Peptide array‐based characterization and design of ZnO‐high affinity peptides

Peptides with both an affinity for ZnO and the ability to generate ZnO nanoparticles have attracted attention for the self‐assembly and templating of nanoscale building blocks under ambient conditions with compositional uniformity. In this study, we have analyzed the specific binding sites of the ZnO‐binding peptide, EAHVMHKVAPRP, which was identified using a phage display peptide library. The peptide binding assay against ZnO nanoparticles was performed using peptides synthesized on a cellulose membrane using the spot method. Using randomized rotation of amino acids in the ZnO‐binding peptide, 125 spot‐synthesized peptides were assayed. The peptide binding activity against ZnO nanoparticles varied greatly. This indicates that ZnO binding does not depend on total hydrophobicity or other physical parameters of these peptides, but rather that ZnO recognizes the specific amino acid alignment of these peptides. In addition, several peptides were found to show higher binding ability compared with that of the original peptides. Identification of important binding sites in the EAHVMHKVAPRP peptide was investigated by shortened, stepwise sequence from both termini. Interestingly, two ZnO‐binding sites were found as 6‐mer peptides: HVMHKV and HKVAPR. The peptides identified by amino acid substitution of HKVAPR were found to show high affinity and specificity for ZnO nanoparticles. Biotechnol. Bioeng. 2010;106: 845–851. © 2010 Wiley Periodicals, Inc.     

Aromatic interactions with naphthylalanine in a β‐hairpin peptide

Stable peptides have been explored as epitope mimics for protein–protein and protein–nucleic acid interactions; however, presentation of a regular structure is critical. Aromatic interactions are ubiquitous and are competent at stabilizing a β‐hairpin fold. The greatest stabilization has been reported from pairs of tryptophan side chains. Naphthylalanine residues are often used as tryptophan replacements, but it is not clear if 1‐naphthylalanine or 2‐naphthylalanine is adequate at replicating the geometry and stability observed with tryptophan aromatic interactions. Herein, a 12‐residue peptide has been constructed with laterally disposed aromatic amino acids. A direct comparison is made between tryptophan and other bicyclic, unnatural amino acids. Significant stabilization is gained from all bicyclic amino acids; however, geometric analysis shows that only 1‐naphthylalanine adopts a similar edge to face geometry as tryptophan, whereas the 2‐naphthylalanine appears most similar to a substituted phenylalanine. Copyright © 2013 European Peptide Society and John Wiley & Sons, Ltd.     

Analysis of tryptophan‐rich region in Clostridium septicum alpha‐toxin involved with binding to glycosylphosphatidylinositol‐anchored proteins

Clostridium septicum alpha‐toxin has a unique tryptophan‐rich region (³⁰²NGYSEWDWKWV³¹²) that consists of 11 amino acid residues near the C‐terminus. Using mutant toxins, the contribution of individual amino acids in the tryptophan‐rich region to cytotoxicity and binding to glycosylphosphatidylinositol (GPI)‐anchored proteins was examined. For retention of maximum cytotoxic activity, W307 and W311 are essential residues and residue 309 has to be hydrophobic and possess an aromatic side chain, such as tryptophan or phenylalanine. When residue 308, which lies between tryptophans (W307 and W309) is changed from an acidic to a basic amino acid, the cytotoxic activity of the mutant is reduced to less than that of the wild type. It was shown by a toxin overlay assay that the cytotoxic activity of each mutant toxin correlates closely with affinity to GPI‐anchored proteins. These findings indicate that the WDW_W sequence in the tryptophan‐rich region plays an important role in the cytotoxic mechanism of alpha‐toxin, especially in the binding to GPI‐anchored proteins as cell receptors.     

