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.     

Crystal structure of afadin PDZ domain–nectin‐3 complex shows the structural plasticity of the ligand‐binding site

Afadin, a scaffold protein localized in adherens junctions (AJs), links nectins to the actin cytoskeleton. Nectins are the major cell adhesion molecules of AJs. At the initial stage of cell–cell junction formation, the nectin–afadin interaction plays an indispensable role in AJ biogenesis via recruiting and tethering other components. The afadin PDZ domain (AFPDZ) is responsible for binding the cytoplasmic C‐terminus of nectins. AFPDZ is a class II PDZ domain member, which prefers ligands containing a class II PDZ‐binding motif, X‐Φ‐X‐Φ (Φ, hydrophobic residues); both nectins and other physiological AFPDZ targets contain this class II motif. Here, we report the first crystal structure of the AFPDZ in complex with the nectin‐3 C‐terminal peptide containing the class II motif. We engineered the nectin‐3 C‐terminal peptide and AFPDZ to produce an AFPDZ–nectin‐3 fusion protein and succeeded in obtaining crystals of this complex as a dimer. This novel dimer interface was created by forming an antiparallel β sheet between β2 strands. A major structural change compared with the known AFPDZ structures was observed in the α2 helix. We found an approximately 2.5 Å‐wider ligand‐binding groove, which allows the PDZ to accept bulky class II ligands. Apparently, the last three amino acids of the nectin‐3 C‐terminus were sufficient to bind AFPDZ, in which the two hydrophobic residues are important.     

Characterization of PDZ domain‐peptide interaction interface based on energetic patterns

PDZ domain is one of the abundant modular domains that recognize short peptide sequences to mediate protein–protein interactions. To decipher the binding specificity of PDZ domain, we analyzed the interactions between 11 mouse PDZ domains and 217 peptides using a method called MIECSVM, which energetically characterizes the domain‐peptide interaction using molecular interaction energy components (MIECs) and predicts binding specificity using support vector machine (SVM). Cross‐validation and leave‐one‐domain‐out test showed that the MIEC‐SVM using all 44 PDZ‐peptide residue pairs at the interaction interface outperformed the sequence‐based methods in the literature. A further feature (residue pair) selection procedure illustrated that 16 residue pairs were uninformative to the binding specificity, even though they contributed significantly (～50%) to the binding energy. If only using the 28 informative residue pairs, the performance of the MIEC‐SVM on predicting the PDZ binding specificity was significantly improved. This analysis suggests that the informative and uninformative residue interactions between the PDZ domain and the peptide may represent those contributing to binding specificity and affinity, respectively. We performed additional structural and energetic analyses to shed light on understanding how the PDZ‐peptide recognition is established. The success of the MIEC‐SVM method on PDZ domains in this study and SH3 domains in our previous studies illustrates its generality on characterizing protein‐ peptide interactions and understanding protein recognition from a structural and energetic viewpoint.     

Recombinant self‐assembling 16‐residue peptide nanofiber scaffolds for neuronal axonal outgrowth

Self‐assembling peptides are considered a good biological scaffold for the repair of injured nervous system. In order to set up a stable system to produce the peptides at low cost, we used a gene recombinant expression method. The sequence of the peptide was devised to facilitate neural cell attachment and growth. The nucleotide sequence of the self‐assembling peptide was designed, artificially synthesized, and inserted into the fusion protein vector pTYB2. After being transformed and expressed in Escherichia coli BL‐21 (DE3) by means of the fusion protein, the soluble 16‐residue peptide (named RAE16) was obtained by one‐step chitin affinity chromatography. During cell culture, bone marrow stromal cells were fully embedded in the 3D environment of the peptide scaffolds. The MTT (3‐(4,5‐dimethyl‐2‐thiazolyl)‐2,5‐diphenyl‐2‐H‐tetrazolium bromide) test indicated that bone marrow stromal cells cultured in RAE16 had the highest survival rate with the absorbance value of 0.7 at 7 days. Moreover, the cortical neural axons in the RAE16 group were longer (118.36 ± 7.04 μm) than in the other groups (p < 0.01). The recombinant peptide nanofiber scaffolds we designed provide a promising cell culture system for general molecular and cell biology studies and are useful as well for neural regeneration studies.     

