Adenovirus DNA replication in vitro: a protein linked to the 5' end of nascent DNA strands.

Soluble nuclear extracts prepared from adenovirus-infected HeLa cells supported adenovirus DNA replication with exogenous DNA-protein complex as template, but protease-treated, phenol-extracted DNA was less active. Replication was enhanced when creatine phosphate and creatine phosphokinase were included in the reaction mixture, rendering the reaction independent of exogenous ATP. Genomic-length, newly synthesized DNA strands were first observed 30 min after initiation of replication and continued to increase in amount for at least 4 h. Thus, the rate of replication is consistent with previous estimates of the rate of replication in vivo. Nascent DNA strands bound to benzoylated, naphthoylated DEAE-cellulose due to their association with protein. The 5' termini of nascent DNA strands were resistant to the 5'- to 3'-specific T7 exonuclease, and the 3' termini of nascent strands were sensitive to the 3'- to 5'-specific exonuclease III. These results suggest that a protein becomes covalently linked to the 5' termini of nascent DNA strands replicated in vitro. Nuclear extracts prepared from adenovirus type 2-infected cells also supported replication of DNA-protein complex prepared from the unrelated type 7 adenovirus. The limited sequence homology between these two viruses at the origin of replication further defines recognition sequences at the origin. These results are discussed in terms of a model for adenovirus DNA replication in which the terminal protein and sequences within the inverted terminal repetition are involved in the formation of an initiation complex that is able to prime DNA replication.     

Sequence of inverted terminal repetitions from different adenoviruses: demonstration of conserved sequences and homology between SA7 termini and SV40 DNA.

We have established the nucleotide sequence for the inverted terminal repetition of human adenovirus type 3, a subgroup B adenovirus. The repetition, which is 136 bp long, shows a high degree of homology with the known sequence for the inverted repetition of adenovirus type 5 (Steenbergh et al., 1977) a subgroup C adenovirus. Partial sequence information convering 120 bp of the inverted terminal repetitions of human serotype 12, a subgroup A member, and of simian adenovirus type 7 has also been obtained. A comparison of the established sequences shows that the terminal repetitions, in particular the first 50 bp from the ends, contain sequences that have been well conserved in adenovirus evolution. For instance, only six mismatched base pairs were detected among the first 50 bp in the repetitions of simian adenovirus type 7 and human adenovirus type 5, although the homology between simian adenovirus 7 and human subgroup C adenoviruses was estimated to be only 30%. A 14 bp sequence located 9-22 nucleotides from the ends is present in DNAs from all the human serotypes examined as well as in simian adenovirus 7 DNA. Furthermore, the simian adenovirus 7 repetition contains a 21 bp sequence which is present in SV40 DNA, close to the origin of DNA replication.     

DNA sequences required for the initiation of adenovirus type 4 DNA replication in vitro

In-vivo studies have demonstrated that adenovirus type 2 and adenovirus type 4 have different DNA sequence requirements for the initiation of DNA replication. To investigate the basis of these differences an in-vitro system has been developed which will faithfully initiate adenovirus type 4 DNA replication. A plasmid containing 140 base-pairs of the right terminus of adenovirus type 4 supported initiation of DNA replication in vitro, provided that the plasmid was linearized in such a way as to locate the viral terminal sequences at the molecular ends of the DNA. Initiation by adenovirus type 4-infected cell extracts was also supported by a plasmid containing the complete adenovirus type 2 inverted terminal repeat (ITR). Deletion analysis of both adenovirus types 2 and 4 ITRs revealed that only the terminal 18 base-pairs of the genomes (perfectly conserved between the 2 viruses) were required for initiation in vitro. Thus, initiation was not enhanced by the presence of either the NFI site, the NFIII site or both sites together. Fractionation of a HeLa cell nuclear extract, by ion-exchange chromatography, identified a nuclear factor that stimulated the initiation reaction four- to fivefold. The stimulatory factor did not correspond to either of the cellular proteins NFI or NFIII which stimulate adenovirus type 2 DNA replication in vitro. Initiation in vitro was also supported by single-stranded DNA templates, albeit at a lower efficiency. Studies with synthetic oligonucleotides indicated a surprising specificity for initiation: whereas the strand used as template during initiation in vivo was active as a template for initiation in vitro, the complementary strand was inactive.     

The origin of adenovirus DNA replication: minimal DNA sequence requirement in vivo.

