Selection of catalytically active biotin ligase and trypsin mutants by phage display.

Phage display has been shown to facilitate greatly the selection of polypeptides with desired properties by establishing a direct link between the polypeptide and the gene that encodes it. However, selection for catalytic activities displayed on phage remains a challenge, since reaction products diffuse away from the enzyme and make it difficult to recover catalytically active phage-enzymes. We have recently described a selection methodology in which the reaction substrate (and eventually the reaction product) is anchored on calmodulin-tagged phage-enzymes by means of a calmodulin binding peptide. Phage displaying a catalytic activity are physically isolated by means of affinity reagents specific for the product of reaction. In this study, we investigated the efficiency of selection for catalysis by phage display, using a ligase (the Escherichia coli biotin ligase BirA) and an endopeptidase (the rat trypsin His57--> Ala mutant) as model enzymes. These enzymes could be displayed on phage as fusion proteins with calmodulin and the minor coat protein pIII. Both the display of functional enzyme and the efficiency of selection for catalysis were significantly improved by using phage vectors, rather than phagemid vectors. In model selection experiments, phage displaying BirA were consistently enriched (between 4-fold and 800-fold) per round of panning, relative to negative controls. Phage displaying the trypsin His57-->Ala mutant, a relatively inefficient endopeptidase which cleaves a specific dipeptide sequence, were enriched (between 15-fold and 2000-fold), relative to negative controls. In order to improve the catalytic properties of the trypsin His57-->Ala mutant, we constructed a combinatorial phage display library of trypsin mutants. Selection of catalytically active phage-enzymes was evidentiated by increasing phage titres at the different rounds of panning relative to negative control selections, but mutants with catalytic properties superior to those of trypsin His57-->Ala mutant could not be isolated. The results obtained provide evidence that catalytic activities can be recovered using phage display technology, but stress the importance of both library design and stringent biopanning conditions for the recovery of novel enzymes.     

Display of active subtilisin 309 on phage: analysis of parameters influencing the selection of subtilisin variants with changed substrate specificity from libraries using phosphonylating inhibitors

Many attempts have been made to endow enzymes with new catalytic activities. One general strategy involves the creation of random combinatorial libraries of mutants associated with an efficient screening or selection scheme. Phage display has been shown to greatly facilitate the selection of polypeptides with desired properties by establishing a close link between the polypeptide and the gene that encodes it. Selection of phage displayed enzymes for new catalytic activities remains a challenge. The aim of this study was to display the serine protease subtilisin 309 (savinase) from Bacillus lentus on the surface of filamentous fd phage and to develop selection schemes that allow the extraction of subtilisin variants with a changed substrate specificity from libraries. Subtilisins are produced as secreted preproenzyme that mature in active enzyme autocatalytically. They have a broad substrate specificity but exhibit a significant preference for hydrophobic residues and very limited reactivity toward charged residues at the P4 site in the substrate. Here, we show that savinase can be functionally displayed on phage in the presence of the proteic inhibitor CI2. The free enzyme is released from its complex with CI2 upon addition of the anionic detergent LAS. The phage-enzyme can be panned on streptavidin beads after labelling by reaction with (biotin-N-epsilon-aminocaproyl-cystamine-N'-glutaryl)-l-Ala-l-Ala-l-P ro-Phe(P)-diphenyl ester. Reactions of libraries, in which residues 104 and 107 forming part of the S4 pocket have been randomised, with (biotin-N-epsilon-aminocaproyl-cystamine-N'-glutaryl)-alpha-l-Lys-l-A la-l-Pro-Phe(P)-diphenylester allowed us to select enzymes with increased specific activity for a substrate containing a lysine in P4. Parameters influencing the selection as for instance the efficiency of maturation of mutant enzymes in libraries have been investigated.     