Formation of stable nanodiscs by bihelical apolipoprotein A‐I mimetic peptide

Nanodiscs are composed of scaffold protein or peptide such as apolipoprotein A‐I (apoA‐I) and phospholipids. Although peptide‐based nanodiscs have an advantage to modulate the size of nanodiscs by changing phospholipid/peptide ratios, they are usually less stable than apoA‐I‐based nanodiscs. In this study, we designed a novel nanodisc scaffold peptide (NSP) that has proline‐punctuated bihelical amphipathic structure based on apoA‐I mimetic peptides. NSP formed α‐helical structure on 1‐palmitoyl‐2‐oleoyl phosphatidylcholine (POPC) nanodiscs prepared by cholate dialysis method. Dynamic light scattering measurements demonstrated that diameters of NSP nanodiscs vary depending upon POPC/NSP ratios. Comparison of thermal unfolding of nanodiscs monitored by circular dichroism measurements demonstrated that NSP forms much more stable nanodiscs with POPC than monohelical peptide, 4F, exhibiting comparable stability to apoA‐I‐POPC nanodiscs. Intrinsic Trp fluorescence measurements showed that Trp residues of NSP exhibit more hydrophobic environment than that of 4 F on nanodiscs, suggesting the stronger interaction of NSP with phospholipids. Thus, the bihelical structure of NSP appears to increase the stability of nanodiscs because of the enhanced interaction of peptides with phospholipids. In addition, NSP as well as 4F spontaneously solubilized POPC vesicles into nanodiscs without using detergent. These results indicate that bihelical NSP forms nanodiscs with comparable stability to apoA‐I and has an ability to control the size of nanodiscs simply by changing phospholipid/peptide ratios. Copyright © 2016 European Peptide Society and John Wiley & Sons, Ltd.     

Exploring new strategies for grafting binding peptides onto protein loops using a consensus‐designed tetratricopeptide repeat scaffold

Peptide display approaches, in which peptide epitopes of known binding activities are grafted onto stable protein scaffolds, have been developed to constrain the peptide in its bioactive conformation and to enhance its stability. However, peptide grafting can be a lengthy process requiring extensive computational modeling and/or optimisation by directed evolution techniques. In this study, we show that ultra‐stable consensus‐designed tetratricopeptide repeat (CTPR) proteins are amenable to the grafting of peptides that bind the Kelch‐like ECH‐associated protein 1 (Keap1) onto the loop between adjacent repeats. We explore simple strategies to optimize the grafting process and show that modest improvements in Keap1‐binding affinity can be obtained by changing the composition of the linker sequence flanking either side of the binding peptide.     

Semienzymatic Cyclization of Disulfide-rich Peptides Using Sortase A

Disulfide-rich cyclic peptides have generated great interest in the development of peptide-based therapeutics due to their exceptional stability toward chemical, enzymatic, or thermal attack. In particular, they have been used as scaffolds onto which bioactive epitopes can be grafted to take advantage of the favorable biophysical properties of disulfide-rich cyclic peptides. To date, the most commonly used method for the head-to-tail cyclization of peptides has been native chemical ligation. In recent years, however, enzyme-mediated cyclization has become a promising new technology due to its efficiency, safety, and cost-effectiveness. Sortase A (SrtA) is a bacterial enzyme with transpeptidase activity. It recognizes a C-terminal penta-amino acid motif, LPXTG, and cleaves the amide bond between Thr and Gly to form a thioacyl-linked intermediate. This intermediate undergoes nucleophilic attack by an N-terminal poly-Gly sequence to form an amide bond between the Thr and N-terminal Gly. Here, we demonstrate that sortase A can successfully be used to cyclize a variety of small disulfide-rich peptides, including the cyclotide kalata B1, α-conotoxin Vc1.1, and sunflower trypsin inhibitor 1. These peptides range in size from 14 to 29 amino acids and contain three, two, or one disulfide bond, respectively, within their head-to-tail cyclic backbones. Our findings provide proof of concept for the potential broad applicability of enzymatic cyclization of disulfide-rich peptides with therapeutic potential.     

