B-ZIP transcription factors dimerization is mediated by a parallel coiled-coil termed the leucine zipper. We have evaluated the dimerization specificity of the seven coiled-coil B-ZIP proteins (ATF6, XBP, LZIP, NFIL3, TEF, CREB, and C/EBP alpha) with themselves and each other. To do this, we designed dominant negative proteins, termed A-ZIPs, that contain the leucine zipper dimerization domain of a B-ZIP protein and an acidic amphipathic N-terminal extension. The A-ZIPs heterodimerize with B-ZIP proteins in a leucine zipper-dependent manner. The acidic N-terminal extension is hypothesized to form an heterodimeric coiled-coil structure with the basic region, essentially zippering the leucine zipper into the basic region. We now present a new acidic extension design that stabilizes heterodimerization with B-ZIP proteins up to 11 kcal mol(-1). We have used these A-ZIP proteins in a competition EMSA to evaluate which A-ZIP can prevent DNA binding of which B-ZIP domain. Inhibition of DNA binding is interpreted to indicate that the A-ZIP is forming a heterodimer with the B-ZIP domain and thus prevents the B-ZIP from binding to DNA. All leucine zippers examined can homodimerize and two pairs (CREB & NFIL3 and ATF6 & XBP) can heterodimerize. We discuss these results with reference to the amino acid sequence of the leucine zipper region. These A-ZIP reagents may be of value in biological systems to inhibit the DNA binding and transcriptional potential of specific B-ZIP families. Published by Elsevier Inc.
