Alternative excision products originating from a single integration of polyomavirus DNA.

The Cyp cell line consists of mouse cells transformed by a thermosensitive polyomavirus (Py) genome and routinely propagated at 39 degrees C. Cyp cells are readily induced to synthesize free Py DNA by being transferred to 33 degrees C. In one subclone (C12/a1/S48, or S48) of this line, such induction resulted in the intracellular accumulation of three discrete species of cyclic DNA, i.e., genomic Py DNA, RmI, and RmII. RmI and RmII are Py-mouse chimeras, each of which contains a distinct set of sequences originating from the site of integration. Conceivably, genomic Py DNA, RmI, and RmII could persist at 39 degrees C as free replicating plasmids or originate from distinct populations of cells in S48 cultures. The data indicated that all three species arise at 33 degrees C from a genetically homogeneous cell population in which neither RmI nor RmII replicates at 39 degrees C. Examination of the sequence at the viral-cellular junction unique to RmII indicated that this chimera is excised from the host chromosome through a recombination event involving a complex viral sequence and a simple cellular sequence. Therefore, RmII provides another example of precise recombination occurring between nonhomologous sequences in a mammalian cell, as already observed for RmI (B. S. Sylla, D. Huberdeau, D. Bourgaux-Ramoisy, and P. Bourgaux, Cell 37:661-667, 1984).     

Transduction of c-src coding and intron sequences by a transformation-defective deletion mutant of Rous sarcoma virus.

The mechanism of cellular src (c-src) transduction by a transformation-defective deletion mutant, td109, of Rous sarcoma virus was studied by sequence analysis of the recombinational junctions in three td109-derived recovered sarcoma viruses (rASVs). Our results show that two rASVs have been generated by recombination between td109 and c-src at the region between exons 1 and 2 defined previously. Significant homology between td109 and c-src sequences was present at the sites of recombination. The viral and c-src sequence junction of the third rASV was formed by splicing a cryptic donor site at the 5' region of env of td109 to exon 1 of c-src. Various lengths of c-src internal intron 1 sequences were incorporated into all three rASV genomes, which resulted from activation of potential splice donor and acceptor sites. The incorporated intron 1 sequences were absent in the c-src mRNA, excluding its being the precursor for recombination with td109 and implying that initial recombinations most likely took place at the DNA level. A potential splice acceptor site within the incorporated intron 1 sequences in two rASVs was activated and was used for the src mRNA synthesis in infected cells. The normal env mRNA splice acceptor site was used for src mRNA synthesis for the third rASV.     

Patch homologies and the integration of adenovirus DNA in mammalian cells.

The hamster cell line HE5 has been derived from primary hamster embryo cells by transformation with human adenovirus type 2 (Ad2). Each cell contains 2-3 copies of Ad2 DNA inserted into host DNA at apparently identical sites. The site of the junction between the right terminus of Ad2 DNA and hamster cell DNA was cloned and sequenced. The eight [corrected] right terminal nucleotides of Ad2 DNA were deleted. The unoccupied cellular DNA sequence in cell line HE5 , corresponding to the site of the junction between Ad2 and hamster cell DNA, was also cloned; 120-130 nucleotides in the cellular DNA were found to be identical to the cellular DNA sequence in the cloned junction DNA fragment, up to the site of the junction. The unoccupied and the occupied cellular DNAs and the adjacent viral DNA exhibited a few short nucleotide homologies. Patch homologies ranging in length from dodeca - to octanucleotides were detected by computer analyses at locations more remote from the junction site. When the right terminal nucleotide sequence of Ad2 DNA was matched to randomly selected sequences of 401 nucleotides from vertebrate or prokaryotic DNA, similar homologies were observed. It is likely that foreign (viral) DNA can be inserted via short sequence homologies at many different sites of cellular DNA.     

Long terminal repeat of murine retroviral DNAs: sequence analysis, host-proviral junctions, and preintegration site.