Catalytic Turnover-Based Phage Selection for Engineering the Substrate Specificity of Sfp Phosphopantetheinyl Transferase

We report a high-throughput phage selection method to identify mutants of Sfp phosphopantetheinyl transferase with altered substrate specificities from a large library of the Sfp enzyme. In this method, Sfp and its peptide substrates are co-displayed on the M13 phage surface as fusions to the phage capsid protein pIII. Phage-displayed Sfp mutants that are active with biotin-conjugated coenzyme A (CoA) analogues would covalently transfer biotin to the peptide substrates anchored on the same phage particle. Affinity selection for biotin-labeled phages would enrich Sfp mutants that recognize CoA analogues for carrier protein modification. We used this method to successfully change the substrate specificity of Sfp and identified mutant enzymes with more than 300-fold increase in catalytic efficiency with 3′-dephospho CoA as the substrate. The method we developed in this study provides a useful platform to display enzymes and their peptide substrates on the phage surface and directly couples phage selection with enzyme catalysis. We envision this method to be applied to engineering the catalytic activities of other protein posttranslational modification enzymes.     

Biotechnological applications of phage and cell display

In recent years, the use of surface-display vectors for displaying polypeptides on the surface of bacteriophage and bacteria, combined with in vitro selection technologies, has transformed the way in which we generate and manipulate ligands, such as enzymes, antibodies and peptides. Phage display is based on expressing recombinant proteins or peptides fused to a phage coat protein. Bacterial display is based on expressing recombinant proteins fused to sorting signals that direct their incorporation on the cell surface. In both systems, the genetic information encoding for the displayed molecule is physically linked to its product via the displaying particle. Using these two complementary technologies, we are now able to design repertoires of ligands from scratch and use the power of affinity selection to select those ligands having the desired (biological) properties from a large excess of irrelevant ones. With phage display, tailor-made proteins (fused peptides, antibodies, enzymes, DNA-binding proteins) may be synthesized and selected to acquire the desired catalytic properties or affinity of binding and specificity for in vitro and in vivo diagnosis, for immunotherapy of human disease or for biocatalysis. Bacterial surface display has found a range of applications in the expression of various antigenic determinants, heterologous enzymes, single-chain antibodies, and combinatorial peptide libraries. This review explains the basis of phage and bacterial surface display and discusses the contributions made by these two leading technologies to biotechnological applications. This review focuses mainly on three areas where phage and cell display have had the greatest impact, namely, antibody engineering, enzyme technology and vaccine development.     

Citrulline-modified phage display: a novel high-throughput discovery approach for the identification of citrulline-containing ligands

Phage display is a high-throughput technology used to identify ligands for a given target. A drawback of the approach is the absence of PTMs in phage-displayed peptides. The applicability of phage display could be broadened considerably by the implementation of PTMs in this system. The aim of this study was to investigate the possible application of citrullination, a PTM of an arginine into a citrulline amino acid, in filamentous (M13) and lytic (T7) phage display. After in vitro citrullination of T7 and M13 phages, citrullination was confirmed and the infectivity of both citrullinated and non-citrullinated phage was compared by titer determination. We demonstrated the successful in vitro citrullination of T7 and M13 phage-displayed peptides. This in vitro modification did not affect the viability or infectivity of the T7 virions, a necessary prerequisite for the implementation of this approach in T7 phage display. For M13 phage, however, the infecting phage titer decreased five-fold upon citrullination, limiting the use of this modification in M13 phage display. In conclusion, in vitro citrullination can be applied in T7 phage display giving rise to a high-throughput and sensitive approach to identify citrulline-containing ligands by the use of the strengths of phage display technology.     

多肽噬菌体展示

噬菌体展示技术已被广泛地应用于生物学研究的各个方面.利用它可融合表达多肽、蛋白质结构域和蛋白质.尤其是多肽噬菌体展示,已被作为一种便利的研究工具去发现和研究那些与受体、酶、凝集素、抗体、核酸以及其他生物分子亲和的多肽配基和酶的底物专一性,该技术在药物的发现,疫苗的设计等医学领域也有着潜在的应用价值.     

