Evolution of binding affinity in a WW domain probed by phage display

The WW domain is an approximately 38 residue peptide-binding motif that binds a variety of sequences, including the consensus sequence xPPxY. We have displayed hYAP65 WW on the surface of M13 phage and randomized one-third of its three-stranded antiparallel beta-sheet. Improved binding to the hydrophobic peptide, GTPPPPYTVG (WW1), was selected in the presence of three different concentrations of proteinase K to simultaneously drive selection for improved stability as well as high-affinity binding. While some of the selected binders show cooperative unfolding transitions, others show noncooperative thermal unfolding curves. Two novel WW consensus sequences have been identified, which bind to the xPPxY motif with higher affinity than the wild-type hYAP65 WW domain. These WW domain sequences are not precedented in any natural WW domain sequence. Thus, there appear to be a large number of motifs capable of recognizing the target peptide sequence, only a subset of which appear to be used in natural proteins.     

Selection of phage antibodies by binding affinity. Mimicking affinity maturation.

We describe a process, based on display of antibodies on the surface of filamentous bacteriophage, for selecting antibodies either by their affinity for antigen or by their kinetics of dissociation (off-rate) from antigen. For affinity selection, phage are mixed with small amounts of soluble biotinylated antigen (less than 1 microgram) such that the antigen is in excess over phage but with the concentration of antigen lower than the dissociation constant (Kd) of the antibody. Those phage bound to antigen are then selected using streptavidin-coated paramagnetic beads. The process can distinguish between antibodies with closely related affinities. For off-rate selection, antibodies are preloaded with biotinylated antigen and diluted into excess unlabelled antigen for variable times prior to capture on streptavidin-coated paramagnetic beads. To mimic the affinity maturation process of the immune system, we introduced random mutations into the antibody genes in vitro using an error-prone polymerase, and used affinity selection to isolate mutants with improved affinity. Starting with a small library (40,000 clones) of mutants (average 1.7 base changes per VH gene) of the mouse antibody B1.8, and using several rounds of affinity selection, we isolated a mutant with a fourfold improved affinity to the hapten 4-hydroxy-5-iodo-3-nitrophenacetyl-(NIP)-caproic acid (mutant Kd = 9.4(+/- 0.3) nM compared with B1.8 Kd = 41.9(+/- 1.6) nm). The relative increase in affinity of the mutant is comparable to the increase seen in the anti-4-hydroxy-3-nitrophenylacetyl/NIP-caproic acid murine secondary immune response.     

A chitin-oligomer binding peptide obtained by screening of a phage display random peptide library and its affinity modulation corresponding to oxidation–reduction state

Screening of a phage display random 9-mer peptide library, in which cysteine residues were at the both terminals of the 7-mer random region, was performed to obtain an oligopeptide that recognizes a chitin-oligomer. Affinity of the obtained peptide (Cys-Ser-Arg-Thr-Thr-Arg-Thr-Arg-Cys) to chitotriose was modulated by its oxidation–reduction state. Only the oxidized form exhibited specific binding to the target molecule, chitotriose. This is the first report of reversible affinity modulation of a synthetic oligopeptide which can recognize a neutral saccharide.     

Determination of glycyrrhizic acid binding sites by a phage display method

Phages that expose peptides specifically interacting with glycyrrhizic acid (GA) were selected from a phage peptide library by affinity selection and ELISA. Amino acid sequence analysis of the selected peptides and human proteins with the SIM program revealed homology to tyrosine protein kinases, serine/threonine protein kinases, tyrosine phosphatases, and some receptors. Analysis of the peptide and virus protein sequences with the BLAST program showed that GA has affinity for various surface proteins of several human viruses such as HIV-1, hepatitis C virus, and herpesviruses.     

