Cory Abate

Transcriptional regulation by Fos and Jun in vitro: interaction among multiple activator and regulatory domains.

The proteins encoded by the proto-oncogenes c-fos and c-jun (Fos and Jun, respectively) form a heterodimeric complex that regulates transcription by interacting with the DNA-regulatory element known as the activator protein 1 (AP-1) binding site. Fos and Jun are members of a family of related transcription factors that dimerize via a leucine zipper structure and interact with DNA through a bipartite domain formed between regions of each protein that are rich in basic amino acids. Here we have defined other domains in the Fos-Jun heterodimer that contribute to transcriptional function in vitro. Although DNA-binding specificity is mediated by the leucine zipper and basic regions, Jun also contains a proline- and glutamine-rich region that functions as an ancillary DNA-binding domain but does not contribute directly to transcriptional activation. Transcriptional stimulation in vitro was associated with two regions in Fos and a single N-terminal activation domain in Jun. These activator regions were capable of operating independently; however, they appear to function cooperatively in the heterodimeric complex. The activity of these domains was modulated by inhibitory regions in Fos and Jun that repressed transcription in vitro. In the context of the heterodimer, the Jun activation domain was the major contributor to transcriptional stimulation and the inhibitory regions in Fos were the major contributors to transcriptional repression in vitro. Potentially, the inhibitory domains could serve a regulatory function in vivo. Thus, transcriptional regulation by the Fos-Jun heterodimer results from a complex integration of multiple activator and regulatory domains.

Jun is phosphorylated by several protein kinases at the same sites that are modified in serum-stimulated fibroblasts.

c-jun is a member of the family of immediate-early genes whose expression is induced by factors such as serum stimulation, phorbol ester, and differentiation signals. Here we show that increased Jun synthesis after serum stimulation is accompanied by a concomitant increase in phosphorylation. Several serine-threonine kinases were evaluated for their ability to phosphorylate Jun in vitro. p34cdc2, protein kinase C, casein kinase II, and pp44mapk phosphorylated Jun efficiently, whereas cyclic AMP-dependent protein kinase and glycogen synthase kinase III did not. The sites phosphorylated by p34cdc2 were similar to those phosphorylated in vivo after serum induction. The major sites of phosphorylation were mapped to serines 63, 73, and 246. Phosphorylation of full-length Jun with several kinases did not affect the DNA-binding activity of Jun homodimers or Fos-Jun heterodimers. Comparison of the DNA binding and in vitro transcription properties of wild-type and mutated proteins containing either alanine or aspartic acid residues in place of Ser-63, -73, and -246 revealed only minor differences among homodimeric complexes and no differences among Fos-Jun heterodimers. Thus, phosphorylation of Jun did not produce a significant change in dimerization, DNA-binding, or in vitro transcription activity. The regulatory role of phosphorylation in the modulation of Jun function is likely to be considerably more complex than previously suggested.

Fos and jun cooperate in transcriptional regulation via heterologous activation domains.

The products of c-fos and c-jun (Fos and Jun) function in gene regulation by interacting with the AP-1 binding site. Here we have examined the contribution of Fos and Jun toward transcriptional activity by using Fos and Jun polypeptides purified from Escherichia coli. Fos contained a transcriptional activation domain as well as a region which exerted a negative influence on transcriptional activity in vitro. Moreover, distinct activation domains in both Fos and Jun functioned cooperatively in transcriptional stimulation. Thus, regulation of gene expression by Fos and Jun results from an integration of several functional domains in a bimolecular complex.