Construction of high-complexity combinatorial phage display peptide libraries

Random peptide libraries displayed on the surface of filamentous bacteriophage are widely used as tools for the discovery of ligands for biologically relevant macromolecules, including antibodies, enzymes, and cell surface receptors. Phage display results in linkage of an affinity-selectable function (the displayed peptide) to the DNA encoding that function, allowing selection of individual binding clones by iterative cycles of in vitro panning and in vivo amplification. Critical to the success of a panning experiment is the complexity of the library: the greater the diversity of clones within the library, the more likely the library contains sequences that will bind a given target with useful affinity. A method for construction of high-complexity (> or = 10(9) independent clones) random peptide libraries is presented. The key steps are highly efficient binary ligation under conditions where the vector is relatively dilute, with only a modest molar excess of insert, followed by efficient electrotransformation into Escherichia coli. Library design strategies and a protocol for rapid sequence characterization are also presented.     

Low free energy cost of very long loop insertions in proteins

Long insertions into a loop of a folded host protein are expected to have destabilizing effects because of the entropic cost associated with loop closure unless the inserted sequence adopts a folded structure with amino- and carboxy-termini in close proximity. A loop entropy reduction screen based on this concept was used in an attempt to retrieve folded sequences from random sequence libraries. A library of long random sequences was inserted into a loop of the SH2 domain, displayed on the surface of M13 phage, and the inserted sequences that did not disrupt SH2 function were retrieved by panning using beads coated with a phosphotyrosine containing SH2 peptide ligand. Two sequences of a library of 2 x 10(8) sequences were isolated after multiple rounds of panning, and were found to have recovery levels similar to the wild-type SH2 domain and to be relatively intolerant to further mutation in PCR mutagenesis experiments. Surprisingly, although these inserted sequences exhibited little nonrandom structure, they do not significantly destabilize the host SH2 domain. Additional insertion variants recovered at lower levels in the panning experiments were also found to have a minimal effect on the stability and peptide-binding function of the SH2 domain. The additional level of selection present in the panning experiments is likely to involve in vivo folding and assembly, as there was a rough correlation between recovery levels in the phage-panning experiments and protein solubility. The finding that loop insertions of 60-80 amino acids have minimal effects on SH2 domain stability suggests that the free energy cost of inserting long loops may be considerably less than polymer theory estimates based on the entropic cost of loop closure, and, hence, that loop insertion may have provided an evolutionary route to multidomain protein structures.     

Selection of a CXCR4 antagonist from a human heavy chain CDR3-derived phage library

Phage display technology is a powerful selection approach to identify strong and specific binders to a large variety of targets. In this study, we compared the efficacy of a phage library displaying human heavy chain complementarity determining region 3 (HCDR3) repertoires with a set of conventional random peptide libraries for the identification of CXCR4 antagonists using a peptide corresponding to the second extracellular loop of the receptor CXCR4 as target. A total of 11 selection campaigns on this target did not result in any specific ligand from the random peptide libraries. In contrast, a single selection campaign with an HCDR3 library derived from the IgM repertoire of a nonimmunized donor resulted in nine specific peptides with lengths ranging from 10 to 19 residues. Four of these HCDR3 sequences interacted with native receptor and the most frequently isolated peptide displayed an affinity of 5.6 μm and acted as a CXCR4 antagonist (IC(50) = 23 μm). To comprehend the basis of the highly efficient HCDR3 library selection, its biochemical properties were investigated. The HCDR3 length varied from 3 to 21 residues and displayed a biased amino acid content with a predominant proportion of Tyr, Gly, Ser and Asp. Repetitive and conserved motifs were observed in the majority of the HCDR3 sequences. The strength and efficacy of the HCDR3 libraries reside in the combination of multiple size peptides and a naturally biased sequence variation. Therefore, HCDR3 libraries represent a powerful and versatile alternative to fully randomized peptide libraries, in particular for difficult targets.     

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.     

High-throughput Pyrosequencing of a phage display library for the identification of enriched target-specific peptides

Gene therapy clinical trials have highlighted the importance of specific cellular/tissue targeting of gene delivery vectors. Phage display libraries are powerful tools for the selection of novel peptide ligands as targeting moieties because of their high-throughput screening potential. However, a severe rate-limiting step in this procedure in terms of time, numbers, and cost is the sequence identification of selected phages. Here we describe the application of Pyrosequencing technology for sequencing phage isolates after panning a random 7-mer peptide expressing phage library against the A549 bronchial epithelial cell line to search for enrichment of possible targeting peptides. Pyrosequencing allows sequencing of 96 phages at one time in approximately 45 min at only a sixth of the cost of conventional sequencing methods. Using this technology, we have identified four sequences of interest. A phage binding assay revealed that three of the four sequences show a significant increase in binding abilities and specificity for A549 cells when compared to an unrelated cell line.     

Complementarity-determining region 1 sequence requirements drive limited V alpha usage in response to influenza hemagglutinin 307-319 peptide

We have developed a T cell activation-based system that allows for the selection of TCRs with defined peptide/MHC specificities from libraries in which complementarity-determining region (CDR) sequences have been randomized by in vitro mutagenesis. Using this system, we have explored the sequence requirements for CDR1 and CDR2 of the TCR alpha-chain in a human T cell response characterized by restricted Valpha and Vbeta usage. Libraries of T cells expressing receptors built on the framework of a TCR specific for the influenza virus peptide hemagglutinin 307-319 presented by HLA-DR4, but with random sequences inserted at CDR1alpha or CDR2alpha, were selected for response to the same peptide/MHC ligand. A wide variety of CDR2alpha sequences were found to be permissive for recognition. Indeed, >25% of T cell clones chosen at random displayed a significant response. In contrast, a similar challenge of a randomized CDR1alpha library yielded only the parental sequence, and then only after multiple rounds of selection. T cell clones cross-reactive on closely related HLA alleles (subtypes of DR4) could be isolated from randomized libraries, but not clones restricted by more distantly related alleles such as HLA-DR1. These results indicate that, in the context of this T cell response, the structural requirements for recognition at CDR1alpha are significantly more restricted than at CDR2alpha. This system for mutation and selection of TCRs in vitro may be of use in engineering T cells with defined specificities for therapeutic applications.     