Rational design of the first small-molecule antagonists of NHERF1/EBP50 PDZ domains

This report describes the first small-molecule antagonists that specifically target the ligand-binding pocket of PDZ domains of NHERF1 multi-functional adaptor protein. Comparison of the peptide sequence homology between the native ligand of NHERF1 PDZ domains and an indole-based non-peptide chemical scaffold allowed the design of a small-molecule antagonist of NHERF1 PDZ domains.     

Ca2+‐independent sortase‐A exhibits high selective protein ligation activity in the cytoplasm of Escherichia coli

A Staphylococcus aureus transpeptidase, sortase A (SrtA), which catalyzes a peptide ligation with high substrate specificity, is a useful tool to site‐specifically attach proteinaceous/peptidic functional molecules to target proteins. However, its strong Ca²⁺ dependency makes SrtA difficult for use under low Ca²⁺ concentrations and in the presence of Ca²⁺‐binding substances. To overcome this problem, we designed a SrtA mutant that Ca²⁺‐independently demonstrates a high catalytic activity. The heptamutant (P94R/E105K/E108A/D160N/D165A/K190E/K196T), which resulted from a combination of known mutations at the Ca²⁺‐binding site and around the substrate‐binding site, successfully catalyzed a selective protein‐protein ligation in the cytoplasm of Escherichia coli. Selective protein modification in living cells is a promising approach for investigating cellular events and regulating cell functions. This SrtA mutant may prove to be a versatile tool for adding new functionalities to proteins of interest by incorporating functional proteins and chemically modified peptides in living cells, which usually retain low Ca²⁺ concentrations.     

Synthetic peptides derived from an N‐terminal domain of the E2 protein of GB virus C in the study of GBV‐C/HIV‐1 co‐infection

Synthetic peptides derived from GB virus C (GBV‐C) have previously been studied in our group for the development of new systems capable of diagnosing diseases caused by this humanotropic virus. We also recently described specific peptide domains of the E2 envelop protein of GBV‐C that have the capacity to interfere with the HIV‐1 fusion peptide, produce a notable decrease in cellular membrane fusion, and perturb HIV‐1 infectivity in a dose‐dependent manner. The present work discloses the design and synthesis of both linear and cyclic branched peptides based on a previously reported N‐terminal sequence of the GBV‐C E2 protein. Immunoassays and cell–cell fusion assays were performed to evaluate their diagnostic value to detect anti‐GBV‐C antibodies in HIV‐1 patients, as well as their putative anti‐HIV‐1 activity as entry inhibitors. Our results showed that chemical modifications of the selected E2(7–26) linear peptide to afford cyclic architecture do not result in an enhanced inhibition of gp41 HIV‐1‐mediated cell–cell fusion nor improved sensitivity in the detection of GBV‐C antibodies in HIV‐1 co‐infected patients. Thus, the ELISA data reinforce the potential utility of linear versions of the E2(7–26) region for the development of new peptide‐based immunosensor devices for the detection of anti‐GBV‐C antibodies in HIV‐1 co‐infected patients. Copyright © 2012 European Peptide Society and John Wiley & Sons, Ltd.     

