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.     

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.     

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.     

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.     

Inhibition of protein synthesis enhances transformation of primary cells by viral DNA

Inhibition of protein synthesis by cycloheximide after transfection and subsequent removal of the drug increased the transformation efficiency of primary cells by plasmids containing the left 4.5, 6.7, or 16% of the adenovirus (Ad) genome. The enhancement factor ranged from 2 to as much as 70 depending on the size of the viral DNA fragments used. Addition of cycloheximide before or at the time of transfection inhibited transformation, suggesting that viral protein synthesis is important during the early phase of transformation. Transient expression assays showed that cells treated with cycloheximide post-transfection contained as much as three times the amount of viral RNA transcribed from regions E1A and E1B. Conversion of a rat cell line lacking thymidine kinase activity (TK-) to the TK+ phenotype by a plasmid containing the herpes TK gene was severely inhibited by the drug treatment, suggesting that the enhancement effects of cycloheximide on transformation may be specific for Ad DNA. Cycloheximide treatment also increased the number of transformants induced by a transformation defective E1B mutant of Ad12 (cyt mutant). Plasmid containing only the E1A region of Ad12 transformed primary rat kidney cells with very low efficiency. The inclusion of E1B in the transfecting DNA fragments increased the transformation frequency by more than 400-fold, much higher than that achieved by cycloheximide. Thus, cycloheximide cannot replace E1B functions in transformation efficiency.     

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.     

Constructing chimeric type 12/type 5 adenovirus E1A genes and using them to identify an oncogenic determinant of adenovirus type 12.

The E1A gene of highly oncogenic type 12 adenovirus (Ad12) possesses a segment unique to this serotype and comprising 60 base pairs contiguous with and separating conserved regions 2 and 3 in the gene. A similar but slightly longer segment is also present in the E1A gene of highly oncogenic simian adenovirus type 7 (D. Kimelman, J. S. Miller, D. Porter, and B. E. Roberts, J. Virol. 53:399-409, 1985). This segment is missing entirely from the E1A gene of type 5 adenovirus, which is nononcogenic. To test the hypothesis that this unique separating or "spacer" region influences the oncogenicity of Ad12, we constructed ClaI and SmaI restriction sites on either side of it, which allowed reciprocal exchange between this and the equivalent cassette from type 5 adenovirus E1A, bounded by the same restriction sites intrinsic to that gene. The resultant Ad12-based chimeric viruses, ch702 and ch704, in which the spacer region is replaced with (in-frame) type 5 sequence, grow normally on human A549 cells and display wild-type transformation frequencies on baby rat and mouse kidney cells. In contrast, the oncogenic capacity of these chimeric viruses, as measured by tumor induction following virus inoculation in Hooded Lister rats, is greatly reduced. Likewise, cells transformed by ch702 and ch704 display reduced tumorigenicity compared with wild-type transformants in syngeneic rats. These results, coupled with recent preliminary tests using a mutant with a point mutation in this region, support the view that the unique spacer region of type 12 is an oncogenic determinant of this virus.     

Adenovirus E1A 12S protein induces DNA synthesis and proliferation in primary epithelial cells in both the presence and absence of serum.

Infection of primary baby rat kidney (BRK) cells with an adenovirus that carries an E1A 12S cDNA in place of the normal E1A region (adenovirus 5 [Ad5] 12S) resulted in the induction of cellular DNA synthesis and proliferation of the epithelial cells in the population, even in the absence of serum. Increased cellular DNA synthesis was first detectable by 12 h after infection and was maintained at a 10- to 20-fold higher level than in mock-infected cells. By 5 days after infection there was a 10-fold-greater number of 12S virus-infected BRK cells. These infected BRK cells retained many of their normal epithelial cell characteristics and were not transformed. The expression of the E1A 12S protein(s) occurred early after infection. There was no induction of adenoviral gene expression or viral DNA replication in these cells. The early effects of a fully transforming gene product(s) were also examined. The Ad5-simian virus 40 hybrid virus, Ad5.SVR4, in which the early region of simian virus 40 has replaced the E1 region of Ad5, was used to infect BRK cells. The kinetics of expression of the T antigens were similar to those of the 12S polypeptides. Infection with Ad5.SV4 also resulted in the induction of cellular DNA synthesis and cell proliferation at levels similar to those observed with the 12S virus. However, infection with Ad5.SVR4 resulted in cells that had lost some of their epithelial cell characteristics and were fully transformed. Thus, although the early cellular events induced by the two genes were similar, they did not yield the same final cellular phenotype.     