Mapping discontinuous protein‐binding sites via structure‐based peptide libraries: combining in silico and in vitro approaches

To perform their various functions, protein surfaces often have to interact with each other in a specific way. Usually, only parts of a protein are accessible and can act as binding sites. Because proteins consist of polypeptide chains that fold into complex three‐dimensional shapes, binding sites can be divided into two different types: linear sites that follow the primary amino acid sequence and discontinuous binding sites, which are made up of short peptide fragments that are adjacent in spatial proximity. Such discontinuous binding sites dominate protein–protein interactions, but are difficult to identify. To meet this challenge, we combined a computational, structure‐based approach and an experimental, high‐throughput method. SUPERFICIAL is a program that uses protein structures as input and generates peptide libraries to represent the protein's surface. A large number of the predicted peptides can be simultaneously synthesised applying the SPOT technology. The results of a binding assay subsequently help to elucidate protein–protein interactions; the approach is applicable to any kind of protein. The crystal structure of the complex of hen egg lysozyme with the well‐characterised murine IgG1 antibody HyHEL‐5 is available, and the complex is known to have a discontinuous binding site. Using SUPERFICIAL, the entire surface of lysozyme was translated into a peptide library that was synthesised on a cellulose membrane using the SPOT technology and tested against the HyHEL‐5 antibody. In this way, it was possible to identify two peptides (longest common sequence and peptide 19) that represented the discontinuous epitope of lysozyme. Copyright © 2012 John Wiley & Sons, Ltd.     

Identification of peptide mimotopes for the fluorescein hapten binding of monoclonal antibody B13‐DE1

Using 6mer and 12mer phage peptide libraries three unique phage clones were identified which specifically bind to a monoclonal anti‐FITC antibody, B13‐DE1. The two 6mer and one 12mer peptide insert sequences are clearly related to each other and contain a high proportion of hydrophobic amino acids. The peptides are bound by the antibody combining site of B13‐DE1 probably in a similar manner to FITC and represent therefore true peptidic mimics of the fluorescein hapten. No reactivity of the peptides could be demonstrated with another monoclonal anti‐fluorescein antibody or with polyclonal anti‐fluorescein antibodies. Immunization of mice with the peptides resulted in the production of antibodies cross‐reacting with all peptides but not with fluorescein. The results show that phage peptide libraries can be used to isolate mimotope peptides which can mimic low molecular weight structures seen by a specific antibody and probably other recognition molecules. Copyright © 1999 John Wiley & Sons, Ltd.     

Dynamic allostery in the ring protein TRAP

We have discovered distinct, characteristic differences in the thermodynamic signatures of tryptophan binding by trp RNA-binding attenuation protein (TRAP) from two different bacterial species. The TRAP 11mer ring binds 11 molecules of tryptophan at symmetry-related sites. Tryptophan binding to Bacillus stearothermophilus TRAP is not cooperative, but isothermal titration calorimetry shows that filling the first tryptophan binding sites of Bacillus subtilis TRAP has a marked effect on the thermodynamics of subsequent ligand binding. We have identified a single, conservative amino acid replacement (Ile to Leu) in B. subtilis TRAP that abolishes this effect, and suggest the initial ligand binding causes a change throughout the wild-type protein ring.     

Proteome‐wide analysis of phospho‐regulated PDZ domain interactions

A key function of reversible protein phosphorylation is to regulate protein–protein interactions, many of which involve short linear motifs (3–12 amino acids). Motif‐based interactions are difficult to capture because of their often low‐to‐moderate affinities. Here, we describe phosphomimetic proteomic peptide‐phage display, a powerful method for simultaneously finding motif‐based interaction and pinpointing phosphorylation switches. We computationally designed an oligonucleotide library encoding human C‐terminal peptides containing known or predicted Ser/Thr phosphosites and phosphomimetic variants thereof. We incorporated these oligonucleotides into a phage library and screened the PDZ (PSD‐95/Dlg/ZO‐1) domains of Scribble and DLG1 for interactions potentially enabled or disabled by ligand phosphorylation. We identified known and novel binders and characterized selected interactions through microscale thermophoresis, isothermal titration calorimetry, and NMR. We uncover site‐specific phospho‐regulation of PDZ domain interactions, provide a structural framework for how PDZ domains accomplish phosphopeptide binding, and discuss ligand phosphorylation as a switching mechanism of PDZ domain interactions. The approach is readily scalable and can be used to explore the potential phospho‐regulation of motif‐based interactions on a large scale.     

