Restriction mapping and molecular cloning of adenovirus type 4 (subgroup E) DNA

The locations of thirty restriction endonuclease cleavage sites were determined on the genome of adenovirus type 4 (Ad4), the sole member of the subgroup E adenovirions. The restriction endonucleases BglII, EcoRI, HindIII, HpaI, KpnI, SalI, and XbaI cut Ad4 DNA 10, 3, 2, 3, 5, 5 and 3 times, respectively. Orientation of the linear Ad4 map with respect to left and right molecular ends was accomplished by taking advantage of the limited sequence homology between Ad2 and Ad4. Ten non-overlapping fragments of Ad4 DNA representing 98% of the genome, map units 1.6 to 99.6, have been cloned into the plasmid vector pKC7.     

Sequence of the DNA-binding protein gene of a human subgroup B adenovirus (type 7). Comparisons with subgroup C (type 5) and subgroup A (type 12)

The adenovirus type 7 (Ad7) single-stranded DNA-binding protein (DBP) structural gene has been sequenced and located between 66.7 and 62.3 map units. This region codes for a protein that contains 517 amino acid residues with a calculated molecular mass of 58,240 daltons. We compared the Ad7 amino acid sequence with those reported for the Ad5 (Kruijer, W., van Schaik, F.M.A., and Sussenbach, J.S. (1981) Nucleic Acids Res. 9, 4439-4457) and Ad12 (Kruijer, W., van Schaik, F.M.A., Speijer, J.G., and Sussenbach, J.S. (1983) Virology 128, 140-153) DNA-binding proteins. A greater amount of amino acid sequence homology was found in the carboxyl-terminal DNA-binding domain of the molecule. This homology is 61% between Ad7 and Ad5 and 49% when Ad12 was included in the comparison. The NH2-terminal domain of DBP retained a 49% homology between Ad7 and Ad5 and a 23% homology for all three serotypes. The greatest difference between the Ad7 and Ad5 DBPs is the absence, in the Ad7 protein, of 12 amino acids located between the two functional domains in the Ad5 protein (amino acids 151-162). In addition, three regions of high amino acid conservation between Ad5, Ad7, and Ad12 consisting of 9 (178-186), 9 (322-330), and 12 (464-475) consecutive amino acids (numbers refer to Ad5) in the DNA-binding portion of the molecule were revealed. These three regions contain a centrally located basic amino acid (183, 326, and 470) as well as an aromatic amino acid residue (181, 324, and 469). Since basic and aromatic amino acids have been implicated in other single-stranded DNA-binding protein/DNA interactions (Anderson, R.A., Nakashima, V., and Coleman, J.E. (1975) Biochemistry 14,907-917; Kowalczykowski, S.C., Lonberg, N., Newport, J.W., and von Hippel, P.H. (1981). J. Mol. Biol. 145, 75-104), these three conserved regions may represent DBP/DNA contact points.     

Several E4 region functions influence mammary tumorigenesis by human adenovirus type 9

Among oncogenic adenoviruses, human adenovirus type 9 (Ad9) is unique in eliciting exclusively estrogen-dependent mammary tumors in rats and in not requiring viral E1 region transforming genes for tumorigenicity. Instead, studies with hybrid viruses generated between Ad9 and the closely related nontumorigenic virus Ad26 have roughly localized an Ad9 oncogenic determinant(s) to a segment of the viral E4 region containing open reading frame 1 (E4-ORF1), E4-ORF2, and part of E4-ORF3. Although subsequent findings have shown that E4-ORF1 codes for an oncoprotein essential for tumorigenesis by Ad9, it is not known whether other E4 region functions may similarly play a role in this process. We report here that new results with Ad9/Ad26 hybrid viruses demonstrated that the minimal essential Ad9 E4-region DNA sequences include portions of both E4-ORF1 and E4-ORF2. Investigations with Ad9 mutant viruses additionally showed that the E4-ORF1 protein and certain E4-ORF2 DNA sequences are necessary for Ad9-induced tumorigenesis, whereas the E4-ORF2 and E4-ORF3 proteins are not. In fact, the E4-ORF3 protein was found to antagonize this process. Also pertinent was that certain crucial nucleotide differences between Ad9 and Ad26 within E4-ORF1 and E4-ORF2 were found to be silent with respect to the amino acid sequences of the corresponding proteins. Furthermore, supporting a prominent role for the E4-ORF1 oncoprotein in Ad9-induced tumorigenesis, an E1 region-deficient Ad5 vector that expresses the Ad9 but not the Ad26 E4-ORF1 protein was tumorigenic in rats and, like Ad9, promoted solely mammary tumors. These findings argue that the E4-ORF1 oncoprotein is the major oncogenic determinant of Ad9 and that an undefined regulatory element(s) within the E4 region represents a previously unidentified second function likewise necessary for tumorigenesis by this virus.     

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.     

Complementation of human adenovirus type 5 ts mutants by human adenovirus type 12.

Temperature-sensitive mutants of type 5 adenovirus belonging to eight complementation groups were complemented in mixed infection by type 12 adenovirus, whereas mutants of 7 other groups were not enhanced. In some crosses, phenotypic mixing took place. No evidence of recombination between type 5 ts mutants and type 12 was found.     