Adenovirus mini-chromosomes which contain two cloned, inverted adenovirus termini replicate in vivo when supplied with non-defective adenovirus as a helper. This system has been used to define the minimum cis acting DNA sequences required for adenovirus DNA replication in vivo. Deletions into each end of the adenovirus inverted terminal repeat (ITR) were generated with Bal31 exonuclease and the resulting molecules constructed into plasmids which contained two inverted copies of the deleted ITR separated by the bacterial neomycin phosphotransferase gene. To determine the effect of the deletion in vivo plasmids cleaved to expose the adenovirus termini were co-transfected with adenovirus type 2 DNA into tissue culture cells. The replicative ability of the molecules bearing adenovirus termini was assayed by Southern blotting of extracted DNA which had been treated with DpnI, a restriction enzyme which cleaves only methylated and therefore unreplicated, input DNA. Molecules containing the terminal 45 bp of the viral genome were fully active whereas molecules containing only 36 bp were in-active in this assay. Therefore sequences required for DNA replication are contained entirely within the terminal 45 bp of the viral genome. Thus, both the previously described highly conserved region (nucleotides 9-18) and the binding site for the cellular nuclear factor I (nucleotides 19-48) are essential for adenovirus DNA replication in vivo.     

Specific binding of the adenovirus terminal protein precursor-DNA polymerase complex to the origin of DNA replication

Initiation of adenovirus DNA replication is dependent on a complex of the precursor of the terminal protein and the adenovirus-coded DNA polymerase (pTP-pol complex). This complex catalyzes the formation of a covalent linkage between dCMP and pTP in the presence of a functional origin of DNA replication residing in the terminal nucleotide sequence of adenovirus DNA. We have purified the pTP-pol complex of adenovirus type 5 and studied its binding to double-stranded DNA. Using DNA-cellulose chromatography it could be shown that the pTP-pol complex has a higher affinity for adenovirus DNA than for calf thymus or pBR322 DNA. From the differential binding of the pTP-pol complex to plasmids containing adenovirus terminal sequences with different deletions, it has been concluded that a sequence of 14 nucleotide pairs at positions 9-22 plays a crucial role in the binding of pTP-pol to adenovirus DNA. This region is conserved in the DNA's of all human adenovirus serotypes and is obviously an important structural element of the adenovirus origin of DNA replication. Comparative binding studies with adenovirus DNA polymerase and pTP-pol indicated that pTP is responsible for the binding. The nature of the binding of pTP-pol to the conserved sequence will be discussed.     

Adenoviruses with nonidentical terminal sequences are viable.

Adenovirus genomes consist of linear DNA molecules containing inverted terminal repeat sequences (ITRs) of 100 to 200 base pairs. The importance of identical termini for viability of adenoviruses was investigated. The viral strains used in this study were wild-type adenovirus type 5 (Ad5) and a variant Ad2 strain with termini which were distinct from those of all other human adenoviruses sequenced to date. A hybrid virus (sub54), obtained by recombination between Ad2 and Ad5, derived the left 42 to 52% of its genome from Ad2 and the right 58 to 48% from Ad5. Southern blotting analysis with labeled oligodeoxynucleotides indicated that both Ad2 and Ad5 ITRs were present in sub54 viral DNA preparations, and successive plaque purifications of sub54 demonstrated that viruses with nonidentical terminal sequences were viable but were rapidly converted to viruses with identical ends. Cloning of the sub54 genome as a bacterial plasmid supported the observations made by analysis of sub54 virion DNA. A plasmid, pFG154, was isolated which contained the entire adenovirus genome with an Ad2 ITR at the left terminus covalently linked to an Ad5 ITR at the right terminus. Upon transfection of mammalian cells with pFG154, viral progeny were obtained which had all possible combinations of termini, thus confirming that molecules with nonidentical termini are viable. Pure populations of viruses with nonidentical termini could not be isolated, suggesting efficient repair of one end with the opposite terminus used as a template. A model for this process is proposed involving strand displacement replication and emphasizing the importance of panhandle formation (annealing of terminal sequences) as a replicative intermediate.     

Polar encapsidation of adenovirus DNA: cloning and DNA sequence of the left end of adenovirus type 3

The left-end adenovirus type 3 DNA sequence is very similar to those of other subgroup B adenoviruses, especially in the area between the HinfI site (320 base pairs) and the early-region Ia gene. This segment of the genome has been implicated as necessary for the left-end polarity of adenovirus DNA encapsidation. This segment and the sequences flanking it are compared with the corresponding sequences of adenovirus type 5 and adenovirus type 12, and the extent and pattern of intersubgroup homologies are discussed.     

The infectivity of adenovirus genomes lacking DNA sequences from their left-hand termini.

