Structure and gene organization in the transformed Hind III-G fragment of Ad12

Nucleotide sequence of human adenovirus type 12 DNA: comparative functional analysis

A fresh inoculum of human adenovirus type 12 (Ad12) was obtained from the American Type Culture Collection and passaged once on human embryonic kidney cells, and Ad12 DNA was prepared from the first-passage yield to avoid higher passages which might have generated host-virus DNA recombinants. The 18 PstI fragments of Ad12 DNA were cloned into the pBluescript KS vector, and the entire nucleotide sequence of both strands from all 18 fragments was determined by using successive oligodeoxyribonucleotide primers. Ad12 DNA extends over 34,125 nucleotide pairs, and its molecular weight is calculated to be about 22 x 10(6). The nucleotide sequence of Ad12 DNA was subjected to computer analyses that determined possible open reading of frames on the two strands, the leader sequences, the position of the virus-associated RNA coding region, possible TATA, and polyadenylation signals. The distribution of the Ad12 open reading frames was similar to that in the previously sequenced Ad2 DNA, but there were also distinct differences. Ad12 DNA has an inverted terminal redundancy of 161 nucleotides, compared with 102 nucleotides in Ad2 DNA. There were stretches of sequence identity between Ad2 and Ad12 DNAs at both termini; the overall sequence similarity between the two viral genomes ranged between 59% (polypeptide IX) and 77% (in the E2 region), with high homology also in the sequences for the adenovirus DNA polymerase.

Recombinant human adenoviruses containing hybrid adenovirus type 5 (Ad5)/Ad12 E1A genes: characterization of hybrid E1A proteins and analysis of transforming activity and host range

Hybrid adenovirus type 12 (Ad12)/Ad5 E1A genes were constructed by homologous recombination in Escherichia coli, a technique which offers several advantages over conventional mutagenesis for genetic analysis of proteins. In particular, functional differences between the proteins can be mapped by correlating the replacement of specific sequences with the acquisition of new properties, and there is no requirement for common unique restriction sites or polymerase chain reaction strategies to construct the hybrids. Recombinant adenoviruses expressing these hybrid E1A proteins were capable of replicating efficiently in HeLa cells, with the exception of one construct which contained a hybrid transactivation domain. The transforming activity of the hybrid E1A constructs was assayed by DNA transfection of primary baby rat kidney cells. Plasmids containing Ad12 E1 were approximately 20-fold less efficient at transformation than those with E1 of Ad5, and it was found that two regions in exon 1 of E1A mediate this difference. No differences were found in the abilities of any hybrid E1A proteins to bind to cellular proteins previously determined to be important for transformation by E1A.

E1A dependent up-regulation of c-jun/AP-1 activity

E1A, the early region 1A transcription unit of human adenovirus, exhibits multiple functions that regulate the expression of some cellular genes and promote cell growth and division. We found that E1A stimulated c-jun gene expression at least fifty-fold in rat 3Y1 cells in a serum-independent manner, concomitantly with E1A down-regulation of jun B expression. The E1A-dependent induction of c-jun transcription resulted in increase amount of cJun/AP1. This induction was mediated by the enhancement of the binding activity of the transcription factor cJun/AP1 to an AP1 binding site in the c-jun promoter. Additionally, this induction can be repressed by introducing junB into the cells. Taken collectively, these results suggest that the differential expression of two closely related proteins greatly expands their cellular regulation. Induction of c-jun expression by E1A as well as c-jun autoregulation may amplify the action of E1A during adenovirus infection. Therefore, some of the biological effects of E1A may include mediating the constitutive activation of c-jun, which is important in transcriptional regulation and oncogenic transformation.

Arrangement and expression of integrated adenovirus type 12 DNA in the transformed hamster cell line HA12/7: amplification of Ad12 and c-myc DNAs and evidence for hybrid viral-cellular transcripts

In the genome of the adenovirus type 12 (Ad12)-transformed hamster cell line HA12/7 about three copies of the viral DNA are fixed by integration. The results of blot-hybridization, molecular cloning, and nucleotide sequencing experiments suggest a model for the arrangement of Ad12 DNA molecules in which the left hand terminus of one of the Ad12 DNA copies is linked to unique hamster DNA. The right hand end of this DNA molecule is fused to an inverted copy of a left terminal approximately 4.3 kb fragment of Ad12 DNA. This ensemble is followed by the second Ad12 DNA copy whose right terminus is again joined to an inverted, supernumerary left terminal approximately 4.3 kb Ad12 DNA fragment. There is a third Ad12 DNA copy whose right terminus is linked to cellular DNA. In this sequence arrangement, the left terminus of Ad12 DNA is overrepresented, as had been shown earlier (S. Stabel, W. Doerfler and R.R. Friis (1980) J. Virol. 36, 22-40). In the presented model, cellular DNA sequences are interspersed in between the three copies of Ad12 DNA. In the left terminus of the integrated Ad12 DNA, transcription of RNA is initiated which extends out into cellular DNA. The interviral DNA junctions are also transcribed. The c-myc gene in cell line HA12/7 is amplified about 10-fold and considerably more c-myc RNA has been identified in the Ad12-transformed cells than in BHK21 or in LSH hamster cells. It has been shown previously that the E1 region of Ad12 DNA is transcribed into mRNA in HA12/7 cells (Ortin et al. (1976) J. Virol. 20, 355-372). It remains to be investigated whether c-myc amplification and expression are related to the transformed phenotype of HA12/7 cells.

Cis- and trans-acting factors for transcription of the adenovirus 12 E1A gene

Cis- and trans-acting factors were analyzed for transcription of the adenovirus 12 E1A gene possessing two sites for transcription initiation. These sites are located at nucleotide positions 306 and 445 with respect to the left end of the viral genome as position 1. The template activity of DNAs with various deletions at the 5'-upstream region of the E1A gene was examined in a cell-free system using a nuclear extract of Ehrlich ascites tumor cells. A DNA region specifically stimulating transcription initiated at the site distal to the E1A coding sequence was found located between positions 1 and 166. No DNA sequence affecting transcription from a proximal start-site appeared to be present in the region between positions 1 and 378. DNaseI-footprinting indicated that factors present in the extract bind to two distinct DNA segments, both of which are located within a region stimulating distal transcription. Two footprints were observed, one between positions 19 and 55 and the other between 77 and 94. The former footprint was inhibited by synthetic oligonucleotides containing a sequence recognized by nuclear factor I and the latter contained a sequence similar to one present in the B-enhancer of polyoma virus. Competition of in vitro transcription with synthetic oligonucleotides indicated (a) nuclear factor(s) bound to the region between positions 19 and 55 to be responsible for stimulating distal transcription of the adenovirus 12 E1A gene.