Folding thermodynamics of β‐hairpins studied by replica‐exchange molecular dynamics simulations

We study the differences in folding stability of β‐hairpin peptides, including GB1 hairpin and a point mutant GB1 K10G, as well as tryptophan zippers (TrpZips): TrpZip1, TrpZip2, TrpZip3‐1, and TrpZip4. By performing replica‐exchange molecular dynamics simulations with Amber03* force field (a modified version of Amber ff03) in explicit solvent, we observe ab initio folding of all the peptides except TrpZip3‐1, which is experimentally known to be the least stable among the peptides studied here. By calculating the free energies of unfolding of the peptides at room temperature and folding midpoint temperatures for thermal unfolding of peptides, we find that TrpZip4 and GB1 K10G peptides are the most stable β‐hairpins followed by TrpZip1, GB1, and TrpZip2 in the given order. Hence, the proposed K10G mutation of GB1 peptide results in enhanced stability compared to wild‐type GB1. An important goal of our study is to test whether simulations with Amber 03* model can reproduce experimentally predicted folding stability differences between these peptides. While the stabilities of GB1 and TrpZip1 yield close agreement with experiment, TrpZip2 is found to be less stable than predicted by experiment. However, as heterogenous folding of TrpZip2 may yield divergent thermodynamic parameters by different spectroscopic methods, mismatching of results with previous experimental values are not conclusive of model shortcomings. For most of the cases, molecular simulations with Amber03* can successfully reproduce experimentally known differences between the mutated peptides, further highlighting the predictive capabilities of current state‐of‐the‐art all‐atom protein force fields. Proteins 2015; 83:1307–1315. © 2015 Wiley Periodicals, Inc.     

Characterization of the Phosphorylation Site of PP59, a Substrate for Cyclic AMP-Dependent Protein Kinase That Is Enriched in the Synaptic Membrane Fraction of Rat Cerebellum

Abstract: We have identified previously a synaptic membrane-associated protein, PP59, that serves as a substrate for cyclic AMP-dependent protein kinase and is enriched in rat cerebellum. We show here that PP59 can be extracted from synaptic plasma membranes with a combination of 2% Triton X-100 plus 1 M KCl. A 290-fold purification of PP59 was achieved by selective solubilization, followed by continuous-elution preparative gel electrophoresis. To determine the amino acid sequence surrounding the cyclic AMP-dependent protein kinase phosphorylation site within PP59, the partially purified ³²P-phosphorylated protein was digested with chymotrypsin, and radiolabeled peptides were purified by sequential reversed-phase HPLC in two different solvent systems. Automated Edman degradation revealed a single phosphorylation site contained within the sequence Ala-Arg-Glu-Arg-Ser-Asp-Ser(P)-Thr-Gly-Ser-Ser-Ser-Val-Tyr. No strong sequence homology to this peptide fragment with other known peptides or proteins in the SwissProt, PIR, or GenPept databases could be found. A synthetic peptide containing this unique 14-amino acid sequence was used to develop polyclonal anti-peptide antibodies that were affinity-purified and shown to recognize intact PP59 as determined by western blotting. These antibodies specifically inhibited the phosphorylation of PP59 by cyclic AMP-dependent protein kinase in an in vitro phosphorylation assay containing synaptic plasma membranes.     

Peptide selectivity between the PDZ domains of human pregnancy‐related serine proteases (HtrA1, HtrA2, HtrA3, and HtrA4) can be reshaped by different halogen probes

