Early and late proteins of adenovirus type 12: translation mapping with RNA isolated from infected and transformed cells

Isolation and characterization of adenovirus type 12 E1 host-range mutants defective for growth in nontransformed human cells

In order to define the functions of human adenovirus type 12 (Ad12) early region 1 (E1) products in lytic infection and oncogenic transformation we have isolated and phenotypically characterized a set of host-range (hr) mutants of this serotype. These mutants grow efficiently upon HER3 cells, which contain and express type 12 E1 genes, but are restricted for growth upon A549 carcinoma and HeLa cells. Inter- and intratypic complementation analysis, marker-rescue mapping, and DNA sequence analysis have assigned some of the mutations to E1A sequence, and some to the reading frame encoding the E1B 54-kDa (482R) protein. Phenotypic analysis of the E1B mutants in particular has revealed some interesting, and in some cases surprising, findings relating to the roles of that protein in virus-cell interactions. This Ad12 gene product is required, either directly or indirectly, for efficient viral DNA replication in A549 and HeLa cells, unlike its counterpart in type 5 virus. Surprisingly, however, despite the severe defect in viral DNA replication, the synthesis of a few species of viral late proteins continues in cells infected by some of the E1B mutants. In contrast, none of these mutants brings about the inhibition of host-cell protein synthesis characteristic of wild-type virus infection, and with some E1B mutants no viral late proteins are made. Further, in a separate study reported elsewhere, we have demonstrated that the E1B 54-kDa product may also be involved, either directly or indirectly, in positive regulation of both E1A and E1B 19-kDa (163R) gene expression. The molecular and/or physiological bases for these various effects remain to be determined, but our initial results suggest that the E1B 54-kDa protein may carry out multiple regulatory functions during the viral life cycle.

E1B functions of type C adenoviruses play a role in the complementation of blocked adenovirus type 12 DNA replication and late gene transcription in hamster cells

Adenovirus type 12 (Ad12) DNA cannot replicate in hamster cells and the late Ad12 genes cannot be expressed. It has been demonstrated previously that these defects can be at least partly overcome by coinfection of hamster cells with Ad12 and wild-type adenovirus type 2 (Ad2) or type 5 (Ad5) or by superinfection of Ad2- or Ad5-transformed cells with Ad12. These transformed cell lines carry in an integrated form and constitutively express the E1 region of Ad2 or Ad5. The compensation in Ad12 DNA replication and late gene transcription does not, however, lead to the assembly of intact Ad12 virions. In the present study, it has been demonstrated that the complementing functions in the Ad5 genome, which can effect Ad12 DNA replication and late transcription in hamster cells, reside predominantly but not exclusively in the E1B region. A supporting role in the E1A region is likely. These conclusions have been adduced from the results of double infection experiments using Ad12 and deletion mutants of Ad5. Inside the E1B region of Ad5 DNA, the complementing functions have not yet been precisely located. Although late Ad12 messenger RNAs are synthesized in Ad12 and Ad5-coinfected hamster cells, most of the late structural Ad12 proteins are not made or are made in minimal amounts, and consequently virions are not assembled. It is necessary to investigate whether hamster cells also exhibit a translational block vis à vis the expression of late Ad12-specific mRNAs. The data presented here also demonstrate that Ad12 functions can effectively complement E1A or to a lesser extent E1B deletions in the Ad5 genome in hamster cells. Upon coinfection with Ad12 and deletion mutants of Ad5 in either the E1A or the E1B region, Ad5 DNA and late proteins are synthesized, although Ad5 E1A or E1B functions cannot complement the deficient late Ad12 protein synthesis in hamster cells.