Selectional and mutational scope of peptides sequestering the Jun-Fos coiled-coil domain

The activator protein-1 (AP-1) complex plays a crucial role in numerous pathways, and its ability to induce tumorigenesis is well documented. Thus, AP-1 represents an interesting therapeutic target. We selected peptides from phage display and compared their ability to disrupt the cFos/cJun interaction to a previously described in vivo protein-fragment complementation assay (PCA). A cJun-based library was screened to enrich for peptides that disrupt the AP-1 complex by binding to the cFos coiled-coil domain. Interestingly, phage display identified one helix, JunW_Ph1 [phage-selected winning peptide (clone 1) targeting cFos], which differs in only 2 out of 10 randomized positions to JunW (PCA-selected winning peptide targeting cFos). Phage-selected peptides revealed higher affinity to cFos than wild-type cJun, harboring a T_m of 53 °C compared to 16 °C for cFos/cJun or 44 °C for cFos/JunW. In PCA growth assays in the presence of cJun as competitor, phage-selected JunW_Ph1 conferred shorter generation times than JunW. Bacterial growth was barely detectable, using JunW_Ph1 as a competitor for the wild-type cJun/cFos interaction, indicating efficient cFos removal from the dimeric wild-type complex. Importantly, all inhibitory peptides were able to interfere with DNA binding as demonstrated in gel shift assays. The selected sequences have consequently improved our ‘bZIP coiled-coil interaction prediction algorithm’ in distinguishing interacting from noninteracting coiled-coil sequences. Predicting and manipulating protein interaction will accelerate the systems biology field, and generated peptides will be valuable tools for analytical and biomedical applications.     

Positive aspects of negative design: simultaneous selection of specificity and interaction stability

The energetic determinants that drive specific protein-protein interactions are not entirely understood. We describe simultaneous in vivo selection of specific and stable interactions using homologous peptides which compete with protein libraries for an interaction with a target molecule. Library members binding to their target, and promoting cell growth, must outcompete competitor interactions with the target (i.e., competition) and evade binding to the competitors (i.e., negative design). We term this a competitive and negative design initiative (CANDI). We combined CANDI with a protein-fragment complementation assay (PCA) and observed major specificity improvements, by driving selection of winning library members that bind their target with maximum efficacy, ensuring that otherwise energetically accessible alternatives are inaccessible. CANDI-PCA has been used with libraries targeted at coiled coil regions of oncogenic AP-1 components cJun and cFos. We demonstrate that comparable hydrophobic and electrostatic contributions in desired species are compromised in nondesired species when CANDI is executed, demonstrating that both core and electrostatic residues are required to direct specific interactions. Major energetic differences (>or=5.6 kcal/mol) are observed between desired and nondesired interaction stabilities for a CANDI-PCA derived peptide relative to a conventional PCA derived helix, with significantly more stability (3.2 kcal/mol) than the wild-type cJun-cFos complex. As a negative control, a library lacking a residue repertoire able to generate a specific and stable helix was tested. Negative protein design has broad implications in generating specific and therapeutically relevant peptide-based drugs, proteins able to act with minimal cross-talk to homologues or analogues, and in nanobiotechnological design.     

The leucine zipper motif of the envelope glycoprotein ectodomain of human immunodeficiency virus type 1 contains conformationally flexible regions as revealed by NMR and circular dichroism studies in different media.

A 43-mer peptide derived from the coiled coil domain of the transmembrane glycoprotein, gp41, of human immunodeficiency virus type 1, was synthesized. Light scattering measurements suggested that the peptide molecules likely exist in the aqueous solution in trimeric form. Circular dichroism experiments showed a moderate helix population enhancement for the peptide in 80% methanol solution relative to helicity in sodium dodecyl sulfate micellar suspension. NMR spectroscopy indicated that the N-terminal section of the peptide was conformationally more sensitive to the medium. The conformationally labile regions contain residues implicated in gp41-gp120 association. Our data support the idea that the coiled coil region is responsible for oligomerization of the gp41 ectodomain and suggest a site of conformational isomerization following receptor binding-induced gp120 dissociation from gp41.     