Identification of CRISP2 from human sperm as PSP94‐binding protein and generation of CRISP2‐specific anti‐peptide antibodies

Cysteine‐rich secretory proteins (CRISPs) are mainly found in the mammalian male reproductive tract and reported to be involved at different stages of fertilization. CRISPs have been shown to interact with prostate secretory protein of 94 amino acids (PSP94) from diverse sources, and the binding of these evolutionarily conserved proteins across species is proposed to be of functional significance. Of the three mammalian CRISPs, PSP94–CRISP3 interaction is well characterized, and specific binding sites have been identified; whereas, CRISP2 has been shown to interact with PSP94 in vitro. Interestingly, human CRISP3 and CRISP2 proteins are closely related showing 71.4% identity. In this study, we identified CRISP2 as a potential binding protein of PSP94 from human sperm. Further, we generated antisera capable of specifically detecting CRISP2 and not CRISP3. In this direction, specific peptides corresponding to the least conserved ion channel regulatory region were synthesized, and polyclonal antibodies were generated against the peptide in rabbits. The binding characteristics of the anti‐CRISP2 peptide antibody were evaluated using competitive ELISA. Immunoblotting experiments also confirmed that the peptide was able to generate antibodies capable of detecting the mature CRISP2 protein present in human sperm lysate. Furthermore, this anti‐CRISP2 peptide antibody also detected the presence of native CRISP2 on sperm.Copyright © 2016 European Peptide Society and John Wiley & Sons, Ltd.     

Targeting of hepatocellular carcinoma with glypican‐3‐targeting peptide ligand

Hepatocellular carcinoma is a common malignancy. The carcinoma cells express glypican‐3 (GPC‐3) on the cell membrane. GPC‐3 is also expressed in melanoma cells. Therefore, GPC‐3 might be a potential target for tumor imaging or therapy. Here, proteomic mass spectrometry was used to identify peptides that target GPC‐3‐expressing tumors. A mammalian expression vector expressing a FLAG‐GPC‐3 fusion protein was cloned for immunoprecipitation. With the use of liposomes, the vector was transfected into HepG2 (HepG2/FLAG‐GPC‐3) and HEK 293 cells, and the transfected cell lines were selected with geneticin. HepG2/FLAG‐GPC‐3 cells were used for immunoprecipitation of FLAG‐GPC‐3 fusion protein. Seven peptide candidates (L1–L7) were selected for GPC‐3‐targeting ligands by mass spectrometric analysis. The L5 peptide with 14 amino acids (Arg‐Leu‐Asn‐Val‐Gly‐Gly‐Thr‐Tyr‐Phe‐Leu‐Thr‐Thr‐Arg‐Gln) showed selective binding to the GPC‐3‐expressing tumor cells, as did a shortened L5 peptide (L5‐2) with seven amino acids (Tyr‐Phe‐Leu‐Thr‐Thr‐Arg‐Gln). These peptide ligands have potential as targeting moieties to GPC‐3‐expressing tumors for diagnostic and/or therapeutic purposes. Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.     

Epitope‐specificity of recombinant antibodies reveals promiscuous peptide‐binding properties

Protein–peptide interactions are a common occurrence and essential for numerous cellular processes, and frequently explored in broad applications within biology, medicine, and proteomics. Therefore, understanding the molecular mechanism(s) of protein–peptide recognition, specificity, and binding interactions will be essential. In this study, we report the first detailed analysis of antibody–peptide interaction characteristics, by combining large‐scale experimental peptide binding data with the structural analysis of eight human recombinant antibodies and numerous peptides, targeting tryptic mammalian and eukaryote proteomes. The results consistently revealed that promiscuous peptide‐binding interactions, that is, both specific and degenerate binding, were exhibited by all antibodies, and the discovery was corroborated by orthogonal data, indicating that this might be a general phenomenon for low‐affinity antibody–peptide interactions. The molecular mechanism for the degenerate peptide‐binding specificity appeared to be executed through the use of 2–3 semi‐conserved anchor residues in the C‐terminal part of the peptides, in analogue to the mechanism utilized by the major histocompatibility complex–peptide complexes. In the long‐term, this knowledge will be instrumental for advancing our fundamental understanding of protein–peptide interactions, as well as for designing, generating, and applying peptide specific antibodies, or peptide‐binding proteins in general, in various biotechnical and medical applications.     

