噬菌体羧基端展示系统

噬菌体羧基端展示系统在一些方面是优于氨基端展示系统的,它可以用于构建和筛选cDNA噬菌体表面展示库,研究需要有自由羧基端时的蛋白质相互作用以及难以分泌的胞内蛋白的展示,特别是构建和筛选cDNA噬菌体表面展示库,将会成为该类展示系统的最重要的应用领域和进一步发展完善的动力。     

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.     

Peptide phage display in biotechnology and biomedicine

To date peptide phage display is one of the most common combinatorial methods used for identifying specific peptide ligands. Phage display peptide libraries containing billions different clones successfully used for selection of ligands with high affinity and selectivity toward wide range of targets including individual proteins, bacteria, viruses, spores, different kind of cancer cells and variety of nonorganic targets (metals, alloys, semiconductors, etc.). Success of using filamentous phage in phage display technologies relays on the robustness of phage particles and a possibility to genetically modify its DNA to construct new phage variants with novel properties. In this review we are discussing characteristics of the most known non-commercial peptide phage display libraries of different formats (landscape libraries in particular) and their successful applications in several fields of biotechnology and biomedicine: discovery of peptides with diagnostic values against different pathogens, discovery and using of peptides recognizing cancer cells, trends in using of phage display technologies in human interactome studies, application of phage display technologies in construction of novel nanomaterials.     

Selection of proteins and peptides from libraries displayed on filamentous bacteriophage

This article attempts to review recent developments in the rapidly developing field of phage display libraries. The current state of peptide, antibody, and cDNA libraries, as well as current and future applications of phage display libraries are discussed. The main focus of the article is on the methods for selecting binding ligands against targets in a variety of different formats. These include solid phase and in-solution selection methods, and the strategies used to select for higher affinity, and binding ligands ampure and cellular target proteins.     

Phage display in pharmaceutical biotechnology

Over the past year, methods for the construction of M13 phage-display libraries have been significantly improved and new display formats have been developed. Phage-displayed peptide libraries have been used to isolate specific ligands for numerous protein targets. New phage antibody libraries have further expanded the practical applications of the technology and phage cDNA libraries have proven useful in defining natural binding interactions. In addition, phage-display methods have been developed for the rapid determination of binding energetics at protein-protein interfaces.     

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.     

Phage display for engineering and analyzing protein interaction interfaces

Phage display is the longest-standing platform among molecular display technologies. Recent developments have extended its utility to proteins that were previously recalcitrant to phage display. The technique has played a dominant role in forming the field of synthetic binding protein engineering, where novel interfaces have been generated from libraries built using antibody fragment frameworks and also alternative scaffolds. Combinatorial methods have also been developed for the rapid analysis of binding energetics across protein interfaces. The ability to rapidly select and analyze binding interfaces, and compatibility with high-throughput methods under diverse conditions, makes it likely that the combination of phage display and synthetic combinatorial libraries will prove to be the method of choice for synthetic binding protein engineering for broad applications.     

Phage display of random peptide libraries: applications, limits, and potential

The identification of ligands from large biological libraries by phage display has now been used for almost 15 years. Most of the successful reports on high-affinity ligand identification originated from work with different antibody libraries. In contrast, the progress of applying phage display to random peptide libraries was relatively slow. However, in the last few years several improvements have led to an increasing number of published peptide ligands identified by phage display from such libraries and which exhibited good biological activity and high affinity. This review summarizes the current state and the technical progress of the application of random peptide libraries using filamentous phage for ligand identification.     

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.     

A Sortase A Programmable Phage Display Format for Improved Panning of Fab Antibody Libraries

Phage display of combinatorial antibody libraries is a versatile tool in the field of antibody engineering, with diverse applications including monoclonal antibody (mAb) discovery, affinity maturation, and humanization. To improve the selection efficiency of antibody libraries, we developed a new phagemid display system that addresses the complication of bald phage propagation. The phagemid facilitates the biotinylation of fragment of antigen binding (Fab) antibody fragments displayed on phage via Sortase A catalysis and the subsequent enrichment of Fab-displaying phage during selections. In multiple contexts, this selection approach improved the enrichment of target-reactive mAbs by depleting background phage. Panels of cancer cell line-reactive mAbs with high diversity and specificity were isolated from a naïve chimeric rabbit/human Fab library using this approach, highlighting its potential to accelerate antibody engineering efforts and to empower concerted antibody drug and target discovery.     

