integration, and interactions with their hosts.Here we examine the formation of circular Ty1 DNA, which iscomparable to the dead-end circular products that arise duringretroviral infection. Appreciable levels of circular Ty1 DNAare present with one-long terminal repeat (LTR) circles anddeleted circles comprising major classes, while two-LTR circlesare enriched when integration is defective. One-LTR circlespersist when homologous recombination pathways are blocked bymutation, suggesting that they result from reverse transcription.Ty1 autointegration events readily occur, and many are coincidentwith and dependent upon DNA flap structures that result fromDNA synthesis initiated at the central polypurine tract. Theseresults suggest that Ty1-specific mechanisms minimize copy numberand raise the possibility that special DNA structures are atargeting determinant.

INTRODUCTION

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Introduction

In addition to undergoing transpositional integration, the linearDNA synthesized by reverse transcription of the long terminalrepeat (LTR) retrotransposon Ty1 and retrovirus RNA has multiplefates which can modulate the efficiency of integration intothe host genome (75, 76, 80, 82). Reverse transcription is asequential process with specific requirements for priming andstrand transfer steps. Specific host tRNAs prime minus-strandreverse transcription, and purine-rich fragments of retroelementRNA (polypurine tracts [PPTs]), which are relatively resistantto the RNase H activity of reverse transcriptase (RT), primeplus-strand synthesis. The minus strand is synthesized first,followed by plus-strand synthesis using the minus strand asa template. Reverse transcription generates a linear double-strandedcDNA that is a substrate for the element-encoded integrase (IN)protein, which inserts the linear DNA into the host genome andcreates a target site duplication (TSD) in the process. Bothreverse transcription and integration are essential steps inthe life cycle of retroelements.

Several lentiviruses, including human immunodeficiency virustype 1 (HIV-1) (13-15) and equine infectious anemia virus (71),as well as the retrotransposon Ty1 (30, 31), have two PPTs,one located just upstream of the 3' LTR boundary (PPT) and thesecond near the center of the element (cPPT) (Fig. 1A). A centralDNA flap is created when the 5' end of the plus strand initiatedat the cPPT is displaced by the 3' end of plus-strand DNA afterstrand transfer (Fig. 1B). The size and position of the DNAflaps are determined by the placement of a central terminationsequence (CTS) downstream of the cPPT. The position of the HIV-1CTS creates an 88- or 98-nucleotide DNA flap downstream of thecPPT, while the Ty1 CTS creates flaps of up to 130 nucleotideswith 30% of the flaps clustered 30 to 50 nucleotides downstreamof the cPPT. The essential role of the PPT in reverse transcriptionis well established; however, the role of the cPPT is somewhatcontroversial. Mutations in the cPPT have been reported to decreasethe efficiency of HIV-1 replication or Ty1 retrotransposition,though defects in HIV-1 replication are not always observed(48). There are also reports that the central DNA flap of HIV-1is important for nuclear import of the preintegration complexin nondividing cells (2, 87). In addition, inclusion of thecPPT and CTS usually stimulates the transduction efficiencyof lentiviral vectors severalfold (4, 18, 69, 88).

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FIG. 1. Organization of the Ty1 polypurine tracts. (A) A Ty1 element showing the locations of the long terminal repeats (triangles), the GAG and POL genes, the integrase-coding domain (IN), the central polypurine tract (cPPT), the central termination sequence (CTS), and the polypurine tract (PPT). The sequences of the wild-type cPPT and the cppt-74 mutant (30) are shown below. (B) The Ty1 central DNA flap is created when the 5' end of the plus strand initiated at the cPPT is displaced by the 3' end of plus-strand DNA. The size and position of the DNA flaps are determined by the CTS.

As has been established for unincorporated retroviral DNAs (75,80), there may be nonproductive fates for unincorporated Ty1DNA that limit retrotransposition, including the formation ofone- or two-LTR circles, and intramolecular integration of theelement into itself, termed autointegration (Fig. 2). Retroviralone-LTR circles can form by homologous recombination (HR) betweenthe directly repeated LTRs (21, 44) or by errors in reversetranscription (51, 75) (Fig. 2A). Retroviral two-LTR circlesform by nonhomologous end joining (NHEJ) (34, 38, 45) and containa characteristic sequence called the circle junction (CJ) (74),where the ends of the unincorporated linear DNA are joined.Retroviral CJ sequences have been used to determine the statusof the linear DNA termini prior to integration (40, 70, 81).Ty1 LTR junction molecules, putative autointegration events,and addition of nontemplated nucleotides to the termini of linearDNA have been detected in virus-like particle preparations (20,30, 58).

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FIG. 2. Circle formation by Ty1. (A) Ty1 circles may form by host homologous recombination (HR) and nonhomologous end joining (NHEJ) functions or by reverse transcription (RT). Ty1 elements may also undergo autointegration mediated by IN. (B) Characteristics of Ty1 circles formed by autointegration. TSD⁺, 5-bp target site duplication created upon IN-catalyzed integration.

Conserved genes involved in HR (RAD51 and RAD52) and NHEJ (RAD50)modulate the levels of retroviral and Ty1 DNA and the levelof retroviral two-LTR circles (41, 61). RAD52 is required forLTR-LTR recombination of chromosomal Ty1 elements and betweenunincorporated Ty1 cDNA and chromosomal Ty1 elements (47, 59,65, 84). DNL4 (ligase 4) encodes a DNA ligase required for NHEJin mammalian cells and Saccharomyces cerevisiae (39) and maybe required for forming Ty1 two-LTR circles.

Autointegration has the potential to divert a significant fractionof transposition intermediates into dead-end products and occurswith diverse mobile genetic elements, including Tn5, Tn10, bacteriophageMu, and retroviruses (5, 50, 55, 67, 79). Two types of DNA circlesresult from IN-mediated autointegration, and each has definingcharacteristics (Fig. 2B); "inversion circles" are producedwhen IN joins opposite DNA strands, and "deletion circles" arisefrom joining of the same strands.

Here we explore the formation of circular DNA by Ty1. Our resultssuggest that more than half of the unincorporated Ty1 cDNA accumulatesas circular forms. Ty1 autointegration occurs preferentiallyin a region adjacent to, and dependent upon, a functional cPPT.These autointegration events may reveal new targeting determinants,because for Ty1, chromosomal integration usually occurs upstreamof genes actively transcribed by RNA polymerase III (76).