The human HtrA family of serine proteases (HtrA1, HtrA2, HtrA3, and HtrA4) are the key enzymes associated with pregnancy and closely related to the development and progression of many pathological events. Previously, it was found that halogen substitution at the indole moiety of peptide Trp‐1 residue can form a geometrically satisfactory halogen bond with the Drosophila discs large, zona occludens‐1 (PDZ) domain of HtrA proteases. Here, we attempt to systematically investigate the effect of substitution with 4 halogen types and 2 indole positions on the binding affinity and specificity of peptide ligands to the 4 HtrA PDZ domains. The complex structures, interaction energies, halogen‐bonding strength, and binding affinity of domain‐peptide systems were modeled, analyzed, and measured via computational modeling and fluorescence‐based assay. It is revealed that there is a compromise between the local rearrangement of halogen bond involving different halogen atoms and the global optimization of domain‐peptide interaction; the substitution position is fundamentally important for peptide‐binding affinity, while the halogen type can effectively shift peptide selectivity between the 4 domains. The HtrA1‐PDZ and HtrA4‐PDZ as well as HtrA2‐PDZ and HtrA3‐PDZ respond similarly to different halogen substitutions of peptide; –Br substitution at R2‐position and –I substitution at R4‐position are most effective in improving peptide selectivity for HtrA1‐PDZ/HtrA4‐PDZ and HtrA2‐PDZ/HtrA3‐PDZ, respectively; –F substitution would not address substantial effect on peptide selectivity for all the 4 domains. Consequently, the binding affinities of a native peptide ligand DSRIWWV^–COOH as well as its 4 R2‐halogenated counterparts were determined as 1.9, 1.4, 0.5, 0.27, and 0.92 μM, which are basically consistent with computational analysis. This study would help to rationally design selective peptide inhibitors of HtrA family members by using different halogen substitutions.     

Intramolecular cyclization of the antimicrobial peptide Polybia‐MPI with triazole stapling: influence on stability and bioactivity

Cationic antimicrobial peptides have attracted increasing attention as a novel class of antibiotics to treat infectious diseases caused by pathogenic bacteria. However, susceptibility to protease is a shortcoming in their development. Cyclization is one approach to increase the proteolytic resistance of peptides. Therefore, to improve the proteolytic resistance of Polybia‐MPI, we have synthesized the MPI cyclic analogs C‐MPI‐1 (i‐to‐i+4) and C‐MPI‐2 (i‐to‐i+6) by copper(I)‐catalyzed azide–alkyne cycloaddition. Compared with MPI, C‐MPI‐1 displayed sustained antimicrobial activity and had enhanced anti‐trypsin resistance, while C‐MPI‐2 displayed no antimicrobial activity. The relationship between peptide structure and bioactivity was further investigated by probing the secondary structure of the peptides by circular dichroism. This showed that C‐MPI‐1 adopted an α‐helical structure in aqueous solution and, interestingly, had increased α‐helical conformation in 30 mM sodium dodecyl sulfate and 50% trifluoroethyl alcohol compared with MPI. C‐MPI‐2 that was not α‐helical in structure, suggesting that the propensity for α‐helix conformation may play an important role in cyclic peptide design. In addition, scanning electron microscopy, propidium iodide uptake, and membrane permeabilization assays indicated that MPI and the optimized analog C‐MPI‐1 had membrane‐active action modes, indicating that the peptides would not be susceptible to conventional resistance mechanisms. Our study provides additional insight into the influence of intramolecular cyclization at various positions on peptide structure and biological activity. In conclusion, the design and synthesis of cyclic analogs via click chemistry offer a new strategy for the development of stable antimicrobial agents. Copyright © 2017 European Peptide Society and John Wiley & Sons, Ltd.     

Sub‐angstrom modeling of complexes between flexible peptides and globular proteins

A wide range of regulatory processes in the cell are mediated by flexible peptides that fold upon binding to globular proteins. Computational efforts to model these interactions are hindered by the large number of rotatable bonds in flexible peptides relative to typical ligand molecules, and the fact that different peptides assume different backbone conformations within the same binding site. In this study, we present Rosetta FlexPepDock, a novel tool for refining coarse peptide–protein models that allows significant changes in both peptide backbone and side chains. We obtain high resolution models, often of sub‐angstrom backbone quality, over an extensive and general benchmark that is based on a large nonredundant dataset of 89 peptide–protein interactions. Importantly, side chains of known binding motifs are modeled particularly well, typically with atomic accuracy. In addition, our protocol has improved modeling quality for the important application of cross docking to PDZ domains. We anticipate that the ability to create high resolution models for a wide range of peptide–protein complexes will have significant impact on structure‐based functional characterization, controlled manipulation of peptide interactions, and on peptide‐based drug design. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Surface plasmon resonance analysis of the binding of high‐risk mucosal HPV E6 oncoproteins to the PDZ1 domain of the tight junction protein MAGI‐1