The nucleotide sequence of the long terminal repeat (LTR) of three murine retroviral DNAs has been determined. The data indicate that the U5 region (sequences originating from the 5' end of the genome) of various LTRs is more conserved than the U3 region (sequences from the 3' end of the genome). The location and sequence of the control elements such as the 5' cap, "TATA-like" sequences, "CCAAT-box," and presumptive polyadenylic acid addition signal AATAAA in the various LTRs are nearly identical. Some murine retroviral DNAs contain a duplication of sequences within the LTR ranging in size from 58 to 100 base pairs. A variant of molecularly cloned Moloney murine sarcoma virus DNA in which one of the two LTRs integrated into the viral DNA was also analyzed. A 4-base-pair duplication was generated at the site of integration of LTR in the viral DNA. The host-viral junction of two molecularly cloned AKR-murine leukemia virus DNAs (clones 623 and 614) was determined. In the case of AKR-623 DNA, a 3- or 4-base-pair direct repeat of cellular sequences flanking the viral DNA was observed. However, AKR-614 DNA contained a 5-base-pair repeat of cellular sequences. The nucleotide sequence of the preintegration site of AKR-623 DNA revealed that the cellular sequences duplicated during integration are present only once. Finally, a striking homology between the sequences flanking the preintegration site and viral LTRs was observed.     

Integration of viral DNA into the genome of the adenovirus type 2-transformed hamster cell line HE5 without loss or alteration of cellular nucleotides

Hamster cell line HE5 has been established from primary LSH hamster embryo cells by transformation with adenovirus type 2 (Ad2) (1). Each cell contains two to three copies of integrated Ad2 DNA (2, 3). We cloned and sequenced the sites of junction between viral and cellular DNAs. The terminal 10 and 8 nucleotides of Ad2 DNA were deleted at the left and right sites of junction, respectively. The integrated viral DNA had an internal deletion between map units 35 and 82 on the Ad2 genome. At the internal site of deletion, the remaining viral sequences were linked via a GT dinucleotide of unknown origin. From HE5 DNA, the unoccupied sequence corresponding to the site of insertion was also cloned and sequenced. Part of this sequence was shown to be expressed as cytoplasmic RNA in HE5 and primary LSH hamster embryo cells. The viral DNA had been inserted into cellular DNA without deletions, rearrangements or duplications of cellular nucleotides at the site of insertion. Thus, insertion of Ad2 DNA appeared to have been effected by a mechanism different from that of bacteriophage lambda in Escherichia coli and from that of retroviral genomes in vertebrates. It was conceivable that the terminal viral protein (4) was somehow involved in integration either on a linear or a circularized viral DNA molecule.     

Features of two hepatitis B virus (HBV) DNA integrations suggest mechanisms of HBV integration.

Two integrated hepatitis B virus (HBV) DNA molecules were cloned from two primary hepatocellular carcinomas each containing only a single integration. One integration (C3) contained a single linear segment of HBV DNA, and the other integration (C4) contained a large inverted duplication of viral DNA at the site of a chromosome translocation (O. Hino, T.B. Shows, and C.E. Rogler, Proc. Natl. Acad. Sci. USA 83:8338-8342, 1986). Sequence analysis of the virus-cell junctions of C3 placed the left virus-cell junction at nucleotide 1824, which is at the 5' end of the directly repeated DR1 sequence and is 6 base pairs from the 3' end of the long (L) negative strand. The right virus-cell junction was at nucleotide 1762 in a region of viral DNA (within the cohesive overlap) which shared 5-base-pair homology with cellular DNA. Sequence analysis of the normal cellular DNA across the integration site showed that 11 base pairs of cellular DNA were deleted at the site of integration. On the basis of this analysis, we suggest a mechanism for integration of the viral DNA molecule which involves strand invasion of the 3' end of the L negative strand of an open circular or linear HBV DNA molecule (at the DR1 sequence) and base pairing of the opposite end of the molecule with cellular DNA, accompanied by the deletion of 11 base pairs of cellular DNA during the double recombination event. Sequencing across the inverted duplication of HBV DNA in clone C4 located one side of the inversion at nucleotide 1820, which is 2 base pairs from the 3' end of the L negative strand. Both this sequence and the left virus-cell junction of C3 are within the 9-nucleotide terminally redundant region of the HBV L negative strand DNA. We suggest that the terminal redundancy is a preferred topoisomerase I nicking region because of both its base sequence and forked structure. Such nicking would lead to integration and rearrangement of HBV molecules within the terminal redundancy, as we have observed in both our clones.     

