Genetic Analysis of the Bovine Papillomavirus E2 Transcriptional Activation Domain

AbstractThe bovine papillomavirus type 1 E2 transactivator has a large amino-terminal 215-residue transcriptional activation domain (TAD) that is active inSaccharomyces cerevisiaeand higher eukaryotic cells. Comparison to other transcriptional activators suggests that its functions may be mediated in part through two acidic regions, A1 and A2, in this domain. We have characterized the functional elements within the E2 TAD using LexA–E2 fusions and by screening randomly generated libraries of E2 mutations for transcriptional activation in yeast. The A1 region was highly sensitive to substitutions that reduce negative charge, although there was not a perfect correlation between overall charge and transcriptional activity. Mutations were isolated within a hydrophobic amino acid motif that overlaps the A2 region and resembles elements described in other viral and cellular transactivation domains. When fused to the LexA DNA binding domain, this hydrophobic motif within the acidic A2 region was unable to activate transcription inS. cerevisiae.Multiple highly defective mutations primarily altering hydrophobic amino acids were identified in the distal third of the E2 TAD. The transcription phenotype of many of these E2 TAD mutations was similar in yeast and COS cells

Mechanism of action of the papillomavirus E2 repressor: repression in the absence of DNA binding.

Repression of papillomavirus E2-dependent gene expression was studied by using transient transfections into mouse embryo fibroblast cells. Cotransfection of a gene corresponding to the naturally occurring repressor E2-TR along with the full-length E2 gene resulted in up to 98% repression of E2-dependent reporter gene expression. A series of E2 DNA-binding domain mutants were transferred into the E2-TR form and characterized for their ability to repress E2-dependent transactivation. All mutants which were defective for DNA binding but were dimerization competent repressed E2 transactivation as well or nearly as well as the wild-type repressor. E2 mutants which lacked dimerization activity repressed transactivation poorly or not at all. These results indicate that the E2 repressor can inhibit transcription, in the absence of DNA binding, by forming heterodimers with full-length E2