Functional expression and affinity selection of single-chain cro by phage display: isolation of novel DNA-binding proteins

A robust selection system affording phage display of the DNA-binding helix-turn-helix protein Cro is presented. The aim of the work was to construct an experimental system allowing for the construction and isolation of Cro-derived protein with new DNA-binding properties. A derivative of the phage lambda Cro repressor, scCro8, in which the protein subunits had been covalently connected via a peptide linker was expressed in fusion with the gene 3 protein of Escherichia coli filamentous phage. The phage-displayed single-chain Cro was shown to retain the DNA binding properties of its wild-type Cro counterpart regarding DNA sequence specificity and binding affinity. A kinetic analysis revealed the rate constant of dissociation of the single-chain Cro-phage/DNA complex to be indistinguishable from that of the free single-chain Cro. Affinity selection using a biotinylated DNA with a target consensus operator sequence allowed for a 3000-fold enrichment of phages displaying single-chain Cro over control phages. The selection was based on entrapment of phage/DNA complexes formed in solution on streptavidin-coated paramagnetic beads. The expression system was subsequently used to isolate variant scCro8 proteins, mutated in their DNA-binding residues, that specifically recognized new, unnatural target DNA ligands.     

Conformation-specific binding of alpha-synuclein to novel protein partners detected by phage display and NMR spectroscopy

Alpha-synuclein (AS) is an intrinsically unstructured protein in aqueous solution but is capable of forming beta-sheet-rich fibrils that accumulate as intracytoplasmic inclusions in Parkinson disease and certain other neurological disorders. However, AS binding to phospholipid membranes leads to a distinct change in protein conformation, stabilizing an extended amphipathic alpha-helical domain reminiscent of the exchangeable apolipoproteins. To better understand the significance of this conformational change, we devised a novel bacteriophage display screen to identify protein binding partners of helical AS and have identified 20 proteins with roles in diverse cellular processes related to membrane trafficking, ion channel modulation, redox metabolism, and gene regulation. To verify that the screen identifies proteins with specificity for helical AS, we further characterized one of these candidates, endosulfine alpha (ENSA), a small cAMP-regulated phosphoprotein implicated in the regulation of insulin secretion but also expressed abundantly in the brain. We used solution NMR to probe the interaction between ENSA and AS on the surface of SDS micelles. Chemical shift perturbation mapping experiments indicate that ENSA interacts specifically with residues in the N-terminal helical domain of AS in the presence of SDS but not in aqueous buffer lacking SDS. The ENSA-related protein ARPP-19 (cAMP-regulated phosphoprotein 19) also displays specific interactions with helical AS. These results confirm that the helical N terminus of AS can mediate specific interactions with other proteins and suggest that membrane binding may regulate the physiological activity of AS in vivo.     

Use of phage display to probe the evolution of binding specificity and affinity in integrins

The specific binding of RGD-containing proteins to integrin is a function of both the conformation of and the local sequence surrounding the RGD motif. To study the effect of these factors on integrin binding affinity and specificity, we obtained RGD-containing ligands specific for different integrins presented on the same protein scaffold. The beta-turn region between two anti-parallel beta-strands on the loop I of tendamistat, an inhibitor of alpha-amylase, was extended by two residues and randomized in a phagemid library. This library and two subsequently constructed RGD-containing loop I libraries were biopanned with purified integrins alphaIIbbeta3, alphaVbeta3 and alphaVbeta5 individually. The sequence analysis of selected tendamistat variants and characterization by phage ELISA revealed that phage adhesion is mediated exclusively by an RGD motif located at only two out of four possible positions on loop I. Further, sequences flanking the RGD motif were specific for different integrin targets. Interestingly, selected tendamistat variants mimic natural integrin ligands, both in sequence similarity and in integrin binding specificity, indicating that various ligand specificity patterns can be generated by driving towards maximum affinity in the integrin-ligand complexes.     

Identification of a novel calpain inhibitor using phage display

Calpains are calcium- and thiol-dependent proteases that cleave a variety of intracellular substrates. Overactivation of the calpains has been implicated in a number of diseases and conditions such as ischemic stroke indicating a need for the development of calpain inhibitors. A major problem with current calpain inhibitors has been specific targeting to calpain. To identify highly specific calpain interacting peptides, we developed a peptide-phage library screening method based on the calcium-dependent conformation change associated with calpain activation. A phage-peptide library representing greater than 2 billion expressed 12-mers was incubated with calpain I in the presence of calcium. The calcium-dependent bound phage was then eluted by addition of EGTA. After four rounds of selection we found a conserved 5-mer sequence represented by LSEAL. Synthetic LSEAL inhibited tau-calpain interaction and in vitro proteolysis of tau- and alpha-synuclein by calpains. Deletion of the portion of the tau protein containing a homologous sequence to LSEAL resulted in decreased calpain-mediated tau degradation. These data suggest that these peptides may represent novel calpastatin mimetics.     