Molecular characterization of transforming plasmid rearrangements in transgenic rice reveals a recombination hotspot in the CaMV 35S promoter and confirms the predominance of microhomology mediated recombination

The characterization of plasmid-genomic DNA junctions following plant transformation has established links between DNA double-strand break repair (DSBR), illegitimate recombination and plasmid DNA integration. The limited information on plasmid-plasmid junctions in plants comes from the dicot species tobacco and Arabidopsis. We analyzed 12 representative transgenic rice lines, carrying a range of transforming plasmid rearrangements, which predominantly reflected microhomology mediated illegitimate recombination involving short complementary patches at the recombining ends. Direct end-ligation, in the absence of homology between the recombining molecules, occurred only rarely. Filler DNA was found at some of the junctions. Short, purine-rich tracts were present, either at the junction site or in the immediate flanking regions. Putative DNA topoisomerase I binding sites were clustered around the junctions. Although different regions of the transforming plasmid were involved in plasmid-plasmid recombination, we showed that a 19 bp palindromic sequence, including the TATA box of the CaMV 35S promoter, acted as a recombination hotspot. The purine-rich half of the palindromic sequence was specifically involved at the recombination junctions. This recombination hotspot is located within the 'highly recombinogenic' region of the full-length CaMV RNA that has been shown to promote viral recombination in dicot plants. Clustering of plasmid recombination events in this highly recombinogenic region, even in the absence of viral enzymes and other cis-acting elements proves that the plant cellular machinery alone is sufficient to recognize and act on these viral sequences. Our data also show the similarity between mechanisms underlying junction formation in dicot and monocot plants transformed using different procedures.     

Proof of recombination between viral and cellular genomes in human KB cells productively infected by adenovirus type 12: structure of the junction site in a symmetric recombinant (SYREC)

In previous work we have described a symmetric recombinant (SYREC1) between Ad12 DNA and human KB cell DNA. This recombinant DNA molecule has been generated during productive infection and is encapsidated into virions. From the DNA of a similar symmetric recombinant (termed SYREC2) between the left terminus of Ad12 DNA and human KB cellular DNA, the site of linkage between the two DNAs was cloned and sequenced. It was demonstrated that the first 2081 Ad12 nucleotides counting from the left viral terminus are conserved and linked to a sequence of GC-rich (70.4% G + C) KB cell DNA which occurs about 20 times per cellular genome. Except for a common 5'-CTGGC-3' pentanucleotide between the Ad12 DNA and KB cell DNA sequences, extensive patch homologies were not apparent at the site of junction. Similarly, comparisons of the deleted Ad12 DNA sequence and the cellular sequence replacing it did not reveal patch homologies. The 304 bp abutting the Ad12 terminus were shown to hybridize to KB cell DNA. These results provided definitive proof for the occurrence of recombinants between viral and cellular DNAs in human cells productively infected by Ad12 as previously shown by less direct experiments (Burger and Doerfler, 1974; Schick et al., 1976). Across the site of junction, an open reading frame exists which extends the truncated 54-kDal protein of the E1b region of Ad12 DNA for another 66 amino acids encoded by KB cellular DNA. This sequence is terminated by two UGA translational termination signals. The hypothetical protein has not yet been isolated.     

Specificity of the dRP/AP lyase of Ku promotes nonhomologous end joining (NHEJ) fidelity at damaged ends

