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.     

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.     

Low molecular weight RNAs with homologies to cellular DNA at sites of adenovirus DNA insertion in hamster or mouse cells.

The adenovirus type 2 (Ad2)-transformed hamster cell line HE5 contains one or very few integrated copies of Ad2 DNA. At the site of insertion of Ad2 DNA, the cellular DNA sequence has been completely preserved and has homologies to small unpolyadenylated, cytoplasmic RNAs of 300 nucleotides in length and to minority populations of smaller RNAs present in HE5 cells and in normal hamster cells. The 300-nucleotide RNA is present on average in approximately 20 copies per cell. This RNA, and shorter RNAs, reveal homologies to the hamster DNA sequence of approximately 400 nucleotides to the right of the site of insertion of Ad2 DNA, which is present in one or very few copies per genome. The nucleotide sequence of the DNA segment homologous to this RNA does not contain open reading frames in excess of a sequence encoding 18 amino acids. Thus, it is unlikely that the small RNAs are actually translated and their function is unknown. The nucleotide sequence does not exhibit similarities to known low mol. wt. RNAs of eukaryotic origin. The low mol. wt. cellular RNA has been found in HE5 cells, in other hamster cell lines and organs, and also in mouse cells. There are differences with respect to size and abundance in the RNAs smaller than 300 nucleotides between HE5 cells and LSH hamster embryo cells. The adenovirus type 12 (Ad12)-induced mouse tumor CBA-12-1-T carries greater than 30 copies of integrated Ad12 DNA. The cellular DNA sequence at the site of Ad12 DNA insertion exhibits homologies to small RNAs (approximately 300 nucleotides long) from mouse cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Deletion of cellular DNA at site of viral DNA insertion in the adenovirus type 12-induced mouse tumor CBA-12-1-T.

The adenovirus type 12 (Ad12)-induced mouse tumor CBA-12-1-T contains greater than 30 copies of viral DNA integrated into cellular DNA. One of the sites of linkage between the left terminus of Ad12 DNA and mouse DNA was cloned, mapped and sequenced by using conventional techniques. The preinsertion sequence was also cloned from normal CBA/J mouse DNA and sequenced. The sequence data and blotting analyses demonstrated that at the site of linkage nine nucleotide pairs of viral DNA and at least 1500 to 1600 nucleotide pairs of cellular DNA were deleted. Up to the site of linkage, the cellular DNA sequence in CBA-12-1-T tumor DNA and the preinsertion sequence in CBA/J mouse cells were identical. The site of Ad12 DNA integration was found to be located close to a site of transition from unique to repetitive cellular DNA sequences. The nucleotide sequence at the site of linkage and at the preinsertion site revealed palindromic stretches of 5 and 10 nucleotides pairs, respectively. Scattered patch homologies (8-10 nucleotide pairs long) were observed between adenoviral and cellular DNAs. A hypothetical model for DNA arrangements at the site of recombination is presented.     

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.     

Patterns of integration of viral DNA in adenovirus type 2-transformed hamster cells

The patterns of integration of viral DNA in five lines of adenovirus type 2-transformed hamster cells have been investigated. Cell lines HE1 to HE5 were obtained by in vitro transformation of hamster embryo cells by ultraviolet light-inactivated Ad2². In all lines, segments in the central parts of the viral genome are missing. The lines HE1, HE2, HE3, HE4 and HE5 contain 2 to 4, 2 to 4, 6 to 10, about 10, and 2 to 3 genome fragment equivalents per cell, respectively.The patterns of integration in lines HE2 and HE3 are identical; however, the viral genome has been amplified in these cell lines to different extents. This result provides evidence for the post-integrational amplification of inserted viral genomes. It is also conceivable that line HE2 may have undergone losses of integrated Ad2 genomes. The persisting Ad2 genomes in lines HE2 and HE3 have deletions in parts of the EcoRI F and D fragments. The remainders of these fragments are linked to cellular DNA. The termini of the segments of the viral genome have been inverted and linked to each other. This linkage could have occurred via a circular intermediate in integration or via tandemly integrated viral genomes with subsequent deletion events. The linkage of the termini of viral DNA might be mediated by short sequences of cellular DNA.In line HE5, approximately 40% of the Ad2 genome is deleted, and the truncated segments, again comprising the terminal Ad2 DNA fragments, have been fused. The termini of the viral DNA are linked to cellular DNA. In lines HE1 and HE4 complex deletion and fusion events have altered the inserted Ad2 genomes.     

