Altered AP-1/ATF complexes in adenovirus-E1-transformed cells due to EIA-dependent induction of ATF3.

The adenovirus (Ad) E1A proteins alter the expression level and activity of AP-1/ATF transcription factors. Previously we have shown that in AdE1-transformed cells cJun is hyperphosphorylated in its N-terminal transactivation domain, which parallels enhanced transactivation function. To find out whether the interaction between cJun and other cellular proteins is altered, we have searched for proteins which would physically associate with cJun. In this report we show that in AdE1-transformed cells cJun specifically associates with two proteins of 21 and 23 kD. These proteins are not expressed at detectable levels in the parental cells or in cells transformed by oncogenes other than AdE1. The cJun-associated proteins represent different forms of the bZIP transcription factor ATF3, the human homolog of rat LRF1. The expression of ATF3 is induced in AdE1-transformed cells and is a direct effect of the expression of E1A. Through induction of ATF3 expression and the subsequent formation of cJun/ATF3 heterodimers, E1A alters the repertoire of AP-1/ATF factors and may thereby redirect the corresponding gene-expression program. Since the induction of ATF3 is a function of sequences within the transforming 12S-ElA protein, cJun/ATF3 complexes might be involved in establishing cellular transformation by AdE1A.

Modulation of AP-1/ATF transcription factor activity by the adenovirus-E1A oncogene products.

The proteins encoded by early region 1 A (E1A) of human adenoviruses (Ad) modulate the expression of both adenovirus genes and various host cell genes. With these transcription-regulating properties the E1A proteins redirect the cell's metabolism, which enables them to induce oncogenic transformation in rodent cells. The E1A proteins modulate transcription by interacting both with gene-specific and general cellular transcription factors. Various members of the AP-1 and ATF/CREB families of transcription factors are targets for E1A-dependent regulation, including cJun, the protein product of the c-jun proto-oncogene. The E1A proteins modulate cJun-dependent transcription both positively and negatively, and affect the activity as well as the expression levels of cJun. By increasing the phosphorylation status of cJun, E1A can stimulate transcription regulated by cJun/ATF2 heterodimers. In contrast, E1A inhibits the expression of various metalloproteases by interfering with the DNA-binding capacity of cJun/cJun and cJun/cFos dimers, which might involve the association of E1A with the putative transcriptional coactivator p300. Since the ability of E1A to alter cJun-dependent transcription correlates with its transforming capacity, interference with cJun-dependent transcription may be an essential step in E1A-induced transformation.

The N-terminal region of the adenovirus type 5 E1A proteins can repress expression of cellular genes via two distinct but overlapping domains.

The transforming E1A 12S and E1A 13S proteins of human adenovirus type 5 (Ad5) contain two and three conserved regions, respectively. In the present study, the contribution of sequences in the nonconserved N-terminal region of the E1A proteins to morphological transformation and to down-regulation of a number of mitogen-inducible genes was investigated. As described previously, transformation of NRK cells (an established normal rat kidney cell line) results in denser cell growth and a cuboidal cellular morphology. None of the cells expressing N-terminally mutated E1A proteins, however, show these transformed properties, which suggests an important role for sequences in that domain. The decrease in cyclin D1 levels requires exactly the same sequences. The ability to transform NRK cells and to reduce cyclin D1 levels does not correlate with the presence in the E1A proteins of binding domains for p300, CBP, p107, pRb, cyclin A, or cdk2. In contrast, down-regulation of expression of the JE gene in NRK cells and repression of transcription of the collagenase gene in human HeLa cells does correlate with the presence in the E1A proteins of an intact binding domain for p300 and CBP. The results suggest that the N-terminal domain of the E1A proteins can repress expression of cellular genes by at least two different mechanisms.

Adenovirus E1A negatively and positively modulates transcription of AP-1 dependent genes by dimer-specific regulation of the DNA binding and transactivation activities of Jun.

Adenovirus E1A proteins inhibit expression of the collagenase gene but activate expression of the c-jun gene. Both effects are mediated by TPA-responsive elements (TREs), the binding sites for members of the AP-1 transcription factor family. By a process that is independent of the retinoblastoma gene product, E1A distinguishes between different AP-1 factors: in vivo binding of Jun/Jun homodimers and Jun/Fos heterodimers to the collagenase TRE is totally blocked by E1A while, in contrast, there is no inhibition of Jun/ATF-2 binding to the TRE sequences in the c-jun promoter. Altered phosphorylation of the DNA binding domain of cJun is not involved in the inhibition of cJun/cJun and cJun/cFos binding. E1A does, however, cause hyperphosphorylation of the transactivation domain of cJun, which is likely to be responsible for the enhanced c-jun transcription by E1A mediated through cJun/ATF-2 heterodimers.