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.     

The nucleotide sequence of adenovirus type 5 early region E1: the region between map positions 8.0 (HindIII site) and 11.8 (SmaI site)

The nucleotide sequence of the region between map positions 8.0 (HindIII site) and 11.8 (SmaI site) of adenovirus type 5 (Ad5) has been determined. Together with the sequences reported earlier (Van Ormondt et al., 1978; Maat and Van Ormondt, 1979) it encompasses the entire leftmost early region E1 of Ad5 DNA (4126 base pairs). The total sequence revealed a number of potential regulatory signals (promoter sites, ribosome binding sites, 3'-poly(A)-associated sequences), which confirm that region E1 is divided into subregions, E1a and E1b, and a region coding for semi-late viral protein IX. By taking into account the adenovirus 2 (Ad2) RNA-splicing data of Perricaudet et al. (1979; 1980) and the Ad2 RNA mapping data of Chow et al. (1979) we predict that E1a codes for polypeptides of 32, 26 and ca. 13 kd, and subregion E1b for polypeptides of 67 kd and 20 kd; the expected molecular weight of protein IX is 14.4 kd.     

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.     

Structure and organization of the gene coding for the DNA binding protein of adenovirus type 5

We have determined the nucleotide sequence of a region of adenovirus type 5 (Ad5) DNA located between map positions 61.7 and 71.4, which covers the gene form the 72 kD DNA binding protein (DBP) and the sequence encoding the amino-terminal part of the 100 kD protein. Sequence analysis of cDNA copies of DBP mRNA revealed the existence of two abundant species of spliced mRNA molecules. One species consists of two short leader sequences from positions 75.2 (67 and 68 nucleotides long) and 68.8 (77 nucleotides long), respectively, and the main body of the RNA molecules. The other species contains only the leader sequence from position 75.2 and the main body. The amino acid sequence of DBP is encoded entirely by a long open reading frame of 1587 nucleotides in the main body of DBP mRNA. From the nucleotide sequence of the DBP gene it can be derived that DBP contains 529 amino acid residues and has an actual molecular weight of 59,049 daltons. The sites of mutation in the mutants H5hr404 and H5ts125 were determined at the nucleotide level. Single nucleotide alterations were detected in H5hr404 and H5ts125 in the sequences corresponding to the amino-terminal part and the carboxy-terminal part of DBP, respectively. The implications of these mutations are discussed.     

Role for the adenovirus IVa2 protein in packaging of viral DNA

Although it has been demonstrated that the adenovirus IVa2 protein binds to the packaging domains on the viral chromosome and interacts with the viral L1 52/55-kDa protein, which is required for viral DNA packaging, there has been no direct evidence demonstrating that the IVa2 protein is involved in DNA packaging. To understand in greater detail the DNA packaging mechanisms of adenovirus, we have asked whether DNA packaging is serotype or subgroup specific. We found that Ad7 (subgroup B), Ad12 (subgroup A), and Ad17 (subgroup D) cannot complement the defect of an Ad5 (subgroup C) mutant, pm8001, which does not package its DNA due to a mutation in the L1 52/55-kDa gene. This indicates that the DNA packaging systems of different serotypes cannot interact productively with Ad5 DNA. Based on this, a chimeric virus containing the Ad7 genome except for the inverted terminal repeats and packaging sequence from Ad5 was constructed. This chimeric virus replicates its DNA and synthesizes Ad7 proteins, but it cannot package its DNA in 293 cells or 293 cells expressing the Ad5 L1 52/55-kDa protein. However, this chimeric virus packages its DNA in 293 cells expressing the Ad5 IVa2 protein. These results indicate that the IVa2 protein plays a role in viral DNA packaging and that its function is serotype specific. Since this chimeric virus cannot package its own DNA, but produces all the components for packaging Ad7 DNA, it may be a more suitable helper virus for the growth of Ad7 gutted vectors for gene transfer.     

Physical organization of subgroup B human adenovirus genomes.

