Constructing chimeric type 12/type 5 adenovirus E1A genes and using them to identify an oncogenic determinant of adenovirus type 12.

The E1A gene of highly oncogenic type 12 adenovirus (Ad12) possesses a segment unique to this serotype and comprising 60 base pairs contiguous with and separating conserved regions 2 and 3 in the gene. A similar but slightly longer segment is also present in the E1A gene of highly oncogenic simian adenovirus type 7 (D. Kimelman, J. S. Miller, D. Porter, and B. E. Roberts, J. Virol. 53:399-409, 1985). This segment is missing entirely from the E1A gene of type 5 adenovirus, which is nononcogenic. To test the hypothesis that this unique separating or "spacer" region influences the oncogenicity of Ad12, we constructed ClaI and SmaI restriction sites on either side of it, which allowed reciprocal exchange between this and the equivalent cassette from type 5 adenovirus E1A, bounded by the same restriction sites intrinsic to that gene. The resultant Ad12-based chimeric viruses, ch702 and ch704, in which the spacer region is replaced with (in-frame) type 5 sequence, grow normally on human A549 cells and display wild-type transformation frequencies on baby rat and mouse kidney cells. In contrast, the oncogenic capacity of these chimeric viruses, as measured by tumor induction following virus inoculation in Hooded Lister rats, is greatly reduced. Likewise, cells transformed by ch702 and ch704 display reduced tumorigenicity compared with wild-type transformants in syngeneic rats. These results, coupled with recent preliminary tests using a mutant with a point mutation in this region, support the view that the unique spacer region of type 12 is an oncogenic determinant of this virus.     

trans-dominant interference of type 5 adenovirus E1a mutants in cell transformation.

Two type 5 adenovirus (Ad5) early region 1a (E1a) mutants, H5in104 and H5dl105, were impaired in viral replication and cell transformation. In addition, these mutants trans dominantly inhibited the frequency with which H5sub309, a phenotypically wild-type mutant, and H5dl520, a high-frequency transformation mutant, transformed CREF cells. Inhibition of transformation varied in proportion to the input ratio of mutant to coinfecting virus. It was found that H5in104, but not H5dl105, could not complement Ad5 E1b mutants that failed to synthesize 19- or 55-kDa E1b product. H5dl105 yielded 10-fold less virus than the wild-type did in 293 cells, which constitutively express E1a and E1b products; similar low yields were also observed with H5in104 and H5dl105 in another E1a- and E1b-expressing transformed cell line, KB16. Marker rescue and DNA sequence analyses, however, indicated that the phenotypes of H5in104 and H5dl105 were the result of their respective E1a mutations. The data presented are the first to demonstrate that mutants of animal viruses can effect dominant interference with the viral function(s) that produce cell transformation.     

Transformation-defective mutant of adenovirus type 5 containing a single altered E1a mRNA species.

A mutant of adenovirus type 5 containing an octanucleotide insert in region E1a of the viral genome was constructed. The insert was present in only one (13s) of the three overlapping mRNA's synthesized from this region. The insert was within the sequences removed by RNA splicing during the production of the other two nRNA's. The insertion resulted in a shift in the translational reading frame of the 13s mRNA and the probable premature termination of translation. The mutant was defective for viral DNA replication in HeLa cells and the transformation of rat embryo and baby rat kidney cells, indicating that a product encoded by the 13s nRNA is required for these two processes. Other early regions of the genome were expressed in HeLa cells infected by this mutant although in some cases the expression was decreased as compared with wild-type-infected cells.