MATERIALS AND METHODS

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Materials and Methods

Genetic techniques, media, and strains. Saccharomyces cerevisiae genetic techniques and media were usedas described previously (29, 66). The Ty1-less strain DG2203(MAT ${alpha}$ his3- ${Delta}$ 200hisG trp1 ura3) was derived by crossing strainsDG2196 and DG1768 (24). Targeted integrative transformationwas carried out after linearization of the TRP1-integratingplasmids pBDG1085 (pGTy1, wild type [WT]), pBDG1095 (pGTy1,frameshift [FS]), pBDG1242 (pGTy1, in-2600) (9), and pRS404(vector) with Bsu36I and linearization of the URA3-integratingplasmids pJef1229 (pGTy1, WT), pBDG1285 (pGTy1Zeo, WT), pBDG1288(pGTy1Zeo, in-2600), pBDG1289 (pGTy1, cppt-74), pBDG1295 (pGTy1Zeo,cppt-74), and pBDG1299 (pGTy1, in-K596,597G) with StuI. DG2203derivatives containing an integrated pGTy1 element at TRP1 orURA3 were identified by Southern analysis using a ³²P-labeledTy1 probe. DNL4 and RAD50-52 deletion derivatives of DG2203were constructed by microhomologous recombination (49) usingdrug resistance genes designed for gene replacement (27, 77)and the genome sequence of Saccharomyces paradoxus (36). Thednl4- ${Delta}$ natMX rad50- ${Delta}$ kanMX rad52- ${Delta}$ kanMX triple mutant was constructedby crossing the Ty1-less strains DG2792 [MATa his3- ${Delta}$ 200hisG Ty1his3-AI(96)trp1 ura3 pBDG1085/TRP1 dnl4- ${Delta}$ natMX rad52- ${Delta}$ kanMX] and DG2642 (DG2203rad50- ${Delta}$ kanMX). The dnl4- ${Delta}$ natMX rad51- ${Delta}$ kanMX rad52- ${Delta}$ kanMX triplemutant was constructed by crossing the Ty1-less strains DG2792[MATa his3- ${Delta}$ 200hisG Ty1his3-AI(96) trp1 ura3 pBDG1085/TRP1 dnl4- ${Delta}$ natMXrad52- ${Delta}$ kanMX] and DG2632 (DG2203 rad51- ${Delta}$ kanMX). In each cross,G418^r (nonparental ditype configuration; 2:2 segregation forG418^r), nourseothricin-resistant Trp⁺ Ura^– His^–segregants were analyzed by genetic complementation tests forsensitivity to the mutagen methyl methanesulfonate (0.0125%[vol/vol] in yeast extract-peptone-dextrose [YEPD]) to confirmthe presence of the rad50, rad51, and rad52 mutations. A 2µm-URA3-basedpGTy1 plasmid pBDG1278 (pGTy1Zeo/2µ-URA3) was introducedinto DG2203 containing pBDG1085 or the triple mutants for repliconrescue. Quantitative Ty1his3-AI insertion rates were determinedas described previously (17).

Plasmids. Plasmids were constructed using standard techniques (32, 63).Briefly, pBDG1085 (pGTy1/TRP1 WT) was constructed by ligatingan EagI-EcoRI fragment from pRS404 (YIp/TRP1), a BstEII-EagIfragment from pBDG202 (pGTy1/2µ-URA3), and a BstEII-EcoRIfragment from pBDG919 (pGTy1/2µ-TRP1). pBDG1095 (pGTy1/TRP1FS) was constructed by ligating an EagI-EcoRI fragment frompRS404, a BstEII-EagI fragment from pBDG202, and a BstEII-EcoRIfragment from pJW117 (pGTy1 frameshift [+1, BamHI]/2µ-URA3).pBDG1242 (pGTy1/TRP1 in-2600) was constructed by subcloningan AflII-BstEII fragment from pBDG720 (pGTy1 in-2600/2µ-URA3)into pBDG1085. pBDG1278 was constructed by introducing a cassettecontaining the zeocin resistance gene (Zeo), a lac operator,and a ColE1 plasmid replication origin that was PCR amplifiedfrom the RSVPCA12 plasmid (60) using primers Ty-ACC1 (5'-GCGATAGTCGACCCGTAGAAAAGATC-3')and Ty-ACC2 (5'-GCATGCGTCGACTGTTGACAATTAATCATCGGCA-3'). Theresulting PCR fragment was digested with AccI and cloned intothe ClaI site of pBDG202. The orientation in which Ty1 and Zeowere transcribed in the same direction was used in the presentstudy (BDG/Cas). pBDG1285 was constructed by subcloning thePshAI-HindIII fragments from pBDG1278 into pBDG725 (pGTy1/YIp5),pBDG1288 was constructed by subcloning a HindIII-XhoI fragmentfrom pBDG720 into pBDG1285, and pBDG1289 was constructed bysubcloning a HindIII-XhoI fragment from pJef1105-74 (pGTy1 cppt-74/2µ-URA3;kindly provided by M. Wilhelm) (Fig. 1A) into pJef1229 (pGTy1/YIp5;kindly provided by J. Boeke). pBDG1295 was constructed by subcloninga HindIII-XhoI fragment from pJef1105-74 into pBDG1288, andpBDG1299 was constructed by subcloning a HindIII-XhoI fragmentfrom pDSM27 (pGTy1 K596,597G/2µ-URA3) into pJef1229. pBDG1198(5,848 nucleotides) was constructed by subcloning a BglII-XhoIfragment from TyA1-GAG into pRS406 and served as a size markerfor circular Ty1 DNA. pBDG1088 was constructed by subcloningthe IN-coding domain (nucleotides 2041 to 3945) as an XhoI-BamHIPCR fragment into pRS426. pBDG996 is a centromere-based URA3plasmid containing Ty1his3-AI(d1) and will be described in detailelsewhere. pDSM207 was constructed by subcloning an XhoI-SnaBIfragment from pJef1105-74 into pBDG996. Plasmid constructs wereverified by drug resistance phenotypes, DNA sequencing, andrestriction enzyme analysis. Plasmids pRS404, pRS406, pRS426(68), pBDG202 (pGTy1-H3Cla) (23), pJW117 (24), pJef1105-74 (30),and pDSM27 (54) have been described previously.

Galactose induction and genomic DNA isolation. Cells were grown to saturation in liquid selective medium plusraffinose (2%) at 20^oC. The cultures were diluted at least 40-foldinto yeast extract-peptone (YEP) plus galactose (2%) and grownto mid-log phase (1 x 10⁷ cells/ml) at 20^oC. Genomic DNA wasisolated from 10 ml of cells after spheroplasting with zymolyase20T (ICN Pharmaceuticals, Costa Mesa, CA) as described previously(8).

Southern analysis. DNA samples digested with PstI or SnaBI were separated by 0.8%(wt/vol) agarose gel electrophoresis and capillary blotted toHybond N membrane according to the supplier's recommendations(Amersham Biosciences, Piscataway, NJ). Undigested genomic DNAsamples were also separated by 0.8% (wt/vol) agarose gel electrophoresisin Tris-acetate running buffer. The gel was stained with ethidiumbromide, photographed, and processed for Southern filter hybridizationas described above. Fifty nanograms of undigested or linearizedmarker plasmid pBDG1198 was usually included on gels containingundigested genomic DNA. ³²P-labeled hybridization probes weregenerated by random-prime labeling (Amersham Biosciences). ProbeI from GAG was generated by digesting pBDG202 with PstI andPvuII and purifying the 663-bp fragment, probe II from TyB1-POLwas generated by digesting pBDG1088 with XhoI and EcoRV andpurifying the 738-bp fragment, and probe III from POL was generatedby digesting pBDG202 with HindIII and SnaBI and purifying the834-bp fragment. Hybridization signals were assigned on thebasis of the patterns obtained with mutant Ty1 elements, andfragment sizes were predicted from restriction enzyme analysisor marker plasmids and from the map locations of different hybridizationprobes. Hybridization signals were quantitated by phosphorimageanalysis and normalized to the integrated pGTy1 element presentin the Ty1-less strains using protocols suggested by the manufacturer(GE Healthcare, Piscataway, NJ).