从噬菌体文库中筛选与表皮生长因子结合的多肽

与许多疾病相关的血管生成作用是由一些血管生成因子介导的 ,其中就包括表皮生长因子 .在肿瘤生长、关节炎等疾病中 ,表皮生长因子参与了其中的血管生成作用 ,拮抗表皮生长因子介导的血管生成就有可能对与其相关的疾病起到治疗作用 ,因此 ,表皮生长因子的拮抗剂可能具有重要的临床价值 .拮抗表皮生长因子的作用可以通过许多途径 ,其中之一就是找到能与表皮生长因子结合并能干预其与受体结合的分子 ,因而表皮生长因子可作为药物靶分子 .从噬菌体文库中筛选药物靶分子的拮抗剂和激动剂已被证明是一种有效的方法 .以表皮生长因子作为药物靶分子 ,从多肽噬菌体文库中筛选与表皮生长因子结合的噬菌体多肽 ,这些潜在的表皮生长因子拮抗剂先导分子经过优化可能具有重要的临床价值 .     

Principles and application of antibody libraries for infectious diseases

Antibodies have been used efficiently for the treatment and diagnosis of many diseases. Recombinant antibody technology allows the generation of fully human antibodies. Phage display is the gold standard for the production of human antibodies in vitro. To generate monoclonal antibodies by phage display, the generation of antibody libraries is crucial. Antibody libraries are classified according to the source where the antibody gene sequences were obtained. The most useful library for infectious diseases is the immunized library. Immunized libraries would allow better and selective enrichment of antibodies against disease antigens. The antibodies generated from these libraries can be translated for both diagnostic and therapeutic applications. This review focuses on the generation of immunized antibody libraries and the potential applications of the antibodies derived from these libraries.     

噬菌体展示技术及其在肿瘤研究中的应用

噬菌体表面展示技术是一项特异性多肽或蛋白的筛选技术,它将随机序列的多肽或蛋白片段与噬菌体衣壳蛋白融合表达而呈现于病毒表面,被展示的多肽能保持相对独立的空间结构,使其能够与配体作用而达到模仿性筛选特异性分子表位,从而提供了高通量高效率的筛选系统。近年来噬菌体展示技术已广泛应用于肿瘤抗原抗体库的建立、单克隆抗体制备、多肽筛选、疫苗研制、肿瘤相关抗原筛选和抗原表位研究、药物设计、癌症检测和诊断、基因治疗及细胞信号转导研究等。就近年来噬菌体展示技术在肿瘤相关研究中的运用作以综述。     

噬菌体表面呈现技术研究进展

噬菌体表面呈现技术是1985年建立的一种将外源基因表达呈现在噬菌体颗粒表面的方法,可用于建立随机多肽文库、抗体文库等。经特定配基的筛选,可获得与其特异结合的配体分子。通过改构,还可将cDNA产物表达于噬菌体颗粒的尾部构建cDNA文库。SIP技术通过将配体和配基分别与基因Ⅲ蛋白的C末端和N末端融合表达,基因Ⅲ的C-末端参与噬菌体颗粒的组装,配基与配体的结合能够重建基因Ⅲ蛋白的功能,才能形成有感染能力的噬菌体,这样就大大提高了筛选效率。     

Selection of internalizing ligand-display phage using rolling circle amplification for phage recovery

Selection of phage libraries against complex living targets such as whole cells or organs can yield valuable targeting ligands without prior knowledge of the targeted receptor. Our previous studies have shown that noninfective multivalent ligand display phagemids internalize into mammalian cells more efficiently than their monovalent counterparts suggesting that cell-based selection of internalizing ligands might be improved using multivalently displayed peptides, antibodies or cDNAs. However, alternative methods of phage recovery are needed to select phage from noninfective libraries. To this end, we reasoned that rolling circle amplification (RCA) of phage DNA could be used to recover noninfective phage. In feasibility studies, we obtained up to 1.5 million-fold enrichment of internalizing EGF-targeted phage using RCA. When RCA was applied to a large random peptide library, eight distinct human prostate carcinoma cell-internalizing peptides were isolated within three selection rounds. These data establish RCA as an alternative to infection for phage recovery that can be used to identify peptides from noninfective phage display libraries or infective libraries under conditions where there is the potential for loss of phage infectivity.     