Identification of mouse adenovirus type 1 early region 1: DNA sequence and a conserved transactivating function

The left end of the genome of mouse adenovirus type 1 (also known as strain FL) was characterized by determination of the DNA sequence, amino acid similarities with early region proteins of primate adenoviruses, and a functional assay. Several specific DNA sequence features were similar to those found in human adenoviruses, and open reading frames from this region could encode proteins similar to human adenovirus early region 1A and early region 1B proteins. DNAs from this region were tested in transient-expression assays in human and mouse cells were found to transactivate the human adenovirus type 5 early region 3 promoter fused to the chloramphenicol acetyltransferase gene. The data indicate structural and functional homologies between mouse adenovirus type 1 early region 1 and early region 1 of primate adenoviruses.

Molecular cloning and characterization of cellular genes whose expression is repressed by the adenovirus E1a gene products and growth factors in quiescent rat cells

Several cDNA clones of cellular genes, whose expression is repressed by the adenovirus type-12 E1a gene products, were isolated from a rat 3Y1 cell cDNA library by differential plaque hybridization with labeled cDNA probes prepared from 3Y1 and the derivative cell line expressing the E1a gene constitutively. The changes in the levels of these gene transcripts during cell-cycle progression from G0 to G1 to S phase were analyzed with 3Y1 cells and gMA cell lines, derived from 3Y1 cells, in which the expression of the E1a gene or its 13S, 12S cDNA can be switched on by the addition of dexamethasone. Quantitation of the transcripts by Northern-blot hybridizations and by nuclear run-on experiments revealed the following. (i) The level of clone-53 mRNA (which turned out to be the fibronectin (FN)-coding mRNA) is very high in resting gMA cells and decreased rapidly after switching on of the E1a gene or its 13S, or 12S cDNA. (ii) The addition of serum or platelet-derived growth factor to resting 3Y1 cells also resulted in a rapid decrease in the FN mRNA level, but the addition of epidermal growth factor (EGF) had little or no effect. (iii) The level of clone-56 mRNA in gMA cells was not affected by the induction of the E1a gene expression; however, the addition of EGF to resting gMA or 3Y1 cells resulted in a decrease of this mRNA after a 12- to 16-h lag period. Induction of the E1a gene expression in gMA cells treated with EGF shortened the lag period. The addition of serum to resting 3Y1 cells decreased the clone-56 mRNA level without a significant lag period.

Characterization of adenovirus type 40 E1 region

The left-most 3.9 kb of adenovirus type 40 (Ad40) DNA has been sequenced using cloned viral DNA fragments. The Ad40 E1 region is deduced to code for at least four polypeptides, 221 and 249 amino acids as E1A products in addition to 166 and 475 amino acids as E1B products. E1B polypeptides share about 50% homology with well-defined adenovirus types, 2/5, 7, and 12, throughout the E1B sequences. E1A homology of Ad40 to these types is relatively lower than that of E1B, while highly conserved regions of E1A are retained to a certain level in Ad40 as well. Activity for morphological transformation of Ad40 E1A on 3Y1 cells is considerably lower when compared to that of Ad5 and Ad12 E1A genes. Transient chloramphenicol acetyltransferase (CAT) expression assay shows that Ad40 E1A has a trans-acting function, though lower than that of other E1A genes, on adenovirus early promoter. The Ad40 E1A promoter also holds only a little cis-acting activity in 3Y1 cells. Lower activities of both Ad40 E1A promoter and certain E1A functions may explain in part the difficulty in propagation of Ad40.

Prediction and demonstration of a novel Epstein-Barr virus nuclear antigen

The protein sequence predicted by the Epstein Barr virus (EBV) BERF4 open reading frame includes a tetrapeptide, Lys-Arg-Pro-Arg (KRPR), shown for other proteins to be a component of a signal for rapid nuclear localization. A subgenomic fragment of EBV DNA containing BERF4 has been incorporated into an expression vector, transfected onto primate cells and the nuclear distribution of the resulting protein established by immunofluorescence using EBV positive human sera. These sera contained high titres of antibodies to a fusion protein, produced in E. coli, consisting of beta-galactosidase and the C-terminal 167 amino acids of BERF4. Immunoaffinity purified antibodies reactive with the EBV component of the fusion show the molecular weight of this antigen in EBV immortalized B-cell lines to be about 160 kD. The demonstration that BERF4 contains an exon encoding a nuclear protein identifies a new EBNA gene (EBNA-6) and suggests that KRPR is a signal sequence common to a number of viral and cellular nuclear polypeptides which bind to nucleic acids and may therefore be of predictive value in identifying karyophilic proteins.

Insertion of adenovirus type 12 DNA in the vicinity of an intracisternal A particle genome in Syrian hamster tumor cells

In the adenovirus type 12 (Ad12)-induced hamster tumor T1111(2) about 10 Ad12 genome equivalents were integrated at different sites. One of the integrated copies proved unstable and was lost from the cellular genome or rearranged upon passage of the cell line, H1111(2), established from this tumor. This unstable site of junction between the left terminus of Ad12 DNA and hamster DNA and the preinsertion site from BHK21 hamster cells was cloned, sequenced, and analyzed. The junction site showed several peculiarities. At the left terminus of Ad12 DNA, the first 64 nucleotides were deleted. At a distance of 127 nucleotides to the left from this junction site, an internal dispersed fragment of Ad12 DNA comprising nucleotides 1290 to 1361 of the authentic Ad12 DNA sequence was inserted into cellular DNA in an inverted orientation relative to the complete Ad12 genome that was located in its vicinity. The 127-nucleotide sequence between the intact Ad12 genome and the separate 72-base-pair (bp) Ad12 DNA fragment was cellular, but it was not identical to the preinsertion sequence at this location. The sequences flanking the termini of the dispersed 72-bp Ad12 DNA fragment were characterized by direct repeats of 9 or 10 nucleotides. To the left of Ad12 nucleotide 1361 in the separate 72-bp fragment, about 620 cellular nucleotides followed which were identical at the occupied and at the preinsertion sites. It was conceivable that the separate 72-bp Ad12 DNA fragment and the cellular sequence of 127 bp to its right had been transposed en bloc from another unknown location. Abutting the 620 nucleotides of cellular DNA to the left of this block, the 3'-terminal sequence of an endogenous, intracisternal A particle (IAP) genome of hamster cells was detected. The possible significance of the proximity of an IAP sequence to an inserted Ad12 genome with respect to the transformation event, to the instability at this site, or to the transcriptional activity of this region is not known. The 620 bp of cellular DNA between the 72-bp Ad12 DNA fragment and the end of the long terminal repeat of the hamster IAP sequence was apparently of a unique type. Transcriptional activity was not found in the approximate region between nucleotides -620 (to the left) and +350 (to the right) relative to the site of Ad12 DNA insertion, but was found outside these boundaries.

