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.     

Total deletion of yeast LEU4: further evidence for a second alpha-isopropylmalate synthase and evidence for tight LEU4-MET4 linkage

Using a combination of restriction endonuclease digestion, nuclease BAL 31 treatment, and standard ligation procedures, a 4.4-kb DNA segment that carried the yeast LEU4 gene [encoding alpha-isopropylmalate synthase (IPMS) I] and adjoining sequences was excised from an appropriate plasmid and replaced with the yeast HIS3 gene. The new plasmid was digested to obtain a linear HIS3-carrying fragment flanked by remnants of the LEU4 region. Integrative transformation of a LEU4fbr LEU5+ his3- strain with this fragment resulted in the deletion of the LEU4 gene from the genome of some recipients, as demonstrated by transformant phenotype, genetic analysis and the absence of RNA capable of hybridizing to a LEU4 probe. The leu4 deletion strains remained Leu+. The extract of one such strain contained about 18% of the IPMS activity of wild-type cells. It is concluded that the residual activity is that of a second IPMS (IPMS II) that depends on an intact LEU5 locus. IPMS II was inhibited by leucine, but its sensitivity was about an order of magnitude lower than that of IPMS I. Deletion of the LEU4 region by the method utilized here resulted in an amino acid auxotrophy that could be satisfied by methionine, homocysteine, or cysteine. Complementation tests and genetic analysis demonstrated that the affected gene was MET4. Linkage to MET4 would place the LEU4 gene on the left arm of chromosome XIV.     

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.     

Properties of a Trifluoroleucine-Resistant Mutant of Saccharomyces cerevisiae

We characterized a trifluoroleucine-resistant mutant of Saccharomyces cerevisiae, TFL20, that has a mutation in the LEU4 gene. We monitored the concentration of extracellular i-AmOH and intracellular amino acids, and compared the ratios of gene expression in TFL20 with the wild-type strain, K30. We found that the LEU1, LEU2, and BAT1 genes were up-regulated in TFL20 for metabolism, and that TFL20 simultaneously produced as much i-AmOH and leucine as K30 does.     

Structure-based design of a leucine zipper protein with new DNA contacting region

We have employed a structure-based design to construct a small folding domain from the F-actin bundling protein villin that contains the amino acids necessary for the DNA binding of the basic leucine zipper protein GCN4 and have compared its DNA binding with GCN4. The monomeric motif folds into a stable domain and binds DNA in a rigid-body mechanism, while its affinity is not higher than that of the basic region peptide. The addition of the leucine zipper region to the folded domain restored its sequence-specific DNA binding comparable to that of GCN4. Unlike the monomeric folded domain, its leucine zipper derivative undergoes a conformational change upon DNA binding. CD spectral and thermodynamic studies indicate that the DNA-contacting region is folded in the presence or absence of DNA and suggest that the junction between the DNA-contacting and the leucine zipper regions transits to a helix in the presence of DNA. These results demonstrate that the structural transition outside the direct-contacting region, which adjusts the precise location of the DNA-contacting region, plays a critical role in the specific complex formation of basic leucine zipper proteins.     

Specific sequence combinations at parallel and antiparallel helix-helix interfaces

Orientation of helices at parallel and antiparallel helix-helix interfaces in proteins depends on interacting amino acids from both helices. Particularly important are amino acids at positions analogous to a and d in GCN4 leucine zipper nomenclature, which form hydrophobic core. In this work repeating sequence combinations at a and d positions characteristic for both parallel and antiparallel packing are shown. Layer packing of hydrophobic groups is compared for possible combinations of aliphatic amino acids at all four positions. Correlation between specific position of methyl groups and interhelical angle is found for parallel and antiparallel types of packing.     

Conformational energy analysis of the leucine repeat regions of C/EBP,GCN4, and the proteins of themyc,jun, andfos oncogenes

It has been recently proposed that certain DNA binding proteins (including C/EBP, GCN4 and themyc, jun, andfos oncogene proteins) share a common structural motif based on helix-promoting regions containing heptad repeat sequences of leucines. It has been suggested that this structure is critical to the biological activity of these proteins, since it facilitates the formation of functional dimers held together by interdigitating leucine side-chains along the hydrophobic interfaces between long α-helical regions of the polypeptide chains in a configuration termed the “leucine zipper.” In this paper, conformational energy analysis is used to determine the preferred three-dimensional structures of the leucine repeat regions of these proteins. The results indicate that, in all cases, the global minimum energy conformation for these regions is an amphipathic α-helix with the leucine side-chains arrayed on one side in such a way to favor “leucine zipper” dimerization. Furthermore, amino acid substitutions in these regions (such as Pro for Leu), that are known to inhibit dimer formation and prevent DNA binding, are found to produce significant conformational changes that disrupt the amphipathic helical structure. Thus, these results provide support for the proposed “leucine zipper” configuration as a critical structural feature of this class of DNA binding proteins.

     

PNA zipper as a dimerization tool: Development of a bZip mimic

The article describes the use of a PNA duplex (PNA zipper) as a tool to dimerize or bring in close proximity two polypeptides or protein domains. The amino acid sequence to be dimerized is covalently bound to complementary PNA sequences. Annealing of the PNA strands results in dimer formation. To test the ability of the “PNA‐zipper” as a dimerization tool, we designed a GCN4 mimetic, where the leucine‐zipper dimerization domain was replaced by the PNA zipper, whereas the basic DNA‐binding domain was covalently attached to the PNA. The molecule was assembled by chemical ligation of the peptide corresponding to the DNA‐binding domain of GCN4 modified with a succinyl thioester with two complementary PNAs harboring a cysteine residue. Electromobility‐shift experiments show the ability of the PNA zipper‐GCN4 to bind selected DNA duplexes. The PNA zipper‐GCN4 binds both the TRE and CRE DNA sites, but it does not bind TRE and CRE mutants containing even a single base mutation, as the native GCN4. The ability to fold upon complexation with DNA was investigated by CD. A good correlation between the ability of the PNA zipper‐GCN4 to fold into α helices and the ability to bind DNA was found. © 2010 Wiley Periodicals, Inc. Biopolymers 93: 434–441, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

Dual DNA recognition codes of a short peptide derived from the basic leucine zipper protein EmBP1

Sequence-specific DNA binding of short peptide dimers derived from a plant basic leucine zipper protein EmBP1 was studied. A homodimer of the EmBP1 basic region peptide recognized a palindromic DNA sequence, and a heterodimer of EmBP1 and GCN4 basic region peptides targets a non-palindromic DNA sequence when a beta-cyclodextrin/adamantane complex is utilized as a dimerization domain. A homodimer of the EmBP1 basic region peptide binds the native EmBP1 binding 5'-GCCACGTGGC-3' and the native GCN4 binding 5'-ATGACGTCAT-3' sequences with almost equal affinity in the alpha-helical conformation, indicating that the basic region of EmBP1 by itself has a dual recognition codes for the DNA sequences. The GCN4 basic region peptide binds 5'-ATGAC-3' in the alpha-helical conformation, but it neither shows affinity nor helix formation with 5'-GCCAC-3'. Because native EmBP1 forms 100 times more stable complex with 5'-GCCACGTGGC-3' over 5'-ATGACGTCAT-3', our results suggest that the sequence-selectivity of native EmBP1 is dictated by the structure of leucine zipper dimerization domain including the hinge region spanning between the basic region and the leucine zipper.