Recognition site of nuclear factor I, a sequence-specific DNA-binding protein from HeLa cells that stimulates adenovirus DNA replication.

Nuclear factor I is a 47-kd protein, isolated from nuclei of HeLa cells, that binds specifically to the inverted terminal repeat of the adenovirus (Ad) DNA and enhances Ad DNA replication in vitro. We have studied the DNA sequence specificity of nuclear factor I binding using cloned terminal fragments of the Ad2 genome and a set of deletion mutants. Binding of nuclear factor I protects nucleotides 19-42 of Ad2 DNA against DNase I digestion. Filter binding assays show that deletion of the first 23 nucleotides does not impair binding while a deletion of 24 nucleotides reduces binding severely. However, binding studies on Ad12 DNA indicate that nucleotide 24 can be mutated. Fragments containing the first 40 bp are bound normally while the first 38 bp are insufficient to sustain binding. Taken together, these results indicate that the minimal recognition site of nuclear factor I contains 15 or 16 nucleotides, located from nucleotide 25 to nucleotide 39 or 40 of the Ad2 DNA. This site contains two of the four conserved nucleotide sequences in this region. Sequences flanking the minimal recognition site may reduce the binding affinity of nuclear factor I. In accordance with these binding studies, DNA replication of a fragment that carries the sequence of the terminal 40 nucleotides of Ad2 at one molecular end is enhanced by nuclear factor I in an in vitro replication system.     

Nucleotide sequence analysis of the linked left and right hand terminal regions of adenovirus type 5 DNA present in the transformed rat cell line 5RK20.

A peculiar phenomenon is observed in several adenovirus type 2 or 5 (Ad2 or Ad5) transformed cell lines: the right hand and left hand terminal regions of the viral genome present in the viral DNA insertions of these cell lines are found to be linked together. A large part of the viral DNA insertion present in the Ad5 transformed rat cell line 5RK20 has been cloned in the lambda vector Charon21A, including the segment containing the linked terminal regions. Sequence analysis of the linkage region showed a perfect homology with the Ad5 DNA sequence and a direct linkage of basepair (bp) 63 of the left hand end of the viral genome to bp 108 of the right hand end. No cellular or rearranged viral sequences were present. Our findings suggest that the joining of viral sequences into the cellular genome.     

Structure of viral DNA in a rat cell line transformed by the cloned EcoRI-C fragment of adenovirus 12.

A DNA segment carrying viral DNA was cloned from a rat cell line transformed by the cloned EcoRI-C fragment (0 to 16.4 map units) of human adenovirus type 12(Ad12), and the viral sequence in the clone was analysed. The cloned segment contained the region from nucleotide positions 118 to 3520 of the Ad12 genome in the middle. No unique structure was found at the viral and non-viral DNA junctions. When examined the transforming activity, the conserved viral sequence was able to transform rat 3Y1 cells efficiently. Southern blotting analysis of the viral sequence in five re-transformed cell lines showed that the viral sequence was inserted at different sites of cellular DNA. These results indicate that (I) the Ad12 DNA moiety from the enhancer-promoter region of the E1A gene to the end of the E1B gene contains enough information for efficient transformation of the rat cell, and (II) integration of the viral sequence at unique cellular sites is not prerequisite for transformation.     

Recombination between adenovirus type 12 DNA and a hamster preinsertion sequence in a cell-free system. Patch homologies and fractionation of nuclear extracts.

