DNase protection analysis of retrovirus integrase at the viral DNA ends for full-site integration in vitro.

Retrovirus intasomes purified from virus-infected cells contain the linear viral DNA genome and integrase (IN). Intasomes are capable of integrating the DNA termini in a concerted fashion into exogenous target DNA (full site), mimicking integration in vivo. Molecular insights into the organization of avian myeloblastosis virus IN at the viral DNA ends were gained by reconstituting nucleoprotein complexes possessing intasome characteristics. Assembly of IN-4.5-kbp donor complexes capable of efficient full-site integration appears cooperative and is dependent on time, temperature, and protein concentration. DNase I footprint analysis of assembled IN-donor complexes capable of full-site integration shows that wild-type U3 and other donors containing gain-of-function attachment site sequences are specifically protected by IN at low concentrations (<20 nM) with a defined outer boundary mapping ~20 nucleotides from the ends. A donor containing mutations in the attachment site simultaneously eliminated full-site integration and DNase I protection by IN. Coupling of wild-type U5 ends with wild-type U3 ends for full-site integration shows binding by IN at low concentrations probably occurs only at the very terminal nucleotides (<10 bp) on U5. The results suggest that assembly requires a defined number of avian IN subunits at each viral DNA end. Among several possibilities, IN may bind asymmetrically to the U3 and U5 ends for full-site integration in vitro.

Avian retrovirus DNA internal attachment site requirements for full-site integration in vitro.

Concerted integration of retrovirus DNA termini into the host chromosome in vivo requires specific interactions between the cis-acting attachment (att) sites at the viral termini and the viral integrase (IN) in trans. In this study, reconstruction experiments with purified avian myeloblastosis virus (AMV) IN and retrovirus-like donor substrates containing wild-type and mutant termini were performed to map the internal att DNA sequence requirements for concerted integration, here termed full-site integration. The avian retrovirus mutations were modeled after internal att site mutations studied at the in vivo level with human immunodeficiency virus type 1 (HIV-1) and murine leukemia virus (MLV). Systematic overlapping 4-bp deletions starting at nucleotide positions 7, 8, and 9 in the U3 terminus had a decreasing detrimental gradient effect on full-site integration, while more internal 4-bp deletions had little or no effect. This decreasing detrimental gradient effect was measured by the ability of mutant U3 ends to interact with wild-type U3 ends for full-site integration in trans. Modification of the highly conserved C at position 7 on the catalytic strand to either A or T resulted in the same severe decrease in full-site integration as the 4-bp deletion starting at this position. These studies suggest that nucleotide position 7 is crucial for interactions near the active site of IN for integration activity and for communication in trans between ends bound by IN for full-site integration. The ability of AMV IN to interact with internal att sequences to mediate full-site integration in vitro is similar to the internal att site requirements observed with MLV and HIV-1 in vivo and with their preintegration complexes in vitro.

Retrovirus DNA termini bound by integrase communicate in trans for full-site integration in vitro.

Integration of linear retrovirus DNA involves the concerted insertion of the viral termini (full-site integration) into the host chromosome. We investigated the interactions that occur between long terminal repeat (LTR) termini bound by avian retrovirus integrase (IN) for full-site integration in vitro. Wild-type (wt) or mutant LTR donors that possess gain-of-function ("G") or loss-of-function ("L") for full-site integration activity were used. G LTR termini are characterized as having significantly higher strand transfer activity than the wt and the L LTR termini. L LTR mutations are classified as partially or extremely defective for strand transfer activity. The L mutations were further classified by their ability to either permit or block the assembly of G or wt LTR termini into nucleoprotein complexes capable of full-site strand transfer. We demonstrated that avian myeloblastosis virus IN bound to G LTR termini increased the incorporation of partially defective L LTR termini into nucleoprotein complexes that were capable of full-site integration. The observed full-site integration activity of these assembled nucleoprotein complexes appeared to be influenced by each individual IN-LTR complex in trans. In contrast, extremely defective L LTR termini exhibited the ability to effectively block the assembly of wt LTR termini into nucleoprotein complexes capable of full-site strand transfer. Data from nonspecific DNA competition experiments suggested that IN had an apparent higher affinity for G LTR donor termini than for partially defective L LTR donor termini as measured by full-site integration activity. However, assembled nucleoprotein complexes containing either two G or two L LTR donors were stable, having a similar half-life of approximately 2 h on ice. The results suggest that LTR termini bound by IN exhibit an allosteric effect to modulate full-site integration in vitro. Similar regulatory controls also appear to exist in vivo between the wt U3 and wt U5 LTR termini in retroviruses as well as purified retrovirus preintegration complexes that promoted full-site integration in vitro.