Deletions extending various distances into the left-hand terminal DNA sequences of the adenovirus type 2 (Ad2) genome were generated in a plasmid containing a cloned fragment spanning from 0 to 4.9 map units. The altered Ad2 DNA sequences were introduced into viral genomes by ligating a plasmid-derived fragment, which included the sequences extending to 3.8 map units, to the 3.8-100 map unit fragment generated by XbaI cleavage of the DNA of the Ad5 variant, d1309 (N.Jones and T.Shenk, Cell 17 683-689, 1979). The infectivity of the ligation products was studied by transfection of line 293 cells. Genomes lacking 11, 40, or 51 nucleotides from their left-hand termini, or containing an additional 18dG residues linked to this position were infectious, and analysis of the progeny virus genomes demonstrated that the structure of these modified termini had been restored to normal. In contrast, genomes from which the first 160 base pairs (bp), including the entire 102 bp left hand inverted terminal repeat (ITR), had been removed were non-infectious. The results indicate that the ITRs present at the opposite ends of transfecting DNA molecules are able to interact in vivo, and enable the production of viable viruses containing corrected left-hand terminal sequences. Possible mechanisms for this interaction are discussed.     

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.     

The nucleotide sequence at the termini of adenovirus type 5 DNA.

The sequences of the first 194 base pairs at both termini of adenovirus type 5 (Ad5) DNA have been determined, using the chemical degradation technique developed by Maxam and Gilbert (Proc. Nat. Acad. Sci. USA 74 (1977), pp. 560-564). The nucleotide sequences 1-75 were confirmed by analysis of labeled RNA transcribed from the terminal HhaI fragments in vitro. The sequence data show that Ad5 DNA has a perfect inverted terminal repetition of 103 base pairs long.     

Lack of evidence for methylation of parental and newly synthesized adenovirus type 2 DNA in productive infections.

Methylations of highly specific sites in the promoter and 5' regions of eucaryotic genes have been shown to shut off gene activity and thus play a role in the long-term regulation of gene expression. It was therefore of interest to investigate whether site-specific DNA methylations could also play a role in adenovirus DNA in productive infections. It has been reported earlier that adenovirion DNA is not detectably methylated (U. Günthert, M. Schweiger, M. Stupp, and W. Doerfler, Proc. Natl. Acad. Sci. USA 73:3923-3927, 1976). In the present study, evidence for the methylation of cytidine residues in 5'-CCGG-3' and 5'-GCGC-3' sequences or the methylation of adenine residues in 5'-GATC-3' and 5'-TCGA-3' sequences in intranuclear adenovirus type 2(Ad2) DNA isolated and analyzed early (5 h) or late (24 h) after infection could not be obtained. In Ad2 DNA, 22.5% of all 5'-CG-3' dinucleotides reside in 5'-CCGG-3' and 5'-GCGC-3' sequences. Intranuclear viral DNA was examined by restriction endonuclease cleavage by using HpaII, MspI, HhaI, DpnI, or TaqI and Southern blot hybridizations. The HindIII fragments of Ad2 DNA served as hybridization probes. The data rendered it very unlikely that free intracellular adenovirus DNA in productively infected cells was extensively methylated. Thus, DNA methylation was not a likely element in the regulation of free adenovirus DNA expression in productively infected cells.     

MDBK nuclear factor-binding site of various serotypes of adenovirus DNA

A fraction with the ability to bind the terminal fragment of equine adenovirus (EAd) DNA was prepared from MDBK cell nuclei. The fraction (MDBK nuclear factor) bound to the terminal fragment of all human and animal adenovirus DNAs examined except avian adenovirus EDS-76. However, the terminal fragments of two animal adenoviruses, EAd and bovine adenovirus type 3 (BAd3), showed higher affinity for the nuclear factor than the others. The MDBK nuclear factor-binding site determined by footprinting analysis was the sequence located between nucleotides 22 and 46 in EAd, between 36 and 53 in canine adenovirus type 2, and between 20 and 46 in BAd3, counting from the terminus. The respective binding site contained a sequence resembling the consensus sequence. The binding site of Ad4 DNA was not within the inverted terminal repetition, but was located at least 550 base pairs apart from the terminus.     

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.     

The nucleotide sequence of the right-hand terminus of adenovirus type 5 DNA: implications for the mechanism of DNA replication.

The nucleotide sequence of the right-hand terminal 3% of adenovirus type 5 (Ad5) DNA has been determined, using the chemical degradation technique developed by Maxam and Gilbert (1977). This region of the genome comprises the 1003 basepair long HindIII-I fragment and the first 75 nucleotides of the adjacent HindIII-F fragment, extending from the right-hand terminus to the sequences from which the main body of the mRNA of early region 4 is transcribed. One of the origins of adenovirus DNA replication is located within this part of the genome. The sequencing results are discussed in relation to several models proposed for the mechanism of replication of linear DNA molecules, which invariably depend on the presence of specific arrangements of nucleotides at the termini of those linear DNAs.     