Analysis of promoters of adenovirus type 12 E1A gene in a cell-free transcription system

Transcription from the E1A gene of adenovirus type 12 initiates at two sites in vivo. In this paper we analyzed the E1A promoter(s) in a cell-free transcription system. Primer extension assay revealed that transcriptions were accurately initiated at two sites apart by 140 bp. The efficiency of transcriptions from two sites was almost equal in the standard reaction. However, when transcription reaction was done following pre-incubation of a nuclear extract and template DNA in the absence of ribonucleotides, transcription from the site proximal to E1A gene significantly decreased with little effect on that from distal site. This suggests the existence of a mechanism which controls the efficiency of transcriptions from two start sites of E1A gene.

Transcriptional activities of mammalian genomes at sites of recombination with foreign DNA

The nucleotide sequences of several sites of recombination between adenovirus DNA and hamster, mouse, or human cell DNAs were determined. These sites of recombination had been cloned from adenovirus type 2 (Ad2)- or type 12 (Ad12)-transformed cells, from Ad12-induced tumor cells, or from a symmetric recombinant between Ad12 DNA and human cell DNA. One important precondition for the generation of recombinants between host and foreign DNAs might be the establishment of a chromatin configuration that permits access of foreign DNA and of the recombination machinery to cellular DNA. Such favorable chromatin structures might arise during cellular DNA replication or transcription or both. As a first approach toward investigating these more complex problems of foreign DNA insertion, we determined transcriptional activities of cellular DNA sequences at viral junction sites. The sites of linkage investigated in this study with respect to their transcriptional activities were those previously cloned and sequenced (W. Doerfler, R. Gahlmann, S. Stabel, R. Deuring, U. Lichtenberg, M. Schulz, D. Eick, and R. Leisten, Curr. Top. Microbiol. Immunol. 109:193-228, 1983). In addition, a site from cell line HA12/7 which is described in this paper was also analyzed. The results presented demonstrate that the cellular DNA sequences involved in linkage to viral DNA at five completely different sites in DNA from three different species are transcribed into RNAs even in cells which have not been transformed or infected by adenovirus. Some of these RNAs were cytoplasmic and were not poly(A)+. Human cell DNA sequences at the junction to Ad12 DNA in SYREC2 DNA were transcribed into poly(A)+ cytoplasmic RNA which could be translated in vitro. These results are consistent with the notion that at least some of the cellular DNA sequences at sites of insertion of adenovirus (foreign) DNA are transcriptionally active and thus provide an opportunity for recombination.

Nucleotide sequence of the adenovirus type 40 inverted terminal repeat: close relation to that of adenovirus type 5

Human adenovirus type 40 (Ad40) is a pathogen that causes acute infantile gastroenteritis. Ad40 has the distinct characteristic of being difficult to propagate in conventional cultured human cells. The nucleotide sequence of the inverted terminal repeat (ITR) of Ad40, which includes the origin of adenoviral DNA replication, was determined using recombinant plasmid DNA. By using our newly developed program to express the ITR homologies simply, we found that the ITR of Ad40, which is 163 nucleotides long, was related most closely to that of adenovirus type 5, which replicates efficiently.

Conserved 12-bp element downstream from mRNA polyadenylation sites

Sequences downstream from the AATAAA motif in a number of cellular and viral transcription units have been compared. A 12-bp conserved element was identified in approximately half of the cases studied, and a consensus sequence TTGANNNTTTTTT was derived from a comparison of 74 such sequences. This element is located immediately (5-20 bp) downstream from the poly(A)-addition site in every case where this is known, and it is suggested that this element may be involved in the cleavage/polyadenylation reaction. This proposal is consistent with published studies on deletion mutants of downstream regions.

Expression of adenovirus type 12 E1b 58-kDa protein in Escherichia coli and production of antibodies raised against a 58-kDa::beta-galactosidase fusion protein

DNA fragments coding for the N-terminal 185 amino acids (aa) and for the entire coding region of the adenovirus (Ad)12 E1b 58-kDa protein have been cloned in a prokaryotic expression vector. The N-terminal region of the 58-kDa viral protein (aa 21-205) is expressed as a beta-galactosidase (beta Gal) fusion protein encoded by plasmid pB58Ngal. Escherichia coli strains transformed with this plasmid synthesize a full-length fusion protein of 150-kDa and two truncated proteins: a 140-kDa protein containing aa 64-205 and a 120-kDa polypeptide containing aa 158-205 of the E1b 58-kDa protein. Antibodies raised against purified fusion proteins specifically immunoprecipitate the E1b 58-kDa protein from Ad12-infected and transformed cells. Bacteria transformed with plasmid pB58 carrying the entire E1b 58-kDa coding region (minus the first N-terminal 20 aa which are replaced by 4 aa of beta Gal) showed dramatically reduced growth properties after induction of 58K gene expression. We have not been able to detect substantial amounts of the 58-kDa protein in these cells. However, the viral 58-kDa polypeptide could be synthesized in vitro from plasmid pB58 in a DNA-dependent translation system from E. coli.