Nonhomologous end joining (NHEJ) is essential for efficient repair of chromosome breaks. However, the NHEJ ligation step is often obstructed by break-associated nucleotide damage, including base loss (abasic site or 5'-dRP/AP sites). Ku, a 5'-dRP/AP lyase, can excise such damage at ends in preparation for the ligation step. We show here that this activity is greatest if the abasic site is within a short 5' overhang, when this activity is necessary and sufficient to prepare such termini for ligation. In contrast, Ku is less active near 3' strand termini, where excision would leave a ligation-blocking α,β-unsaturated aldehyde. The Ku AP lyase activity is also strongly suppressed by as little as two paired bases 5' of the abasic site. Importantly, in vitro end joining experiments show that abasic sites significantly embedded in double-stranded DNA do not block the NHEJ ligation step. Suppression of the excision activity of Ku in this context therefore is not essential for ligation and further helps NHEJ retain terminal sequence in junctions. We show that the DNA between the 5' terminus and the abasic site can also be retained in junctions formed by cellular NHEJ, indicating that these sites are at least partly resistant to other abasic site-cleaving activities as well. High levels of the 5'-dRP/AP lyase activity of Ku are thus restricted to substrates where excision of an abasic site is required for ligation, a degree of specificity that promotes more accurate joining.     

Nucleotide sequence at the site of junction between adenovirus type 12 DNA and repetitive hamster cell DNA in transformed cell line CLAC1.

The hamster cell line CLAC1 originated from a tumor induced by injecting human adenovirus type 12 (Ad12) into newborn hamsters. Each cell contained about 12 copies of viral DNA colinearly integrated at two or three different sites. We have cloned and sequenced a DNA fragment comprising the site of junction between the left terminus of Ad12 DNA and cellular DNA. The first 174 nucleotides of Ad12 DNA were deleted at the site of junction. Within 40 nucleotides, there were one tri-, two tetra-, one penta-, and one heptanucleotide which were identical in the 174 deleted viral nucleotides and the cellular sequence replacing them. In addition, there were patch-type homologies ranging from octa- to decanucleotides between viral and cellular sequences. There is no evidence for a model assuming adenovirus DNA to integrate at identical cellular sites. The cellular DNA sequence corresponding to the junction fragment was cloned also from BHK21 (B3) hamster cells and sequenced. Up to the site of linkage with viral DNA, this middle repetitive cellular DNA sequence was almost identical with the equivalent sequence from CLAC1 hamster cells. Taken together with the results of previously published analyses (11, 12), the data suggest a model of viral (foreign) DNA integration by multiple short sequence homologies. Multiple sets of short patch homologies might be recognized as patterns in independent integration events. The model also accounts for the loss of terminal viral DNA sequences.     

Site-specific excision of integrated polyoma DNA

Cyp cells are permissive murine cells carrying a thermosensitive polyoma virus genome that remains integrated at 39 degrees C, but is effectively excised and replicated after transfer to 33 degrees C. In rare subclones of the Cyp line, temperature shift-down yields predominantly homogeneous populations of chimeric molecules that appear to reflect the circularization of defined segments of DNA spanning one of the junctions between the integrated viral genome and the adjacent cellular DNA. Such accurate and frequent excision requires a specific recombination mechanism. We examined both the cellular and the viral sequences that cross-over to generate one of these chimeric molecules, Rm I. The homology at the cross-over site is one of 1 or 2 base pairs at most; patches of homology, amounting in total to 19 or 20 base pairs, are found in perfect register on both sides of this site; and the two stretches of DNA that are joined to form RM I contain similar 12-14 base pair sequences (5'- CTCCTTTACAGAGG -3' and 5'- CTCCTTTCAAGG -3') in opposite orientations.     

Characterization of unintegrated retroviral DNA with long terminal repeat-associated cell-derived inserts.

We have used a replication-competent shuttle vector based on the genome of Rous sarcoma virus to characterize genomic rearrangements that occur during retrovirus replication. The strategy involved cloning circular DNA that was generated during an acute infection. While analyzing a class of retroviral DNA clones that are greater than full length, we found several clones which had acquired nonviral inserts in positions adjacent to the long terminal repeats (LTRs). There appear to be two distinct mechanisms leading to the incorporation of cellular sequences into these clones. Three of the molecules contain a cell-derived insert at the circle junction site between two LTR units. Two of these molecules appear to be the results of abortive integration attempts, because of which, in each case, one of the LTRs is missing 2 bases at its junction with the cell-derived insert. In the third clone, pNO220, the cellular sequences are flanked by an inappropriately placed copy of the tRNA primer-binding site on one side and a partial copy of the U3 sequence as part of the LTR on the other side. A fourth molecule we characterized, pMD96, has a single LTR with a U5-bounded deletion of viral sequences spanning gag and pol, with cell-derived sequences inserted at the site of the deletion; its origin may be related mechanistically to pNO220. Sequence analysis indicates that all of the cellular inserts were derived from the cell line used for the acute infection rather than from sequences carried into the cell as part of the virus particle. Northern (RNA) analysis of cellular RNA demonstrated that the cell-derived sequences of two clones, pNO220 and pMD96, were expressed as polyadenylated RNA in uninfected cells. One mechanism for the joining of viral and cellular sequences suggested by the structures of pNO220 and pMD96 is recombination occurring during viral DNA synthesis, with cellular RNA serving as the template for the acquisition of cellular sequences.     