PCR. Ty1 junction molecules and CJs were detected by PCR using about1 µg genomic DNA per 50-µl reaction mixture volume,Titanium Taq DNA polymerase and conditions recommended by thesupplier (Clontech, Mountain View, CA), primers CJxba5784w-2(5'-GCCATTCTAGAGTGTAGAATTGCAGATTCC-3') and CJ1125c (5'-CGATGAATTCGCGTCATCTTCTAACACCGT-3'),and the following cycling conditions: 2 min at 95^oC (1 cycle);30 cycles, with 1 cycle consisting of 30 s at 95^oC, 15 s at56^oC, and 1 min at 72^oC; and 7 min at 72^oC (1 cycle). PCR productswere separated by 2% agarose gel electrophoresis, and bandsof 200 to 300 bp were purified using QIAquick (QIAGEN, Valencia,CA), followed by TOPO TA cloning (Invitrogen, Carlsbad, CA).An M13Reverse primer (5'-CAGGAAACAGCTATGAC-3') was used forDNA sequencing. PCRs to detect the autointegration events adjacentto the cPPT were performed as described above except the cyclingconditions were 2 min at 95^oC (1 cycle); 30 cycles, with 1 cycleconsisting of 15 s at 95^oC, 15 s at 58^oC, and 15 s at 72^oC;and 72^oC 7 min (1 cycle), and the PCR primers were TYB4203c(5'-GATGCTGAATATCACCTCTTGC-3'), TYB5130c (5'-ACGAAGCATCACTTATTGCGAC-3'),TYB5483c (5'-CTTGGTCTCGATGTAGTATACGT-3'), and TYBout (5'-GAACATTGCTGATGTGATGACA-3').DNA preparations were analyzed by PCR using primers specificto LEU2 as described previously (24).

Ty1Zeo circles. Aliquots of genomic DNA were digested with PvuI to minimizethe possibility of recovering the pGTy1 expression vector, followedby electroporation into Escherichia coli DH5 ${alpha}$ and selection forzeocin resistance. Plasmids isolated from zeocin-resistant,ampicillin-sensitive transformants were subjected to restrictionenzyme analysis and then sequenced using a primer complementaryto the Zeo cassette (Ori-2 [5'-GCAAGCAGCAGATTACGCGCA-3']). Targetsite duplications from inversion circles were verified by DNAsequence analysis with a primer from the 5' end of Ty1 (TyAout2[5'-GCCTTCTCACATTCTTCTGTT-3']). BLAST 2 sequences (http://www.ncbi.nlm.nih.gov/BLAST/bl2seq/wblast2.cgi)was used to map the LTR junctions by comparing Ty1Zeo sequenceswith Ty1-H3 (GenBank accession number M18706). Similar distributionsof joining events were obtained from several independent experimentsusing wild-type and cppt-74 pGTy1Zeo elements; therefore, thedata were pooled. WebLogo (http://weblogo.berkeley.edu/logo.cgi)(16) was used to derive consensus 5-bp TSDs inferred from thesequence adjacent to the Ty1 LTR.

RESULTS

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Results

Ty1 circles. To determine the overall level of circular Ty1 DNA present incells undergoing retrotransposition, Southern analysis was performedusing genomic DNA and a ³²P-labeled probe derived from TYA1-GAG(Fig. 3). The strains contained a wild-type or mutant GAL1-promotedTy1 element integrated into the genome to minimize Ty1 copynumber without sacrificing the ability of a GAL1-promoted Ty1to induce high levels of retrotransposition in the presenceof galactose (8). In addition, the strains have no other chromosomalTy1 elements (24), which would complicate the hybridizationpatterns.

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FIG. 3. Presence of Ty1 circles. Undigested genomic DNAs were isolated from cells expressing wild-type Ty1 (WT), mutant Ty1 elements defective in IN (in-2600) or in the cPPT (cppt-74), or GAG-POL due to a +1 frameshift mutation early in GAG (FS) and cellular mutants defective in HR and NHEJ (dnl4 ${Delta}$ rad51 ${Delta}$ rad52 ${Delta}$ and dnl4 ${Delta}$ rad50 ${Delta}$ rad52 ${Delta}$ ). Undigested genomic DNAs isolated from various cells were separated by agarose gel electrophoresis and analyzed by Southern hybridization using a ³²P-labeled TyA1-GAG probe. pBDG1198 (5,848 bp; refer to Materials and Methods) was used as a size marker for Ty1 (5,918-bp) linear and circular molecules. The positions of circular DNA containing single-strand breaks (NC), covalently closed circles (CCC), and linear DNA (L) and of linear size standards (in kilobases) are shown to the left. The relative amounts of linear and circular DNA were determined using phosphorimage analysis and normalized to the amount of integrated pGTy1 element present in genomic DNA.

Putative circular Ty1 DNA molecules comprised at least halfof the unincorporated Ty1 DNA in cells expressing a wild-typeelement, as determined by phosphorimage analysis (Fig. 3). Inaddition to linear Ty1 DNA (5,918 bp), two types of circularTy1 DNA were detected by Southern hybridization. The first hadan electrophoretic mobility in agreement with that expectedfor Ty1 circles containing one or two LTRs. This band was independentof functional IN, because its intensity was not altered in anin-2600 mutant, which encodes a defective IN protein resultingfrom the insertion of five additional codons (52). The second,faster-migrating band was dependent on the presence of functionalIN, suggesting that it contains circular Ty1 DNA produced byautointegration and, if so, the circular DNA could also be catenated(21, 44). Heterogeneously sized circles may also be presentbut would not be visible by this type of analysis.

We initially determined that Ty1 circle formation was not appreciablyaffected in a rad52 ${Delta}$ mutant (data not shown), suggesting thepossibility that Ty1 circles are produced using multiple recombinationpathways. To address this possibility, two triple deletion mutantswere constructed that should block HR (by deleting RAD50, therecA homolog RAD51, and RAD52) and NHEJ (by deleting RAD50 andthe DNA ligase gene DNL4). Both mutants contained deletionsfor DNL4 and RAD52. One of the mutants also had a RAD50 deletion(dnl4 ${Delta}$ rad50 ${Delta}$ rad52 ${Delta}$ ), while the other mutant had a RAD51 deletion(dnl4 ${Delta}$ rad51 ${Delta}$ rad52 ${Delta}$ ). However, one-LTR and two-LTR circles, aswell as autointegration circles, were present at wild-type levelsin dnl4 ${Delta}$ rad51 ${Delta}$ rad52 ${Delta}$ and dnl4 ${Delta}$ rad50 ${Delta}$ rad52 ${Delta}$ mutants (Fig. 3). Wealso determined that both types of Ty1 circles were presentin a cppt-74 mutant (Fig. 1A), which is defective for plus-strandDNA synthesis from the cPPT (30). As expected, unincorporatedTy1 cDNA was not detected when the pGTy1 element contained a+1 frameshift mutation early in the GAG gene (FS).