Evidence for conformationally different states of interleukin‐10: binding of a neutralizing antibody enhances accessibility of a hidden epitope

We present the mapping of two anti‐human interleukin‐10 (hIL‐10) antibodies (CB/RS/2 and CB/RS/11) which have been described as binding their antigen cooperatively. The epitopes were identified using hIL‐10‐derived overlapping peptide scans prepared by spot synthesis. To identify residues essential for binding within the two epitopes, each position was replaced by all other L ‐amino acids. The epitope‐derived peptides were further characterized with respect to antibody affinity and their inhibition of the antibody–hIL‐10 interaction. One antibody (CB/RS/11) binds to residues which are completely buried in the X‐ray structure of IL‐10. Accessibility of this hidden epitope is enhanced upon binding of the antibody CB/RS/2, which recognizes a discontinuous epitope located nearby. The recognition of the hidden CB/RS/11 epitope, as well as the cooperative binding behaviour of the two antibodies, provides evidence that IL‐10 can adopt a conformational state other than that observed in the crystal structure. Copyright © 1999 John Wiley & Sons, Ltd.     

Probing the roles of two tryptophans surrounding the unique zinc coordination site in lipase family I.5

A unique zinc domain found in all of the identified members of the lipase family I.5 is surrounded by two conserved tryptophans (W61 and W212). In this study, we investigated the role of these hydrophobic residues in thermostability and thermoactivity of the lipase from Bacillus thermocatenulatus (BTL2) taken as the representative of the family. Circular dichroism spectroscopy revealed that the secondary structure of BTL2 is conserved by the tryptophan mutations (W61A, W212A, and W61A/W212A), and that W61 is located in a more rigid and less solvent exposed region than is W212. Thermal denaturation and optimal activity analyses pointed out that zinc induces thermostability and thermoactivity of BTL2, in which both tryptophans W61 and W212 play contributing roles. Molecular explanations describing the roles of these tryptophans were pursued by X‐ray crystallography of the open form of the W61A mutant and molecular dynamics simulations which highlighted a critical function for W212 in zinc binding to the coordination site. This study reflects the potential use of hydrophobic amino acids in vicinity of metal coordination sites in lipase biocatalysts design. Proteins 2016; 84:129–142. © 2015 Wiley Periodicals, Inc.     

Structural and functional studies of differentially O‐glycosylated analogs of a thrombin inhibitory peptide – variegin

Variegin is a 32‐amino acid long thrombin inhibitory peptide isolated from the salivary gland extract of tropical bont tick Amblyomma variegatum. It was identified to be O‐glycosylated on its Thr‐14 side chain, and this glycosylated form was 14‐fold more potent than that of its non‐glycosylated form. However, as the identity of this glycosylation remained elusive, the mechanistic details underlying its functional impact are not yet known. In this report, we synthesized four different O‐glycosylated analogs of variegin bearing physiologically relevant sugars on its Thr‐14. Functional characterization of these analogs by enzyme inhibitory kinetics and surface plasmon resonance methods showed that all the synthesized glycopeptides are strong thrombin inhibitors. Structural studies by macromolecular docking identified that the sugar moiety of these peptides can potentially mediate favorable interactions with amino acids at the base of thrombin's autolysis loop. This report, for the first time, describes the impact of differential glycosylation on the function of a thrombin inhibitory peptide and tries to provide structural insights into the relevance of peptide glycosylation in thrombin inhibition. Copyright © 2017 European Peptide Society and John Wiley & Sons, Ltd.     