Transposon-mediated site-specific recombination in vitro: DNA cleavage and protein-DNA linkage at the recombination site

Resolvase, the product of the tnpR gene of the transposable element gamma delta, mediates a site-specific recombination between two copies of the element directly repeated on the same replicon. The resolution site, res, at which resolvase acts lies in the intercistronic region between the tnpA and tnpR genes. We have studied this site-specific recombination in vitro. In the absence of Mg2+, a resolvase-res complex is formed, which contains DNA molecules that have been cleaved at res. Our data suggest that in this complex resolvase is covalently attached to the 5' ends of the cleaved DNA, leaving free 3' hydroxyl groups. DNA cleavage is stimulated by the interaction of two res sites on the same substrate molecule and appears to be an intermediate step in normal res site recombination. We show that the DNA is cut within a region previously identified as containing the crossover point at the palindromic sequence 5'- (see formula in text) to generate 3' extensions of two bases.     

Resolution of undistorted symmetric immobile DNA junctions by vaccinia topoisomerase I

Holliday junctions are intermediates in genetic recombination. They consist of four strands of DNA that flank a branch point. In natural systems, their sequences have 2-fold (homologous) sequence symmetry. This symmetry enables the molecules to undergo an isomerization, known as branch migration, that relocates the site of the branch point. Branch migration leads to polydispersity, which makes it difficult to characterize the physical properties of the junction and the effects of the sequence context flanking the branch point. Previous studies have reported two symmetric junctions that do not branch migrate: one that is immobilized by coupling to an asymmetric junction in a double crossover context, and a second that is based on molecules containing 5',5' and 3',3' linkages. Both are flawed by distorting the structure of the symmetric junction from its natural conformation. Here, we report an undistorted symmetric immobile junction based on the use of DNA parallelogram structures. We have used a series of these junctions to characterize the junction resolution reaction catalyzed by vaccinia virus DNA topoisomerase. The resolution reaction entails cleavage and rejoining at CCCTT/N recognition sites arrayed on opposing sides of the four-arm junction. We find that resolution is optimal when the scissile phosphodiester (Tp/N) is located two nucleotides 5' to the branch point on the helical strand. Covalent topoisomerase-DNA adducts are precursors to recombinant strands in all reactions, as expected. Kinetic analysis suggests a rate limiting step after the first-strand cleavage.     

'Illegitimate' recombination events in polyoma-transformed rat cells

In the LPT line of polyoma (Py)-transformed rat cells, amplification of the integrated viral DNA and of cell nucleotide sequences flanking the viral integration site, can be induced either spontaneously or by treatment with carcinogens. We show here that the amplified DNA includes interspersed viral and cellular sequences generated by 'illegitimate' recombination events. Genomic libraries have been prepared in phage lambda vectors from LPT cells treated with the inducing agent mitomycin C and from untreated LPT cells. Four phages, including viral-cell DNA recombinants, have been isolated from these libraries. Sequencing through the recombination sites revealed the following characteristics: (i) The crossover points map at four different positions in the viral DNA and at four different positions in the flanking cell DNA. (ii) There are very short homologous sequences of 1, 2, or 4 bp, at the recombination sites. (iii) Aside from the exchanges between the viral and the cellular DNA, no further rearrangements occurred around the new viral-cellular DNA junctions. (iv) Next to the recombination sites, there are blocks of homopurine-homopyrimidine sequences, which may assume a structure that differs from the Watson-Crick double helix. (v) Clustered homologous sequence blocks of up to 10 bp are present less than 200 bp away from the recombination sites. These homologies are not in register. Based on these results, we propose a model that may account for these recombination events and, more generally, for recombination events that occur during gene amplification in mammalian cells.     