LTR junction molecules and circle junctions. Although putative circular forms of Ty1 DNA were reproduciblydetected in genomic DNA by Southern analysis, we were unsuccessfulin isolating enough circular DNA for direct physical analysesof catenated molecules. However, the presence of Ty1 circlesallowed us to investigate the nature of the LTR-LTR joiningevent using the following assays: PCR analysis using nonoverlappingprimers that span the circle junction (Fig. 4; see file S1 inthe supplemental material), replicon rescue using Ty1 elementsthat contain a Zeo^r gene and a bacterial plasmid origin of replication(Fig. 5; see Table 2; also see file S2 in the supplemental material),and additional Southern analyses (Fig. 6). PCR amplificationwas carried out using DNA from galactose-induced cells expressingwild-type Ty1, from the in-2600 mutant, or from glucose-growncells (Fig. 4A). The CJ5784w and CJ125c primers amplified abroad band of 200 to 250 bp, which is in the size range expectedfor the CJ product containing two LTRs (259 bp). When the in-2600mutant was analyzed, a minor band (B band) was present in additionto a major band (T band) that was closer to the size expectedfor a canonical CJ. PCR products were not detected when cellswere grown in the repressing carbon source glucose or when templateDNA was omitted from the reaction mixture. All of the DNA preparationswere competent for PCR as shown by amplification of the LEU2gene.

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FIG.4. Ty1 LTR junction formation. (A) The structure of a Ty1 two-LTR junction molecule containing a circle junction (CJ). The LTR domains unique 3' (U3), repeated (R), and unique 5' (U5) are shown (6, 75). The positions of the PCR primers CJ5784w and CJ125c used to amplify LTR junction molecules and the positions of PPT (polypurine tract) (used to initiate plus-strand DNA synthesis) and the primer binding site (PBS) (tRNA-Met anneals to initiate minus-strand reverse transcription) are shown. Below are PCR products, separated by agarose gel electrophoresis, in the size range expected for a canonical circle junction (CJ = 259 bp) amplified with primers CJ5784w and CJ125c and genomic DNA from cells expressing wild-type Ty1 (WT, galactose), an in-2600 mutant (in-2600, galactose), cells grown under repressing conditions (WT, glucose), or a reaction mixture lacking yeast DNA (– template). When the in-2600 mutant was analyzed, a minor, bottom band (labeled B) was present in addition to a major, top band (T) that was closer to the size expected for a canonical CJ. Primers specific to the LEU2 gene were used to show that genomic DNA was PCR competent. (B) LTR junction molecules obtained from wild-type Ty1. Unidirectional deletions into U5 or U3 are at the top and designated by the arrow. A canonical CJ is depicted by the striped bar, and a canonical CJ with intervening DNA inserted between the LTR ends is shown by the open bar and asterisk. LTR junction molecules with deletions into U5 (PPT-proximal LTR; also refer to panel A) are on the left (filled bars, minus numbering), while those with deletions into U3 (PBS-proximal LTR) are on the right (filled bars, plus numbering). LTR junction molecules with intervening DNA are designated by asterisks (see file S1 in the supplemental material). (C) LTR junction molecules obtained from an in-2600 mutant enriched for T-band sequences (Fig. 4A). The resolution of the figure is about 5 bp.

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FIG. 5. Autointegration events recovered using wild-type or cPPT-defective (cppt-74) Ty1 elements containing the Zeo cassette. (A) The positions of the Ty1 LTRs (triangles), the cPPT, and autointegration events resulting in deletion circles (short solid lines) and inversion circles (short dotted lines with diamonds) are shown. Ty1 sequence coordinates are shown below. The resolution of the figure is about 10 bp (see file S2 in the supplemental material for nucleotide positions of the autointegration events). (B) Consensus sequence of the 5-bp target site duplication for Ty1 autointegration events constructed using WebLogo (16). The size of the nucleotide at each position reflects the frequency with which that nucleotide occurs in the target site. Target sites are oriented in the 5' to 3' direction from the end of the LTR adjacent to the Zeo cassette. Error bars are twice the small sample correction.

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TABLE 2. The cPPT and endogenous Ty1his3-AI retrotransposition^a

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FIG. 6. Southern analysis of unincorporated Ty1 DNA. (A) Organization of the Ty1 element. The positions of regions I (black rectangle), II (rectangle with brickwork pattern), and III (shaded rectangle) that were used as hybridization probes, positions of restriction endonuclease cleavage sites for PstI (P) and SnaBI (S), and positions of the cPPT, the cPPT-associated autointegration hot spot (filled and unfilled circles), and resulting deletion circles (dotted lines) are shown. Probes I and II hybridized with PstI fragments of 3 to 3.3 kb (filled circle). (B) Genomic DNAs from cells expressing wild-type Ty1, the +1 frameshift mutant (FS), and in-2600 were digested with PstI, separated by agarose gel electrophoresis, and subjected to Southern analysis with ³²P-labeled probe I (black rectangle) or II (rectangle with brickwork pattern) from GAG or the proximal segment of POL, respectively. Hybridization signals from the integrated pGTy1 element (pGTy1), LTR junctions, left-end (LE) and right-end (RE) cDNA, and the cPPT-associated autointegration hot spot (filled circle) are shown alongside the blots. (C) Genomic DNA from cells expressing wild-type Ty1 or the cppt-74 mutant was digested with PstI and analyzed with probe I, as described above for panel B, or with SnaBI and probe III (shaded rectangle) from the end of POL. Signals from the cPPT-associated autointegration hot spot (filled and unfilled circles) and cPPT-initiated plus-strand DNA (cPPT) are shown alongside the blots. The positions of the autointegration band adjacent to the cPPT (filled circle) and the autointegration hot spot fragment derived from one deletion circle (2.1 kb; unfilled circle) are indicated.

We cloned and sequenced 82 PCR products from cells expressingwild-type Ty1 (Fig. 4B; see file S1 in the supplemental material)and 47 products from the in-2600 mutant (Fig. 4C; see file S1in the supplemental material). The sequence analysis revealedonly one PCR product containing a canonical CJ from wild-typeTy1, while two others contained intervening sequence insertedbetween two complete LTRs. The remaining PCR products from wild-typeTy1 contained one complete LTR U3 or U5 segment and deletionsof various lengths extending into the other LTR. Several ofthe junctions that contained deletions also contained additionalsequences of various lengths inserted between the complete LTRand a deleted U3 or U5 segment.