Sequence analysis in the E1 region of adenovirus type 4 DNA

Adenovirus type 4 (Ad4) is the sole member of adenovirus group E based on overall DNA sequence homology, restriction endonuclease cleavage patterns, and the size of capsid proteins. We cloned the BamHI-F fragment from the left end of Ad4 in pUC13-1 between the SalI and BamHI sites in order to carry out the structural analysis of the E1A region of Ad4. The complete sequence of the BamHI-F fragment (2042 bp) has been determined. From the DNA sequence, the splice sites for the putative 12 S and 13 S mRNAs, encoded by the E1A region of Ad4 were deduced. If protein synthesis initiates at the first available AUG triplet (position 575), these 12 S and 13 S mRNAs would code for polypeptides containing 226 and 257 amino acids, respectively. Comparison of Ad4- and Ad7-13 S mRNA-coded polypeptides indicates that there is 57% homology, whereas the homology is only 38% with Ad12 and 31% with Ad2-13 S mRNA-coded polypeptides. The structural analysis in the E1 region of Ad4 also includes the coding region for the E1B 19-kDa protein. Ad4 and Ad7 shows 65% homology in the coding regions for E1B 19-kDa protein. Comparison of the DNA sequence of Ad4 with those of Ad2, Ad7, and Ad12 by using a dot matrix computer program and by Southern hybridization revealed that Ad4 bears a stronger homology with Ad7 than with Ad2 and Ad12 in this region. Hydropathy plots and alignments of the putative polypeptides coded by this region in Ad4 with those from the corresponding regions of different serotypes to reveal the highly conserved domains also support the above conclusion.

Trans-activation of a methylated adenovirus promoter by a frog virus 3 protein

The high degree of methylation of the frog virus 3 (FV3) genome suggests that FV3-infected cells are capable of transcribing highly methylated DNA. We tested this hypothesis by assaying the transcriptional activity of adenovirus promoters known to be inhibited by methylation. Plasmid constructs containing the E1a and E2aE promoters of adenovirus type 12 linked to the gene for chloramphenicol acetyltransferase [(CAT) EC 2.3.1.28], when methylated and introduced into eukaryotic cells, promoted CAT synthesis only when the cells were subsequently infected with FV3. Mapping of transcriptional initiation sites revealed that the same sites in the E1a promoter were used for the initiation of transcription in uninfected and infected cells. Moreover, Southern blots showed that transfected plasmid DNA from FV3-infected cells was not demethylated. The absence of CAT-specific RNA in transfected cells infected with FV3 in the presence of protein synthesis inhibitors demonstrated that a virus-induced protein was responsible for the trans-activation. Inhibition of transcription from the methylated template by alpha-amanitin indicated that a functional host RNA polymerase II is required for transcription of methylated DNA in FV3-infected cells. The virus-induced trans-acting protein presumably alters either host RNA polymerase II or the methylated DNA template to allow transcription from the methylated adenovirus promoters.

Adenovirus type 12 E1A protein expressed in Escherichia coli is functional upon transfer by microinjection or protoplast fusion into mammalian cells

We efficiently expressed, in Escherichia coli, and purified the protein product encoded by the human adenovirus type 12 (Ad12) 13S mRNA. The functional properties of the E1A protein were analyzed by introducing the protein by microinjection or protoplast fusion into living mammalian cells. We showed that the E. coli-expressed E1A protein induces gene expression of the adenovirus type 5 (Ad5) E1A deletion mutant Ad5dl312. The purified E1A protein rapidly and quantitatively localized to the cell nucleus after microinjection into the cytoplasm. In addition, we raised high-titered monospecific antibodies to the purified Ad12 E1A protein. Using deleted forms of an adenovirus type 2 and Ad5 hybrid (Ad2/5) E1A protein, we showed that all of the epitopes conserved between Ad2/5 E1A and Ad12 E1A protein that are recognized by the Ad12 E1A-specific antiserum map to within the first exon-encoded amino-terminal half of the protein.

Adenovirus type 12 early region 1A proteins repress class I HLA expression in transformed human cells

The adenovirus type 12 (Ad12) early region 1A (E1A) gene is thought to play a major role in repressing class I major histocompatibility complex expression in transformed rodent cells. However, since transformation by adenovirus requires both E1A and E1B genes, it has not been demonstrated whether the Ad12 E1A gene acts alone or synergistically with the E1B gene to accomplish this effect. Moreover, it is not known whether the repression of class I antigen synthesis by Ad12-transforming gene products occurs only in rodent cells. We show that the Ad12 E1A gene, in the absence of the E1B gene, is capable of greatly reducing the levels of class I HLA antigens and mRNAs in primary human cells transformed by the E1A gene of Ad12 and the large tumor antigen (T-antigen) gene of BK virus; control cells transformed by BK virus T-antigen gene alone or the highly related simian virus 40 T-antigen gene showed no apparent alteration in class I HLA expression. Human recombinant interferon gamma was able to restore synthesis of class I HLA antigens in transformed cells that produced Ad12 E1A proteins, indicating that these cells were not deficient for class I genes. These results strongly indicate that the Ad12 E1A proteins modulate class I gene expression by similar mechanisms in both transformed rodent and human cells.

N6-methyldeoxyadenosine residues at specific sites decrease the activity of the E1A promoter of adenovirus type 12 DNA

The activity of eukaryotic promoters is highly sensitive to site-specific modifications by DNA methylations. We have used the E1A promoter of adenovirus type 12 (Ad12) DNA to investigate the effects of methylations at different promoter sites on its activity. The chloramphenicol acetyltransferase gene has served as an activity indicator. Activity of the E1A promoter is lost or markedly decreased by deoxycytidine methylation of two HpaII (5'-C-C-G-G-3') or seven HhaI (5'-G-C-G-C-3') sites upstream from the 3' located T-A-T-A signal. There are two T-A-T-A signals in the E1A promoter of adenovirus type 12 DNA, one T-A-T-T-A-T sequence starting at nucleotide 276 (5' located), a second T-A-T-T-T-A-A sequence starting at nucleotide 414 (3' located). Deoxycytidine methylations at two AluI (5'-A-G-C-T-3') sites downstream from the 5' located T-A-T-A signal have no effect on promoter activity. When one EcoRI (5'-G-A-A-T-T-C-3') or one TaqI (5'-T-C-G-A-3') sequence at 281 base-pairs upstream or 61 base-pairs downstream from the 5' located E1A T-A-T-A signal, respectively, is deoxyadenosine methylated, the promoter becomes inactive. Deoxyadenosine methylation at one MboI (5'-G-A-T-C-3') site, which is located 127 nucleotides downstream from the 5' located T-A-T-A signal, fails to decrease E1A promoter activity. There is no conspicuous anatomical relation of any of these sites to the two presumptive enhancer sequences in the E1A promoter. We conclude that 5-deoxymethylcytidine or N6-methyldeoxyadenosine residues have to be introduced at highly specific promoter sites to inactivate the promoter. These sites are probably different for different promoters.