Surface presentation of protein epitopes using bacteriophage expression systems.

Vast libraries of filamentous phage expression vectors that display foreign (poly)peptides on the virion surface can be screened by affinity-purifying those phage whose displayed foreign peptide binds to an antibody or another binding protein. Present libraries display only short random peptides, but work is presently underway to create libraries displaying antibodies with a great diversity of binding specificities.     

Efficient selection of DARPins with sub-nanomolar affinities using SRP phage display

There is an ever-increasing demand to select specific, high-affinity binding molecules against targets of biomedical interest. The success of such selections depends strongly on the design and functional diversity of the library of binding molecules employed, and on the performance of the selection strategy. We recently developed SRP phage display that employs the cotranslational signal recognition particle (SRP) pathway for the translocation of proteins to the periplasm. This system allows efficient filamentous phage display of highly stable and fast-folding proteins, such as designed ankyrin repeat proteins (DARPins) that are virtually refractory to conventional phage display employing the post-translational Sec pathway. DARPins comprise a novel class of binding molecules suitable to complement or even replace antibodies in many biotechnological or biomedical applications. So far, all DARPins have been selected by ribosome display. Here, we harnessed SRP phage display to generate a phage DARPin library containing more than 10¹⁰ individual members. We were able to select well behaved and highly specific DARPins against a broad range of target proteins having affinities as low as 100 pM directly from this library, without affinity maturation. We describe efficient selection on the Fc domain of human IgG, TNFα, ErbB1 (EGFR), ErbB2 (HER2) and ErbB4 (HER4) as examples. Thus, SRP phage display makes filamentous phage display accessible for DARPins, allowing, for example, selection under harsh conditions or on whole cells. We envision that the use of SRP phage display will be beneficial for other libraries of stable and fast-folding proteins.     

Selection of novel ligands from phage display libraries: an alternative approach to drug and vaccine discovery?

Phage display involves the production and screening of large numbers of random peptide sequences of a specific length expressed on the surface of phage particles. This approach provides a powerful tool to probe the molecular basis of many biological processes, including host-parasite interactions. Phage display libraries have been used to study the binding specificity of numerous peptides and protein domains. Practical applications include the identification of peptide sequences that bind with high affinity to antibodies, enzymes or receptors, and that may serve as diagnostics and vaccine or drug candidates. Here, David Jefferies outlines the concept of phage display and summarizes recent developments in the field, with emphasis on those that may be of interest to parasitologists.     

Signal sequences directing cotranslational translocation expand the range of proteins amenable to phage display

Even proteins that fold well in bacteria are frequently displayed poorly on filamentous phages. Low protein presentation on phage might be caused by premature cytoplasmic folding, leading to inefficient translocation into the periplasm. As translocation is an intermediate step in phage assembly, we tested the display levels of a range of proteins using different translocation pathways by employing different signal sequences. Directing proteins to the cotranslational signal recognition particle (SRP) translocation pathway resulted in much higher display levels than directing them to the conventional post-translational Sec translocation pathway. For example, the display levels of designed ankyrin-repeat proteins (DARPins) were improved up to 700-fold by simply exchanging Sec- for SRP-dependent signal sequences. In model experiments this exchange of signal sequences improved phage display from tenfold enrichment to >1,000-fold enrichment per phage display selection round. We named this method 'SRP phage display' and envision broad applicability, especially when displaying cDNA libraries or very stable and fast-folding proteins from libraries of alternative scaffolds.     

Staphylococcal surface display in combinatorial protein engineering and epitope mapping of antibodies

The field of combinatorial protein engineering for generation of new affinity proteins started in the mid 80s by the development of phage display. Although phage display is a prime example of a simple yet highly efficient method, manifested by still being the standard technique 25 years later, new alternative technologies are available today. One of the more successful new display technologies is cell display. Here we review the field of cell display for directed evolution purposes, with focus on a recently developed method employing Gram-positive staphylococci as display host. Patents on the most commonly used cell display systems and on different modifications as well as specific applications of these systems are also included. General strategies for selection of new affinity proteins from cell-displayed libraries are discussed, with detailed examples mainly from studies on the staphylococcal display system. In addition, strategies for characterization of recombinant proteins on the staphylococcal cell surface, with an emphasis on an approach for epitope mapping of antibodies, are included.