The T band from the in-2600 mutant element yielded a differentpattern of LTR junction molecules than the broad band from wild-typeTy1 (Fig. 4C), while the B band resembled the pattern obtainedwith wild type (data not shown). Canonical CJs recovered fromthe in-2600 mutant comprised about 21% of the PCR products (10of 47), and those containing additional DNA made up another47% (22 of 47). The remaining 15 PCR products contained unidirectionaldeletions at the CJ similar to those obtained with wild-typeTy1. Most of the intervening DNA sequences obtained with wild-typeTy1 or the in-2600 mutant were too short to identify by databasesearches (see file S1 in the supplemental material); however,many of the intervening sequences contained 5'-CCA-3' or itscomplement 5'-TGG-3' at one terminus. Since CCA is added tothe termini of tRNAs, it is likely that the intervening DNAsegments are derived from tRNAs, or from the addition of CCAto Ty1 RNA by ATP (CTP):tRNA nucleotidyltransferase (1). Inaddition, five of the longer DNA segments inserted at the CJwere derived from the 3' ends of Thr-tRNA (UGU). Together theseresults suggest that the unidirectional deletions are largelydependent on active IN, and those recovered from the in-2600mutant may result from leaky IN activity and were detected becauseof the sensitivity of the PCR assay. As will become evidentbelow, the unidirectional deletions probably are autointegrationevents within the LTRs, resulting in deletion circles.

Recovery of Ty1Zeo circles by replicon rescue. Genomic DNA was prepared from galactose-induced cells containingan integrated pGTy1 element tagged with the Zeo cassette, whichincludes a bacterial plasmid replication origin and a zeocinresistance gene (60). The DNA was digested with PvuI to minimizethe recovery of pGTy1Zeo circles that might form in yeast. ThepGTy1Zeo plasmid contains a single PvuI restriction site inthe ampicillin resistance gene, whereas Ty1Zeo does not containany PvuI sites. The DNA was introduced into the recA Escherichiacoli strain DH5 ${alpha}$ by electroporation followed by selection forzeocin resistance. The resulting transformants were screenedfor ampicillin resistance, and plasmid DNA from zeocin-resistant,ampicillin-sensitive colonies were analyzed (Fig. 5 and Table1; see file S2 in the supplemental material). In a typical experimentusing a wild-type Ty1Zeo element, 75% (18 of 24) of the transformantswere Zeo^r Amp^s, and the defective pGTy1FSZeo element yieldedonly Zeo^r Amp^r transformants. Plasmids recovered from Zeo^r Amp^rcolonies usually resembled pGTy1Zeo.

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TABLE 1. Ty1Zeo circles

The 131 Ty1Zeo circles recovered from cells expressing wild-typeTy1 were subjected to DNA sequence analysis using a primer fromthe 3' end of the Zeo cassette to determine the sequence acrossthe LTR junction (Fig. 5A and Table 1; see file S2 in the supplementalmaterial). The most common type of Ty1Zeo circle recovered (45.8%[60 of 131]) was from an autointegration event joining the samestrands, forming deletion circles. These circular Ty1Zeo elementscontained a complete LTR joined to Ty1 sequences located elsewherein the element. Surprisingly, there was a possible "hot spot"for autointegration events generating deletion circles startingabout 30 nucleotides downstream of the cPPT (nucleotides 3782to 3791). The other type of autointegration event, called aninversion circle, occurs when IN catalyzes joining of oppositeDNA strains. About 6% (8 of 131) of the recovered plasmids wereTy1Zeo inversion circles; these circles were the same size asa complete element and contained an inversion of Ty1 sequencesat the insertion site. Another prominent class of Ty1Zeo circles(25.2% [33 of 131]) contained a single LTR. Consistent withthe PCR analysis, we did not recover any circle junctions wherethe two LTRs were joined. We also recovered 24 (18.3%) bidirectionaldeletions, most of which removed one LTR completely but didnot delete much of the LTR downstream of the Zeo cassette, aswould be expected from the way the Ty1Zeo circles were selected.Six (4.6%) of the deletions were complex in that they containedadditional inversions or insertions of non-Ty1 sequences. Bidirectionaldeletions were sometimes bracketed by perfect or imperfect homologiesof less than 15 nucleotides and therefore may have been formedby recombination.

Ty1Zeo circles recovered from an in-2600 mutant and a dnl4 ${Delta}$ rad51 ${Delta}$ rad52 ${Delta}$ mutant were compared with the Ty1 circles obtained froma wild-type element (Table 1). The types of Ty1Zeo circles recoveredwere in general agreement with the results of Southern analysesof undigested genomic DNA from cells expressing an unmarkedTy1 element (Fig. 3). Notably, autointegration circles werenot obtained with the in-2600 mutant, perhaps because the Ty1Zeoassay is not sensitive enough to detect the residual IN activitypresent in the in-2600 mutant. Ty1Zeo circles containing a singleLTR were also recovered from the dnl4 ${Delta}$ rad51 ${Delta}$ rad52 ${Delta}$ triple mutant,suggesting that these events are not the result of homologousrecombination between the LTRs present in linear Ty1 DNA.

To determine whether the autointegration events adjacent tothe cPPT observed with wild-type Ty1Zeo were dependent on thecPPT, 129 Ty1Zeo circles were recovered from cells expressingthe cppt-74 mutant (Fig. 5A and Table 1; see file S2 in thesupplemental material). The number of Ty1 autointegration eventsdecreased about threefold, and the number of bidirectional deletionsincreased twofold in the absence of the cPPT compared with thoseof a wild-type Ty1Zeo element. Although autointegration eventswere recovered at a number of positions in the cppt-74 mutant,none were close to the cPPT.

Autointegration consensus sequence. Four of the Ty1Zeo inversion circles recovered from cells expressingwild-type Ty1Zeo were sequenced from both LTRs and showed 5-bpTSDs typical of Ty1 transposition events in that they did notshow a strong consensus sequence (see file S2 in the supplementalmaterial): 5'-ATTAG-3' (insertion site 1514), 5'-CATCT-3' (insertionsite 12906), 5'-CAATC-3' (insertion site 13116), and 5'-GAAAT-3'(insertion site 14736). Therefore, we derived a consensus targetsite from a larger collection of Ty1Zeo deletion and inversioncircles recovered from cells expressing wild-type Ty1 (74 circles)and the cppt-74 mutant (22 circles), assuming that the TSD occurrednormally during autointegration (Fig. 5B). The consensus sequenceobtained by analyzing autointegration events using WebLogo (16)showed a preference for AT-rich sequences for both wild-typeTy1 and the cppt-74 mutant, which is similar to previous studieswhere large numbers of Ty1 integration sites have been determinedat the CAN1 locus (46, 62, 83).

