mRNA展示技术

mRNA展示技术是一种新兴的体外筛选多肽和蛋白质的有力工具.在筛选过程中,mRNA与其编码的多肽或蛋白质共价结合,形成mRNA-蛋白质融合体,能在大容量的多肽文库(1013～1015)中筛选具有特定生物学功能的多肽和蛋白质.目前,mRNA展示技术主要应用于各种靶分子的多肽和蛋白质适体的发现以及蛋白质相互作用机制的阐明和分析.由于其自身的巨大发展潜力,mRNA展示技术具有更为广阔的应用前景.     

文库筛选与分子进化的核糖体展示新方法

利用适当的文库筛选技术快速、简便地从DNA文库、随机肽库、抗体库或其它蛋白文库中筛选生物活性物质是目前分子生物学研究的一个热点.核糖体展示是一种完全离体进行的功能蛋白筛选和进化鉴定的新技术,避免了传统的活体筛选技术的缺陷,使得文库容量增大、分子多样性加强.本文系统地评述了核糖体展示技术在制备ScFv单链抗体方面的应用,包括ScFv单链抗体模板的构建、体外转录与体外翻译、亲和筛选及筛选效率的测定以及分子多样性和体外进化研究,讨论了核糖体展示技术目前的发展动态、存在问题及发展趋势.     

Selection of proteins with desired properties from natural proteome libraries using mRNA display

mRNA display is a powerful yet challenging in vitro selection technique that can be used to identify proteins with desired properties from both natural proteome and combinatorial polypeptide libraries. The physical conjugation between a protein and its own RNA presents unique challenges in manipulating the displayed proteins at a low nanomolar scale in an RNase-free environment. The following protocol outlines the generation of cDNA libraries derived from natural organisms as well as the steps required for generation of mRNA-protein fusion molecules, in vitro functional selection and regeneration of the selected cDNA library. The selection procedures for the identification of protease substrates and Ca(2+)-dependent calmodulin-binding proteins from natural cDNA libraries are presented as examples. The method can be generally applied to the identification of protein sequences with desired properties from various natural proteome libraries. One round of mRNA display-based selection can be accomplished in ~7 d.     

Photocleavable linkage between genotype and phenotype for rapid and efficient recovery of nucleic acids encoding affinity-selected proteins

In vitro display technologies, such as mRNA display and DNA display are powerful tools to screen peptides and proteins with desired functions from combinatorial libraries in the fields of directed protein evolution and proteomics. When screening combinatorial libraries of polypeptides (phenotype), each of which is displayed on its gene (genotype), the problem remains, how best to recover the genotype moiety whose phenotype moiety has bound to the desired target. Here, we describe the use of a photocleavable 2-nitrobenzyl linker between genotype (DNA or mRNA) and phenotype (protein) in our DNA and mRNA display systems. This technique allows rapid and efficient recovery of selected nucleic acids by simple UV irradiation at 4 degrees C for 15 min. Further, we confirmed that the photocleavable DNA display and mRNA display systems are useful for in vitro selection of epitope peptides, recombinant antibodies, and drug-receptor interactions. Thus, these improved methods should be useful in therapeutics and diagnostics, e.g., for screening high-affinity binders, such as enzyme inhibitors and recombinant antibodies from random peptide and antibody libraries, as well as for screening drug-protein interactions from cDNA libraries.     

Advantages of mRNA display selections over other selection techniques for investigation of protein–protein interactions

mRNA display is a genotype–phenotype conjugation method that allows for amplification-based, iterative rounds of in vitro selection to be applied to peptides and proteins. mRNA display can be used to display both long natural protein and short synthetic peptide libraries with unusually high diversities for the investigation of protein–protein interactions. Here, we summarize the advantages of mRNA display by comparing it with other widely used peptide or protein-selection techniques, and discuss various applications of this technique in studying protein–protein interactions.     

Advantages of mRNA display selections over other selection techniques for investigation of protein-protein interactions

mRNA display is a genotype-phenotype conjugation method that allows for amplification-based, iterative rounds of in vitro selection to be applied to peptides and proteins. mRNA display can be used to display both long natural protein and short synthetic peptide libraries with unusually high diversities for the investigation of protein-protein interactions. Here, we summarize the advantages of mRNA display by comparing it with other widely used peptide or protein-selection techniques, and discuss various applications of this technique in studying protein-protein interactions.     

