mRNA display selection and solid‐phase synthesis of Fc‐binding cyclic peptide affinity ligands

Cyclic peptides are attractive candidates for synthetic affinity ligands due to their favorable properties, such as resistance to proteolysis, and higher affinity and specificity relative to linear peptides. Here we describe the discovery, synthesis and characterization of novel cyclic peptide affinity ligands that bind the Fc portion of human Immunoglobulin G (IgG; hFc). We generated an mRNA display library of cyclic pentapeptides wherein peptide cyclization was achieved with high yield and selectivity, using a solid‐phase crosslinking reaction between two primary amine groups, mediated by a homobifunctional linker. Subsequently, a pool of cyclic peptide binders to hFc was isolated from this library and chromatographic resins incorporating the selected cyclic peptides were prepared by on‐resin solid‐phase peptide synthesis and cyclization. Significantly, this approach results in resins that are resistant to harsh basic conditions of column cleaning and regeneration. Further studies identified a specific cyclic peptide—cyclo[Link‐M‐WFRHY‐K]—as a robust affinity ligand for purification of IgG from complex mixtures. The cyclo[Link‐M‐WFRHY‐K] resin bound selectively to the Fc fragment of IgG, with no binding to the Fab fragment, and also bound immunoglobulins from a variety of mammalian species. Notably, while the recovery of IgG using the cyclo[Link‐M‐WFRHY‐K] resin was comparable to a Protein A resin, elution of IgG could be achieved under milder conditions (pH 4 vs. pH 2.5). Thus, cyclo[Link‐M‐WFRHY‐K] is an attractive candidate for developing a cost‐effective and robust chromatographic resin to purify monoclonal antibodies (mAbs). Finally, our approach can be extended to efficiently generate and evaluate cyclic peptide affinity ligands for other targets of interest. Biotechnol. Bioeng. 2013; 110: 857–870. © 2012 Wiley Periodicals, Inc.     

交替洗脱法筛选高亲和力噬菌体肽

以人胰岛素为靶蛋白从七肽展示库中筛选高亲和力噬菌体肽,在洗脱阶段采用酸性洗脱液和高浓度靶蛋白溶液进行4次交替洗脱,选择性回收高亲和力噬菌体肽。测定滴度计算回收率,ELISA法分别测定噬菌体洗脱液整体亲和力和噬菌体单克隆的结合特性并计算亲合率。洗脱步骤采用4次交替洗脱后,第二轮第4次噬菌体的回收率比第一轮增长了1800倍,高亲和力噬菌体在洗脱液中所占比例也迅速提高,第二轮第4次洗脱液中达75％,在第三轮的各次洗脱液中几乎均达100％。建立了一种快速筛选高亲和力噬菌体肽的方法,改进后的筛选方法能使高亲和力噬菌体肽的筛选工作更为简便且效果显著。     

Large‐scale survey and database of high affinity ligands for peptide recognition modules

Many proteins involved in signal transduction contain peptide recognition modules (PRMs) that recognize short linear motifs (SLiMs) within their interaction partners. Here, we used large‐scale peptide‐phage display methods to derive optimal ligands for 163 unique PRMs representing 79 distinct structural families. We combined the new data with previous data that we collected for the large SH3, PDZ, and WW domain families to assemble a database containing 7,984 unique peptide ligands for 500 PRMs representing 82 structural families. For 74 PRMs, we acquired enough new data to map the specificity profiles in detail and derived position weight matrices and binding specificity logos based on multiple peptide ligands. These analyses showed that optimal peptide ligands resembled peptides observed in existing structures of PRM‐ligand complexes, indicating that a large majority of the phage‐derived peptides are likely to target natural peptide‐binding sites and could thus act as inhibitors of natural protein–protein interactions. The complete dataset has been assembled in an online database (http://www.prm‐db.org) that will enable many structural, functional, and biological studies of PRMs and SLiMs.     