Purification of recombinant Rous sarcoma virus integrase possessing physical and catalytic properties similar to virion-derived integrase.

Recombinant Rous sarcoma virus integrase cloned from the Prague A (PrA) virus strain was expressed in Escherichia coli. Here we report the detailed purification procedure resulting in an apparently homogeneous integrase. Recombinant PrA integrase was compared at both the protein structural and the catalytic levels to avian myeloblastosis virus integrase purified from virions. Both proteins exist minimally in a dimeric state at low nanomolar concentrations as analyzed by glycerol gradient sedimentation and protein crosslinking studies. Likewise, both proteins have similar specific activities for full-site (concerted integration reaction) and half-site strand transfer activities using linear 480-bp retrovirus-like donor substrates that contain wild-type or mutant termini. They respond similarly to high NaCl concentrations ( approximately 350 mM) as well as aprotic solvents for efficient full-site strand transfer. The data suggest that recombinant integrase proteins with physical and catalytic properties similar to the virion counterpart can be purified using these techniques and will faithfully and efficiently promote the full-site integration reaction in vitro.

Avian retrovirus U3 and U5 DNA inverted repeats. Role Of nonsymmetrical nucleotides in promoting full-site integration by purified virion and bacterial recombinant integrases.

The U3 and U5 termini of linear retrovirus DNA contain imperfect inverted repeats that are necessary for the concerted insertion of the termini into the host chromosome by viral integrase. Avian myeloblastosis virus integrase can efficiently insert the termini of retrovirus-like DNA donor substrates (480 base pairs) by a concerted mechanism (full-site reaction) into circular target DNA in vitro. The specific activities of virion-derived avian myeloblastosis virus integrase and bacterial recombinant Rous sarcoma virus (Prague A strain) integrase (approximately 50 nM or less) appear similar upon catalyzing the full-site reaction with 3'-OH recessed wild type or mutant donor substrates. We examined the role of the three nonsymmetrical nucleotides located at the 5th, 8th, and 12th positions in the U3 and U5 15-base pair inverted repeats for their ability to modify the full-site and simultaneously, the half-site strand transfer reactions. Our data suggest that the nucleotide at the 5th position appears to be responsible for the 3-5-fold preference for wild type U3 ends over wild type U5 ends by integrase for concerted integration. Additional mutations at the 5th or 6th position, or both, of U3 or U5 termini significantly increased (approximately 3 fold) the full-site reactions of mutant donors over wild type donors.

Host site selection for concerted integration by human immunodeficiency virus type-1 virions in vitro.

Host site selection for full-site integration by human immunodeficiency virus type-1 (HIV-1) intergrase (IN) from nonionic detergent-lysed virions was investigated. Linear retrovirus-like DNA (469 bp) possessing 3' OH recessed long terminal repeat termini was efficiently inserted by a bimolecular donor reaction into a supercoiled DNA target (2867 bp), producing the HIV-1 5-bp host site duplication. Sequence data were analyzed from 193 donor-target recombinants obtained from the linear 3.8-kb DNA product. The selection of host target sites appeared randomly distributed and was independent of lysis and assay conditions. The fidelity of the 5-bp duplications in comparison to other size duplications was highest (94%) with high-salt (300 mM NaCl) lysis of the virions and 60 mM NaCl for strand transfer using Mg2+ as the divalent cation. Base sequence analysis demonstrated some biases in the 5-bp duplications at the sites of strand transfer and at the immediate host sequences surrounding the duplications. In addition to the observed duplications, approximately 30% of the recombinants isolated from the linear 3.8-kb DNA product contained specific and repetitive small-size deletions. No deletions smaller that 17 bp were observed and the distance between the deletion sets had a periodicity of approximately 10 bp. The mechanisms involved in how HIV-1 IN produces the 5-bp duplications and the repetitive host site deletions are discussed.

Assembly and catalytic properties of retrovirus integrase-DNA complexes capable of efficiently performing concerted integration.