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.     

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。     

Ribosome display: cell-free protein display technology.

Ribosome display is a cell-free system for the in vitro selection of proteins and peptides from large libraries. It uses the principle of coupling individual nascent proteins (phenotypes) to their corresponding mRNA (genotypes), through the formation of stable protein-ribosome-mRNA (PRM) complexes. This permits the simultaneous isolation of a functional nascent protein, through affinity for a ligand, together with the encoding mRNA, which is then converted and amplified as DNA for further manipulation, including repeated cycles or protein expression. Ribosome display has a number of advantages over cell-based systems such as phage display; in particular, it can display very large libraries without the restriction of bacterial transformation. It is also suitable for generating toxic, proteolytically sensitive and unstable proteins, and allows the incorporation of modified amino acids at defined positions. In combination with polymerase chain reaction (PCR)-based methods, mutations can be introduced efficiently into the selected DNA pool in subsequent cycles, leading to continuous DNA diversification and protein selection (in vitro protein evolution). Both prokaryotic and eukaryotic ribosome display systems have been developed and each has its own distinctive features. In this paper, ribosome display systems and their application in selection and evolution of proteins are reviewed.     

Ribosome display: selecting and evolving proteins in vitro that specifically bind to a target

Ribosome display is an in vitro selection and evolution technology for proteins and peptides from large libraries. As it is performed entirely in vitro, there are two main advantages over other selection technologies. First, the diversity of the library is not limited by the transformation efficiency of bacterial cells, but only by the number of ribosomes and different mRNA molecules present in the test tube. Second, random mutations can be introduced easily after each selection round, as no library must be transformed after any diversification step. This allows facile directed evolution of binding proteins over several generations. A prerequisite for the selection of proteins from libraries is the coupling of genotype (RNA, DNA) and phenotype (protein). In ribosome display, this link is accomplished during in vitro translation by stabilizing the complex consisting of the ribosome, the mRNA and the nascent, correctly folded polypeptide. The DNA library coding for a particular library of binding proteins is genetically fused to a spacer sequence lacking a stop codon. This spacer sequence, when translated, is still attached to the peptidyl tRNA and occupies the ribosomal tunnel, and thus allows the protein of interest to protrude out of the ribosome and fold. The ribosomal complexes are allowed to bind to surface-immobilized target. Whereas non-bound complexes are washed away, mRNA of the complexes displaying a binding polypeptide can be recovered, and thus, the genetic information of the binding polypeptides is available for analysis. Here we describe a step-by-step procedure to perform ribosome display selection using an Escherichia coli S30 extract for in vitro translation, based on the work originally described and further refined in our laboratory. A protocol that makes use of eukaryotic in vitro translation systems for ribosome display is also included in this issue.     

分子文库展示技术

分子文库展示技术是一系列广泛应用于多肽、蛋白质及药物筛选和研究蛋白质间相互作用的有效的生物学技术。它将组合成的具有一定长度的随机序列寡核苷酸片段(或cDNA)克隆到特定表达载体中,使其表达产物(多肽片段或蛋白质结构域)以融合蛋白的形式展示在活的噬菌体或细胞表面。根据其蛋白质表达是否依赖于宿主表达系统,分为体内表达展示系统和无细胞展示系统(体外表达展示系统)。就其展示的部位不同又可分为噬菌体展示技术、细胞表面展示技术、核糖体展示技术、mRNA展示技术等。现对各种展示技术的基本原理及相关应用做简要综述。     

Comparison of mRNA-display-based selections using synthetic peptide and natural protein libraries