Role of the buried glutamate in the alpha-helical coiled coil domain of the macrophage scavenger receptor

The macrophage scavenger receptor exhibits a pH-dependent conformational change around the carboxy-terminal half of the alpha-helical coiled coil domain, which has a representative amino acid sequence of a (defgabc)n heptad. We previously demonstrated that a peptide corresponding to this region formed a random coil structure at pH 7 and an alpha-helical coiled coil structure at pH 5 [Suzuki, K., Doi, T., Imanishi, T., Kodama, T., and Tanaka, T. (1997) Biochemistry 36, 15140-15146]. To determine the amino acid responsible for the conformational change, we prepared several peptides in which the acidic amino acids were replaced with neutral amino acids. Analyses of their structures by circular dichroism and sedimentation equilibrium gave the result that the presence of Glu242 at the d position was sufficient to induce the pH-dependent conformational change of the alpha-helical coiled coil domain. Furthermore, we substituted a Glu residue for the Ile residue at the d or a position of a de novo designed peptide (IEKKIEA)4, which forms a highly stable triple-stranded coiled coil. These peptides exhibited a pH-dependent conformational change similar to that of the scavenger receptor. Therefore, we conclude that a buried Glu residue in the hydrophobic core of a triple-stranded coiled coil has the potential to induce the pH-dependent conformational change. This finding makes it possible to elucidate the functions of natural proteins and to create a de novo protein designed to undergo a pH-dependent conformational change.     

Vimentin Coil 1A—A Molecular Switch Involved in the Initiation of Filament Elongation

Interestingly, our previously published structure of the coil 1A fragment of the human intermediate filament protein vimentin turned out to be a monomeric α-helical coil instead of the expected dimeric coiled coil. However, the 39-amino-acid-long helix had an intrinsic curvature compatible with a coiled coil. We have now designed four mutants of vimentin coil 1A, modifying key a and d positions in the heptad repeat pattern, with the aim of investigating the molecular criteria that are needed to stabilize a dimeric coiled-coil structure. We have analysed the biophysical properties of the mutants by circular dichroism spectroscopy, analytical ultracentrifugation and X-ray crystallography. All four mutants exhibited an increased stability over the wild type as indicated by a rise in the melting temperature (T_m). At a concentration of 0.1 mg/ml, the T_m of the peptide with the single point mutation Y117L increased dramatically by 46 °C compared with the wild-type peptide. In general, the introduction of a single stabilizing point mutation at an a or a d position did induce the formation of a stable dimer as demonstrated by sedimentation equilibrium experiments. The dimeric oligomerisation state of the Y117L peptide was furthermore confirmed by X-ray crystallography, which yielded a structure with a genuine coiled-coil geometry. Most notably, when this mutation was introduced into full-length vimentin, filament assembly was completely arrested at the unit-length filament (ULF) level, both in vitro and in cDNA-transfected cultured cells. Therefore, the low propensity of the wild-type coil 1A to form a stable two-stranded coiled coil is most likely a prerequisite for the end-to-end annealing of ULFs into filaments. Accordingly, the coil 1A domains might “switch” from a dimeric α-helical coiled coil into a more open structure, thus mediating, within the ULFs, the conformational rearrangements of the tetrameric subunits that are needed for the intermediate filament elongation reaction.     

Selection of a buried salt bridge by phage display

The α-helical coiled coil is a valuable folding motif for protein design and engineering. By means of phage display technology, we selected a capable binding partner for one strand of a coiled coil bearing a charged amino acid in a central hydrophobic core position. This procedure resulted in a novel coiled coil pair featuring an opposed Glu-Lys pair arranged staggered within the hydrophobic core of a coiled coil structure. Structural investigation of the selected coiled coil dimer by CD spectroscopy and MD simulations suggest that a buried salt bridge within the hydrophobic core enables the specific dimerization of two peptides.     