The E6 oncoproteins from high‐risk mucosal human papillomavirus (HPV) induce cervical cancer via two major activities, the binding and the degradation of the p53 protein and PDZ domain‐containing proteins. Human MAGI‐1 is a multi‐PDZ domain protein implicated into protein complex assembly at cell–cell contacts. High‐risk mucosal HPV E6 proteins interact with the PDZ1 domain of MAGI‐1 via a C‐terminal consensus binding motif. Here, we developed a medium throughput protocol to accurately measure by surface plasmon resonance affinity constants of protein domains binding to peptidic sequences produced as recombinant fusions to the glutathione‐S‐transferase (GST). This approach was applied to measure the binding of MAGI‐1 PDZ1 to the C‐termini of viral or cellular proteins. Both high‐risk mucosal HPV E6 C‐terminal peptides and cellular partners of MAGI‐1 PDZ1 bind to MAGI‐1 PDZ1 with comparable dissociation constants in the micromolar range. MAGI‐1 PDZ1 shows a preference for C‐termini with a valine at position 0 and a negative charge at position ?3, confirming previous studies performed with HPV18 E6. A detailed combined analysis via site‐directed mutagenesis of the HPV16 C‐terminal peptide and PDZ1 indicated that interactions mediated by charged residues upstream the PDZ‐binding motif strongly contribute to binding selectivity of this interaction. In addition, our work highlighted the K₄₉₉ residue of MAGI‐1 as a novel determinant of binding specificity. Finally, we showed that MAGI‐1 PDZ1 also binds to the C‐termini of LPP and Tax proteins, which were already known to bind to PDZ proteins but not to MAGI‐1. Copyright © 2010 John Wiley & Sons, Ltd.     

Design, synthesis, structure and binding properties of PDZ binding, cyclic β-finger peptides

Protein interaction domains (PIDs) play a critical role in signal transduction. One PID of great interest is the PDZ domain, a 100 amino-acid-residue domain. Most PDZ domains recognize short, C-terminal peptide motives. In the heterodimer of the nNOS-PDZ domain and the α-syntrophin-PDZ domain, however, one PDZ domain forms a β-finger that binds to the other PDZ domain. We show here that cyclic peptides derived from the β-finger of the nNOS-PDZ domain can bind the syntrophin-PDZ domain in the same manner as the whole domain. The structure of three “finger-peptides” of different size has been determined and the binding investigated using calorimetry and NMR-titration experiments.     

A cleavable self‐assembling tag strategy for preparing proteins and peptides with an authentic N‐terminus

Recombinant protein expression and purification remains a central need for biotechnology. Herein, the authors report a streamlined protein and peptide purification strategy using short self‐assembling peptides and a C‐terminal cleavage intein. In this strategy, the fusion protein is first expressed as an aggregate induced by the self‐assembling peptide. Upon simple separation, the target protein or peptide with an authentic N‐terminus is then released in the solution by intein‐mediated cleavage. Different combinations of four self‐assembling peptides (ELK16, L₆KD, FK and FR) with three inteins (Sce VMA, Mtu ΔI‐CM and Ssp DnaB) were explored. One protein and two peptides were used as model polypeptides to test the strategy. The intein Mtu ΔI‐CM, which has pH‐shift inducible cleavage, was found to work well with three self‐assembling peptides (L₆KD, FR, FK). Using this intein gave a yield of protein or peptide comparable with that from other more established strategies, such as the Trx‐strategy, but in a simpler and more economical way. This strategy provides a simple and efficient method by which to prepare proteins and peptides with an authentic N‐terminus, which is especially effective for peptides of 30‐100 amino acids in length that are typically unstable and susceptible to degradation in Escherichia coli.     