Cleavage sites of nine bacterial restriction endonucleases were mapped in the DNA of adenovirus type 3 (Ad3) and Ad7, representative serotypes of the "weakly oncogenic" subgroup B human adenoviruses. Of 94 sites mapped, 82 were common to both serotypes, in accord with the high overall sequence homology of DNA among members of the same subgroups. Of the sites in Ad3 and Ad7 DNA, fewer than 20% corresponded to mapped restriction sites in the DNA of Ad2 or Ad5. The latter serotypes represent the "nononcogenic" subgroup C, having only 10 to 20% overall sequence homology with the DNA of subgroup B adenoviruses. Hybridization mapping of viral mRNA from Ad7-infected cells resulted in a complex physical map that was nearly identical to the map of early and late gene clusters in Ad2 DNA. Thus the DNA sequences of human adenoviruses of subgroups B and C have significantly diverged in the course of viral evolution, but the complex organization of the adenovirus genome has been rigidly conserved.     

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.     

Cloning and sequencing of the bovine adenovirus type 2 early region 4

Bovine adenovirus type 2 (BAV2) is a medium size double-stranded DNA virus which infects both bovine and ovine species, resulting in mild respiratory and gastrointestinal disorders. To better understand the virus and its growth characterisitics in Madin-Darby bovine kidney (MDBK) cells, we have cloned and sequenced the extreme right-end segment of the BAV2 genome (90.5–100 map units). Analysis of the nucleotide sequence revealed 40 potential open reading frames (ORFs) with coding capacity for polypeptides that are 25 or more amino acid (aa) residues long. Six of these ORFs encode polypeptides that show homology to well-characterized early region 4 (E4) proteins of human adenovirus type 2 (Ad2) and Ad12. ORF1 has the potential to encode a 114 aa long polypeptide that is 54% homologous to the E4 14 kDa protein of Ad2. ORF2 encodes a 78 aa long polypeptide that exhibits 40% homology to the E4 13 kDa protein of Ad2. ORFs 3–6 encode polypeptides that have homology to the E4 34 kDa protein encoded by ORF6 of Ad2 and Ad12. ORFs 3, 4 and 5 encode 128, 96 and 31 aa long polypeptides, respectively. The 128-aa polypeptide exhibits 59% homology, while the 96 and 31 aa long polypeptides exhibit 61% and 70% homology to the E4 34 kDa protein, respectively. ORF6 has the potential to encode a 57 aa long polypeptide that has 67% homology to the E4 34 kDa protein of Ad2 and 50% homology to the E4 34 kDa protein of Ad12.     

The nucleotide sequence of the polypeptide IX gene of human adenovirus type 3

The nucleotide sequence of the DNA segment encompassing the polypeptide IX gene of class B human adeno-virus serotype 3 (Ad3) has been determined using cloned restriction fragments. There is only a single, open translational reading frame capable of specifying a protein of 138 amino acids, comparable to the M_r 12000–13000 of protein IX detected in virions (Wadell, 1980). The corresponding region of a closely related class B virus, Ad7, is virtually identical (Dijkema et al., 1981), but the comparable segments of class C viruses Ad2 or Ad5 are much less homologous (Aleström et al., 1980; Maat et al., 1980). There are 150 single bp changes and 19 deletion-insertions, at least one frameshift, together affecting 210 nucleotides within the 455 bp comparison positions of the protein-coding regions of Ad2 (423 bp) and Ad3 (417 bp). Each of the 19 deletion-insertions involves an integral multiple of 3 bp in phase with the open translation frame. There is no “TATA” promoter box in Ad3 DNA at the position comparable to that of Ad2. The deduced protein sequences near the amino-terminus are extensively conserved between the two classes of viruses, but the carboxy-terminal portion and the nucleotide sequences flanking the gene are much more diverged. In both classes, these N- and C-terminal regions of the inferred proteins are linked by an alanine-rich chain, an arrangement suggestive of two functional domains.     