Expression of integrated viral DNA sequences outside the transforming region in eight adenovirus-transformed cell lines

The expression of early and intermediate-early viral regions in eight adenovirus type 5 transformed cell lines was analyzed by radioimmuno-inhibition and RNA-DNA hybridization techniques. Details on the arrangement of the integrated viral DNA sequences in these cell lines have already been published (Visser, L., Wassenaar, A.D.C., Van Maarschalkerweerd, M.W. and Rozijn, T.H. (1981) J. Virol, 39, 684-693). In all cell lines tested, proteins encoded by the transforming region E1 are present. Dependent on the viral DNA content, additional early regions are expressed in most cell lines. In two of the cell lines polypeptides related to the adenoviral terminal protein, encoded by the recently described region E2b, could be detected. The viral DNA sequence encoding the body of the terminal protein mRNA is probably integrated intact, but the promoter region and at least some of the leaders are lacking in these cell lines.     

Transformation of primary rat kidney cells by DNA fragments of weakly oncogenic adenoviruses.

Primary cultures of baby rat kidney (BRK) cells were transformed by intact DNA and DNA fragments of weakly oncogenic human adenovirus types 3 and 7. The smallest fragment found to contain transforming activity was the left-terminal 4% endo R.HindIII fragment (for both adenovirus type 3 and 7 DNAs). The efficiency of transformation of this fragment was low, and no permanent cell line could be established. Left-terminal fragments ranging from 84 to 4,5% of the viral genome could all transform BRK cells with the same efficiency as intact viral DNA. A number of adenovirus type 7 DNA fragment-transformed lines were established and were found to contain persistent viral DNA sequences and adenovirus subgroup B-specific T antigen. Consequently, the transforming functions of adenovirus types 3 and 7 are located at the extreme left-hand end of the genome, and the minimum size for a DNA fragment with transforming activity is 1.0 X 10(6) daltons. These results do not rule out the possibility that viral genes located outside the transforming region may also influence transformation.     

Adenovirus type 2 activates cell cycle-dependent genes that are a subset of those activated by serum.

We have studied a panel of 10 genes and cDNA sequences that are expressed in a cell cycle-dependent manner in different types of cells from different species and that are inducible by different mitogens. These include five sequences (c-myc, 4F1, 2F1, 2A9, and KC-1) that are preferentially expressed in the early part of the G1 phase, three genes (ornithine decarboxylase, p53, and c-rasHa) preferentially expressed in middle or late G1, and two genes (thymidine kinase and histone H3) preferentially expressed in the S phase of the cell cycle. We have studied the expression of these genes in nonpermissive (tsAF8) and semipermissive (Swiss 3T3) cells infected with adenovirus type 2. Under the conditions of these experiments, adenovirus type 2 infection stimulates cellular DNA synthesis in both tsAF8 and 3T3 cells. However, four of the five early G1 genes (c-myc, 4F1, KC-1, and 2A9) and one of the late G1 genes (c-ras) are not induced by adenovirus infection, although they are strongly induced by serum. The other sequences (2F1, ornithine decarboxylase, p53, thymidine kinase, and histone H3) are activated by both adenovirus and serum. We conclude that the cell cycle-dependent genes activated by adenovirus 2 are a subset of the cell cycle-dependent genes activated by serum. The data suggest that the mechanisms by which serum and adenovirus induce cellular DNA synthesis are not identical.     

Replication of origin containing adenovirus DNA fragments that do not carry the terminal protein.

Nuclear extracts from adenovirus type 5 (Ad5) infected HeLa cells were used to study the template requirements for adenovirus DNA replication in vitro. When XbaI digested Ad5 DNA, containing the parental terminal protein (TP), was used as a template preferential synthesis of the terminal fragments was observed. The newly synthesized DNA was covalently bound to the 82 kD preterminal protein (pTP). Plasmid DNAs containing the Ad2 origin sequence or the Ad12 origin sequence with small deletions were analyzed for their capacity to support pTP-primed DNA replication. Circular plasmid DNAs were inactive. When plasmids were linearized to expose the adenovirus origin, both Ad2 and Ad12 TP-free fragments could support initiation and elongation similarly as Ad5 DNA-TP, although with lower efficiency. These observations indicate that the parental terminal protein is dispensable for initiation in vitro. The presence of 29 nucleotides ahead of the molecular end or a deletion of 14 base pairs extending into the conserved sequence (9-22) destroyed the template activity. DNA with a large deletion within the first 8 base pairs could still support replication while a small deletion could not. The results suggest that only G residues at a distance of 4-8 nucleotides from the start of the conserved sequence can be used as template during initiation of DNA replication.