Sequence organization of a viral DNA insertion present in the adenovirus-type-5-transfonned hamster line BHK268-C31

The hamster cell line BHK268-C31 contains two large viral inserts which both include sequences from the left-hand end of adenovirus type 5 (Ad5) DNA. One of these viral inserts has been cloned in the λ vector Charon 4A. Electron microscopic analysis and restriction enzyme mapping shows that the recombinant carries a 4.4-kb-long colinear segment of viral DNA, which is located between map positions 1.5 and 14.2 in the Ad5 genome. The junctions between viral DNA and flanking sequences have been sequenced and found not to show any specific features. One of the junctions is located in the E1 a coding region, 573 bp from the left-hand end of the Ad5 genome, whereas the other junction is situated in the coding region for polypeptide IVa2. The promoter region as well as the cap site for the mRNAs from region E la are thus missing from this insert and its role in viral transformation is unclear.     

The nucleotide sequence of the transforming early region E1 of adenovirus type 5 DNA

The sequence of the leftmost 11.3% of the non-oncogenic human adenovirus type 5 (Ad5) DNA has been determined. This segment contains the entire early region E1 of the Ad5 genome which has been shown to be involved in in vitro transformation of non-permissive rodent cells (Van der Eb et al., 1980). From the DNA sequence, and from the mRNA sequence data obtained by Perricaudet et al, (1979, 1980) for the E1 mRNAs from the closely related adenovirus type 2 (Ad2), it is possible to predict the primary structure of the polypeptides encoded by this region. The function of these proteins in cell transformation is discussed. From the positions of mapped restriction endonuclease sites and termini of RNA segments in the nucleotide sequence the length of the Ad5 DNA is estimated to be 36.6 kb.     

Nucleotide sequence of the genes encoded in early region 2b of human adenovirus type 12

The nucleotide (nt) sequence of a cloned DNA segment containing the early 2b region of the class A adenovirus Ad12 has been determined. When compared to the corresponding region of Ad2 or Ad7, there is a high degree of nt and predicted amino acid (aa) sequence homology within the r-strand regions that encode the preterminal protein and the viral DNA polymerase. A gene coding region comparable to the Mr 13,600 gene product found in Ad2 can be identified; this hypothetical gene product shares 30% aa homology with its Ad2 counterpart and has a very similar hydropathy profile.     

Integration Sites of Adenovirus Type 12 DNA in Transformed Hamster Cells and Hamster Tumor Cells

The patterns and sites of integration of adenovirus type 12 (Ad12) DNA were determined in three lines of Ad12-transformed hamster cells and in two lines of Ad12-induced hamster tumor cells. The results of a detailed analysis can be summarized as follows. (i) All cell lines investigated contained multiple copies (3 to 22 genome equivalents per cell in different lines) of the entire Ad12 genome. In addition, fragments of Ad12 DNA also persisted separately in non-stoichiometric amounts. (ii) All Ad12 DNA copies were integrated into cellular DNA. Free viral DNA molecules did not occur. The terminal regions of Ad12 DNA were linked to cellular DNA. The internal parts of the integrated viral genomes, and perhaps the entire viral genome, remained colinear with virion DNA. (iii) Except for line HA12/7, there were fewer sites of integration than Ad12 DNA molecules persisting. This finding suggested either that viral DNA was integrated at identical sites in repetitive DNA or, more likely, that one or a few viral DNA molecules were amplified upon integration together with the adjacent cellular DNA sequences, leading to a serial arrangement of viral DNA molecules separated by cellular DNA sequences. Likewise, in the Ad12-induced hamster tumor lines (CLAC1 and CLAC3), viral DNA was linked to repetitive cellular sequences. Serial arrangement of Ad12 DNA molecules in these lines was not likely. (iv) In general, true tandem integration with integrated viral DNA molecules directly abutting each other was not found. Instead, the data suggested that the integrated viral DNA molecules were separated by cellular or rearranged viral DNA sequences. (v) The results of hybridization experiments, in which a highly specific probe (143-base pair DNA fragment) derived from the termini of Ad12 DNA was used, were not consistent with models of integration involving true tandem integration of Ad12 DNA or covalent circularization of Ad12 DNA before insertion into the cellular genome. (vi) Evidence was presented that a small segment at the termini of the integrated Ad12 DNA in cell lines HA12/7, T637, and A2497-3 was repeated several times. The exact structures of these repeat units remained to be determined. The occurrence of these units might reflect the mechanism of amplification of viral and cellular sequences in transformed cell lines.     

Gene organization of the transforming region of adenovirus type 7 DNA

The sequence of the leftmost 11% of the weakly oncogenic human adenovirus type 7 (Ad7) DNA has been determined. This part of the Ad7 viral genome encompasses early region E1 which has been shown to be involved in the process of cell transformation in vitro (Dijkema et al., 1979). From the nucleotide sequence and determined coordinates of the E1 mRNAs, we are able to predict the primary structure of the polypeptides encoded by the transforming region of Ad7. The organization of the E1 region of Ad7 and of other adenovirus serotypes (Bos et al. 1981) leads to the proposal of a novel mechanism for gene regulation at the translational level in which protein synthesis can initiate at either the first or the second AUG triplet available in mRNA. The differences between the large E1b-specific tumor antigens of adenovirus types 12, 7 and 5 may explain the differences in oncogenicity of these viruses.