Molecular design and optimization of hepatic cancer SLP76‐derived PLCγ1 SH3‐binding peptide with the systematic N‐substitution of peptide PXXP motif

The phospholipase Cγ1 (PLCγ1) is essential for T‐cell signaling and activation in hepatic cancer immune response, which has a regulatory Src homology 3 (SH3) domain that can specifically recognize and interact with the PXXP‐containing decapeptide segment (¹⁸⁵QP P VP P QRPM¹⁹⁴, termed as SLP76^185–194 peptide) of adaptor protein SLP76 following T‐cell receptor ligation. The isolated peptide can only bind to the PLCγ1 SH3 domain with a moderate affinity due to lack of protein context support. Instead of the traditional natural residue mutagenesis that is limited by low structural diversity and shifted target specificity, we herein attempt to improve the peptide affinity by replacing the two key proline residues Pro187 and Pro190 of SLP76^185–194 PXXP motif with nonnatural N‐substituted amino acids, as the proline is the only endogenous N‐substituted amino acid. The replacement would increase peptide flexibility but can restore peptide activity by establishing additional interactions with the domain. Structural analysis reveals that the domain pocket can be divided into a large amphipathic region and a small negatively charged region; they accommodate hydrophobic, aromatic, polar, and moderate‐sized N‐substituted amino acid types. A systematic replacement combination profile between the peptide residues Pro187 and Pro190 is created by structural modeling, dynamics simulation, and energetics analysis, from which six improved and two reduced N‐substituted peptides as well as native SLP76^185–194 peptide are identified and tested for their binding affinity to the recombinant protein of the human PLCγ1 SH3 domain using fluorescence‐based assays. Two N‐substituted peptides, SLP76^185–194(N‐Leu187/N‐Gln190) and SLP76^185–194(N‐Thr187/N‐Gln190), are designed to have high potency (K_d = 0.67 ± 0.18 and 1.7 ± 0.3 μM, respectively), with affinity improvement by, respectively, 8.5‐fold and 3.4‐fold relative to native peptide (K_d = 5.7 ± 1.2 μM).     

Pan1 is an intrinsically disordered protein with homotypic interactions

The yeast scaffold protein Pan1 contains two EH domains at its N‐terminus, a predicted coiled‐coil central region, and a C‐terminal proline‐rich domain. Pan1 is also predicted to contain regions of intrinsic disorder, characteristic of proteins that have many binding partners. In vitro biochemical data suggest that Pan1 exists as a dimer, and we have identified amino acids 705 to 848 as critical for this homotypic interaction. Tryptophan fluorescence was used to further characterize Pan1 conformational states. Pan1 contains four endogenous tryptophans, each in a distinct region of the protein: Trp³¹² and Trp⁶⁴² are each in an EH domain, Trp⁹⁵⁷ is in the central region, and Trp¹²⁸⁰ is a critical residue in the Arp2/3 activation domain. To examine the local environment of each of these tryptophans, three of the four tryptophans were mutagenized to phenylalanine to create four proteins, each with only one tryptophan residue. When quenched with acrylamide, these single tryptophan mutants appeared to undergo collisional quenching exclusively and were moderately accessible to the acrylamide molecule. Quenching with iodide or cesium, however, revealed different Stern‐Volmer constants due to unique electrostatic environments of the tryptophan residues. Time‐resolved fluorescence anisotropy data confirmed structural and disorder predictions of Pan1. Further experimentation to fully develop a model of Pan1 conformational dynamics will assist in a deeper understanding of the mechanisms of endocytosis. Proteins 2013; 81:1944–1963. © 2013 Wiley Periodicals, Inc.     

Characterization of continuous B‐cell epitopes in the N‐terminus of glutamate decarboxylase67 using monoclonal antibodies

