Genetic analysis of carcinogen enhancement of type 5 adenovirus transformation of cloned Fischer rat embryo fibroblast cells.

Abstract

Pretreatment of CREF cells with methyl methanesulfonate (MMS) before infection with the host-range cold-sensitive type 5 adenovirus (Ad5) mutant H5hr1 results in a dose-dependent carcinogen enhancement of viral transformation (CET). The properties of CET observed with H5hr1, which include both an MMS dose-dependent enhancement in the number of transformed foci and an increase in transformation frequency after correction for cell toxicity, are not observed in carcinogen-pretreated wild-type (wt) Ad5 (H5wt)-infected CREF cells. This study was conducted to determine the role of the viral E1A and E1B transforming genes of H5hr1 in mediating the unique CET phenotype of H5hr1. Coinfection of MMS-pretreated CREF cells with H5wt or H5sub309 (which displays a wt Ad5 phenotype) and H5hr1 resulted in a suppression of the unique CET phenotype that was directly related to the multiplicity of infection with wt Ad5. Suppression of the unique H5hr1 CET phenotype was also apparent in MMS-pretreated CREF cells coinfected with H5hr1 and an Ad5 mutant expressing either a wt 13S E1A-encoded 289 amino-acid (aa) protein and an intact wt E1B gene or a wt 13S E1A-encoded 289-aa protein and a 22S E1B-encoded 495-aa protein. In contrast, the unique H5hr1 CET phenotype was not suppressed in MMS-pretreated CREF cells coinfected with H5hr1 and Ad5 or Ad2 mutants expressing either a wt 12S E1A-encoded 243-aa protein and both wt E1B gene products or an intact wt E1A gene and a wt E1B 13S-encoded 175-aa protein. That genetic changes in both the E1A and E1B viral regions of H5hr1 were required to induce the unique CET phenotype was also indicated by the inability of a recombinant Ad5 containing the 0-4.5 map-unit region of H5hr1 and the 4.5-100 map-unit region of H5sub309 to display the H5hr1 unique CET phenotype. Direct confirmation of the requirement for both gene regions of H5hr1 to mediate its unique CET was obtained by generating CREF cells stably expressing a wt Ad5 E1A 13S-encoded 289-aa protein and a wt E1B 22S-encoded 495-aa protein. In these CREF transformants (which displayed a CREF-like morphology), transformation by H5hr1 was not reduced, but the unique CET phenotype after MMS pretreatment was eliminated. These results suggest that alterations in both the 13S-encoded E1A and 22S-encoded E1B gene products of H5hr1 contribute to its unique CET.