Influence of a heptad repeat stutter on the pH‐dependent conformational behavior of the central coiled‐coil from influenza hemagglutinin HA2

The coiled‐coil is one of the most common protein structural motifs. Amino acid sequences of regions that participate in coiled‐coils contain a heptad repeat in which every third then forth residue is occupied by a hydrophobic residue. Here we examine the consequences of a “stutter,” a deviation of the idealized heptad repeat that is found in the central coiled‐coil of influenza hemagluttinin HA2. Characterization of a peptide containing the native stutter‐containing HA2 sequence, as well as several variants in which the stutter was engineered out to restore an idealized heptad repeat pattern, revealed that the stutter is important for allowing coiled‐coil formation in the WT HA2 at both neutral and low pH (7.1 and 4.5). By contrast, all variants that contained idealized heptad repeats exhibited marked pH‐dependent coiled‐coil formation with structures forming much more stably at low pH. A crystal structure of one variant containing an idealized heptad repeat, and comparison to the WT HA2 structure, suggest that the stutter distorts the optimal interhelical core packing arrangement, resulting in unwinding of the coiled‐coil superhelix. Interactions between acidic side chains, in particular E69 and E74 (present in all peptides studied), are suggested to play a role in mediating these pH‐dependent conformational effects. This conclusion is partially supported by studies on HA2 variant peptides in which these positions were altered to aspartic acid. These results provide new insight into the structural role of the heptad repeat stutter in HA2. Proteins 2014; 82:2220–2228. © 2014 Wiley Periodicals, Inc.     

A calorimetric characterization of the salt dependence of the stability of the GCN4 leucine zipper.

The effects of different salts (LiCl, NaCl, ChoCl, KF, KCl, and KBr) on the structural stability of a 33-residue peptide corresponding to the leucine zipper region of GCN4 have been studied by high-sensitivity differential scanning calorimetry. These experiments have allowed an estimation of the salt dependence of the thermodynamic parameters that define the stability of the coiled coil. Independent of the nature of the salt, a destabilization of the coiled coil is always observed upon increasing salt concentration up to a maximum of approximately 0.5 M, depending on the specific cation or anion. At higher salt concentrations, this effect is reversed and a stabilization of the leucine zipper is observed. The effect of salt concentration is primarily entropic, judging from the lack of a significant salt dependence of the transition enthalpy. The salt dependence of the stability of the peptide is complex, suggesting the presence of specific salt effects at high salt concentrations in addition to the nonspecific electrostatic effects that are prevalent at lower salt concentrations. The data is consistent with the existence of specific interactions between anions and peptide with an affinity that follows a reverse size order (F- > Cl- > Br-). Under all conditions studied, the coiled coil undergoes reversible thermal unfolding that can be well represented by a reaction of the form N2<==>2U, indicating that the unfolding is a two-state process in which the helices are only stable when they are in the coiled coil conformation.     

Protein design of a bacterially expressed HIV-1 gp41 fusion inhibitor

Peptides derived from the carboxyl-terminal heptad repeat of the gp41 envelope glycoprotein ectodomain (C-peptides) can inhibit HIV-1 membrane fusion by binding to the amino-terminal trimeric coiled coil of the same protein. The fusion inhibitory peptide T-20 contains an additional tryptophan-rich sequence motif whose binding site extends beyond the gp41 coiled-coil region yet provides the key determinant of inhibitory activity in T-20. Here we report the design of a recombinant peptide inhibitor (called C52L) that includes both the C-peptide and tryptophan-rich regions. By calorimetry, C52L binds to a peptide mimic of the amino-terminal coiled coil with a Kd of 80 nM, reflecting the large degree of helicity in C52L as measured by circular dichroism spectroscopy. The C52L peptide potently inhibits in vitro infection of human T cells by diverse primary HIV-1 isolates irrespective of coreceptor preference, with nanomolar IC50 values. Significantly, C52L is fully active against T-20-resistant variants in a single-cycle HIV-1 infectivity assay. Moreover, because it can be expressed in bacteria, the C52L peptide might be more economical to manufacture on a large scale than T-20-like peptides produced by chemical synthesis. Hence the C52L fusion inhibitor may find a practical application, for example as a vaginal or rectal microbicide to prevent HIV-1 infection in the developing world.     