mRNA display is a genotype-phenotype conjugation method that allows the amplification-based, iterative rounds of in vitro selection to be applied to peptides and proteins. Compared to prior protein selection techniques, mRNA display can be used to select functional sequences from both long natural protein and short combinatorial peptide libraries with much higher complexities. To investigate the basic features and problems of using mRNA display in studying conditional protein-protein interactions, we compared the target-binding selections against calmodulin (CaM) using both a natural protein library and a combinatorial peptide library. The selections were efficient in both cases and required only two rounds to isolate numerous Ca2+/CaM-binding natural proteins and synthetic peptides with a wide range of affinities. Many known and novel CaM-binding proteins were identified from the natural human protein library. More than 2000 CaM-binding peptides were selected from the combinatorial peptide library. Unlike sequences from prior CaM-binding selections that correlated poorly with naturally occurring proteins, synthetic peptides homologous to the Ca2+/CaM-binding motifs in natural proteins were isolated. Interestingly, a large number of synthetic peptides that lack the conventional CaM-binding secondary structures bound to CaM tightly and specifically, suggesting the presence of other interaction modes between CaM and its downstream binding targets. Our results indicate that mRNA display is an ideal approach to the identification of Ca2+-dependent protein-protein interactions, which are important in the regulation of numerous signaling pathways.     

In vitro display technologies: novel developments and applications

In vitro display techniques are powerful tools to select polypeptide binders against various target molecules. Novel applications include maturation of protein affinity and stability, selection for enzymatic activity, and the display of cDNA and random polypeptide libraries. Taken together, these display techniques have great potential for biotechnological, medical and proteomic applications.     

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.     

In vitro selection and characterization of Bcl-X(L)-binding proteins from a mix of tissue-specific mRNA display libraries

The covalent coupling of an mRNA to the protein that it encodes (mRNA display) provides a powerful tool for analysis of protein function in the post-genomic era. This coupling allows the selective enrichment of individual members from libraries of displayed proteins and the subsequent regeneration of an enriched library using the RNA moiety. Tissue-specific libraries from poly(A)(+) mRNA were prepared by priming first and second strand cDNA synthesis with oligonucleotides containing nine random 3' nucleotides, the fixed regions of which encoded the requisite sequences for formation of mRNA display constructs and a library-specific sequence tag. Starting with a pool of uniquely tagged libraries from different tissues, an iterative selection was performed for binding partners of the anti-apoptotic protein Bcl-X(L). After four rounds of selection, the pool was deconvoluted by polymerase chain reaction amplification with library-specific primers. Subsequent clonal sequence analysis revealed the selection of three members of the Bcl-2 family known to bind to Bcl-X(L). In addition, several proteins not previously demonstrated to interact with Bcl-X(L) were identified. The relative binding affinities of individual selected peptides were determined, as was their susceptibility to competition with a BH3 domain peptide. Based on these data, a putative BH3 domain was identified in most peptides.     

运用 mRNA 体外展示技术筛选胸苷酸合成酶 RNA 亲和肽

以体外选择方法筛选不同功能的核酸、肽和蛋白质是近年的研究热点, mRNA 体外展示是一种新兴的高效多肽选择技术,其基本原理是通过含嘌呤霉素寡核苷酸的 Linker 使 mRNA 与它编码的肽或蛋白质共价结合,形成 mRNA- 蛋白质融合体,这一方法已用于多种功能肽的鉴定 . 以 mRNA 体外展示技术进行了由大容量多肽库中 (>1013) 筛选胸苷酸合成酶 (thymidylate synthase , TS) RNA 亲和肽的研究,通过精密的实验设计,建立了一套完整有效的筛选方法,并对实验条件进行了优化 . 已进行了 8 轮筛选,结果表明,以 mRNA 体外展示技术获得的多肽分子,可以与 TS mRNA 亲和 . 将测序结果与初始肽库进行比较,发现亲和肽中碱性氨基酸及芳香族氨基酸含量明显增加,说明其在与 RNA 结合中具有重要作用 . mRNA 展示技术作为一种大容量文库的体外筛选方法,将广泛应用于与固定化靶物质具高度亲和性及特异性的多肽和蛋白质的筛选 .     

Ribosome display selection of a metal-binding motif from an artificial peptide library

A new ribosome display system was applied for the in vitro selection of a metal-binding motif from an artificial peptide library. The display system consisted of an mRNA-associating protein, a ribosome, and mRNA. The protein part of this display system was designed to provide a random peptide library and to stabilize the ribosome display. The random peptide library was newly designed to isolate stable metal-binding motifs. We employed the system for in vitro selection and found several new proteins and peptides that bind Co(II)-immobilized resin and Co(II)-complex, respectively. This newly developed system can be conveniently applied to the in vitro selection of peptide aptamers.