Dimerization of leucine zippers analyzed by random selection.

The leucine zipper is a coiled coil that mediates specific dimerization of bZIP DNA-binding domains. A hydrophobic spine involving the conserved leucines runs down the coiled-coil and is thought to stabilize the dimer. We used the method of random selection to further define the primary sequence requirements for homodimer formation and heterodimer formation with Fos. When positions on either side of the hydrophobic spine of GCN4 are diversified to include the corresponding residues of Jun, a large percentage of the resulting sequences form homodimers, and a large percentage form heterodimers with Fos. Basic residues were preferred, but not essential, at position e of zippers which heterodimerize with Fos. When random sequences containing 5 heptad repeat of leucines are subject to a selection for homodimer formation, a diverse set of sequences is isolated. Certain residues are preferred at each position in the heptad repeat, although no essential primary sequence determinants could be identified. No pair of residues not involving the conserved leucines could be identified which strongly promotes homodimerization. These results suggest that factors determining leucine zipper dimerization are complex, with numerous interactions contributing to the association.     

Crystal structure of a super leucine zipper,an extended two‐stranded super long coiled coil

Coiled coil is a ubiquitous structural motif in proteins, with two to seven alpha helices coiled together like the strands of a rope, and coiled coil folding and assembly is not completely understood. A GCN4 leucine zipper mutant with four mutations of K3A, D7A, Y17W, and H18N has been designed, and the crystal structure has been determined at 1.6 Å resolution. The peptide monomer shows a helix trunk with short curved N‐ and C‐termini. In the crystal, two monomers cross in 35° and form an X‐shaped dimer, and each X‐shaped dimer is welded into the next one through sticky hydrophobic ends, thus forming an extended two‐stranded, parallel, super long coiled coil rather than a discrete, two‐helix coiled coil of the wild‐type GCN4 leucine zipper. Leucine residues appear at every seventh position in the super long coiled coil, suggesting that it is an extended super leucine zipper. Compared to the wild‐type leucine zipper, the N‐terminus of the mutant has a dramatic conformational change and the C‐terminus has one more residue Glu 32 determined. The mutant X‐shaped dimer has a large crossing angle of 35° instead of 18° in the wild‐type dimer. The results show a novel assembly mode and oligomeric state of coiled coil, and demonstrate that mutations may affect folding and assembly of the overall coiled coil. Analysis of the formation mechanism of the super long coiled coil may help understand and design self‐assembling protein fibers.     

The role of helix stabilizing residues in GCN4 basic region folding and DNA binding

Basic region leucine zipper (bZip) proteins contain a bipartite DNA-binding motif consisting of a coiled-coil leucine zipper dimerization domain and a highly charged basic region that directly contacts DNA. The basic region is largely unfolded in the absence of DNA, but adopts a helical conformation upon DNA binding. Although a coil --> helix transition is entropically unfavorable, this conformational change positions the DNA-binding residues appropriately for sequence-specific interactions with DNA. The N-terminal residues of the GCN4 DNA-binding domain, DPAAL, make no DNA contacts and are not part of the conserved basic region, but are nonetheless important for DNA binding. Asp and Pro are often found at the N-termini of alpha-helices, and such N-capping motifs can stabilize alpha-helical structure. In the present study, we investigate whether these two residues serve to stabilize a helical conformation in the GCN4 basic region, lowering the energetic cost for DNA binding. Our results suggest that the presence of these residues contributes significantly to helical structure and to the DNA-binding ability of the basic region in the absence of the leucine zipper. Similar helix-capping motifs are found in approximately half of all bZip domains, and the implications of these findings for in vivo protein function are discussed.     

Antiparallel four-stranded coiled coil specified by a 3-3-1 hydrophobic heptad repeat

Coiled-coil sequences in proteins commonly share a seven-amino acid repeat with nonpolar side chains at the first (a) and fourth (d) positions. We investigate here the role of a 3-3-1 hydrophobic repeat containing nonpolar amino acids at the a, d, and g positions in determining the structures of coiled coils using mutants of the GCN4 leucine zipper dimerization domain. When three charged residues at the g positions in the parental sequence are replaced by nonpolar alanine or valine side chains, stable four-helix structures result. The X-ray crystal structures of the tetramers reveal antiparallel, four-stranded coiled coils in which the a, d, and g side chains interlock in a combination of knobs-into-knobs and knobs-into-holes packing. Interfacial interactions in a coiled coil can therefore be prescribed by hydrophobic-polar patterns beyond the canonical 3-4 heptad repeat. The results suggest that the conserved, charged residues at the g positions in the GCN4 leucine zipper can impart a negative design element to disfavor thermodynamically more stable, antiparallel tetramers.     