Bovine adenovirus type 3 internalization is independent of primary receptors of human adenovirus type 5 and porcine adenovirus type 3

Usefulness of adenoviral vectors derived from human adenovirus (HAd) type 5 (HAd5) is mainly limited by wide prevalence of preexisting anti-HAd5 immunity as well as non-specific tissue tropism of these vectors. As an alternative, non-human adenoviral vectors including bovine adenovirus type 3 (BAd3) are currently being investigated. Non-prevalence of BAd3 in humans and its ability to evade preexisting HAd immunity are some of the features that make BAd3 a promising vector for human gene delivery. BAd3 appears to have a tissue tropism distinct from that of HAd5 and also the repertoire of cells efficiently transduced by BAd3 is different. We performed antibody-mediated receptor blocking experiments to show that BAd3 internalization was independent of coxsackievirus-adenovirus receptor, the primary determinant of HAd5 tropism, or integrin alpha(v)beta3, a secondary molecule involved in HAd5 entry. Using homologous and heterologous knob-mediated competition assays with recombinant knobs of HAd5, porcine adenovirus type 3 (PAd3), or BAd3, we observed that BAd3 internalization was independent of the primary receptors of HAd5 and PAd3. These results provide support for further exploration of BAd3 vectors for designing targeted vectors for human gene therapy.     

Induction of apoptosis by adenovirus E4orf4 protein

Adenovirus E4orf4 protein is a multifunctional viral regulator that induces p53-independent apoptosis in transformed cells, but not in normal cells. E4orf4-induced apoptosis can occur without activation of known caspases, although E4orf4 induces caspase activity in some cell lines. The interaction of E4orf4 with a specific subpopulation of protein phosphatase 2A (PP2A) molecules that contain B subunits, but not with those that contain B subunits, is required for induction of apoptosis. This review suggests the potential use of E4orf4 in cancer therapy, and discusses whether E4orf4-induced apoptosis plays a role in the viral life cycle. Future research directions are also highlighted.     

Two distinct activities contribute to the oncogenic potential of the adenovirus type 5 E4orf6 protein

Previous studies have shown that the adenovirus type 5 (Ad5) E4orf6 gene product displays features of a viral oncoprotein. It initiates focal transformation of primary rat cells in cooperation with Ad5 E1 genes and confers multiple additional transformed properties on E1-expressing cells, including profound morphological alterations and dramatically accelerated tumor growth in nude mice. It has been reported that E4orf6 binds to p53 and, in the presence of the Ad5 E1B-55kDa protein, antagonizes p53 stability by targeting the tumor suppressor protein for active degradation. In the present study, we performed a comprehensive mutant analysis to assign transforming functions of E4orf6 to distinct regions within the viral polypeptide and to analyze a possible correlation between E4orf6-dependent p53 degradation and oncogenesis. Our results show that p53 destabilization maps to multiple regions within both amino- and carboxy-terminal parts of the viral protein and widely cosegregates with E4orf6-dependent acceleration of tumor growth, indicating that both effects are related. In contrast, promotion of focus formation and morphological transformation require only a carboxy-terminal segment of the E4 protein. Thus, these effects are completely independent of p53 stability, but may involve other interactions with the tumor suppressor. Our results demonstrate that at least two distinct activities contribute to the oncogenic potential of Ad5 E4orf6. Although genetically separable, both activities are largely mediated through a novel highly conserved, cysteine-rich motif and a recently described arginine-faced amphipathic alpha helix, which resides within a carboxy-terminal "oncodomain" of the viral protein.     

Sequence of the immunoregulatory early region 3 and flanking sequences of adenovirus type 35

Adenovirus type 35 (Ad35) is an important pathogen in immunosuppressed individuals such as AIDS patients and bone marrow transplant recipients. Ad35, a member of Ad subgroup B, differs with respect to pathogenic properties from the more fully characterized subgroup C Ad, such as Ad2 and Ad5. One region of human Ad which varies between subgroups and which may influence Ad pathogenesis is early region 3 (E3), a region which appears to modulate the immune response to Ad infection. In order to begin to characterize the differences between the Ad35 E3 and the E3 of other Ad, the complete DNA sequence of the Ad35 E3 promoter and coding sequence along with two flanking structural proteins, pVIII and fiber, has been determined. Ad35 contains open reading frames which are unique to the subgroup B Ad in addition to the four characterized immunoregulatory proteins encoded by the subgroup C Ad. Further evaluation of the sequence of one of these proteins, 18.5K, which is the class-I major histocompatibility complex (MHC) binding protein of 18.5 kDa, demonstrates that the amino acid sequence of this Ad2 gp19K homologue fits a proposed model of gp19K-MHC interaction. Analysis of promoter sequences demonstrates that an NF-κB site found in the subgroup C E3 promoter is absent from the Ad35 E3 promoter. In addition, the fiber genes of Ad35 and other subgroup B Ad have been shown to diverge in an unexpected way, yielding three clusters of fiber homology.