Selection of ceramic fluorapatite‐binding peptides from a phage display combinatorial peptide library: optimum affinity tags for fluorapatite chromatography

Peptide affinity tags have become efficient tools for the purification of recombinant proteins from biological mixtures. The most commonly used ligands in this type of affinity chromatography are immobilized metal ions, proteins, antibodies, and complementary peptides. However, the major bottlenecks of this technique are still related to the ligands, including their low stability, difficulties in immobilization, and leakage into the final products. A model approach is presented here to overcome these bottlenecks by utilizing macroporous ceramic fluorapatite (CFA) as the stationary phase in chromatography and the CFA‐specific short peptides as tags. The CFA chromatographic materials act as both the support matrix and the ligand. Peptides that bind with affinity to CFA were identified from a randomized phage display heptapeptide library. A total of five rounds of phage selection were performed. A common N‐terminal sequence was found in two selected peptides: F4‐2 (KPRSMLH) and F5‐4 (KPRSVSG). The peptide F5‐4, displayed by more than 40% of the phages analyzed in the fifth round of selection, was subjected to further studies. Selectivity of the peptide for the chemical composition and morphology of CFA was assured by the adsorption studies. The dissociation constant, obtained from the F5‐4/CFA adsorption isotherm, was in the micromolar range, and the maximum capacity was 39.4 nmol/mg. The chromatographic behavior of the peptides was characterized on a CFA stationary phase with different buffers. Preferential affinity and specific retention properties suggest the possible application of the phage‐derived peptides as a tag in CFA affinity chromatography for enhancing the selective recovery of proteins. Copyright © 2013 John Wiley & Sons, Ltd.     

An effective peptide screening system using recombinant fluorescent bacterial surface display

An effective method for peptide screening of ligand-binding proteins was applied by using recombinant E. coli which is capable of expressing green fluorescent protein (GFP) and which can also express random peptides displayed on flagella of the cells. This screening method used a combination of fluorescence-activated cell sorting (FACS) and flagella display on the basis of a commercial FliTrx random peptide library for isolating the peptide-displaying clones which are able to bind Alexa 546 fluorescence-labeled cytochrome c. Flow cytometry simultaneously detected the two different fluorescence intensities, from GFP in the library and Alexa546-labeled to cytochrome c, enabling the specific clones bound to cytochrome c to be obtained from the first or second round of cell sorting. Compared with original FliTrx peptide screening system that requires repeating biopanning five times, our results suggested that detecting two different fluorescence intensities by flow cytometry is feasible for effective peptide screening.     

Monoclonal antibody purification by affinity chromatography with ligands derived from the screening of peptide combinatory libraries

The peptide, Ala-Pro-Ala-Arg (APAR), was selected from the screening of a tetrapeptide combinatorial synthetic library as the ligand for affinity purification of an anti-Granulocyte Macrophage-Colony Stimulating Factor (GM-CSF) monoclonal antibody (Mab) developed in mouse ascitis. The affinity chromatographic matrix obtained by attachment of APAR to agarose, having a peptide density of 0.5 mol ml^–1, showed a maximum capacity of 9.1 mg Mab ml^–1 and a dynamic capacity of 3.9 mg Mab ml^–1. A 95% yield of electrophoretically pure anti-GM-CSF was obtained in a single step.     

Searching sequence space for high-affinity binding peptides using ribosome display

We present the construction of a synthetic library based on the scaffold of bovine heart fatty acid-binding protein (FABP) with 1.1x10(14) independent members. Ribosome display was applied to select streptavidin-binding peptides in vitro from 2x10(13) molecules of the library each encoding FABP with 15 contiguous random amino acid residues at its N terminus. The selection yielded several different binding peptides. The best binder possessed a dissociation constant as low as 4nM and, in contrast to the previously isolated peptides, contained no HPQ motif. A substitution analysis enabled shortening of the 15-mer peptide and revealed a 9-mer variant with a dissociation constant of 17nM, which is a 1000-fold increase of affinity compared to the already known peptides of this size. This high-affinity binding peptide in combination with the whole set of streptavidin conjugates should be an extremely useful tool for the detection and purification of recombinant proteins.     

