核糖体展示技术的研究与应用现状

核糖体展示技术是20世纪90年代建立并发展起来的一种完全在体外进行的分子筛选与进化技术,避免了体内展示技术的缺陷,不受细胞转染与基因表达等因素影响,已经成功用于筛选与靶分子特异结合的高亲和力多肽、抗体和酶等.本文主要概述了核糖体展示技术的基本原理、具体步骤、技术改进及应用现状.     

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.     

体外展示技术及其在抗体工程中的应用

体外展示技术包括核糖体展示技术、mRNA展示技术、DNA展示技术,是在无细胞蛋白质表达体系内将基因型和表型通过一定的方法连接在一起,体外高通量的筛选多肽和蛋白质的技术。抗体的产生是一个不断选择的过程,利用体外展示技术在体外选择针对某一抗原的抗体分子,并结合基因工程技术对抗体进行改造,以产生高亲和力、高特异性的抗体。体外展示技术的研究和应用已越来越广泛,有望成为下一代的抗体制备技术。     

核糖体展示技术

组合化学在分子生物学中的应用,大大提高了所构建分子文库的容量,而高通量筛选技术对于大容量文库的筛选是至关重要的。核糖体展示技术克服了传统筛选技术库容量小和筛选效率低等缺陷。该技术完全在体外进行,其文库容量不受细胞转染效率的影响,库容量和筛选效率得到很大提高,可与其他技术相组合,在体外分子高效表达和定向进化方面具有广泛的应用前景。该文介绍核糖体展示技术的基本原理、技术特点以及最新研究进展。     

利用核糖体展示技术筛选功能性蛋白质方法的建立

核糖体展示(ribosomedisplay)是一种体外筛选功能性蛋白质的有力的工具.利用体外转录和翻译偶联系统可以方便而快捷地完成核糖体展示.筛选系统利用一对能够紧密结合的蛋白质:人锚蛋白(ankyrin)和红血球膜带3蛋白细胞质区域(cytoplasmicdomainoferythrocytemembraneproteinBand3,Cdb3)作为模式分子,希望利用cdb3蛋白通过核糖体展示亲和选择得到锚蛋白基因.用于核糖体展示的人锚蛋白基因结构由组装PCR构建,通过PCR技术引入核糖体展示所需的结构元件.在亲和筛选步骤后,只能利用红血球膜带3蛋白筛选得到锚蛋白基因,而不能利用对照牛血清白蛋白(bovineserumalbumin,BSA)筛选得到,从而说明建立的核糖体展示技术能够正常发挥作用.     

蛋白质体外表达与进化技术

蛋白质体外表达与进化技术包括核糖体展示技术和mRNA展示技术。与蛋白质体内表达系统相比,体外表达技术可产生较大容量的蛋白质文库（约10^12～10^13左右）,同时在回收编码蛋白质的信息时对文库进行了进化,增加了蛋白质文库的多样性,促进了抗体或配体类蛋白质的亲和成熟能力。该文介绍了蛋白质体外表达技术在新蛋白质（如抗体或配体等）表达筛选中的应用。     

DNA重排及体外分子进化

ＤＮＡ重排是目前为止最简便、最有效的体外定向进化技术,可以对单一基因、质粒、代谢途径、部分甚至整个基因组进行改造。本综述了ＤＮＡ重排的基本原理、特点、与其它体外进化技术的不同,着重介绍了其在体外分子进化上的广泛应用,并对应用前景进行了展望。     

酶分子体外定向进化的研究方法*

酶分子体外定向进化不仅可大幅度提高酶分子的进化效率,短期内在实验室完成自然状态下需要千百万年的进化过程,还可使酶分子按照人们期望的特定目标进化,因此对酶工程今后的发展非常重要。本对酶分子体外定向进化的研究方法进行了归纳总结。     

体外分子展示技术

作为一项新的基因技术,体外分子展示技术的用途十分广泛.该文对各种体外分子展示技术的基本原理及相关应用进行综述,并展望其应用前景.     

分子酶工程学研究进展

酶工程的研究已经发展到分子水平,通过基因操作,已实现了许多酶的克隆和表达。定点突变成为研究酶结构与功能的常规手段,并被广泛用于改善酶的性能。体外分子进化方法则大幅提高了酶分子的进化效率,并有可能发展新功能酶。融合蛋白技术的发展使构建新型多功能融合酶成为可能。这里对分子酶工程学的研究与发展情况进行了综述。      

利用核糖体展示技术筛选口蹄疫病毒 单链抗体基因

目的:利用核糖体展示技术筛选口蹄疫病毒特异性单链抗体基因。方法:在已构建好的核糖体展示文库的基础上,利用核糖体展示技术,经过5轮的体外转录、体外转译、亲和筛选和RT-PCR,将得到的序列进行测序分析。结果:筛选到FMDV scFv基因,且基因得到富集。结论:实验运用核糖体展示技术,以FMDV抗原和纯化的146S病毒粒子为靶标筛选到了FMDV scFv基因,将为scFv用于FMD的基础研究、免疫学研究以及为预防、治疗和诊断提供帮助,也为研制FMD的快速诊断技术奠定先前基础。     

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.     

Selection of bisphenol A – single-chain antibodies from a non-immunized mouse library by ribosome display

Developing reagents with high affinity and specificity are critical to detect the environmental hormones or toxicants. Ribosome display technology has been widely used in functional protein or peptide screening and in directed evolution of protein molecules in vitro. In this study, single-chain variable fragments (scFvs) against bisphenol A (BPA) were selected from a library constructed from splenocytes of non-immunized mice. After five rounds of selection, the selected scFvs bound to BPA with high affinity. Indirect competitive enzyme-linked immunosorbent assay (ELISA) was introduced to screen the antibody affinity and specificity to BPA. The equilibrium dissociation constants (KD_S) of one clone was 1.76 μM as determined by surface plasmon resonance (SPR). This study indicated that ribosome display can isolate binders to small molecules from a non-immunized naive library without any in vivo steps and can generate recombinant antibodies efficiently and rapidly. In addition, this study provides a methodological framework for detection of small molecules using recombinant antibodies.