Global substrate specificity profiling of post‐translational modifying enzymes

Enzymes that modify the proteome, referred to as post‐translational modifying (PTM) enzymes, are central regulators of cellular signaling. Determining the substrate specificity of PTM enzymes is a critical step in unraveling their biological functions both in normal physiological processes and in disease states. Advances in peptide chemistry over the last century have enabled the rapid generation of peptide libraries for querying substrate recognition by PTM enzymes. In this article, we highlight various peptide‐based approaches for analysis of PTM enzyme substrate specificity. We focus on the application of these technologies to proteases and also discuss specific examples in which they have been used to uncover the substrate specificity of other types of PTM enzymes, such as kinases. In particular, we highlight our multiplex substrate profiling by mass spectrometry (MSP‐MS) assay, which uses a rationally designed, physicochemically diverse library of tetradecapeptides. We show how this method has been applied to PTM enzymes to uncover biological function, and guide substrate and inhibitor design. We also briefly discuss how this technique can be combined with other methods to gain a systems‐level understanding of PTM enzyme regulation and function.     

A novel strategy for the functional cloning of enzymes using filamentous phage display: the case of nucleotidyl transferases

In vitro selections for catalytic activity have been designed for the isolation of genes encoding enzymes from libraries of proteins displayed on filamentous phages. The proteins are generally expressed as C-terminal fusions with the N-terminus of the minor coat protein p3 for display on phages. As full-length cDNAs generally contain several stop codons near their 3′ end, this approach cannot be used for their expression on the surface of phages. Here we show that in vitro selection for catalytic activity is compatible with a system for expression of proteins as N-terminal fusions on the surface of bacteriophages. It is highlighted for the Stoffel fragment of Taq DNA polymerase I and makes use of (p3–Jun/Fos–Stoffel fragment) fusions. The efficiency of the selection is measured by an enrichment factor found to be about 55 for a phage polymerase versus a phage not expressing a polymerase. This approach could provide a method for the functional cloning of nucleotidyl transferases from cDNA libraries using filamentous phage display.     

The phage display of Bacillus subtilis Lipase A significantly enhances catalytic activity due to altered nanoscale distribution in colloidal solution

Screening libraries of mutant proteins by phage display is now relatively common. However, one unknown factor is how the bacteriophage scaffold itself influences the properties of the displayed protein. This communication evaluates the effect of solution parameters on the catalytic activity of phage displayed Bacillus subtilis Lipase A (BSLA), compared to the free enzyme in solution. While the pH- and temperature-activity profiles of BSLA were not intrinsically affected by phage display, the nanoscale distribution of BSLA within the micellar assay buffer was. This lead to a pronounced increase of activity of phage–BSLA relative to the free enzyme, owing to the accumulation of phage–BSLA at the substrate-rich micelles. Considering this result obtained for BSLA, caution is warranted and similar effects should be considered when selecting other enzymes/proteins by phage display, as the activity of the displayed protein may differ from that of the free protein.     

Display of Ras on filamentous phage through cysteine replacement

Phage display technology has been used in a variety of contexts to understand and manipulate biomolecular interactions between proteins and other biomolecules. In this paper we describe the establishment of a phage display system for elucidation of the interactions between the GTPase Ras and its panel of effectors. It is shown how technical problems associated with phage display of a protein with unpaired cysteines, likely to be caused by the oxidizing environment of the bacterial periplasm into which the protein is directed, can be overcome by cysteine replacement based on functional and structural studies. First, the catalytic domain (residues 1-166) of mammalian H-Ras (Ras) was observed to be displayed on phage in an incorrect conformation not detectable by antibodies recognizing conformational epitopes on Ras. Although truncation of the phage coat protein used as fusion partner (g3p) resulted in minor improvements in the display, Ras was tailored for phage display by cysteine replacement. By replacing the three cysteines at positions 51, 80 and 118 of Ras with the corresponding residues in Saccharomyces cerevisiae RAS1, the resulting fusion-phage is recognized by the conformation-dependent anti-Ras antibodies. Furthermore, display of cysteine-free Ras is demonstrated by GTP-analogue dependent binding to the Ras-binding domain of the Ras-effector Raf1. These data pave the way for analysis of Ras-effector interactions using phage display technology yet demonstrate that phage display of proteins with normally reduced cysteines should be approached with caution.     