Directed discovery of bivalent peptide ligands to an SH3 domain

The Caenorhabditis elegans SEM-5 SH3 domains recognize proline-rich peptide segments with modest affinity. We developed a bivalent peptide ligand that contains a naturally occurring proline-rich binding sequence, tethered by a glycine linker to a disulfide-closed loop segment containing six variable residues. The glycine linker allows the loop segment to explore regions of greatest diversity in sequence and structure of the SH3 domain: the RT and n-Src loops. The bivalent ligand was optimized using phage display, leading to a peptide (PP-G(4)-L) with 1000-fold increased affinity for the SEM-5 C-terminal SH3 domain over that of a natural ligand. NMR analysis of the complex confirms that the peptide loop segment is targeted to the RT and n-Src loops and parts of the beta-sheet scaffold of this SH3 domain. This binding region is comparable to that targeted by a natural non-PXXP peptide to the p67(phox) SH3 domain, a region not known to be targeted in the Grb2 SH3 domain family. PP-G(4)-L may aid in the discovery of additional binding partners of Grb2 family SH3 domains.     

Selection of substrate recognition sequence of protein kinase with ferric chelation affinity chromatography

Protein kinase substrate phage (PKS phage) was constructed by fusing the substrate recognition consensus sequence of cAMP-dependent protein kinase (cAPK) with bacteriophage minor coat protein g3p and by dis-playing it on the surface of filamentous bacteriophage fd. Phosphorylation in vitro by cAPK showed a unique labelled band of approximately 60 ku, which was consistent with the molecular weight of the PKS-g3p fusion protein. Some weakly phosphorylated bands for both PKS phage and wild-type phage were also observed. Phage display random 15-mer peptide library phosphorylated by cAPK was selected with ferric (Fe3 ) chelalion affinity resin. After 4 rounds of screening, phage clones were picked out to determine the displayed peptide sequences by DNA sequencing. The results showed that 5 of 14 sequenced phages displayed the cAPK recognition sequence motif (R)RXS/T. Their in vitro phosphorylation analyses revealed the specific labelled bands corresponding to the positive PKS phages with and without the typ     

A new generation of protein display scaffolds for molecular recognition

Engineered antibodies and their fragments are invaluable tools for a vast range of biotechnological and pharmaceutical applications. However, they are facing increasing competition from a new generation of protein display scaffolds, specifically selected for binding virtually any target. Some of them have already entered clinical trials. Most of these nonimmunoglobulin proteins are involved in natural binding events and have amazingly diverse origins, frameworks, and functions, including even intrinsic enzyme activity. In many respects, they are superior over antibody-derived affinity molecules and offer an ever-extending arsenal of tools for, e.g., affinity purification, protein microarray technology, bioimaging, enzyme inhibition, and potential drug delivery. As excellent supporting frameworks for the presentation of polypeptide libraries, they can be subjected to powerful in vitro or in vivo selection and evolution strategies, enabling the isolation of high-affinity binding reagents. This article reviews the generation of these novel binding reagents, describing validated and advanced alternative scaffolds as well as the most recent nonimmunoglobulin libraries. Characteristics of these protein scaffolds in terms of structural stability, tolerance to multiple substitutions, ease of expression, and subsequent applications as specific targeting molecules are discussed. Furthermore, this review shows the close linkage between these novel protein tools and the constantly developing display, selection, and evolution strategies using phage display, ribosome display, mRNA display, cell surface display, or IVC (in vitro compartmentalization). Here, we predict the important role of these novel binding reagents as a toolkit for biotechnological and biomedical applications.     

Identifying peptide ligands for cell surface receptors using cell-growth-on-bead assay and one-bead one-compound combinatorial library

A cell-growth-on-bead assay was used to screen one-bead, one-compound combinatorial libraries for peptide ligands that attract attachment and growth of human lung cancer cells. A consensus cyclic peptide sequence, d-cys-l-asn-l-gly-l-arg-l-gly-l-glu-l-gln-d-cys (cNGRGEQc), was identified as a ligand for a cell surface receptor, 31 integrin. This peptide ligand and its analogs have the potential to be used as diagnostic and therapeutic agents for lung cancer.     