Design, synthesis, and evaluation of linear and cyclic peptide ligands for PDZ10 of the multi-PDZ domain protein MUPP1

PDZ10 is the 10th of 13 PDZ domains found within MUPP1, a cytoplasmic scaffolding protein first identified as an endogenous binding partner of serotonin receptor type 2c (5HT2c). This association, as with those of several other interacting proteins that have subsequently been identified, is mediated through the C-terminal tail of the PDZ domain partner. Using isothermal titration calorimetry (ITC), we measured the thermodynamic binding parameters [changes in Gibbs free energy (DeltaG), enthalpy (DeltaH) and entropy (TDeltaS)] of the isolated PDZ10 domain for variable-length N-acetylated peptides from the 5HT2c serotonin receptor C-terminal sequence, as well as for octapeptides of eight other putative partner proteins of PDZ10 (5HT2a, hc-kit, hTapp1, mTapp2, TARP, NG2, claudin-1, and HPV-18 E6). In length dependence studies of the 5HT2c sequence, the maximal affinity of the peptides leveled off rapidly and further elongation did not significantly improve the dissociation constant (Kd) of 11 microM observed with the pentapeptide. Among the native partners of PDZ10, octapeptides derived from the hc-kit and 5HT2c proteins were the strongest binders, with Kd values of 5.2 and 8.5 microM, respectively. The heat capacity change (DeltaCp) for the 5HT2c octapeptide was determined to be -94 cal/mol, and a calculated estimate indicates burial of polar and apolar surface areas in equal measure upon ligand binding. Peptides with phosphoserine at either the P-1 or P-2 position experienced decreased affinity, which is in accord with the hypothesis that reversible phosphorylation is a possible mechanism for regulating PDZ domain-mediated interactions. Additionally, two conformationally constrained side chain-bridged cyclic peptide ligands were also designed, prepared, evaluated by ITC, and shown to bind PDZ10 primarily through a favorable change in entropy.     

Synthesis and screening of support-bound combinatorial peptide libraries with free C-termini: determination of the sequence specificity of PDZ domains

Preparation of support-bound combinatorial peptide libraries with free C-termini has been challenging in the past because solid-phase peptide synthesis usually starts from the C-terminus, which must be covalently attached to the solid support. In this work, we have developed a general methodology to synthesize and screen one-bead-one-compound peptide libraries containing free C-termini. TentaGel microbeads (90 mum) were spatially segregated into outer and inner layers, and peptides were synthesized on the beads in the conventional C --> N manner, with their C-termini attached to the support through an ester linkage on the bead surface but through an amide bond in the bead interior. The surface peptides were cyclized between their N-terminal amine and a carboxyl group installed at a C-terminal linker sequence, while the internal peptides were kept in the linear form. Base hydrolysis of the ester linkage in the cyclic peptides regenerated linear peptides that contained a free alpha-carboxyl group at their C-termini but remained covalently attached to the resin via the N-termini ("inverted" peptides). An inverted peptide library containing five random residues (theoretical diversity of 3.2 x 10 (6)) was synthesized and screened for binding to four postsynaptic density-95/discs large/zona occluden-1 (PDZ) domains of sodium-hydrogen exchanger regulatory factor-1 (NHERF1) and channel-interacting PDZ domain protein (CIPP). The identity of the binding peptides was determined by sequencing the linear encoding peptides inside the bead by partial Edman degradation/mass spectrometry. Consensus recognition motifs were identified for the PDZ domains, and representative peptides were resynthesized and confirmed for binding to their cognate PDZ domains. This method should be generally applicable to all PDZ domains as well as other protein domains and enzymes that recognize the C-terminus of their target proteins.