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.     

Structural basis for paramyxovirus-mediated membrane fusion

Paramyxoviruses are responsible for significant human mortality and disease worldwide, but the molecular mechanisms underlying their entry into host cells remain poorly understood. We have solved the crystal structure of a fragment of the simian parainfluenza virus 5 fusion protein (SV5 F), revealing a 96 A long coiled coil surrounded by three antiparallel helices. This structure places the fusion and transmembrane anchor of SV5 F in close proximity with a large intervening domain at the opposite end of the coiled coil. Six amino acids, potentially part of the fusion peptide, form a segment of the central coiled coil, suggesting that this structure extends into the membrane. Deletion mutants of SV5 F indicate that putative flexible tethers between the coiled coil and the viral membrane are dispensable for fusion. The lack of flexible tethers may couple a final conformational change in the F protein directly to the fusion of two bilayers.     

Buried polar interactions and conformational stability in the simian immunodeficiency virus (SIV) gp41 core

For human (HIV) and simian (SIV) immunodeficiency viruses, the gp41 envelope protein undergoes a receptor-activated conformational change from a labile native structure to an energetically more stable fusogenic conformation, which then mediates viral-cell membrane fusion. The core structure of fusion-active gp41 is a six-helix bundle in which three antiparallel carboxyl-terminal helices are packed against an amino-terminal trimeric coiled coil. Here we show that a recombinant model of the SIV gp41 core, designated N36(L6)C34, forms an alpha-helical trimer that exhibits a cooperative two-state folding-unfolding transition. We investigate the importance of buried polar interactions in determining the overall fold of the gp41 core. We have replaced each of four polar amino acids at the heptad a and d positions of the coiled coil in N36(L6)C34 with a representative hydrophobic amino acid, isoleucine. The Q565I, T582I, and T586I variants form six-helix bundle structures that are significantly more stable than that of the wild-type peptide, whereas the Q575I variant misfolds into an insoluble aggregate under physiological conditions. Thus, the buried polar residues within the amino-terminal heptad repeat are important determinants of the structural specificity and stability of the gp41 core. We suggest that these conserved buried polar interactions play a role in governing the conformational state of the gp41 molecule.     

Structural characterization of the SARS-coronavirus spike S fusion protein core

The spike (S) glycoprotein of coronaviruses mediates viral entry into host cells. It is a type 1 viral fusion protein that characteristically contains two heptad repeat regions, denoted HR-N and HR-C, that form coiled-coil structures within the ectodomain of the protein. Previous studies have shown that the two heptad repeat regions can undergo a conformational change from their native state to a 6-helix bundle (trimer of dimers), which mediates fusion of viral and host cell membranes. Here we describe the biophysical analysis of the two predicted heptad repeat regions within the severe acute respiratory syndrome coronavirus S protein. Our results show that in isolation the HR-N region forms a stable alpha-helical coiled coil that associates in a tetrameric state. The HR-C region in isolation formed a weakly stable trimeric coiled coil. When mixed together, the two peptide regions (HR-N and HR-C) associated to form a very stable alpha-helical 6-stranded structure (trimer of heterodimers). Systematic peptide mapping showed that the site of interaction between the HR-N and HR-C regions is between residues 916-950 of HR-N and residues 1151-1185 of HR-C. Additionally, interchain disulfide bridge experiments showed that the relative orientation of the HR-N and HR-C helices in the complex was antiparallel. Overall, the structure of the hetero-stranded complex is consistent with the structures observed for other type 1 viral fusion proteins in their fusion-competent state.     