Posttranslational modification at the N terminus of the human adenovirus type 12 E1A 235R tumor antigen

The adenovirus E1A transforming region, which encodes immortalization, partial cell transformation, and gene activation functions, expresses two early mRNAs, 13S and 12S. Multiple-T antigen species with different electrophoretic mobilities are formed from each mRNA, presumably by unknown posttranslational modifications. The adenovirus type 12 (Ad12) 13S and 12S mRNAs encode E1A T antigens of 266 and 235 amino acid residues (266R and 235R), respectively. To study possible posttranslational processing at the N and C termini and to distinguish between the Ad12 266R and 235R T antigens, we prepared antibodies targeted to synthetic peptides encoded at the common C (peptide 204) and N (peptide 202) termini of the 266R and 235R T antigens and at the unique internal domain of the 266R T antigen (peptide 206). The specificity of each anti-peptide antibody was confirmed by immunoprecipitation of the 266R and 235R T antigens produced in Escherichia coli. Immunoprecipitation analysis of the E1A T antigens synthesized in Ad12-infected KB cells revealed the following. Antibody to the common C terminus recognized three T antigens with apparent Mrs of 43,000, 42,000, and 39,000 (43K, 42K, and 39K). All three forms were phosphorylated and were present in both the nucleus and the cytoplasm. The 43K and 42K T antigens were rapidly synthesized during a 10-min pulse with [35S]methionine in Ad12-infected cells. The 43K T antigen had a half-life of 20 min, the 42K T antigen had a longer half-life of about 40 min, and the 39K T antigen became the predominant E1A T antigen. Antibodies to the unique region immunoprecipitated the 43K T antigen but not the 42K and 39K T antigens. Antibody to the N terminus immunoprecipitated the 43K and 42K T antigens but not the 39K T antigen, suggesting that the 39K T antigen possessed a modified N terminus. Partial N-terminal amino acid sequence analysis showed that the 43K and 42K T antigens contain methionine at residues 1 and 5, as predicted from the DNA sequence, whereas no methionine was released from the 39K T antigen during the first six cycles of Edman degradation. We propose that the short-lived 43K T antigen is the primary product of the 13S mRNA, the 266R T antigen; the somewhat more stable 42K T antigen is the primary product of the 12S mRNA, the 235R T antigen.(ABSTRACT TRUNCATED AT 400 WORDS)

The adenovirus type 12 early-region 1B 58,000-Mr gene product is required for viral DNA synthesis and for initiation of cell transformation

An E1B 58K mutant of adenovirus type 12 (Ad12), dl207, was constructed by the deletion of 852 base pairs in the E1B 58K coding region. The mutant could grow efficiently in 293E1 cells but not in HeLa, KB, or human embryo kidney (HEK) cells. Viral DNA replication of dl207 was not detected in HeLa and KB cells and was seldom detected in HEK cells. Analysis of viral DNA synthesis in vitro showed that the Ad12-DNA-protein complex replicated by using the nuclear extract from Ad12 wild-type (WT)-infected HeLa cells but not by using the nuclear extract from dl207-infected cells. In dl207-infected HeLa and KB cells, early mRNAs were detected, but late mRNAs were not detected. The mutant induced fewer transformed foci than the WT in rat 3Y1 cells. Cells transformed by dl207 could grow efficiently in fluid medium, form colonies in soft agar culture, and induce tumors in rats transplanted with the transformed cells at the same efficiency as WT-transformed cells. Tumors were induced in hamsters injected with WT virions but were not induced in hamsters injected with dl207 virions. The results indicate that the E1B 58K protein is required both for viral DNA replication in productive infection and for initiation of cell transformation, but not for maintenance of the transformed phenotype.

An insertion mutation in the adenovirus type 12 early region 1A 13S mRNA unique region

An adenovirus type 12 mutant, in203S, was constructed to contain an insertion of two amino acids in the early region 1A (E1A) 13S mRNA-coding region and in the E1A 12S mRNA intron. in203S could not grow in HeLa and KB cells. Virus DNA replication was scarcely detected at a low multiplicity of infection, but was detected at a high multiplicity of infection. The transcription of early genes other than E1A was not detected at 13 h after infection, but became detectable after longer incubation. The transcription of the E1A gene was also reduced to about one-fifth of the wild-type level. The mutant induced fewer foci of smaller sizes than the wild type in rat 3Y1 and secondary rat kidney cells. The induction of cellular DNA synthesis was reduced in rat 3Y1 cells infected with in203S as compared with that in wild type-infected cells. These results show that the E1A 13S mRNA-derived polypeptide of adenovirus type 12 is required for activation of early genes, cell transformation, and induction of cellular DNA synthesis.

Nuclear location signals in polyoma virus large-T

We have found two mutually independent sequence elements that contribute to the nuclear location of polyoma virus large-T. The first sequence (pro lys lys282 ala arg glu asp) resembles the SV40 large-T nuclear signal (pro lys lys128 lys arg lys val) and occurs at a corresponding position within polyoma large-T. The second sequence (val ser arg lys192 arg pro arg) may be structurally related to the SV40 signal, although it has little sequence homology and falls in a region of the protein that has no counterpart in SV40 large-T. The data suggest that nuclear location signals with characteristics similar to the SV40 large-T prototype may be a more general feature of nuclear proteins, and that several such signals in a given protein can exert cooperative effects.

