The basic region of Fos mediates specific DNA binding.

The DNA-binding domains of the members of the Fos and Jun families of proteins consist of a basic region followed by a dimerizing segment with heptad repeats of leucine. Fos-Jun heterodimers and Jun alone, but not Fos alone, bind to the symmetrical sequences TGACTCA (AP-1 site) or TGACGTCA (cAMP response element or CRE). We set out to test the hypothesis that in the Fos-Jun heterodimer the basic region of Fos confers specific DNA-binding properties equivalent to the contribution of the basic region of Jun. Fos-Jun chimeric proteins were prepared consisting of the basic region of one protein joined to the leucine repeat of the other. Heterodimers with mixed Fos and Jun leucine repeat segments showed high affinity binding to the AP-1 site or CRE whether they contained two basic regions from Jun, two basic regions from Fos, or one from each source. Heterodimers with two Fos basic regions showed somewhat greater affinity for the CRE and AP-1 site than the heterodimer with two Jun basic regions. The DNA sequence specificity and the purine and phosphate DNA contact sites for each heterodimer were similar. We conclude that in the Fos-Jun heterodimer the basic region of Fos contributes specific DNA-binding properties equivalent to those of Jun. Our results support a model in which the Fos and Jun basic regions of the Fos-Jun heterodimer each interact with symmetrical DNA half sites.     

Fos-Jun heterodimers and Jun homodimers bend DNA in opposite orientations: implications for transcription factor cooperativity

Association of Fos and Jun with the AP-1 site results in a conformational change in the basic amino acid regions that constitute the DNA-binding domain. We show that Fos and Jun induce a corresponding alteration in the conformation of the DNA helix. Circular permutation analysis indicated that both Fos-Jun heterodimers and Jun homodimers induce flexure at the AP-1 site. Phasing analysis demonstrated that Fos-Jun heterodimers and Jun homodimers induce DNA bends that are directed in opposite orientations. Fos-Jun heterodimers bend DNA toward the major groove, whereas Jun homodimers bend DNA toward the minor groove. Fos and Jun peptides encompassing the dimerization and DNA-binding domains bend DNA in the same orientations as the full-length proteins. However, additional regions of both proteins influence the magnitude of the DNA bend angle. Thus, despite the amino acid sequence similarity in the basic region Fos-Jun heterodimers and Jun homodimers form topologically distinct DNA-protein complexes.     

Asymmetrical recognition of the palindromic AP1 binding site (TRE) by Fos protein complexes.

Fos and Jun proteins form a tight complex which binds specifically to the AP1 recognition sequence, a palindromic DNA element also referred to as the TPA responsive element (TRE). To elucidate the mechanism of Fos-Jun interaction with the TRE we have performed UV cross-linking studies using oligonucleotides where thymines were replaced with bromouracil. Our results indicate that both Fos and Jun directly contact the TRE but that the interaction of Fos and Jun with thymines in structurally equivalent positions in the two half sites of the TRE is different. In addition, we have carried out a comprehensive mutagenesis study of the TRE by introducing all possible point mutations plus thymine----uracil substitutions into the palindromic TRE core sequences and the adjacent nucleotides on both sides. The results of this analysis clearly show that the palindromic TRE is asymmetrical with respect to binding of Fos-Jun. We also show that a Fos protein complex with a homodimeric DNA binding site binds considerably less efficiently to TRE mutants with a perfect dyad symmetry compared with the binding to the wild-type TRE. This demonstrates that the asymmetrical recognition of the TRE is not due to the heterodimeric nature of the Fos/Jun complex but directly related to an asymmetry in the TRE sequence. The methyl groups of all four thymine residues within the TRE seem to be functionally crucial since thymine----uracil substitutions strongly reduce or abolish binding to Fos/Jun. The relevance of structurally equivalent methyl groups in the TRE core sequence is different, lending further support to the conclusion that the TRE is asymmetrical.