The in vitro assembly process for forming nucleoprotein complexes containing linear retrovirus-like DNA and integrase (IN) was investigated. Solution conditions that allowed avian myeloblastosis virus IN to efficiently pair two separate linear DNA fragments (each 487 bp in length) containing 3' OH recessed long terminal repeat termini were established. Pairing of the viral termini by IN during preincubation on ice permitted these nucleoprotein complexes to catalyze the concerted insertion of the two termini into a circular DNA target (full-site reaction), mimicking the in vivo reaction. The three major solution determinants were high concentrations of NaCl (0.33 M), 1,4-dioxane, and polyethylene glycol. The aprotic solvent dioxane (15%) was significantly better (sixfold) than 15% dimethyl sulfoxide for forming complexes capable of full-site rather than half-site integration events. Half-site reactions by IN involved the insertion of a single donor terminus into circular pGEM. Although NaCl was essential for the efficient promotion of the concerted integration reaction, dioxane was necessary to prevent half-site reactions from occurring at high NaCl concentrations. Under optimal solution conditions, the concerted integration reaction was directly proportional to a sixfold range of IN. The complexes appeared not to turn over, and few half-site donor-donor molecules were produced. In the presence of 0.15 or 0.35 M NaCl, dioxane prevented efficient 3' OH trimming of a blunt-ended donor by IN, suggesting that the complexes formed by IN with blunt-ended donors were different from those formed with donors containing 3' OH recessed termini for strand transfer. The results suggest that IN alone was capable of protein-protein and protein-DNA interactions that efficiently promote the in vitro concerted integration reaction.

Efficient concerted integration of retrovirus-like DNA in vitro by avian myeloblastosis virus integrase.

We report the efficient concerted integration of a linear virus-like DNA donor into a 2.8 kbp circular DNA target by integrase (IN) purified from avian myeloblastosis virus. The donor was 528 bp, contained recessed 3' OH ends, was 5' end labeled, and had a unique restriction site not found in the target. Analysis of concerted (full-site) and half-site integration events was accomplished by restriction enzyme analysis and agarose gel electrophoresis. The donor also contained the SupF gene that was used for genetic selection of individual full-site recombinants to determine the host duplication size. Two different pathways, involving either one donor or two donor molecules, were used to produce full-site recombinants. About 90% of the full-site recombinants were the result of using two donor molecules per target. These results imply that juxtapositioning an end from each of two donors by IN was more efficient than the juxtapositioning of two ends of a single donor for the full-site reaction. The formation of preintegration complexes containing integrase and donor on ice prior to the addition of target enhanced the full-site reaction. After a 30 min reaction at 37 degrees C, approximately 20-25% of all donor/target recombinants were the result of concerted integration events. The efficient production of full-site recombinants required Mg2+; Mn2+ was only efficient for the production of half-site recombinants. We suggest that these preintegration complexes can be used to investigate the relationships between the 3' OH trimming and strand transfer reactions.

Retroviral integration: in vitro host site selection by avian integrase.

Viral integrase catalyzes the integration of the linear viral DNA genome into the chromatin of the infected host cell, an essential step in the life cycle of retroviruses. The reaction produces a characteristic small duplication of host sequences at the site of integration, implying that there is a close juxtaposition of the viral DNA ends during a concerted integration event. We have used an in vitro assay to measure the concerted integration of virus-like plasmid DNA into naked lambda DNA catalyzed by virion purified avian integrase. In contrast to in vivo avian integration, which has strong fidelity for a 6-bp duplication, purified avian integrase in the context of this assay produced a distribution of duplication sizes, with the 6-bp size dominating. The metal cofactor Mg2+ induced increased fidelity for the 6-bp duplication relative to that with Mn2+. The immediate sequence of the host site may also influence duplication size in that we found sites that sustained multiple independent integration events producing the same duplication size. Additionally, for each set of cloned integration sites (5, 6, and 7 bp), a unique but similar symmetrical pattern of G/C and A/T sequence biases was found. Using duplex oligonucleotides as target substrates, we tested the significance of the 6-bp G/C and A/T pattern for site selection. In the context of this assay, which is likely dominated by the integration of only one viral end, the 6-bp pattern was not preferred. Instead, integration was predominantly into the 3' ends of the oligonucleotides. The combined results of the lambda and oligonucleotide assays indicated that although host site selection has properties in common with recognition of the viral DNA termini, the nonrandom sequence preferences seen for host site selection were not identical to the sequence requirements for long terminal repeat recognition.

Folding of the multidomain human immunodeficiency virus type-I integrase.