Structure of viral DNA in a rat cell line, GY1, transformed by Ad12 HindIII fragment-G

The cell line GY1, established by transformation of a rat cell line 3Y1 with the Ad12 HindIII fragment-G (leftmost 6.8%, nucleotide 1 to 2322), contains more than 100 viral copies per haploid genome. The viral DNAs in this cell line were cloned into a phage vector, lambda gtWES lambda B, and recloned into pBR322 with their flanking cellular DNAs. Independently isolated 39 clones were analyzed by restriction enzyme cleavage and Southern blot hybridization experiment and divided into 11 classes. Some of classes contained multiple identical clones, at maximum 16 clones. It may be interpreted that amplification of some of the recombined sequences had occurred after the multiple integrations of transfected DNAs within cells. Using five clones from different classes the sequences of recombination sites were determined. Viral DNAs deleted with varying degrees at both ends were flanked by quite different cellular sequences in different clones and no common sequences were revealed around viral-cellular junctions. Tandemly repeated viral DNAs were found in one of the clones to be integrated in a head to tail manner into cellular DNA. The linkage of these two viral DNAs had occurred at the site where parental viral DNAs shared 2 bp. Palindrome structures could be constructed around viral-cellular and viral-viral junction sites and around the regions of parental viral DNAs corresponding to the junction sites in all of the cases investigated.

Mapping of functional domains in adenovirus E1A proteins

We have modified the E1A gene of human subgroup C adenovirus by introducing deletions in its coding sequence. Various truncated E1A proteins were expressed in Escherichia coli, purified, and microinjected via glass capillaries into Vero cells. We monitored their movement from the cell cytoplasm to the nucleus and their ability to induce expression of H5dl312, an adenovirus E1A deletion mutant. Our results show that the carboxyl terminus of E1A contains sequences essential for rapid and efficient nuclear localization. Essential information for efficient H5dl312 complementation is contained in an internal region, comprising sequences of both exons of the E1A gene. A first exon-encoded region, however, is sufficient to induce low levels of adenovirus gene expression. Information for nuclear localization and for H5dl312 complementation are therefore encoded by distinct domains of the E1A gene. In addition, we determined that the human c-myc product was unable to complement H5dl312.

Adenovirus 5 early region 1A host range mutants hr3, hr4, and hr5 contain point mutations which generate single amino acid substitutions

The early region 1A (E1A) gene of adenovirus 5 encodes two proteins, 289AA and 243AA, which are translated from mRNAs of 13S and 12S, respectively. These two E1A proteins are identical except for an internal stretch of 46 amino acids unique to the larger protein. The 289AA protein activates transcription from promoters of other early adenoviral genes. The adenovirus type 5 host range mutants hr3, hr4, and hr5 are unable to activate transcription of these early viral genes. We show here that hr3, hr4, and hr5 each contain a distinct missense mutation in the E1A gene. We first localized the mutations in a series of constructed wild-type-hr hybrid E1A genes by using a biological assay which can discriminate between functional and nonfunctional E1A proteins. We then identified the mutations by DNA sequencing. In hr3 lysine replaced methionine at position 176, and in hr4 phenylalanine replaced leucine at position 173; both substitutions occurred in the region unique to the 289AA protein. In hr5, due to the splicing patterns of the two mRNAs, asparagine replaced serine as the last amino acid in the unique region of the 289AA protein at position 185, while aspartic acid replaced glycine at position 139 in the 243AA protein, which is the last amino acid common to both proteins before the unique region. These results substantiate the role of the 289AA protein in transcriptional activation and underscore the importance of the unique region as the basis of the functional difference between the two E1A proteins. Implications as to how these mutations affect the structure and function of the E1A proteins in transcriptional activation and transformation are discussed.

The release of growth arrest by microinjection of adenovirus E1A DNA

The induction of DNA synthesis in growth-arrested mouse fibroblasts (NIH 3T3) was studied by microinjection of different constructs of adenovirus DNA using SV40 DNA and plasmid DNA as positive and negative controls. The E1A region of adenovirus types 2 and 12 appears to be sufficient to induce cellular DNA synthesis after growth arrest in approximately 30% of the cells and both 13S and 12S cDNA constructs mediate this effect. The presence of the E1A protein products as assayed by immunofluorescence does not strictly correlate with the induction of DNA synthesis in microinjected cells in contrast to the SV40 large T-antigen. Microinjection of truncated fragments of the Ad12 E1A region suggests, however, that the protein products of 12S and 13S may be involved in the induction process. A sequence comparison of the SV40 T-antigen and the adenovirus E1A products identified a region of significant homology providing a basis for a hypothesis concerning the evolution of T-antigen genes in DNA viruses.

Structure and expression of adenovirus type 12 E1B 58K protein in infected and transformed cells: studies using antibodies directed against a synthetic peptide

We have studied the kinetics of synthesis of the early adenovirus type 12 (Ad12) E1B 58K tumor antigen during lytic infection and analysed its half-life, intracellular localization and phosphorylation in infected KB and transformed hamster (HA12/7) cells. Our analysis has been based on immunoprecipitations using antibodies directed against a synthetic peptide corresponding to the carboxy-terminal end of the E1B 58K protein. Its synthesis was first detectable approximately 8 h after infection and reached a maximum at about 20 h. There is a slight decrease of synthesis late after infection although its level of production is rather high throughout the infectious cycle. The half-life of the Ad12 E1B 58K polypeptide is 2-3 h in infected cells, but strikingly higher (less than 10 h) in the Ad12-transformed cell line HA12/7. Pulse-chase experiments combined with cell fractionation and immunofluorescence studies suggested that about 50% of the amount of the 58K polypeptide accumulates in the nucleus of infected KB cells at least at late times after infection, but only approximately 10% in Ad12-transformed cells. The 58K polypeptide is phosphorylated in both infected and transformed cells. Analysis of the products of acid hydrolysis indicates phosphorylation to equal amounts of serine and threonine. The implications of all these findings for possible roles of the E1B 58K tumor antigen in lytic infection and transformation are discussed.