Cloning and sequencing of viral integration site in human fibroblasts immortalized by simian virus 40.

We have analyzed cellular DNA sequences at the viral genome integration site in a human fibroblast cell line VA13 immortalized by simian virus 40 (SV40). The computer analysis of the junctional cellular DNA sequences did not show any homology to the DNA sequences previously reported. This suggests that immortalization by SV40 was not induced by the destruction of any known oncogene or anti-oncogene at the integration site. We did not find the precise substantial sequence homology at the junctional site between the cellular DNA and SV40 DNA, indicating that the recombination mechanism involved does not require precise sequence homology and therefore, SV40 genome was probably not integrated by homologous recombination. Short direct and inverted repeats of 5 to 29 nucleotides were found in the junctional cellular and SV40 DNA. Cellular DNA abutting SV40 DNA was found by the Northern blot analysis to be expressed in diploid human fibroblasts and SV40-transformed cells. The nature of this RNA is now under study.     

The mechanism of transduction of proto-oncogene c-src by avian retroviruses

Chicken c-src sequences have been transduced by avian leukosis viruses (ALV) and by partial src-deletion (td) mutants of Rous sarcoma virus in several independent events. Analyses of the recombination junctions in the genomes of src-containing viruses and the c-src DNA have shed light on the mechanism of transduction, which involves at least two steps of recombination. The initial recombination between a viral genome and the 5' region of c-src appears to occur at the DNA level. This step does not require extensive homology and can be mediated by stretches of sequences with only partial homology. The 5' recombination junction can also be formed by splicing between viral and c-src sequences. The second recombination is presumed to occur between the transducing ALV or td viral RNA and the viral-c-src hybrid RNA molecule generated from the initial recombination. This step involving recombination at the 3' ends of those molecules restores the 3' viral sequences essential for replication to the viral-c-src hybrid molecule. High frequency of c-src transduction by partial td mutants suggests that the second recombination is greatly enhanced when there is sequence homology between the transducing virus and the 3' region of c-src. Incorporation of the c-src sequences into an ALV genome results in greatly elevated expression of the gene. However, increased expression of c-src alone is insufficient to activate its transforming potential. Structural changes in c-src are necessary to convert it into a transforming gene. The changes can be as small as single nucleotide changes resulting in single amino aid substitutions at certain positions. Mutations can occur rapidly during viral replication after c-src is incorporated into the viral genome. Therefore, it is most likely that transduction of c-src by ALV is followed by subsequent mutation and selection for the sarcomagenic virus. In the case of transduction by td viruses that retain certain src sequences, joining of these sequences with the transduced c-src apparently is sufficient to activate its transforming potential.     

Intermediates in Hin-mediated DNA inversion: a role for Fis and the recombinational enhancer in the strand exchange reaction.

The site-specific inversion reaction controlling flagellin synthesis in Salmonella involves the function of three proteins: Hin, Fis and HU. The DNA substrate must be supercoiled and contain a recombinational enhancer sequence in addition to the two recombination sites. Using mutant substrates or modified reaction conditions, large amounts of complexes can be generated which are recognized by double-stranded breaks within both recombination sites upon quenching. The cleaved molecules contain 2-bp staggered cuts within the central dinucleotide of the recombination site. Hin is covalently associated with the 5' end while the protruding 3' end contains a free hydoxyl. We demonstrate that complexes generated in the presence of an active enhancer are intermediates that have advanced past the major rate limiting step(s) of the reaction. In the absence of a functional enhancer, Hin is also able to assemble and catalyze site-specific cleavages within the two recombination sites. However, these complexes are kinetically distinct from the complexes assembled with a functional enhancer and cannot generate inversion without an active enhancer. The results suggest that strand exchange leading to inversion is mediated by double-stranded cleavage of DNA at both recombination sites followed by the rotation of strands to position the DNA into the recombinant configuration. The role of the enhancer and DNA supercoiling in these reactions is discussed.