We have previously described a cell-free recombination system derived from hamster cell nuclear extracts in which the in vitro recombination between a hamster preinsertion sequence, the cloned 1768 base-pair p7 fragment, and adenovirus type 12 (Ad12) DNA has been demonstrated. The nuclear extracts have now been subfractionated by gel filtration on a Sephacryl S-300 column. The activity promoting cell-free recombination elutes from the Sephacryl S-300 matrix with the shoulder and not the peak fractions of the absorbancy profile. By using these protein subfractions, in vitro recombinants have been generated between the p7 preinsertion sequence and the 60 to 70 map unit fragment of Ad12 DNA, which has previously shown high recombination frequency. In all of the analyzed recombinants thus produced in vitro, striking patchy homologies have been observed between the p7 and Ad12 junction sequences, and between Ad12 DNA or p7 DNA and pBR322 DNA. The patchy homologies are similar to those found earlier during the analyses of some of the junction sequences in integrated Ad12 genomes in Ad12-induced hamster tumor cell lines. Proteins in the shoulder fractions of the gel-filtration experiment can form specific complexes with double-stranded synthetic oligodeoxyribonucleotides corresponding to several p7 and Ad12 DNA sequences. These sequences participate in the recombination reactions catalyzed by the same column fractions in the shoulder of the absorbancy profile. Such proteins have not been found in the peak fractions. Further work will be required to ascertain that the cell-free recombination system mimics certain elements of the mechanisms of integrative recombination and to purify the cellular components essential for recombination.     

Sequence of the junction in adenovirus 2-SV40 hybrids: examples of illegitimate recombination.

The nucleotide sequences of six Ad2-SV40 junctions from three Ad2-SV40 hybrid viruses (Ad2++HEY, Ad2++LEY and Ad2+D1) were determined. Comparison of parental adenovirus 2 and SV40 DNA sequences with the sequence at the Ad2-SV40 junctions revealed that 5 out of 6 junctions are abrupt transitions from Ad2 to SV40 DNA, and in one case (Ad2++LEY, right junction) there is an additional nucleotide at the junction, which cannot be ascribed to either DNA. Ad2++HEY and Ad2+D1 right junctions are identical and Ad2++LEY and Ad2+ND4 left junctions are identical, a result that strongly suggests these Ad2-SV40 hybrids arose by recombination between the linear Ad2 DNA and circular SV40 DNA, followed by recombination between Ad2 DNA and SV40 DNA present in the Ad2-SV40 hybrid DNA. The unambiguous transition of Ad2 DNA into SV40 DNA at the junction sites is an example of recombination events which have apparently occurred without any homology at the recombination site.     

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.     

Circular DNA of human immunodeficiency virus: analysis of circle junction nucleotide sequences.

During infection of cells by retroviruses, some of the nonintegrated viral DNA can be found as a circular form containing two tandem, directly repeated long terminal repeats. The nucleotide sequence at the point where the long terminal repeats join (the circle junction) can be used to deduce the terminal nucleotides of the linear form of the viral DNA. Comparison of the termini of linear viral DNA with sequences at the junctions between the integrated provirus and the host chromosome has revealed that for most retroviruses 2 bp are removed from each end of the linear viral DNA during integration. For human immunodeficiency virus type 1 (HIV-1), however, sequence considerations involving primer-binding sites had suggested that only 1 bp is removed during integration. We obtained the nucleotide sequences at the ends of HIV-1 DNA by using the polymerase chain reaction to amplify fragments corresponding to the HIV-1 circle junction. Of 17 clones containing amplified sequences, 10 had identical circle junctions that contained an additional 4 bp (GTAC) relative to the integrated provirus. This indicates that, as for other retroviruses, 2 bp are removed from each end of the linear HIV-1 viral DNA during integration. The remaining seven isolates contained insertions or deletions at the circle junction.     

Viral DNA sequences and gene products in hamster cells transformed by adenovirus type 2.

Complementary strand-specific adenovirus DNA of full length or from endonuclease BamHI fragments was used as a probe to estimate the fractional representation and abundance of viral sequences in five hamster cell lines (Ad2HE1-5) transformed with UV-inactivated adenovirus type 2. The fraction of the viral genome present in the five transformed cell lines varied from 44% in the Ad2HE5 cell line to 84% in the Ad2HE3 cell line. The number of viral DNA copies per diploid cell equivalent ranged from 1.8 in the Ad2HE1 line to 7.1 in the Ad2HE4 line. In vivo labeling with [35S]methionine followed by immunoprecipitation with an antiserum against adenovirus type 2 early proteins revealed virus-specific polypeptides with molecular weights of 42,000 to 58,000 in extracts from all five hamster cell lines. Several other early viral polypeptides were detected in some of the adenovirus type 2-transformed hamster cell lines.     

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.