Southern analysis of unincorporated Ty1 DNA. To gain independent evidence for an autointegration preferencenear the cPPT and confirm the presence of circular Ty1 DNA,we performed Southern hybridizations using ³²P-labeled probesfrom GAG (probe I), the center of the element (probe II), andfrom the RT region (probe III) (Fig. 6). Autointegrations adjacentto the cPPT form deletion circles of about 3.8 and 2.1 kb; therefore,subsequent restriction enzyme digestion results in fragmentsof predicted sizes (Fig. 6A). Genomic DNA was digested withPstI and processed for Southern analysis, and the resultingfilters were hybridized with probes I and II (Fig. 6B). PstIcuts twice in Ty1 and yields fragments of 1,138, 754, and 4,053bp. Both probes I and II hybridized with PstI fragments of 3to 3.3 kb from cells expressing wild-type Ty1, which is theexpected size for fragments generated if autointegration eventsoccurred near the cPPT. The autointegration band adjacent tothe cPPT was not detected in the in-2600 or FS mutant. PstIfragments of 5.1 to 5.4 kb from circular LTR junction moleculescontaining one LTR and two LTRs and from LTR-LTR autointegrationevents (Fig. 4B) were also detected. As expected, a genomicDNA fragment containing the integrated pGTy1 element, and unincorporatedTy1 cDNA fragments of about 1.1 and 4 kb from the left end (LE)and right end (RE) of Ty1 were present. The integrated pGTy1band was present in all samples, and the LE and RE bands werepresent in the wild-type and in-2600 strains.

Southern analysis was used to determine whether the autointegrationpreference adjacent to the cPPT was maintained in the cppt-74mutant (Fig. 6C). The autointegration band adjacent to the cPPTdetected after PstI digestion and hybridization with probe Iwas not detected in the cppt-74 mutant. Genomic DNA was alsodigested with SnaBI, which cleaves once in Ty1 at nucleotide5463, and hybridized with probe III to detect an autointegrationhot spot fragment derived from one deletion circle (2.1 kb)and the cPPT-initiated plus-strand fragment (cPPT; 1.7 kb).The difference in size between these two SnaBI fragments resultsfrom the complete LTR (334 bp) present in the deletion circle.Both restriction fragments were detected in cells expressingwild-type Ty1, but not in the cppt-74 mutant. In contrast, theLTR junction molecules derived from circular Ty1 DNA containingone or two LTRs and LE cDNA remained at wild-type levels inthe cppt-74 mutant.

Detecting autointegration events by PCR. The results of Ty1Zeo and Southern analyses encouraged us todevelop a PCR-based assay to detect autointegration events adjacentto the cPPT (Fig. 7). Oligonucleotide primers that annealedto sequences at various distances downstream of the cPPT (4203c,5130c, and 5483c) were used in PCRs with a primer adjacent tothe 3' LTR of Ty1 (TyBout, nucleotide 5486) and with DNA fromstrains expressing wild-type Ty1, several defective elements(in-2600, cppt-74, in-K596,597G, and the FS mutant), and anempty GAL1 vector (Fig. 7A). If the cPPT mediates a preferencefor autointegration events, PCR products of $~$ 827 bp (TyBout plus4203c), $~$ 1,754 bp (TyBout plus 5130c), and $~$ 2,107 bp (TyBout plus5483c) should be amplified on the basis of the closest Ty1Zeoinsertion at nucleotide 3808 (see file S2 in the supplementalmaterial). The ability to amplify these products should requirean expression-competent Ty1 element with a functional IN anda cPPT. PCR products in the expected size range (Fig. 7B) wereobtained using DNA from cells expressing wild-type Ty1 but notfrom the in-2600, cppt-74, or FS mutant. We also determinedthat nuclear entry of the Ty1 preintegration complex was notrequired for autointegration activity adjacent to the cPPT byanalyzing an element that contained a defective nuclear localizationsignal (NLS) in IN (in-K596,597G) (54). The NLS-defective mutanthad wild-type levels of autointegration activity adjacent tothe cPPT, as shown by amplification of the $~$ 827-bp product. AllDNA samples were competent for PCR, as determined by amplificationof the chromosomal LEU2 gene (data not shown).

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FIG. 7. PCR analysis of the autointegration hot spot mediated by the cPPT. (A) The autointegration hot spot region adjacent to the cPPT (nucleotide 3782) is shown along with primers 4203c, 52130c, 5483c, and TyBout (5486) and one deletion circle (dotted line). DNA from strains expressing wild-type Ty1, several defective elements (in-2600, cppt-74, in-K596,597G, and the FS mutant), and an empty GAL1 vector was used. If the hot spot were adjacent to the cPPT and begins at Ty1 nucleotide $~$ 3808 (inferred from analyzing Ty1Zeo circles), PCR products of $~$ 827 bp (TyBout plus 4203c), $~$ 1,754 bp (TyBout plus 5130c), $~$ 2,107 bp (TyBout plus 5483c) should be amplified. (B) Genomic DNA from cells expressing wild-type, in-2600, cppt-74, FS, nuclear-localization-defective (in-K596,597G) Ty1 elements or an empty vector were used in PCRs with the primer pairs shown below, and the amplified fragments were separated by agarose gel electrophoresis. PCR products resulting from autointegration events associated with the cPPT are noted. The asterisks indicate PCR products in the expected size range. The positions of molecular size standards (in base pairs) are noted to the left of the leftmost gel. (C) The $~$ 827-bp PCR product resulting from amplification with primers TyBout plus 4203c was sequenced, and the autointegration insertion sites were compared with those obtained from sequencing Ty1Zeo circles (Fig. 5). The resolution is about 5 bp (see file S2 in the supplemental material for insertion sites). Also shown are the central Ty1 DNA flaps resulting from cPPT-initiated DNA synthesis and variable termination of the incoming plus strand at the CTS (rectangle), with 30% of strands terminating 30 to 50 nucleotides downstream of the cPPT (filled rectangle) (30).

Central DNA flap and autointegration. The $~$ 827-bp amplification products obtained by PCR with primersTyBout plus 4203c were cloned and sequenced to determine theautointegration sites (see file S2 in the supplemental material).We then aligned the Ty1 autointegration events obtained fromanalyzing Ty1Zeo circles and PCR products described above withthe position of the Ty1 central DNA flap structures mapped previously(30) (Fig. 7C). There was a striking correspondence betweenthe autointegration activity adjacent to the cPPT using twoindependent approaches and the positions of the central DNAflaps present in Ty1. The Ty1 autointegration events in thispreferred region started 26 nucleotides downstream of the cPPT,occurred in a region of about 80 nucleotides, and were coincidentwith the positions of the central DNA flaps.

Ty1his3-AI retrotransposition. To determine whether additional defects in Ty1 retrotranspositioncould be detected in the cppt-74 mutant under more stringentgenetic conditions (25, 53), we introduced the cppt-74 mutationinto a Ty1 element marked with the his3-AI indicator gene (17)and determined the rate of His⁺ colony formation in wild-typeand rad52 ${Delta}$ Ty1-less backgrounds. Retrotransposition generatesmost of the His⁺ colonies obtained with wild-type Ty1his3-AI.Following splicing of the artificial intron (AI) and reversetranscription, recombination events involving Ty1HIS3 cDNA arealso detected by this assay and become more prevalent when Ty1cannot complete reverse transcription or undergo integration(65). The cppt-74 mutation decreased Ty1his3-AI integration2.5-fold in a wild-type Ty1-less background (Table 2) and 1.75-foldin a rad52 ${Delta}$ mutant, where Ty1 DNA recombination is blocked, whichis comparable to previous results obtained using a GAL1-promotedTy1 element (30, 31).