Identification of the amino acid-AZT-phosphoramidase by affinity T7 phage display selection

A CEM cell cDNA T7 phage display library was prepared and used to screen for activating enzymes of phosphoramidate prodrugs of AZT monophosphate. Although, inefficient compared to ribonucleotide based phosphoramidates, hHint 1 was identified as the likely intracellular pronucleotide activating enzyme.     

Development of mammalian serum albumin affinity purification media by peptide phage display

Several phage isolates that bind specifically to human serum albumin (HSA) were isolated from disulfide-constrained cyclic peptide phage-display libraries. The majority of corresponding synthetic peptides bind with micromolar affinity to HSA in low salt at pH 6.2, as determined by fluorescence anisotropy. One of the highest affinity peptides, DX-236, also bound well to several mammalian serum albumins (SA). Immobilized DX-236 quantitatively captures HSA from human serum; mild conditions (100 mM Tris, pH 9.1) allow release of HSA. The DX-236 affinity column bound HSA from human serum with a greater specificity than does Cibacron Blue agarose beads. In addition to its likely utility in HSA and other mammalian SA purifications, this peptide media may be useful in the proteomics and medical research markets for selective removal of mammalian albumin from serum prior to mass spectrometric and other analyses.     

Efficient one-cycle affinity selection of binding proteins or peptides specific for a small-molecule using a T7 phage display pool

Here, we report an efficient one-cycle affinity selection using a natural-protein or random-peptide T7 phage pool for identification of binding proteins or peptides specific for small-molecules. The screening procedure involved a cuvette type 27-MHz quartz-crystal microbalance (QCM) apparatus with introduction of self-assembled monolayer (SAM) for a specific small-molecule immobilization on the gold electrode surface of a sensor chip. Using this apparatus, we attempted an affinity selection of proteins or peptides against synthetic ligand for FK506-binding protein (SLF) or irinotecan (Iri, CPT-11). An affinity selection using SLF-SAM and a natural-protein T7 phage pool successfully detected FK506-binding protein 12 (FKBP12)-displaying T7 phage after an interaction time of only 10 min. Extensive exploration of time-consuming wash and/or elution conditions together with several rounds of selection was not required. Furthermore, in the selection using a 15-mer random-peptide T7 phage pool and subsequent analysis utilizing receptor ligand contact (RELIC) software, a subset of SLF-selected peptides clearly pinpointed several amino-acid residues within the binding site of FKBP12. Likewise, a subset of Iri-selected peptides pinpointed part of the positive amino-acid region of residues from the Iri-binding site of the well-known direct targets, acetylcholinesterase (AChE) and carboxylesterase (CE). Our findings demonstrate the effectiveness of this method and general applicability for a wide range of small-molecules.     

Characterization of 11-dehydro-thromboxane B2 recombinant antibody obtained by phage display technology

Recombinant monoclonal antibodies specific for 11-dehydro-thromboxane B(2) (11D-TX) were isolated from the combinatorial libraries on a pComb3 phage-display vector using a magnetic cell sorting (MACS) system. The libraries were constructed from repertories of light and heavy-chains derived from the total RNA of 11D-TX conjugated keyhole limpet haemocyanin-immunized mice. Biotinylation of 11D-TX conjugated bovine serum albumin (BSA) was performed through free thiol groups on BSA using 1-biotinamido-4-[4'-(maleimidomethyl) cyclohexanecarboxamido] butane (Biotin-BMCC). Affinity bio-panning was performed to enrich the phage display libraries against biotinylated 11D-TX conjugated BSA with the MACS system. Results indicated that the selected anti-11D-TX Fab fragments expressed by E. coli exhibited a five-fold higher affinity for BSA conjugated 11D-TX compared to BSA alone and little specificity to other related compounds as determined by the binding assay and inhibition enzyme-linked immunosorbent assay (ELISA). This is the first report of an antibody against prostaglandin produced by phage display technology and also determination of the DNA sequence of this antibody. The MACS system was shown to be a simpler and more efficient method of panning than the conventional ELISA procedure. According to our results, we concluded that the phage display technique combined with the MACS system allowed the selection of the antibody with high affinity and some specificity.     