Protein folding conditions were established for human immunodeficiency virus integrase (IN) obtained from purified bacterial inclusion bodies. IN was denatured by 6 M guanidine.HCl-5 mM dithiothreitol, purified by gel filtration, and precipitated by ammonium sulfate. The reversible solvation of precipitated IN by 6 M guanidine.HCl allowed for wide variation of protein concentration in the folding reaction. A 6-fold dilution of denatured IN by 1 M NaCl buffer followed by dialysis produced enzymatically active IN capable of 3' OH end processing, strand transfer, and disintegration using various human immunodeficiency virus-1 (HIV-1) long terminal repeat DNA substrates. The specific activities of folded IN preparations for these enzymatic reactions were comparable to those of soluble IN purified directly from bacteria. The subunit composition and enzymatic activities of IN were affected by the folding conditions. Standard folding conditions were defined in which monomers and protein aggregates sedimenting as dimers and tetramers wree produced. These protein aggregates were enzymatically active, whereas monomers had reduced strand transfer activity. Temperature modifications of the folding conditions permitted formation of mainly monomers. Upon assaying, these monomers were efficient for strand transfer and disintegration, but the oligomeric state of IN under the conditions of the assay is determinate. Our results suggest that monomers of the multidomain HIV-1 IN are folded correctly for various catalytic activities, but the conditions for specific oligomerization in the absence of catalytic activity are undefined.

Comparison of DNA binding and integration half-site selection by avian myeloblastosis virus integrase.

Insertion of the linear retrovirus DNA genome into the host DNA by the virus-encoded integrase (IN) is essential for efficient replication. We devised an efficient virus-like DNA plasmid integration assay which mimics the standard oligonucleotide assay for integration. It permitted us to study, by electron microscopy and sequence analysis, insertion of a single long terminal repeat terminus (LTR half-site) of one plasmid into another linearized plasmid. The reaction was catalyzed by purified avian myeloblastosis virus IN in the presence of Mg2+. The recombinant molecules were easily visualized and quantitated by agarose gel electrophoresis. Agarose gel-purified recombinants could be genetically selected by transformation of ligated recombinants into Escherichia coli HB101 cells. Electron microscopy also permitted the identification and localization of IN-DNA complexes on the virus-like substrate in the absence of the joining reaction. Intramolecular and intermolecular DNA looping by IN was visualized. Although IN preferentially bound to AT-rich regions in the absence of the joining reaction, there was a bias towards GC-rich regions for the joining reaction. Alignment of 70 target site sequences 5' of the LTR half-site insertions with 68 target sites previously identified for the concerted insertion of both LTR termini (LTR full-site reaction) indicated similar GC inflection patterns with both insertional events. Comparison of the data suggested that IN recognized only half of the target sequences necessary for integration with the LTR half-site reaction.

Concerted integration of viral DNA termini by purified avian myeloblastosis virus integrase.

Concerted integration of retroviral DNA termini, which produces a characteristic duplication of sequences at the integration site and formation of the proviral state, is a necessary step of the retroviral life cycle. We investigated the pairwise integration reaction catalyzed by purified avian retrovirus integrase by measuring the response to solution parameters and how the sequences of the viral termini, which comprise the avian imperfect inverted repeat, affect the reaction. When we optimized the reaction, an efficiency was achieved which approached that measured in systems using cytoplasmic extracts from virus-infected cells. The response of purified avian integrase to solution parameters was similar to that of the integration activity derived from cellular extracts. For strand transfer, the U3 viral terminal sequences were preferred to those of the U5 termini, a result we previously showed for the trimming reaction. That the sequence preference was the same for trimming and strand transfer may be further evidence that only one catalytic site is used for both reactions. A significant number of integration sites were sequenced. Interesting trends were found for the fidelity of the host duplications to the avian 6-bp duplication size, the clustering of the integration sites in the nonessential region of the lambda host DNA, and the sequence characteristics of the duplication sites.

Characterization of a stable eukaryotic cell line expressing the Rous sarcoma virus integrase.

The Rous sarcoma virus integration protein (IN) is required for efficient integration of viral DNA into the host genome. IN was expressed in mouse C127 cells using a bovine papillomavirus vector. This system utilizes the mouse metallothionein promoter and the SV40 late polyadenylation signal for efficient expression of IN. A stable cell line derived from a single hygromycin-resistant colony was characterized. The expression of IN increased significantly upon Zn2+ induction of the metallothionein promoter, but did not respond to "superinduction" protocols. Full-length nonphosphorylated IN was the major product of expression. A minor product resulting from initiation of translation at an internal Met codon was also produced. The expressed IN did not exhibit the polypeptide heterogeneity at its COOH-terminus nor phosphorylation as is seen when IN is immunoprecipitated from virions. Using subcellular fractionation and indirect immunofluorescence, IN was primarily localized to nuclei and in some cells appeared to concentrate at discrete loci within the nuclei.

v-Src enhances phosphorylation at Ser-282 of the Rous sarcoma virus integrase.