DISCUSSION

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Discussion

We show that at least half the unincorporated Ty1 DNA presentin cells undergoing retrotransposition is diverted into dead-endjoining reactions, resulting in circular DNA. Accumulation ofTy1 circles does not completely depend on the activities ofyeast HR and NHEJ pathways. Instead, Ty1 one-LTR circles mayarise by errors in reverse transcription and by IN-mediatedautointegration events. Wild-type Ty1 produces few two-LTR circles.However, two-LTR circles are greatly enriched when IN is defective,suggesting that integration-competent Ty1 DNA is short-livedbecause Ty1 DNA is efficiently integrated or degraded. Analysisof Ty1 autointegration events revealed a hot spot adjacent to,and dependent upon, the cPPT near the center of the element.Because the length of this Ty1 autointegration hot spot correspondsto the variation in the positions and accompanying sizes ofthe central DNA flaps formed by variable termination of plus-strandsynthesis, Ty1 target specificity may be enhanced by the presenceof special DNA structures.

Formation of solo LTRs from chromosomal Ty1 elements can occurby HR or single-strand annealing pathways, which require RAD52(39, 47, 84). For these reasons, we expected that RAD52 wouldalso be required for one-LTR circle formation. Nonetheless,Southern analyses of undigested genomic DNA show that wild-typelevels of Ty1 circles containing one or two LTRs are presentnot only in rad52 ${Delta}$ mutants but also when NHEJ is blocked in dnl4 ${Delta}$ rad50 ${Delta}$ rad52 ${Delta}$ or dnl4 ${Delta}$ rad51 ${Delta}$ rad52 ${Delta}$ host mutants. The followingresults suggest that the hybridization signal from undigestedgenomic DNA is primarily from one-LTR circles. (i) Ty1 circlesare present when IN is defective. (ii) CJs characteristic oftwo-LTR circles are present at a low level when Ty1 producesactive IN. (iii) LTR junction molecules of the size expectedfor a single LTR are present when genomic DNA is digested withPstI or SnaBI and analyzed by Southern blotting. (iv) Ty1Zeocircles containing a single LTR are recovered from a dnl4 ${Delta}$ rad51 ${Delta}$ rad52 ${Delta}$ mutant. However, the recovery of Ty1Zeo circles containingbidirectional deletions ending in microhomologies extends previousresults indicating that linear Ty1 cDNA undergoes degradation(43) and suggests a role for HR and NHEJ in forming circularTy1 DNA in wild-type cells (39).

In contrast, cell lines defective for HR and NHEJ genes containmuch lower levels of retroviral two-LTR circles (34, 38, 45).The cellular factors required for forming retroviral one-LTRcircles have not been completely defined. Results from one studysuggest that the RAD50/MRE11/NBS1 nuclease is involved in retroviralone-LTR circle formation, perhaps by exposing single strandsof the repeated LTRs for subsequent HR (38).

Ty1 one-LTR circles may result from reverse transcription intermediatesthat stall after plus-strand strong-stop synthesis or from opencircular intermediates predicted to be present during reversetranscription, as was first proposed for retroviruses (51, 75).Base pairing between the primer binding site (PBS) sequenceson plus-strand strong-stop DNA and the PBS present on the 3'end of minus-strand DNA would produce a one-LTR circle afterdisplacement synthesis by RT or a host polymerase. Lauermannand Boeke (42) showed that Ty1 PPT-initiated plus-strand strong-stopDNA is a dead-end intermediate because sequence variants withinthe PBS are not inherited in a subsequent retrotranspositionevent. Interestingly, these plus-strand reverse transcriptionintermediates are the ones postulated to anneal with the PBSon minus-strand DNA to form one-LTR circles and therefore areprobably involved in the conversion of linear Ty1 DNA into one-LTRcircles. Furthermore, if the cPPT-initiated plus-strand DNAdisplaces PPT-initiated strong-stop DNA and the released primeris utilized to form one-LTR circles, the overall level of circularTy1 DNA should decrease in the cppt-74 mutant. In support ofthis idea, we observed a decrease in the level of circular Ty1DNA and a modest increase in linear Ty1 DNA in the cppt-74 mutant(Fig. 3).

Several studies reported that HIV-1 two-LTR circles are relativelyabundant and can be long-lived (10, 12, 26, 56). Conversely,we show that Ty1 two-LTR circles, as monitored by the presenceof a CJ, are difficult to detect when IN is functional. A totalof 82 PCR products have been sequenced; only 1 contains a canonicalCJ, and 2 others contain small intervening DNA segments betweenthe complete LTRs. The remaining 79 products probably resultfrom Ty1 autointegration events within the LTRs because mostof these products contain the sequence arrangement expectedfor a deletion circle. Furthermore, almost 70% of the LTR junctionmolecules have either canonical CJs or exogenous DNA insertedbetween the complete LTRs when IN is defective. These resultssuggest that the fraction of Ty1 DNA which can undergo eithergenomic integration or autointegration does so rapidly, whilethe remaining Ty1 DNA is degraded or modified by cellular orelement-encoded factors (43, 58). If so, the rapid removal ofintegration-competent DNA from the total pool may result inan overestimate of the fraction of circles, since this signalis compared to the remaining unincorporated Ty1 DNA rather thanthe total pool.

Mules et al. (58) reported that the ends of Ty1 and Ty2 linearDNAs can be altered by the addition of nontemplated bases, whichprobably interferes with IN-mediated integration. A varietyof appended sequences have been found at the ends of linearTy1 extracted from virus-like particles, including C and A residues,5'-CCA-3' or 5'-GGT-3', and sequences from tRNAs for Lys (CUUand UUU), Asp (GUC), Arg (UCU and ACG), Gln (UUG), and Ser (GCU).We have also recovered CJs from unfractionated genomic DNA withsequences at the LTR-LTR junctions indicative of CCA addition,and two partial tRNA Thr (UGU) sequences. These results takentogether suggest that linear Ty1 DNA with modified ends cancircularize to generate two-LTR circles.

Ty1 undergoes high levels of autointegration compared with othermobile genetic elements. Autointegration events comprise 19%of the Ty1 circles that accumulate in cells expressing wild-typeTy1, as determined by Southern analysis of undigested genomicDNA, and almost 70% of the recovered Ty1Zeo circles. Comparableresults have been obtained by characterizing molecular clonesof unincorporated circular Moloney murine leukemia virus (Mo-MuLV)cDNA where about 20% of the clones appeared to derive from autointegrationevents (67). In experiments involving plasmid substrates invivo, Tn10 autointegration events occur at frequencies similarto that of intermolecular transposition (5). Interestingly,Mo-MuLV produces about the same number of inversion and deletionautointegration events (67), while Tn10 forms only inversioncircles (5) and Tn5 forms mostly deletion circles (79). In ouranalyses using Ty1Zeo, deletion circles are recovered much morefrequently than inversion circles. These results suggest thatthe level and type of autointegration events reflect the differentinteractions each mobile genetic element has during the processof integration. For example, the bacteriophage Mu B protein,enhances intermolecular transposition in vitro by activatingDNA strand transfer (50), while the global cellular regulatorH-NS promotes intermolecular transposition of Tn10 by helpingmaintain the preintegration complex in an unfolded state (78).Retroviruses have coopted the nuclear envelope proteins BAF,LAP2 ${alpha}$ , and emerin that act to compact retroviral DNA, reduceautointegration, and stimulate the association between the preintegrationcomplex and target DNA to promote intermolecular integration(33, 73). Ty1 autointegration is also likely to have specialrequirements, since the Ty1 preintegration complex normallyrecognizes features of chromatin extending from genes transcribedby RNA polymerase III (7), and as is evident from our work,there is an autointegration preference associated with the cPPT.

