Structural basis for dimerization in DNA recognition by Gal4.

Gal4 is a Zn2Cys6 binuclear cluster containing transcription factor that binds DNA as a homodimer and can activate transcription by interacting with the mutant Gal11P protein. Although structures have been reported of the Gal4 dimerization domain and the binuclear cluster domain bound to DNA as a dimer, the structure of the "complete" Gal4 dimer bound to DNA has not previously been described. Here we report the structure of a complete Gal4 dimer bound to DNA and additional biochemical studies to address the molecular basis for Gal4 dimerization in DNA binding.

High-resolution structure of the p53 core domain: implications for binding small-molecule stabilizing compounds.

The p53 transcriptional regulator is the most frequently mutated protein in human cancers and the majority of tumor-derived p53 mutations map to the central DNA-binding core domain, with a subset of these mutations resulting in reduced p53 stability. Here, the 1.55 A crystal structure of the mouse p53 core domain with a molecule of tris(hydroxymethyl)aminomethane (Tris) bound through multiple hydrogen bonds to a region of p53 shown to be important for repair of a subset of tumor-derived p53-stability mutations is reported.

Structure of the p53 core domain dimer bound to DNA.

The p53 tumor suppressor protein binds to DNA as a dimer of dimers to regulate transcription of genes that mediate responses to cellular stress. We have prepared a cross-linked trapped p53 core domain dimer bound to decamer DNA and have determined its structure by x-ray crystallography to 2.3A resolution.

Structure of a Leu3-DNA complex: recognition of everted CGG half-sites by a Zn2Cys6 binuclear cluster protein.

Gal4 is the prototypical Zn2Cys6 binuclear cluster transcriptional regulator that binds as a homodimer to DNA containing inverted CGG half-sites. Leu3, a member of this protein family, binds to everted (opposite polarity to inverted) CGG half-sites, and an H50C mutation within the Leu3 Zn2Cys6 binuclear motif abolishes its transcriptional repression function without impairing DNA binding. We report the X-ray crystal structures of DNA complexes with Leu3 and Leu3(H50C) and solution DNA binding studies of selected Leu3 mutant proteins.

Modulation of DNA-binding domains for sequence-specific DNA recognition.

Sequence-specific DNA-binding proteins use diverse mechanisms to recognize their cognate DNA sites. In addition to direct sequence-specific DNA contacts made by DNA recognition domains, extrinsic factors such as ligand binding, homo- and hetero-dimeric protein associations, and association via other transcription factors can also modulate the DNA-recognition properties of DNA-binding domains. In each case, these extrinsic factors act as molecular switches to facilitate cognate DNA recognition.