The Rous sarcoma virus (RSV) integrase (IN) and the beta polypeptide (beta) of the reverse transcriptase are posttranslationally modified by phosphorylation on Ser at amino acid position 282 of IN. When IN was immunoprecipitated from RSV (Prague A strain) virions, approximately 30 to 40% of the IN molecules were phosphorylated. When IN was immunoprecipitated from a v-src deletion mutant (delta Mst-A) of RSV or from avian myeloblastosis virus (AMV), the percentage of IN molecules that were phosphorylated was significantly reduced. This reduction in phosphorylation of IN between virions was verified by [35S]Met-[35S]Cys or 32P labeling of IN, followed by immunoprecipitation analysis using antisera directed to the amino or carboxyl terminus of IN. In delta Mst-A or AMV, a nonphosphorylated, slightly truncated (at the carboxyl terminus) polypeptide was the major species of IN. The enhanced phosphorylation of IN does not appear to be a general function of transformed cells, since enhanced phosphorylation was not detected in AMV derived from viremic chickens or from a v-src deletion mutant of RSV propagated in a chemically transformed quail cell line, QT6. From these data, we conclude that v-Src is necessary for efficient phosphorylation of IN and beta.

Development of an acid-soluble assay for measuring retrovirus integrase 3'-OH terminal nuclease activity.

A quantitative and efficient assay was developed to measure the 3'-OH terminal DNA endonuclease activity of the avian myeloblastosis virus (AMV) integrase protein. A retroviral-like linearized plasmid containing long terminal repeat (LTR) sequences at its recessed 3'-OH termini was filled in and labeled with the Escherichia coli Klenow DNA polymerase fragment. The 32P-labeled nucleotide was located at the penultimate position. The labeled linearized plasmid or restriction fragments derived from it were incubated with AMV IN and release of the label was quantitated by conversion to acid-soluble counts. The structure of the released product was characterized on 23% sequencing gels. Results indicate that AMV integration protein is functioning as an endonuclease releasing a dinucleotide and that the activity is stoichiometric with a preference for the cleavage of the U3 LTR terminus over that of the U5 LTR terminus.

Retrovirus integrase: identification of a potential leucine zipper motif.

The secondary structure of the retrovirus integration protein (IN) was predicted from seven inferred retrovirus IN sequences. The IN sequences were aligned by computer and the phylogenetic relationships between them were determined. The secondary structure of the aligned IN sequences was predicted by two consensus prediction methods. The predicted secondary structural patterns from the two consensus prediction schemes were compared with and superimposed on a composite structural profile of hydropathic/chain flexibility/amphipathic indexes with each index profile being calculated independently for the aligned IN sequences. The use of this composite structural profile not only enhanced the prediction accuracy but also helped in defining the surface loop regions which would be otherwise unpredictable by the use of consensus prediction methods alone. An amphipathic helix was identified by these united structural prediction-chain property profiles. Helical wheel analysis gave the amphipathic helix a coiled-coil like pattern which was similar to the leucine zipper discovered for some eukaryotic gene regulatory proteins. The proposed amphipathic helix may play an essential role in defining the biological properties of IN.

Phosphorylation of the avian retrovirus integration protein and proteolytic processing of its carboxyl terminus.

The integration protein (IN) of the Prague A strain of Rous sarcoma virus (RSV) was analyzed by high-resolution sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Three polypeptides of similar proportions and molecular mass (32 kDa) were immunoprecipitated by an antiserum directed against the first 10 amino acids of the amino terminus of IN. However, the faster-migrating nonphosphorylated polypeptide was not immunoprecipitated by two different polyclonal antisera directed against the last 11 amino acids of the carboxyl terminus of IN. These results suggest that the faster-migrating species was proteolytically processed at its carboxyl terminus. RSV IN is phosphorylated on an S residue located five amino acids from its carboxyl terminus. Two different missense mutations at this S residue resulted in the isolation of slow-growing viable mutants whose phenotypes were stable. Each mutation at residue 282 eliminated both major phosphorylated-Ser-containing tryptic peptides observed with wild-type IN. An S----F mutation resulted in the conversion of all IN polypeptides to one species that was not precipitable by carboxyl-terminal antisera, suggesting that this amino acid transition promoted proteolysis at the carboxyl terminus. An S----D mutation resulted in the recovery of one major (greater than 95%) slower-migrating polypeptide that was immunoprecipitated by carboxyl-terminal antisera, suggesting that this negatively charged D residue (similar to phosphorylated Ser) inhibited proteolysis. Modification of the S residue at amino acid 262 to R had no apparent effect on the proteolytic processing or phosphorylation of IN.