Characterization of prostate-specific antigen binding peptides selected by phage display technology

Prostate-specific antigen (PSA) is an important marker for the diagnosis and management of prostate cancer. Free PSA has been shown to be more extensively cleaved in sera from benign prostatic hyperplasia patients than in sera from prostate cancer patients. Moreover, the presence of enzymatically activatable PSA was characterized previously in sera from patients with prostate cancer by the use of the specific anti-free PSA monoclonal antibody (mAb) 5D3D11. As an attempt to obtain ligands for the specific recognition of different PSA forms including active PSA, phage-displayed linear and cyclic peptide libraries were screened with PSA coated directly into microplate wells or presented by two different anti-total PSA mAbs. Four different phage clones were selected for their ability to recognize PSA and the inserted peptides were produced as synthetic peptides. These peptides were found to capture and to detect specifically free PSA, even in complex biological media such as sera or tumour cell culture supernatants. Alanine scanning of peptide sequences showed the involvement of aromatic and hydrophobic residues in the interaction of the peptides with PSA whereas Spotscan analysis of overlapping peptides covering the PSA sequence identified a peptide binding to the kallikrein loop at residues 82-87, suggesting that the peptides could recognize a non-clipped form of PSA. Moreover, the PSA-specific peptides enhance the enzymatic activity of PSA immobilized into microplate wells whereas the capture of PSA by the peptides inhibited totally its enzymatic activity while the peptide binding to PSA had no effect in solution. These PSA-specific peptides could be potential tools for the recognition of PSA forms more specifically associated to prostate cancer.     

High affinity peptides for the recognition of the heart disease biomarker troponin I identified using phage display

Troponin I is a specific and sensitive clinical biomarker for myocardial injury. In this study we have used polyvalent phage display to isolate unique linear peptide motifs which recognize both the human and rat homologs of troponin I. The peptide specific for human troponin I has a sequence of FYSHSFHENWPS and the peptide specific for the rat troponin I has a sequence of FHSSWPVNGSTI. Enzyme‐linked immunosorbent assays (ELISAs) were used to evaluate the binding interactions, and the two phage‐displayed peptides exhibited some cross‐reactivity, but they were both more specific for the troponin I homolog they were selected against. The binding affinities of the phage‐displayed peptides were decreased by the presence of complex tissue culture media (MEM), and the addition of 10% calf serum further interfered with the binding of the target proteins. Kinetic indirect phage ELISAs revealed that both troponin I binding peptides were found to have nanomolar affinities for the troponin proteins while attached to the phage particles. To our knowledge, this is the first example of isolation and characterization of troponin I binders using phage display technology. These new peptides may have potential utility in the development of new clinical assays for cardiac injury as well as in monitoring of cardiac cells grown in culture. Biotechnol. Bioeng. 2010. 105: 678–686. © 2009 Wiley Periodicals, Inc.     

A phage display technique identifies a novel regulator of cell differentiation

The formation of new bone during the process of bone remodeling occurs almost exclusively at sites of prior bone resorption. In an attempt to discover what regulatory pathways are utilized by osteoblasts to effect this site-specific formation event we probed components of an active bone resorption surface with an osteoblast phage expression library. In these experiments primary cultures of rat osteoblasts were used to construct a phage display library in T7 phage. Tartrate-resistant acid phosphatase (type V) (TRAP) was used as the bait in a biopanning procedure. 40 phage clones with very high affinity for TRAP were sequenced, and of the clones with multiple consensus sequences we identified a regulatory protein that modulates osteoblast differentiation. This protein is the TGFbeta receptor-interacting protein (TRIP-1). Our data demonstrate that TRAP activation of TRIP-1 evokes a TGFbeta-like differentiation process. Specifically, TRIP-1 activation increases the activity and expression of osteoblast alkaline phosphatase, osteoprotegerin, collagen, and Runx2. Moreover, we show that TRAP interacts with TRIP intracellularly, that activation of the TGFbeta type II receptor by TRIP-1 occurs in the presence of TRAP and that the differentiation process is mediated through the Smad2/3 pathway. A final experiment demonstrates that osteoblasts, when cultured in osteoclast lacunae containing TRAP, rapidly and specifically differentiate into a mature bone-forming phenotype. We hypothesize that binding to TRAP may be one mechanism by which the full osteoblast phenotype is expressed during the process of bone remodeling.     