Purification of anti-MUC1 antibodies by peptide mimotope affinity chromatography using peptides derived from a polyvalent phage display library

A polyvalent, lytic phage display system (T7Select415-1b) displaying a random peptide library has been investigated for its ability to discover novel mimotopes reactive with the therapeutic monoclonal antibody C595. Sequence analysis of enriched phage lead to the identification of a predominant sequence RNREAPRGKICS, and two other consensus sequences RXXP and RXP. The novel synthetic peptide RNREAPRGKICS was linked to beaded agarose and the performance as a mimotope affinity chromatography matrix evaluated. Antibody purified using the novel matrix was found to be of higher specific reactivity than antibody purified using the conventional epitope matrix (peptide APDTRPAPG). The RNREAPRGKICS peptide binding to C595 demonstrated a higher equilibrium association constant (K(A)=0.75 x 10(6)) than the epitope peptide (K(A)=0.16 x 10(6)). Circular dichroism showed that the novel peptide had a more highly ordered structure at 4 degrees C and room temperature, than the epitope peptide.     

High resolution structure of streptavidin in complex with a novel high affinity peptide tag mimicking the biotin binding motif

A novel peptide was designed which possesses nanomolar affinity of less than 20 nM for streptavidin. Therefore it was termed Nano-tag and has been used as an affinity tag for recombinant proteins. The minimized version of the wild type Nano-tag is a seven-amino acid peptide with the sequence fMDVEAWL. The three-dimensional structure of wild type streptavidin in complex with the minimized Nano-tag was analyzed at atomic resolution of 1.15 A and the details of the binding motif were investigated. The peptide recognizes the same pocket of streptavidin where the natural ligand biotin is bound, but the peptide requires significantly more space than biotin. Therefore the binding loop adopts an "open" conformation in order to release additional space for the peptide. The conformation of the bound Nano-tag corresponds to a 3(10) helix. However, the analysis of the intermolecular interactions of the Nano-tag with residues of the binding pocket of streptavidin reveals astonishing similarities to the biotin binding motif. In principle the three-dimensional conformation of the Nano-tag mimics the binding mode of biotin. Our results explain why the use of the Nano-tag in fusion with recombinant proteins is restricted to their N-terminus and we describe the special significance of the fMet residue for the high affinity binding mode.     

Expansion of protein interaction maps by phage peptide display using MDM2 as a prototypical conformationally flexible target protein

Expanding on the possible protein interaction partners in a biochemical pathway is one key molecular goal in the post-genomic era. Phage peptide display is a versatile in vitro tool for mapping novel protein-protein interfaces and the advantage of this technique in expanding protein interaction maps is that in vitro manipulation of the bait protein conformational integrity can be controlled carefully. Phage peptide display was used to expand on the possible types of binding proteins for the conformationally responsive protein MDM2. Peptides enriched differ depending upon whether MDM2 is ligand-free, zinc-bound, or RNA-bound, suggesting that MDM2 conformational changes alter the type of peptide ligands enriched. Classes of putative/established MDM2-binding proteins identified by this technique included ubiquitin-modifying enzymes (F-box proteins, UB-ligases, UBC-E1) and apoptotic modifiers (HSP90, GAS1, APAF1, p53). Of the many putative MDM2 proteins that could be examined, the impact of HSP90 on MDM2 activity was studied, since HSP90 has been linked with p53 protein unfolding in human cancers. Zinc ions were required to reconstitute a stable MDM2-HSP90 protein complex. Zinc binding converted MDM2 from a monomer to an oligomer, and activated MDM2 binding to its internal RING finger domain, providing evidence for a conformational change in MDM2 protein when it binds zinc. Reconstitution of an HSP90-MDM2 protein complex in vitro stimulated the unfolding of the p53 tetramer. A p53 DNA-binding inhibitor purified from human cells that is capable of unfolding p53 at ambient temperature in vitro contains co-purifying pools of HSP90 and MDM2. These data highlight the utility of phage peptide display as a powerful in vitro method to identify regulatory proteins that bind to a conformationally flexible protein like MDM2.     