Phage display: Concept,innovations, applications and future

Phage display is the technology that allows expression of exogenous (poly)peptides on the surface of phage particles. The concept is simple in principle: a library of phage particles expressing a wide diversity of peptides is used to select those that bind the desired target. The filamentous phage M13 is the most commonly used vector to create random peptide display libraries. Several methods including recombinant techniques have been developed to increase the diversity of the library. On the other extreme, libraries with various biases can be created for specific purposes. For instance, when the sequence of the peptide that binds the target is known, its affinity and selectivity can be increased by screening libraries created with limited mutagenesis of the peptide. Phage libraries are screened for binding to synthetic or native targets. The initial screening of library by basic biopanning has been extended to column chromatography including negative screening and competition between selected phage clones to identify high affinity ligands with greater target specificity. The rapid isolation of specific ligands by phage display is advantageous in many applications including selection of inhibitors for the active and allosteric sites of the enzymes, receptor agonists and antagonists, and G-protein binding modulatory peptides. Phage display has been used in epitope mapping and analysis of protein-protein interactions. The specific ligands isolated from phage libraries can be used in therapeutic target validation, drug design and vaccine development. Phage display can also be used in conjunction with other methods. The past innovations and those to come promise a bright future for this field.     

从噬菌体文库中筛选潜在的GMCSF的拮抗剂(英文)

以粒细胞巨噬细胞集落刺激因子（ＧＭＣＳＦ） 为筛选文库的靶分子, 通过高效筛选（Ｈｉｇｈ ｔｈｒｏｕｇｈｐｕｔｓｃｒｅｅｎｉｎｇ, ＨＴＳ） 方法来筛选多种多肽噬菌体文库, 在一个以噬菌体主要蛋白质为载体的多肽噬菌体文库中筛选到了一些与ＧＭＣＳＦ结合的多肽, 并通过了ＥＬＩＳＡ和微淘选（ｍｉｃｒｏｐａｎｎｉｎｇ） 实验的证实。这些多肽先导化合物经过进一步的优化, 可能成为ＧＭＣＳＦ细胞因子的拮抗剂     

Overlapping binding sites for trypsin and papain on a Kunitz-type proteinase inhibitor from Prosopis juliflora

Proteinase inhibitors are among the most promising candidates for expression by transgenic plants and consequent protection against insect predation. However, some insects can respond to the threat of the proteinase inhibitor by the production of enzymes insensitive to inhibition. Inhibitors combining more than one favorable activity are therefore strongly favored. Recently, a known small Kunitz trypsin inhibitor from Prosopis juliflora (PTPKI) has been shown to possess unexpected potent cysteine proteinase inhibitory activity. Here we show, by enzyme assay and gel filtration, that, unlike other Kunitz inhibitors with dual activities, this inhibitor is incapable of simultaneous inhibition of trypsin and papain. These data are most readily interpreted by proposing overlapping binding sites for the two enzymes. Molecular modeling and docking experiments favor an interaction mode in which the same inhibitor loop that interacts in a canonical fashion with trypsin can also bind into the papain catalytic site cleft. Unusual residue substitutions at the proposed interface can explain the relative rarity of twin trypsin/papain inhibition. Other changes seem responsible for the relative low affinity of PTPKI for trypsin. The predicted coincidence of trypsin and papain binding sites, once confirmed, would facilitate the search, by phage display for example, for mutants highly active against both proteinases.     

Taking aim on bacterial pathogens: from phage therapy to enzybiotics

The bactericidal activity of bacteriophages has been used to treat human infections for years as an alternative or a complement to antibiotic therapy. Nowadays, endolysins (phage-encoded enzymes that break down bacterial peptidoglycan at the terminal stage of the phage reproduction cycle) have been used successfully to control antibiotic-resistant pathogenic bacteria in animal models. Their cell wall binding domains target the enzymes to their substrate, and their corresponding catalytic domains are able to cleave bonds in the peptidoglycan network. Recent research has not only revealed the surprising rich structural catalytic diversity of these murein hydrolases but has also yielded insights into their modular organization, their three-dimensional structures, and their mechanism of recognition of bacterial cell wall. These results allow endolysins to be considered as effective antimicrobials with potentially important applications in medicine and biotechnology.     