Exploration of the binding proteins of perfluorooctane sulfonate by a T7 phage display screen

Perfluorooctane sulfonate (PFOS) is a pollutant widely found throughout nature and is toxic to animals. We created a PFOS analogue on a polyethylene glycol polyacrylamide copolymer and isolated peptides that preferentially bound the PFOS analogue using a T7 phage display system. Bioinformatic analysis using the FASTAskan program on the RELIC bioinformatics server showed several human proteins that likely bound PFOS. Among them, we confirmed binding between PFOS and a recombinant soluble form of monocyte differentiation antigen CD14 (sCD14) by a surface plasmon biosensor. Furthermore, PFOS inhibited TNF-α production induced by the sCD14 in mouse macrophage RAW264.7 cells.     

High affinity divalent cation binding to actin. Effect of low affinity salt binding

Monomeric actin labeled with the fluorescent probe N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine (1,5-I-AEDANS-actin) displays a fast fluorescence intensity increase immediately upon addition of salt and then a slow fluorescence intensity change concurrent with Ca2+/Mg2+ exchange at the high affinity divalent cation binding site on actin. The fast change appears to reflect competitive binding of K+ at low affinity (nonspecific) sites and of Mg2+ or Ca2+ at low and intermediate affinity sites. Binding of cation at the low affinity sites (but apparently not at the intermediate affinity sites) results in an increase in k-Ca and k-Mg and thus a decrease in affinity for divalent cations at the high affinity site. The effect of Mg2+ on k-Ca is twice that of K+ for equal fractional saturations of the low affinity binding, and the effect of K+ and Mg2+ together on k-Ca reflects competitive binding at the low affinity sites. Thus the affinity and kinetics of divalent cation binding at the high affinity site of actin are significantly affected by concurrent cation binding at low affinity sites.     

High affinity binding of the mastoparans by calmodulin

Calmodulin exhibits high affinity, calcium-dependent binding of the mastoparans — a group of cytoactive tetradecapeptides. The dissociation constants for the peptide-calmodulin complexes determined in 0.20 N KCl, 1.0 mM CaCl₂, pH 7.3 are ～0.3 nM for mastoparan, ～0.9 nM for mastoparan X, and ～3.5 nM for $\text{Polistes}$ mastoparan. The dissociation constant for the mastoparan-calmodulin complex is the smallest known for any calmodulin binding protein or peptide, suggesting that some type of peptide-calmodulin interaction could be physiologically significant.     

EphB receptor-binding peptides identified by phage display enable design of an antagonist with ephrin-like affinity

The Eph receptor tyrosine kinases are overexpressed in many pathologic tissues and have therefore emerged as promising drug target candidates. However, there are few molecules available that can selectively bind to a single Eph receptor and not other members of this large receptor family. Here we report the identification by phage display of peptides that bind selectively to different receptors of the EphB class, including EphB1, EphB2, and EphB4. Peptides with the same EphB receptor specificity compete with each other for binding, suggesting that they have partially overlapping binding sites. In addition, several of the peptides contain amino acid motifs found in the G-H loop of the ephrin-B ligands, which is the region that mediates high-affinity interaction with the EphB receptors. Consistent with targeting the ephrin-binding site, the higher affinity peptides antagonize ephrin binding to the EphB receptors. We also designed an optimized EphB4-binding peptide with affinity comparable with that of the natural ligand, ephrin-B2. These peptides should be useful as selective inhibitors of the pathological activities of EphB receptors and as targeting agents for imaging probes and therapeutic drugs.