What promotes Ty1 autointegration downstream of the cPPT? Weshow that many autointegration events overlap the Ty1 centraltermination sequence, which contains signals that cause plus-strandsynthesis to terminate over a 130-nucleotide A+T-rich region(30). Moreover, Ty1 autointegration events show the same weakpreference for AT-rich sequences as do insertions at "cold"chromosomal targets, such as the CAN1 gene (46, 62, 83). Wepropose that the Ty1 preintegration complex recognizes the DNAflap structures resulting from cPPT-primed DNA synthesis andautointegrates at, or just downstream of, the displaced plusstrand within the CTS (Fig. 1). In addition, compilations oflarge numbers of retroviral insertion sites from several studieshave identified weak DNA palindromes as a targeting determinantfor HIV-1, simian immunodeficiency virus, Mo-MuLV, and aviansarcoma-leukosis virus (reference 85 and references therein),and the unpaired stems of a DNA cruciform, which are structurallyrelated to palindromes, are hot spots for retroviral integrationin vitro using INs from HIV-1 and avian sarcoma virus (35).It will be interesting to determine whether DNA flap structuresalso create hot spots for Ty1 integration in vitro.

Could DNA flap structures influence Ty1 integration elsewherein the genome? Ty1 integrates at preferred locations at sitesnear active RNA polymerase III transcription and is influencedby alterations in the TFIIIB subunit Bdp1 and the Isw2 and Set3chromatin-remodeling complexes (3, 57). There are less favoredsites for Ty1 integration in the promoter regions of genes transcribedby RNA polymerase II and within coding sequences (6). If DNAstructure is a component of Ty1 target site specificity, thenspecialized DNA structures, such as transcription bubbles andDNA flaps created by replication, could also be targeting determinants.However, additional nucleolytic processing would be requiredto complete Ty1 integration if the branch point of a DNA flapis a targeting determinant (Fig. 1). In addition, cellular Ty1modulators involved in processing special DNA structures, suchas the RecQ family helicase SGS1 (11) and the Fen-1 endonucleaseRAD27 (72), or in transcription elongation, such as the Elongatorcomplex subunits ELP2-4, ELP6, and IKI3 may alter target sitespecificity throughout the genome (28, 64).

Alternatively, a link between the central DNA flap and nuclearimport of the HIV-1 preintegration complex has been reported,where HIV-1 mutants lacking the central DNA flap exhibit a nuclearimport defect (87). One idea put forth by Zennou et al. (87)is that the central DNA flap allows the retroviral DNA to foldduring IN multimerization and this configuration facilitatesnuclear entry. If linear Ty1 DNA is folded in a similar way,then the central DNA flap, IN, and the element's termini maybe brought together, creating an autointegration preferenceadjacent to the cPPT. An attractive feature of this model isthat Ty1 IN contains the nuclear localization signal requiredfor nuclear entry and retrotransposition (37, 54). Two predictionsof this type of nuclear import model are that cPPT and NLS mutationsshould both confer similar defects in the level of Ty1 retrotranspositionand that nuclear import may be required for autointegrationhot spot activity. Our results show that the cppt-74 mutantdoes not phenocopy the NLS-defective in-K596,597G mutant, whichhas a transposition defect of over 200-fold (54). The autointegrationpreference adjacent to the cPPT also is not epistatic to nuclearimport, since this hot spot persists in the in-K596,597G mutant.Therefore, our results do not support a role for the centralDNA flap in nuclear import of the Ty1 preintegration complex.Along these lines, other reports suggest that the HIV-1 centralDNA flap is not required for nuclear import (19, 48).

In addition to the cPPT region and associated DNA flap structures,preferential sites for autointegration may exist elsewhere inTy1 that have escaped detection by replicon rescue of Ty1Zeoelements. If the cPPT is responsible for most of the Ty1 autointegrationcircles detected by Southern analysis of undigested genomicDNA (Fig. 3), then the cppt-74 mutant should contain fewer autointegrationcircles. However, the level of overall autointegration eventsremains about the same in the WT (19%) and cppt-74 mutant (26%)(Fig. 3), even though Ty1Zeo autointegration events decreasethreefold in the cppt-74 mutant (Table 1). One class of autointegrationevents that may be underrepresented using the Ty1Zeo recoveryassay includes those that occur in the LTRs, which are detectedby PCR in cells containing functional IN (Fig. 4). More-detailedanalysis of the autointegration circles will be required touncover additional preferential integration sites.

The presence of active cPPT priming and CTS termination sitesin diverse retroelements, such as HIV-1 and Ty1, strongly suggeststhat producing two distinct DNA segments separated by a DNAflap may offer a selective advantage. cPPT/CTS mutants replicateor retrotranspose at lower levels than wild-type elements do,but the mechanism through which replication of these mutantsis impaired is not fully understood. One problem is that cPPTmutations can apparently cause relatively modest defects onHIV-1 replication (48), which is similar to our results withendogenous Ty1 retrotransposition or with more profound defectson HIV-1 replication (13, 15). Lentiviral vectors appear torespond more uniformly to the presence of the cPPT, where anincrease in efficiency is usually observed (4, 18, 69, 88).A further complication is that the cPPT may provide more thana single advantage for viral or Ty1 replication. For example,the cPPT may protect HIV-1 from DNA editing (86), and the cPPTalso promotes DNA-DNA recombination by HIV-1 RT displacementsynthesis in vitro (22). Whether the cPPT is actually involvedin retroviral or Ty1 recombination in vivo remains to be determined.Ty1 presents an additional possibility, since any selectiveadvantage provided by the cPPT can be offset by autointegrationvia the cPPT, which is a suicidal pathway for Ty1 in the absenceof yeast barrier-to-autointegration factors.

ACKNOWLEDGMENTS

We thank J. Boeke and M. Wilhelm for plasmids and M. Chandler,A. Rattray, and J. Westpheling for helpful discussions.

This work was sponsored by the Center for Cancer Research ofthe National Cancer Institute, Department of Health and HumanServices.

The contents of this publication do not necessarily reflectthe views or policies of the Department of Health and HumanServices, and mentioning trade names, commercial products, ororganizations does not imply endorsement by the U.S. government.

FOOTNOTES

* Corresponding author. Mailing address: National Cancer Institute, P.O. Box B, Frederick, MD 21702-1201. Phone: (301) 846-5604. Fax: (301) 846-6911. E-mail: garfinke{at}ncifcrf.gov.

Published ahead of print on 27 September 2006.

Supplemental material for this article may be found at http://jvi.asm.org/.

REFERENCES

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