The nucleotide sequence of the genes encoded in early region 2b of human adenovirus type 7

The nucleotide sequence of a cloned DNA segment encoding the early region 2b from the group B human adenovirus Ad7 has been determined. When compared to Ad2, a group C adenovirus, these sequences were found to be approx. 80% homologous within the l-strand gene-coding regions. Most changes are transitions or transversions, although several deletions/insertions also occur within the N-terminal domain of one of the coding regions. The substantial nucleotide homology results in a high degree of amino acid conservation in the predicted polypeptides encoded by the early region 2b genes. Two major open reading frames, corresponding to the Mr 87000 and Mr 140000 polypeptides of Ad2, are found in the l strand of Ad7 between genome coordinates 28.5 to 23.1 and 13.8, respectively. The r strand of the DNA in this region encodes the three leader segments joined to the 5' end of the most late viral mRNAs, and also encodes the i-leader segment found between the second and third leaders on some mRNAs. The positions of the donor and acceptor splice sites of the three leaders are conserved and can be identified by homology to Ad2. Only two of the unidentified open reading frames (URF) in Ad2 (Gingeras et al., J. Biol. Chem., in press) can be found in Ad7. URF1, encoding an Mr 13500 polypeptide at genome coordinate 17, is predominantly conserved in nucleotide and amino acid sequence, but contains one half as many arginine amino acids as does URF1 of Ad2. URF2, encoding an Mr 13600 protein which lies within the i-leader region, is not well conserved in either nucleotide or amino acid sequence.     

Human adenovirus early region 4 open reading frame 1 genes encode growth-transforming proteins that may be distantly related to dUTP pyrophosphatase enzymes.

An essential oncogenic determinant of subgroup D human adenovirus type 9 (Ad9), which uniquely elicits estrogen-dependent mammary tumors in rats, is encoded by early region 4 open reading frame 1 (E4 ORF1). Whereas Ad9 E4 ORF1 efficiently induces transformed foci on the established rat embryo fibroblast cell line CREF, the related subgroup A Ad12 and subgroup C Ad5 E4 ORF1s do not (R. T. Javier, J. Virol. 68:3917-3924, 1994). In this study, we found that the lack of transforming activity associated with non-subgroup D adenovirus E4 ORF1s in CREF cells correlated with significantly reduced protein levels compared to Ad9 E4 ORF1 in these cells. In the human cell line TE85, however, the non-subgroup D adenovirus E4 ORF1s produced protein levels higher than those seen in CREF cells as well as transforming activities similar to that of Ad9 E4 ORF1, suggesting that all adenovirus E4 ORF1 polypeptides possess comparable cellular growth-transforming activities. In addition, searches for known proteins related to these novel viral transforming proteins revealed that the E4 ORF1 proteins had weak sequence similarity, over the entire length of the E4 ORF1 polypeptides, with a variety of organismal and viral dUTP pyrophosphatase (dUTPase) enzymes. Even though adenovirus E4 ORF1 proteins lacked conserved protein motifs of dUTPase enzymes or detectable enzymatic activity, E4 ORF1 and dUTPase proteins were predicted to possess strikingly similar secondary structure arrangements. It was also established that an avian adenovirus protein, encoded within a genomic location analogous to that of the human adenovirus E4 ORF1s, was a genuine dUTPase enzyme. Although no functional similarity was found for the E4 ORF1 and dUTPase proteins, we propose that human adenovirus E4 ORF1 genes have evolved from an ancestral adenovirus dUTPase and, from this structural framework, developed novel transforming properties.     

Electron microscopy of late adenovirus type 2 mRNA hybridized to double-stranded viral DNA.

R loops were generated with late adenovirus type 2 (Ad2) mRNA in double-stranded viral DNA, and visualized by electron microscopy. Unpaired DNA sequences in Ad2:Ad2+ND4 heteroduplex DNA served as a visual marker for the orientation of R loops with respect to the conventional DNA map. The most abundant classes of late Ad2 mRNA observed by this technique hybridized, in order of R-loop frequency, with midpoints near posit1ons 0.57, 0.88, 0.77, and 0.40 to 0.50 of the DNA map. The R loop at position 0.57, 0.88, 0.77, and 0.40 containing the hexon gene; the one at position 0.88 corresponded to a region containing the fiber gene. The relative frequencies of these two R loops paralleled those of the encoded gene products. The mRNA sizes, calculated from those of the respective R loops, were slightly larger than needed to code for these polypeptides. Using the R-loop technique, two locations at which adjacent mRNA''s hybridized to different strands were accurately mapped at positions 0.61 and 0.91 of the DNA. The map positions of late Ad2 mRNA correlated well to published RNA and protein maps.     