Stabilities of leucine zipper dimers estimated by an empirical free energy method.

The leucine zipper motif is a characteristic amino acid sequence found in dimeric DNA-binding proteins. Computer-generated models for leucine zippers were constructed as alpha-helical coiled dimers with leucine repeated every seventh residue. An empirical Gibbs free energy, delta G, function which incorporates hydrophobic force, electrostatic interactions, and conformational entropy loss as the major intermolecular interactions was used to estimate the delta G of dimer formation in fos, jun, and GCN4 zipper sequences. The calculations showed that complexes known to form stable homo- or heterodimers have favorable (negative) delta G, while other less stable complexes have unfavorable (positive) delta G. Leucines in position d of the coiled coil contribute large hydrophobic stabilization energies while residues in the a position contribute less to dimer stability. Hydrophobic contributions show little sequence specificity, however, and do not contribute significantly to homo/heterodimer preference. Charged residues in the e and g positions, on the other hand, determine homo/heterodimer specificity. In GCN4 homodimers, residues GLU el, Glu b2, Lys g2, and Lys e4 greatly contribute to dimer stability. The preferential stability of fos-jun heterodimer over the jun-jun and fos-fos homodimers is primarily due to the side chains Asp b1, Glu g1, Asp b2, Glu e2, Glu g2, Glu g3, and Lys a5 of the fos helix, and Arg c1, Lys g1, Lys b2, Lys e2, Arg e4, and Glu g4 of the jun helix.     

An intrahelical salt bridge within the trigger site stabilizes the GCN4 leucine zipper

We previously reported that a helical trigger segment within the GCN4 leucine zipper monomer is indispensable for the formation of its parallel two-stranded coiled coil. Here, we demonstrate that the intrinsic secondary structure of the trigger site is largely stabilized by an intrahelical salt bridge. Removal of this surface salt bridge by a single amino acid mutation induced only minor changes in the backbone structure of the GCN4 leucine zipper dimer as verified by nuclear magnetic resonance. The mutation, however, substantially destabilized the dimeric structure. These findings support the proposed hierarchic folding mechanism of the GCN4 coiled coil in which local helix formation within the trigger segment precedes dimerization.     

Identification of C/EBP basic region residues involved in DNA sequence recognition and half-site spacing preference.

C/EBP and GCN4 are basic region-leucine zipper (bZIP) DNA-binding proteins that recognize the dyad-symmetric sequences ATTGCGCAAT and ATGAGTCAT, respectively. The sequence specificities of these and other bZIP proteins are determined by their alpha-helical basic regions, which are related at the primary sequence level. To identify amino acids that are responsible for the different DNA sequence specificities of C/EBP and GCN4, two kinds of hybrid proteins were constructed: GCN4-C/EBP chimeras fused at various positions in the basic region and substitution mutants in which GCN4 basic region amino acids were replaced by the corresponding residues from C/EBP. On the basis of the DNA-binding characteristics of these hybrid proteins, three residues that contribute significantly to the differences in C/EBP and GCN4 binding specificity were defined. These residues are clustered along one face of the basic region alpha helix. Two of these specificity residues were not identified as DNA-contacting amino acids in a recently reported crystal structure of a GCN4-DNA complex, suggesting that the residues used by C/EBP and GCN4 to make base contacts are not identical. A random binding site selection procedure also was used to define the optimal recognition sequences for three of the GCN4-C/EBP fusion proteins. These experiments identify an element spanning the hinge region between the basic region and leucine zipper domains that dictates optimal half-site spacing (either directly abutted for C/EBP or overlapping by one base pair for GCN4) in high-affinity binding sites for these two proteins.