Defining nucleic acid-binding properties of avian retrovirus integrase by deletion analysis.

Integration of retroviral DNA into the host genome requires the activity of retrovirus-encoded integration protein IN. We expressed Rous sarcoma virus (RSV) IN, 286 amino acid residues in length, by using in vitro transcription, followed by in vitro translation in rabbit reticulocyte lysate. The nucleic acid-binding activity of in vitro-translated IN was assessed by using DNA-cellulose affinity chromatography and poly(U)-Sepharose affinity chromatography and by sedimentation analysis in the presence or absence of DNA. In vitro-translated RSV IN exhibited nucleic acid-binding activity similar to that of IN purified from avian myeloblastosis virus. To identify regions of IN which bind to nucleic acids, several deletions of RSV IN were generated. The NH2-terminal 26 amino acids, including the two His residues of a His-Cys box, were not necessary for IN nucleic acid binding with any of the substrates tested. The substrates included native calf thymus DNA, poly(U), and a double-stranded linear DNA molecule with RSV long terminal repeat sequences at its termini. The COOH-terminal region (residues 178 to 286) of IN bound quantitatively (greater than 90%) to poly(U) and to single-stranded circular phi X174 DNA but did not exhibit the double-stranded linear DNA-binding ability of the entire IN molecule.

Removal of 3'-OH-terminal nucleotides from blunt-ended long terminal repeat termini by the avian retrovirus integration protein.

The avian myeloblastosis virus integration protein (IN) was capable of removing a specific set of 3'-OH-terminal nucleotides from blunt-ended long terminal repeat (LTR) substrates which resembled linear viral DNA in vivo. The 3'-OH-recessed ends map to the in vivo site of integration on linear viral DNA. The linear DNA plasmid substrate was formed by the generation of a unique DraI restriction enzyme site (TTT/AAA) at the circle junction of a 330-bp tandem LTR-LTR insert. IN preferentially released the three T nucleotides from the minus strand of the U3 LTR substrate compared with its ability to remove the three T nucleotides from the plus strand of the U5 LTR substrate. It was also observed that IN was capable of cleaving a non-LTR DNA substrate containing sequence homology to the U5 LTR terminus.

Rearrangements in unintegrated retroviral DNA are complex and are the result of multiple genetic determinants.

We used a replication-competent retrovirus shuttle vector based on a DNA clone of the Schmidt-Ruppin A strain of Rous sarcoma virus to characterize rearrangements in circular viral DNA. In this system, circular molecules of viral DNA present after acute infection of cultured cells were cloned as plasmids directly into bacteria. The use of a replication-competent shuttle vector permitted convenient isolation of a large number of viral DNA clones; in this study, over 1,000 clones were analyzed. The circular DNA molecules could be placed into a limited number of categories. Approximately one-third of the rescued molecules had deletions in which one boundary was very near the edge of a long terminal repeat (LTR) unit. Subtle differences in the patterns of deletions in circular DNAs with one versus two copies of the LTR sequence were observed, and differences between deletions emanating from the right and left boundaries of the LTR were seen. A virus with a missense mutation in the region of the pol gene responsible for integration and exhibiting a temperature sensitivity phenotype for replication had a marked decrease in the number of rescued molecules with LTR-associated deletions when infection was performed at the nonpermissive temperature. This result suggests that determinants in the pol gene, possibly in the integration protein, play a role in the generation of LTR-associated deletions. Sequences in a second region of the genome, probably within the viral gag gene, were also found to affect the types of circular viral DNA molecules present after infection. Sequences in this region from different strains of avian sarcoma-leukosis viruses influenced the fraction of circular molecules with LTR-associated deletions, as well as the relative proportion of circular molecules with either one or two copies of the LTR. Thus, the profile of rearrangements in unintegrated viral DNA is complex and dependent upon the nature of sequences in the gag and pol regions.