Organization of early region 1B of human adenovirus type 2: identification of four differentially spliced mRNAs

The mRNAs from early region 1B of adenovirus type 2 have been studied by Northern blot, S1 nuclease, and cDNA analysis. Two novel mRNAs, designated 14S and 14.5S, have been observed in addition to the previously identified 9S, 13S, and 22S mRNAs. They are 1.26 and 1.31 kilobases long and differ from the 13S and 22S mRNAs in being composed of three exons instead of two. Their two terminal exons are the same as those present in the 13S mRNA, whereas the middle exon is unique to each of the two novel mRNA species. The structures of the 14S and 14.5S mRNAs allow the prediction of their coding capacities: both mRNA species, like the 22S and 13S mRNAs, contain an uninterrupted translational reading frame encoding a 21,000-molecular-weight (21K) polypeptide. The 14S mRNA can, in addition, encode a 16.5K polypeptide which shares N-terminal and C-terminal sequences with the 55K polypeptide, known to be encoded by the 22S mRNA. The 14.5S mRNA species encodes a hypothetical 9.2K polypeptide which has the same N terminus as the 55K polypeptide but a unique C terminus. The two mRNAs differ in their kinetics of appearance; the 14.5S mRNA is preferentially expressed late after infection in contrast to the 14S mRNA, which is present in approximately equal amounts early and late after infection. Taken together with previously published information the results suggest that early region 1B of adenovirus type 2 encodes five proteins in addition to virion polypeptide IX. These have predicted molecular weights of 55,000, 21,000, 16,500, 9,200, and 8,100.

Acylation of adenovirus type 12 early region 1b 18-kDa protein. Further evidence for its localisation in the cell membrane

The 18-kDa E1b protein in Ad 12-transformed rat cells and in Ad 12-infected human cells binds lipid strongly. The lipid is not removed by boiling in the presence of SDS or by extraction with methanol/chloroform. It is, however, dissociated from the protein by treatment with methanolic KOH suggesting that attachment is through an ester linkage. The acylated 18-kDa protein is detected only in the membrane fraction. Labelling cell surface proteins on Ad 12-transformed cells with [125I]iodosulphanilic acid shows that some of the Ad 12 18-kDa E1b protein is present on the outside of the cell. It is concluded that this protein is responsible for cell surface T-antigen activity.

The consensus sequence YGTGTTYY located downstream from the AATAAA signal is required for efficient formation of mRNA 3' termini

Our previous DNA sequence comparisons of 3' terminal portions from equivalent herpes simplex virus type 1 (HSV-1) and HSV-2 genes identified a conserved sequence (consensus YGTGTTYY; Y = pyrimidine) located approximately 30bp downstream from the AATAAA signal. We report here that this signal is located downstream from 67% of the mammalian mRNA 3' termini examined. Using constructions with the bacterial chloramphenicol acetyl transferase (CAT) gene linked to an HSV 'terminator' fragment, we show that deletions in the 'terminator' reduce CAT activities and the levels of CAT mRNA 3' termini. Specifically: (1) deletions of downstream sequences which extend up to the consensus YGTGTTYY signal reduce CAT levels to values 35% of those obtained with undeleted plasmids, (2) a deletion of a further 14bp, which removes the YGTGTTYY consensus but not the poly A site, reduces CAT activities to 1%-4%. The levels of CAT mRNA 3' termini reflect the reductions in CAT activities however, levels of mRNA 5' termini are unaffected by these deletions. The RNA produced in the absence of the YGTGTTYY signal is present in the cytoplasm although no CAT activity is detectable.

E1a regions of the human adenoviruses and of the highly oncogenic simian adenovirus 7 are closely related

Simian adenovirus 7 (SA7) is a highly oncogenic virus, capable of causing tumors in hamsters upon the direct injection of viral DNA. We determined the transcriptional organization of the transforming region and compared it with that of the human adenoviruses. This analysis demonstrated that there are two independently promoted transcription units similar to the E1a and E1b regions of the human adenoviruses. The nucleotide sequence of the SA7 E1a region demonstrated considerable homology with the human adenoviruses, both in the sequences that regulate E1a expression and in the encoded polypeptides. The amino acid homology was reflected in the ability of SA7 to complement the growth of human adenoviruses mutant in the E1a region. Furthermore, we found two regions of amino acid homology unique to SA7 and the highly oncogenic human adenovirus 12.

Synthesis in Escherichia coli of human adenovirus type 12 transforming proteins encoded by early region 1A 13S mRNA and 12S mRNA

Human adenovirus (Ad)-encoded early region 1A (E1A) tumor (T) antigens have been implicated in the positive regulation of viral early genes, the positive and negative regulation of some cellular genes, and cell immortalization and transformation. To further study the Ad E1A T antigens and to facilitate their purification, we have cloned cDNA copies of the Ad12 E1A 13S mRNA and 12S mRNA downstream of a hybrid Escherichia coli trp-lac (tac) promoter. Up to 8% of the protein synthesized in E. coli cells transformed by each of the two different Ad12 E1A cDNA constructs were immunoprecipitated as a Mr 47,000 protein by antibody to a synthetic peptide encoded in the Ad12 E1A DNA sequence. Both proteins produced in E. coli appear to be authentic and complete Ad12 E1A T antigens because they possess (i) the Ad12 E1A NH2-terminal amino acid sequence predicted from the DNA sequence; (ii) the Ad12 E1A COOH-terminal sequence, as shown by immunoprecipitation with anti-peptide antibody; and (iii) a molecular weight and an acidic isoelectric point similar to that of the E1A T antigens synthesized in Ad12-infected and transformed mammalian cells. The T antigens were purified to near homogeneity in yields of 100-200 micrograms per g wet weight of transformed E. coli cells.

Identification of adenovirus 12-encoded E1A tumor antigens synthesized in infected and transformed mammalian cells and in Escherichia coli

A 16-amino acid peptide, H2N-Arg-Glu-Gln-Thr-Val-Pro-Val-Asp-Leu-Ser-Val-Lys-Arg-Pro-Arg-Cys-COOH (peptide 204), targeted to the common C-terminus of human adenovirus 12 (Ad12) tumor antigens encoded by the E1A 13S mRNA and 12S mRNA, has been synthesized. Antibody prepared in rabbits against peptide 204 immunoprecipitated two proteins of apparent Mr 47,000 and 45,000 from extracts of [35S]methionine-labeled Ad12-early infected KB cells and a 47,000 protein from extracts of the Ad12-transformed hamster cell line, HE C19. Immunoprecipitation analysis of infected and transformed cells labeled with 32Pi showed that both major Ad12 E1A T antigens are phosphoproteins. Immunofluorescence microscopy of Ad12-early infected KB cells with antipeptide antibody showed the site of E1A protein concentration to be predominantly nuclear. E1A proteins were detected by immunofluorescence at 4 to 6 h postinfection and continued to increase until at least 18 h postinfection. Antipeptide 204 antibody was used to analyze the proteins synthesized in Escherichia coli cells transformed by plasmids containing cDNA copies of the Ad12 E1A 13S mRNA or 12S mRNA under the control of the tac promoter (D. Kimelman, L. A. Lucher, M. Green, K. H. Brackmann, J. S. Symington, and M. Ptashne, Proc. Natl. Acad. Sci. U.S.A., in press). A major protein of ca. 47,000 was immunoprecipitated from extracts of each transformed E. coli cell clone. Two-dimensional gel electrophoretic analysis of immunoprecipitates revealed that the T antigens synthesized in infected KB cells, transformed hamster cells, and transformed E. coli cells possess very similar molecular weights and acidic isoelectric points of 5.2 to 5.4.

