Homodimeric DNA-binding proteins with relaxed half-site spacing requirements for their DNA targets have been described. As an example, the yeast transcriptional activator Gcn4p binds in vitro equally well to the AP1 site (5'A4T3G2A1C0T1'C2'A3'T4'3') and the ATF/CREB site (5'A4T3G2A1C0G0'T1'C2'A3'T4'3'), which have identical but differently spaced half-site blocks. We describe a novel feature for the bZip class of DNA-binding proteins. The N-14 mutant of a Gcn4p-derived bZip peptide shows a diametrically opposed base-pair recognition specificity depending on the half-site spacing of its DNA target: on pseudo-palindromic, AP1 site-like binding sites, guanine is required in position 2 for proper binding; in contrast, on palindromic, ATF/CREB site-like targets, position 2 must be cytosine to prevent a loss of binding. Modeling studies suggest that the different base-pair requirements on differently spaced DNA targets are due to minimal alterations of the distances between the relevant atoms of the N-14 side-chain and the corresponding target groups on the DNA. Although the N-14 peptide does not have a natural counterpart, its behavior hints at the possibility that dual binding modi dependent on half-site spacing may occur also for natural homodimeric DNA-binding proteins.