Identification of epitopes recognized by monoclonal antibodies directed against HTLV-I envelope surface glycoprotein using peptide phage display

Summary Phage peptide libraries constitute powerful tools for the mapping of epitopes recognized by monoclonal antibodies (mAbs). Using screening of phage displayed random peptide libraries we have characterized the binding epitopes of three mAbs directed against the surface envelope glycoprotein (gp46) of the human T-cell leukemia virus type I (HTLV-I). Two phage libraries, displaying random heptapeptides with or without flanking cysteine residues, were screened for binding to mAbs 7G5D8, DB4 and 4F5F6. The SSSSTPL consensus sequence isolated from constrained heptapeptide library defines the epitope recognized by DB4 mAb and corresponds to the exact region 249–252 of the virus sequence. The APPMLPH consensus sequence isolated from non constrained heptapeptide library defines the epitope recognized by 7G5D8 mAb and corresponds to the region 187–193 with a single amino acid substitution, methionine to leucine at position 190. The third consensus sequence LYWPHD isolated from constrained heptapeptide library defines the epitope recognized by 4F5F6 mAb. It corresponds to an epitope without direct equivalence with the virus sequence. The data presented here showed that 7G5D8 and DB4 mAbs are raised against linear epitopes while 4F5F6 mAb recognized a continoous topographic epitope.     

Identification of epitopes recognized by monoclonal antibodies directed against HTLV-I envelope surface glycoprotein using peptide phage display

Phage peptide libraries constitute powerful tools for themapping of epitopes recognized by monoclonal antibodies (mAbs).Using screening of phage displayed random peptide libraries wehave characterized the binding epitopes of three mAbs directedagainst the surface envelope glycoprotein (gp46) of the humanT-cell leukemia virus type I (HTLV-I). Two phage libraries,displaying random heptapeptides with or without flankingcysteine residues, were screened for binding to mAbs 7G5D8, DB4and 4F5F6. The SSSSTPL consensus sequence isolated fromconstrained heptapeptide library defines the epitope recognizedby DB4 mAb and corresponds to the exact region 249–252 of thevirus sequence. The APPMLPH consensus sequence isolated fromnon constrained heptapeptide library defines the epitoperecognized by 7G5D8 mAb and corresponds to the region 187–193with a single amino acid substitution, methionine to leucine atposition 190. The third consensus sequence LYWPHD isolated fromconstrained heptapeptide library defines the epitope recognizedby 4F5F6 mAb. It corresponds to an epitope without directequivalence with the virus sequence. The data presented hereshowed that 7G5D8 and DB4 mAbs are raised against linearepitopes while 4F5F6 mAb recognized a continuous topographic epitope.     

Highly efficient purification of protein complexes from mammalian cells using a novel streptavidin-binding peptide and hexahistidine tandem tag system: application to Bruton's tyrosine kinase

Tandem affinity purification (TAP) is a generic approach for the purification of protein complexes. The key advantage of TAP is the engineering of dual affinity tags that, when attached to the protein of interest, allow purification of the target protein along with its binding partners through two consecutive purification steps. The tandem tag used in the original method consists of two IgG‐binding units of protein A from Staphylococcus aureus (ProtA) and the calmodulin‐binding peptide (CBP), and it allows for recovery of 20–30% of the bait protein in yeast. When applied to higher eukaryotes, however, this classical TAP tag suffers from low yields. To improve protein recovery in systems other than yeast, we describe herein the development of a three‐tag system comprised of CBP, streptavidin‐binding peptide (SBP) and hexa‐histidine. We illustrate the application of this approach for the purification of human Bruton's tyrosine kinase (Btk), which results in highly efficient binding and elution of bait protein in both purification steps (>50% recovery). Combined with mass spectrometry for protein identification, this TAP strategy facilitated the first nonbiased analysis of Btk interacting proteins. The high efficiency of the SBP‐His₆ purification allows for efficient recovery of protein complexes formed with a target protein of interest from a small amount of starting material, enhancing the ability to detect low abundance and transient interactions in eukaryotic cell systems.     

Construction of a novel cell-surface display system for heterologous gene expression in Escherichia coli by using an outer membrane protein of Zymomonas mobilis as anchor motif

A novel bacterial cell-surface display system was developed in Escherichia coli using omp1, a hypothetical outer membrane protein of Zymomonas mobilis. By using this system, we successfully expressed β-amylase gene of sweet potato in E. coli. The display of enzyme on the membrane surface was also confirmed. The recombinant β-amylase showed to significantly increase hydrolytic activity toward soluble starch. Our results provide a basis for constructing an engineered Z. mobilis strain directly fermenting raw starch to produce ethanol.