Glutamate decarboxylase (GAD) is an autoantigen associated with the autoimmune disorders Type‐1 diabetes (T1D) and stiff‐person syndrome (SPS). The protein, being an essential enzyme involved in the production of the inhibitory neurotransmitter γ‐aminobutyric acid, exists in two isoforms, GAD67 and GAD65. Both isoforms may be targeted by autoantibodies in SPS and T1D patients, although SPS primarily is associated with the presence of GAD67 autoantibodies, whereas T1D mainly is associated with the presence of GAD65 autoantibodies. In this study, we describe antibody reactivity to overlapping GAD67 peptides covering the complete protein sequence by modified peptide enzyme‐linked immunosorbent assay in order to identify potential GAD67 epitopes using two monoclonal antibodies (mAbs). Both GAD67 mAbs showed reactivity to linear epitopes located at the N‐terminal end of GAD67. The epitopes of GAD mAb 1 and 2 were identified as the amino acid sequences NAGADPNTTN and TETDFSNLF, respectively, corresponding to amino acids 14–23 and 91–99. Fine mapping of the epitopes revealed that antibody reactivity was related to amino acid side‐chain functionality, rather than amino acid side‐chain specificity. Additionally, results suggested that non‐contact amino acids in the epitope structure were essential for antibody reactivity. The exact role of these amino acids remains to be determined, but they are thought to be involved in backbone hydrogen bonds or stabilization of the epitope structure. As only limited knowledge is available in relation to antigenic regions of GAD67, this study contributes to characterization of GAD67 epitopes and may be a first step in the development of peptide‐based therapeutics against SPS. Copyright © 2014 European Peptide Society and John Wiley & Sons, Ltd.     

Development of short and highly potent self‐assembling elastin‐derived pentapeptide repeats containing aromatic amino acid residues

Tropoelastin is the primary component of elastin, which forms the elastic fibers that make up connective tissues. The hydrophobic domains of tropoelastin are thought to mediate the self‐assembly of elastin into fibers, and the temperature‐mediated self‐assembly (coacervation) of one such repetitive peptide sequence (VPGVG) has been utilized in various bio‐applications. To elucidate a mechanism for coacervation activity enhancement and to develop more potent coacervatable elastin‐derived peptides, we synthesized two series of peptide analogs containing an aromatic amino acid, Trp or Tyr, in addition to Phe‐containing analogs and tested their functional characteristics. Thus, position 1 of the hydrophobic pentapeptide repeat of elastin (X¹P²G³V⁴G⁵) was substituted by Trp or Tyr. Eventually, we acquired a novel, short Trp‐containing elastin‐derived peptide analog (WPGVG)₃ with potent coacervation ability. From the results obtained during this process, we determined the importance of aromaticity and hydrophobicity for the coacervation potency of elastin‐derived peptide analogs. Generally, however, the production of long‐chain synthetic polypeptides in quantities sufficient for commercial use remain cost‐prohibitive. Therefore, the identification of (WPGVG)₃, which is a 15‐mer short peptide consisting simply of five natural amino acids and shows temperature‐dependent self‐assembly activity, might serve as a foundation for the development of various kinds of biomaterials. Copyright © 2015 European Peptide Society and John Wiley & Sons, Ltd.     

Examining post‐translational modification‐mediated protein–protein interactions using a chemical proteomics approach

Post‐translational modifications (PTM) of proteins can control complex and dynamic cellular processes via regulating interactions between key proteins. To understand these regulatory mechanisms, it is critical that we can profile the PTM‐dependent protein–protein interactions. However, identifying these interactions can be very difficult using available approaches, as PTMs can be dynamic and often mediate relatively weak protein–protein interactions. We have recently developed CLASPI (cross‐linking‐assisted and stable isotope labeling in cell culture‐based protein identification), a chemical proteomics approach to examine protein–protein interactions mediated by methylation in human cell lysates. Here, we report three extensions of the CLASPI approach. First, we show that CLASPI can be used to analyze methylation‐dependent protein–protein interactions in lysates of fission yeast, a genetically tractable model organism. For these studies, we examined trimethylated histone H3 lysine‐9 (H3K9Me₃)‐dependent protein–protein interactions. Second, we demonstrate that CLASPI can be used to examine phosphorylation‐dependent protein–protein interactions. In particular, we profile proteins recognizing phosphorylated histone H3 threonine‐3 (H3T3‐Phos), a mitotic histone “mark” appearing exclusively during cell division. Our approach identified survivin, the only known H3T3‐Phos‐binding protein, as well as other proteins, such as MCAK and KIF2A, that are likely to be involved in weak but selective interactions with this histone phosphorylation “mark”. Finally, we demonstrate that the CLASPI approach can be used to study the interplay between histone H3T3‐Phos and trimethylation on the adjacent residue lysine 4 (H3K4Me₃). Together, our findings indicate the CLASPI approach can be broadly applied to profile protein–protein interactions mediated by PTMs.