Polar encapsidation of adenovirus DNA: evolutionary variants reveal dispensable sequences near the left ends of Ad3 genomes

Repeated passage of adenovirus type 3 in HeLa cells has led to a novel stock of variant genomes, characterized by deletions and substitutions of DNA sequences within the left-end 750 base pairs. This heterogeneous stock retains few if any parental genomes--the majority of variants appear viable. Analysis of viable variants with deleted sequences reveals the 182 nucleotides proximal to the left-end inverted terminal repeat (136-318 bp) are not required for Ad3 infectivity in cultured human cell lines nor for maintenance of viral DNA encapsidation polarity.

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.

Production of a monospecific antiserum against the early region 1A proteins of adenovirus 12 and adenovirus 5 by an adenovirus 12 early region 1A-beta-galactosidase fusion protein antigen expressed in bacteria

Antisera were prepared against the amino acid sequences encoded within the N-terminal half of the adenovirus 12 (Ad12) early region 1A (E1A) gene. This was accomplished by construction of a plasmid vector which encoded the N-terminal 131 amino acids of Ad12 E1A joined in frame to the coding sequence of beta-galactosidase. After induced synthesis in Escherichia coli, the Ad12 E1A-beta-galactosidase fusion protein (12-1A-FP) was extracted with urea and used to raise antibodies in rabbits. The 12-1A-FP antisera immunoprecipitated major phosphoproteins of 39,000 and 37,000 apparent molecular weights from Ad12-transformed and infected cells. The 12-1A-FP antisera also immunoprecipitated E1A phosphoproteins from Ad5-transformed and infected cells. Immunospecificity of the 12-1A-FP antisera was demonstrated by the ability of 12-1A-FP antigen to block immunoprecipitation of E1A proteins. Furthermore, E1A proteins immunoprecipitated from in vivo-labeled cells comigrated with those translated in vitro by RNA that had been hybridization selected to E1A DNA.

Structure and function of the adenovirus origin of replication

Efficient initiation of adenovirus DNA replication requires the presence of specific terminal nucleotide sequences that collectively constitute the viral origin of replication. Using plasmids with deletions or base substitutions in a cloned segment of DNA derived from the terminus of the adenovirus 2 genome, we have demonstrated that the origin contains two functionally distinct regions. The first 18 bp of the viral genome are sufficient to support a limited degree of initiation. However, the presence of a sequence in the region between nucleotides 19 and 67 greatly enhances the efficiency of the initiation reaction. This region contains a specific binding site for a protein present in uninfected cells (KD = 2 X 10(-11) M). The bound protein protects the DNA segment between base pairs 19 and 43 from attack by DNAase I. Studies with deletion mutants indicate that binding of the cellular protein is responsible for the enhancement of initiation.

DNA sequences required for the in vitro replication of adenovirus DNA

Initiation of adenovirus (Ad) DNA replication occurs on viral DNA containing a 55-kilodalton (kDa) protein at the 5' terminus of each viral DNA strand and on plasmid DNAs containing the origin of Ad replication but lacking the 55-kDa terminal protein (TP). Initiation of replication proceeds via the synthesis of a covalent complex between an 80-kDa precursor to the TP (pTP) and the 5'-terminal deoxynucleotide, dCMP. Formation of the covalent pTP-dCMP initiation complex with Ad DNA as the template requires the viral-encoded pTP and DNA polymerase and, in the presence of the Ad DNA binding protein, is dependent upon a 47-kDa host protein, nuclear factor I. Initiation of replication with recombinant plasmid templates requires the aforementioned proteins and an additional host protein, factor pL. Deletion mutants of the Ad DNA replication origin contained within the 6.6-kilobase plasmid pLA1 were used to analyze the nucleotide sequences required for the formation and subsequent elongation of the pTP-dCMP initiation complex. The existence of two domains within the first 50 base pairs of the Ad genome, both of which are required for the efficient use of recombinant DNA molecules as templates in an in vitro DNA replication system, was demonstrated. The first domain, consisting of a 10-base-pair "core" sequence located at nucleotide positions 9-18, has been identified tentatively as a binding site for the pTP [ Rijinders , A. W. M., van Bergen, B. G. M., van der Vliet , P. C. & Sussenbach , J. S. (1983) Nucleic Acids Res. 11, 8777-8789]. The second domain, consisting of a 32-base-pair region spanning nucleotides 17-48, was shown to be essential for the binding of nuclear factor I.

Characterization of a host range mutant of human adenovirus 12 defective in early region 1B

We isolated an adenovirus 12 early region 1B mutant (in206B) by ligation of the cleaved DNA-protein complex and transfection of human embryo kidney cells with the ligation products. By deduction from the DNA sequencing analysis, the two polypeptides (with molecular weights of 19,000 and 54,000) coded in the early region 1B were fused in this mutant to produce a large polypeptide. This mutant could replicate efficiently in 293 cells but not efficiently in KB or human embryo kidney cells. In KB cells, viral DNA replication could not be detected after infection with in206B. In human embryo kidney cells, viral DNA replication did occur, but the transition of viral mRNA patterns from early to late did not occur even after DNA replication, resulting in failure to produce the late polypeptides. These results indicate that the early region 1B products may be involved in both viral DNA replication and regulation of transcription.

Site-specific nicking within the adenovirus inverted terminal repetition

Site-specific nicking occurs on the l-strand, but not on the r-strand, of the adenovirus left inverted terminal repeat. Nicks are presumably introduced into double- or single-stranded DNA by a cellular endonuclease in an ATP-independent reaction. The consensus nick site has the sequence: (sequence in text).