Biodistribution of filamentous phage peptide libraries in mice

In vivo phage display is a new approach to acquire peptide molecules that bind stably to a given target. Phage peptide display libraries have been selected in mice and humans and numerous vasculature-targeting peptides have been reported. However, in vivo phage display has not typically produced molecules that extravasate to target specific organ or tumor antigens. Phage selections in animals have been performed for very short times without optimization for biodistribution or clearance rates to a particular organ. It is hypothesized that peptides that home to a desired antigen/organ can be obtained from in vivo phage experiments by optimization of incubation times, phage extraction and propagation procedures. To accomplish this goal, one must first gain a better understanding of the in vivo biodistribution and rate of clearance of engineered phage peptide display libraries. While the fate of wild type phage in rodents has been reported, the in vivo biodistribution of the commonly used engineered fd-tet M13 phage peptide display libraries (such as in the fUSE5 vector system) have not been well established. Here we report the biodistribution and clearance properties of fd-tet fifteen amino acid random peptide display libraries in fUSE5 phage in three common mouse models employed for drug discovery - CF-1, nude, and SCID mice.     

Phage display as a powerful tool to engineer protease inhibitors

Since its introduction by Georges Smith some 25 years ago, phage display has proved to be a powerful molecular technique for selecting proteins with desired biological properties from huge libraries. Early on, various protease inhibitor scaffolds were displayed at the surface of filamentous phages to select new inhibitors with shifted specificities and enhanced affinities towards one or more target protease(s). The past two decades have seen a number of natural protease inhibitors subjected to phage display, mostly to shift and increase their inhibitory specificity, but also to explore the molecular mechanisms by which they interact with their cognate enzymes with low or very high selectivity. This review focuses on the major uses of phage display in the field of protein protease inhibitors. The exquisite molecular mechanisms by which natural protease inhibitors prevent unwanted or excessive proteolysis in cells and tissues are also examined along with some of the general principles underlying the way phage display is applied to these molecules.     

The interaction of phage and biofilms

Biofilms present complex assemblies of micro-organisms attached to surfaces. they are dynamic structures in which various metabolic activities and interactions between the component cells occur. When phage come in contact with biofilms, further interactions occur dependent on the susceptibility of the biofilm bacteria to phage and to the availability of receptor sites. If the phage also possess polysaccharide-degrading enzymes, or if considerable cell lysis is effected by the phage, the integrity of the biofilm may rapidly be destroyed. Alternatively, coexistence between phage and host bacteria within the biofilm may develop. Although phage have been proposed as a means of destroying or controlling biofilms, the technology for this has not yet been successfully developed.     

Phage display of functional, full-length human and viral membrane proteins

Phage display of protein and peptide libraries offers a powerful technology for the selection and isolation of ligands and receptors. To date, the technique has been considered limited to soluble, non-membrane proteins. We report two examples of phage display of full-length, folded and functional membrane proteins. Consistent display required the recently reported KO7(+) helper phage. The two proteins, full-length caveolin-1 and HIV gp41, display well on the surface of the phage, and maintain their binding activities as shown by in vitro assays.     

New perspective for phage display as an efficient and versatile technology of functional proteomics

Phage display with antibody libraries has been widely used with versatile applications. However, phage display with cDNA libraries is rare and inefficient. Because of uncontrollable reading frames and stop codons in cDNA repertoires, high percentage of phage clones identified from conventional cDNA libraries are non-open reading frames (non-ORFs) encoding unnatural short peptides with minimal implications in protein networks. Consequently, phage display has not been used as a technology of functional proteomics to elucidate protein–protein interactions like yeast two-hybrid system and mass spectrometry-based technologies. Several strategies, including C-terminal display and ORF cDNA libraries, have been explored to circumvent the technical problem. The accumulative endeavors eventually led to the efficient elucidation of a large number of tubby- and phosphatidylserine-binding proteins in recent studies by ORF phage display with minimal reading frame issue. ORF phage display inherits all the versatile applications of antibody phage display, but enables efficient identification of real endogenous proteins with efficiency, sensitivity, and accuracy comparable to other technologies of functional proteomics. Its ELISA-like procedure can be conveniently adapted by individual laboratories or fully automated for high-throughput screening. Thus, ORF phage display is an efficient, sensitive, versatile, and convenient technology of functional proteomics for elucidation of global and pathway-specific protein–protein interactions, disease mechanisms, or therapeutic targets.