New insights into the spring-loaded conformational change of influenza virus hemagglutinin

Influenza virus hemagglutinin undergoes a conformational change in which a loop-to-helix "spring-loaded" conformational change forms a coiled coil that positions the fusion peptide for interaction with the target bilayer. Previous work has shown that two proline mutations designed to disrupt this change disrupt fusion but did not determine the basis for the fusion defect. In this work, we made six additional mutants with single proline substitutions in the region that undergoes the spring-loaded conformational change and two additional mutants with double proline substitutions in this region. All double mutants were fusion inactive. We analyzed one double mutant, F63P/F70P, as an example. We observed that F63P/F70P undergoes key low-pH-induced conformational changes and binds tightly to target membranes. However, limited proteolysis and electron microscopy observations showed that the mutant forms a coiled coil that is only approximately 50% the length of the wild type, suggesting that it is splayed in its N-terminal half. This work further supports the hypothesis that the spring-loaded conformational change is necessary for fusion. Our data also indicate that the spring-loaded conformational change has another role beyond presenting the fusion peptide to the target membrane.     

Synergistic interactions between aqueous and membrane domains of a designed protein determine its fold and stability

Membrane-spanning proteins contain both aqueous and membrane-spanning regions, both of which contribute to folding and stability. To explore the interplay between these two domains we have designed and studied the assembly of coiled-coil peptides that span from the membrane into the aqueous phase. The membrane-spanning segment is based on MS1, a transmembrane coiled coil that contains a single Asn at a buried a position of a central heptad in its sequence. This Asn has been shown to drive assembly of the monomeric peptide in a membrane environment to a mixture of dimers and trimers. The coiled coil has now been extended into the aqueous phase by addition of water-soluble helical extensions. Although too short to fold in isolation, these helical extensions were expected to interact synergistically with the transmembrane domain and modulate its stability as well as its conformational specificity for forming dimers versus trimers. One design contains Asn at a position of the aqueous helical extension, which was expected to specify a dimeric state; a second peptide, which contains Val at this position, was expected to form trimers. The thermodynamics of assembly of the hybrid peptides were studied in micelles by sedimentation equilibrium ultracentrifugation. The aqueous helical extensions indeed conferred additional stability and conformational specificity to MS1 in the expected manner. These studies highlight the delicate interplay between membrane-spanning and water-soluble regions of proteins, and demonstrate how these different environments define the thermodynamics of a given specific interaction. In this case, an Asn in the transmembrane domain provided a strong driving force for folding but failed to specify a unique oligomerization state, while an Asn in the water-soluble domain was able to define specificity for a specific aggregation state as well as modulate stability.     

Structural and functional role of the amino-terminal region of porcine cytosolic aspartate aminotransferase. Catalytic and structural properties of enzyme derivatives truncated on the amino-terminal side

In porcine cytosolic aspartate aminotransferase, a dimeric enzyme, the amino-terminal region anchoring onto the neighboring subunit is linked to the adjoining floppy peptide segment (residues 12-47), an integral part of the small domain whose facile movement upon substrate binding is a striking "induced fit" feature of this enzyme. To assess the contribution by the amino-terminal region to small domain movement and protein stability, a series of enzyme derivatives truncated on the amino-terminal side (residues 1-9) was prepared by using oligonucleotide-directed in vitro mutagenesis. Deletion of residues 1-3 showed no effect on catalytic activity and heat stability. Del 1-5 mutant enzyme with an extra methionine at position 5 showed only 43% of the kappa cat value (in the overall transamination) of the wild-type enzyme. Further deletion up to residue 9 resulted in a slight decrease in kappa cat values. Del 1-9 mutant enzyme still retained a kappa cat value of 33% that of wild-type enzyme. Km values for aspartate and 2-oxoglutarate increased sharply upon deletion of residues 1-9. Accordingly, Del 1-9 mutant enzyme showed a striking decrease in the kappa cat/Km value, to only 2% of that for the wild-type enzyme. Deletion of amino-terminal residues 1-9 resulted also in a large decrease in thermostability and in an enhanced susceptibility to limited proteolysis by protease 401, which is known to cleave at Leu20 of the wild-type enzyme. These findings indicate that an increase in the conformational freedom of the floppy segment (residues 12-47) would occur upon the loss of most of the anchorage region, thereby presenting an entropic barrier to conformational changes that facilitate substrate binding with high affinity.