The genes of influenza virus

The 5′ terminal sequences of several adenovirus 2 (Ad2) mRNAs, isolated late in infection, are complementary to sequences within the Ad2 genome which are remote from the DNA from which the main coding sequence of each mRNA is transcribed. This has been observed by forming RNA displacement loops (R loops) between Ad2 DNA and unfractionated polysomal RNA from infected cells. The 5′ terminal sequences of mRNAs in R loops, variously located between positions 36 and 92, form complex secondary hybrids with single-stranded DNA from restriction endonuclease fragments containing sequences to the left of position 36 on the Ad2 genome. The structures visualized in the electron microscope show that short sequences coded at map positions 16.6, 19.6 and 26.6 on the R strand are joined to form a leader sequence of 150–200 nucleotides at the 5′ end of many late mRNAs. A late mRNA which maps to the left of position 16.6 shows a different pattern of second site hybridization. It contains sequences from 4.9?6.0 linked directly to those from 9.6?10.9. These findings imply a new mechanism for the biosynthesis of Ad2 mRNA in mammalian cells.     

Protein IX, a minor component of the human adenovirus capsid, is essential for the packaging of full length genomes.

Human adenovirus type 5 (Ad5) contains a 36-kb double-stranded DNA molecule in an icosahedral capsid. Attempts to construct Ad5 insertion mutants containing DNA of more than about 105% of the genome size resulted in viral progeny in which deletions had occurred suggesting the existence of severe constraints on the size of packageable DNA molecules. To partially circumvent these constraints we used an adenovirus vector, Ad5dlE1,3, with deletions in early regions 1 (E1) and 3 for a total net reduction in genome size of 5349 bp and an expected capacity for inserts of greater than 7 kb. To use this vector efficiently we generated a circular form of dlE1,3 DNA which could be propagated as an infectious bacterial plasmid. When this plasmid was used as a recipient for inserts of various sizes it was found that its capacity was much less than expected and that dlE1,3 virion capsids could not even package DNA as large as the wt genome. Because the E1 deletion of dlE1,3 extends into the coding sequences for protein IX, a minor capsid component known to affect the heat stability of adenovirions, the possibility that absence of this polypeptide might also affect the DNA capacity of the virion was investigated. It was found that when the coding sequences for protein IX were restored the packaging capacity of the vector was also restored to that of wt virions. Thus protein IX is an essential constituent of virion capsids dispensable only for virions containing DNA of less than genomic size.     

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.     

The nucleotide sequence of the transforming HindIII-G fragment of adenovirus type 5 DNA. The region between map positions 4.5 (HpaI site) and 8.0 (HindIII site).

The nucleotide sequence of the region between map positions 4.5 (HpaI-site) and 8.0 (HindIII-site) of adenovirus type 5 (Ad5) DNA has been determined. This stretch of DNA is part of the transforming HindIII-G fragment, which is 2809 nucleotides long. The sequenced segment was found to have a long open reading frame for protein biosynthesis, starting 23 nucleotides from the HpaI site and extending all the way to the HindIII-G site, which could code for a protein of at least 44 000 daltons. The possible correlation beteen the coding capacity of the HindIII-G fragment and the "transforming" proteins specified by it will be discussed in the light of the recent data on the splicing of early mRNAs.     

Mapping of an adenovirus function involved in the inhibition of DNA degradation.

A function involved in the inhibition of DNA degradation has been assigned through complementation tests to a product of region E1b of the adenovirus genome (between 4.5 and 10.5 map units). DNA degradation induced by the adenovirus type 12 (Ad12) cyt mutant H12cyt70 and the Ad5 early deletion mutant dl313 (with the deletion between 3.5 and 10.7 map units) was inhibited by coinfection with Ad5 region E1a (between 0 and 4.5 map units) mutants dl312 and hr1 and region E1b mutant hr6. The defect of inhibition of DNA degradation in Ad5 dl313 was also complemented in 293 cells. This DNase-inhibitory function does not appear to involve polypeptide IX or the 58,000-dalton polypeptide. Wild-type Ad12 induced DNA degradation in hamster embryo cells, suggesting that the DNase-inhibitory function is not expressed in these nonpermissive cells. Additional evidence suggests the involvement of a second viral product which positively influences the DNase activity and which appears to be an early function.