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.     

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.     

Mimotopes and proteome analyses using human genomic and cDNA epitope phage display

In the post-genomic era, validation of candidate gene targets frequently requires proteinbased strategies. Phage display is a powerful tool to define protein-protein interactions by generating peptide binders against target antigens. Epitope phage display libraries have the potential to enrich coding exon sequences from human genomic loci. We evaluated genomic and cDNA phage display strategies to identify genes in the 5q31 Interleukin gene cluster and to enrich cell surface receptor tyrosine kinase genes from a breast cancer cDNA library. A genomic display library containing 2 x 106 clones with exon-sized inserts was selected with antibodies specific for human Interleukin-4 (IL-4) and Interleukin-13. The library was enriched significantly after two selection rounds and DNA sequencing revealed unique clones. One clone matched a cognate IL-4 epitope; however, the majority of clone insert sequences corresponded to E. coli genomic DNA. These bacterial sequences act as 'mimotopes' (mimetic sequences of the true epitope), correspond to open reading frames, generate displayed peptides, and compete for binding during phage selection. The specificity of these mimotopes for IL-4 was confirmed by competition ELISA. Other E. coli mimotopes were generated using additional antibodies. Mimotopes for a receptor tyrosine kinase gene were also selected using a breast cancer SKBR-3 cDNA phage display library, screened against an anti-erbB2 monoclonal antibody. Identification of mimotopes in genomic and cDNA phage libraries is essential for phage display-based protein validation assays and two-hybrid phage approaches that examine protein-protein interactions. The predominance of E. coli mimotopes suggests that the E. coli genome may be useful to generate peptide diversity biased towards protein coding sequences.ABBREVIATIONS USED: IL, interleukin; ELISA, enzyme linked immunoabsorbant assay; PBS, phospho-buffered saline; cfu, colony forming units.     

A method for generation of arbitrary peptide libraries using genomic DNA

Random peptide libraries can be constructed either by in vitro synthesis of random peptides, or through translation of DNA sequences from synthetic random oligonucleotides. Here we describe an alternative way of making arbitrary peptide libraries with high diversity that can be used in screening as random peptide libraries. Genomic DNA digested with a frequent-cutting restriction enzyme recognizing four nucleotides will theoretically consist of small DNA pieces with average length of 256 nucleotides, and on average around 10⁷ fragments can be generated from a genome of 3 × 10⁹ bases. A peptide library translated from these fragments will have sufficient diversity for some protein interaction screening experiments. Moreover, the same genome digested with a different four-cutter enzyme or ligated into different reading frames will result in different nonoverlapping libraries. A series of such libraries could be generated with genomic DNAs from different species. In this study, human genomic DNA was digested with four-cutter restriction enzymes DpnII and Tsp509I, respectively, and cloned into yeast expression vector pGADT7 to generate arbitrary peptide libraries. These libraries were used in yeast two-hybrid assays to screen for binding motifs of the PDZ domain containing protein synectin. Our results showed that in addition to various native carboxy-terminal tails, synectin could also bind to many artificial ones, some of which contained a consensus sequence—(S/T)XC-COOH.     

In vitro selection of scFv and its production: an application of mRNA display and wheat embryo cell-free and <Emphasis Type="Italic">E. coli</Emphasis> cell production system

Synthetic DNA libraries encoding human antibody V_L and V_H fragments were designed, constructed, and enriched using mRNA display. The enriched libraries were then combined to construct a scFv library for mRNA display. Sequencing revealed that 46% of the library coded for full-length scFvs. Considering the number of molecules used in mRNA display, the size of the library displayed was calculated to be >10¹⁰. To verify this, we tried to isolate a scFv against human RANK. A scFv was successfully isolated in the sixth round of panning and was synthesized in wheat embryo cell-free (WE) and Escherichia coli cell systems. In the WE system, even though the production level was high, the product was almost soluble. However, in the E. coli system, it was over-produced as inclusion bodies. The inclusion bodies were successfully refolded and showed approximately the same binding affinity as the WE product. These results demonstrate that using mRNA display with synthetic libraries and WE and E. coli cell production systems, a system for in vitro selection and small- to large-scale production of scFvs has been established.     

利用大肠杆菌鞭毛展示的随机肽库筛选TNF—α拮抗须

TNF－α是一种在机体抗感染,抗肿瘤过程中发挥重要作用的细胞因子,其对机体具有保护和损伤两方面的作用,为了探讨新的抑制TNF－α所致炎症损伤等反应的手段,构建了细菌鞭毛递呈的随机肽库,利用构建得到的肽库,进行TNF－α特异性结合肽的筛选工作。经过5轮筛选及DNA测序,共得到6条小肽编码序列。其中2条序列中含有－V－－N－WG的相同序列框架。进行6条序列与TNF－α结合力的确证后,选择了其中的4条肽序列进行人工化学合成,纯化及鉴定。利用L929细胞及MTT法对4条小肽进行活性测定,检测其对TNF－α的抑制活性。结果表明,在TNF－α对L929细胞毒性为30％左右,含同源序列框架的2条肽可抑制90％左右的TNF－α活性。     

Affinity chromatographic screening of soluble combinatorial peptide libraries.

Affinity chromatography using immobilized S-protein was used for the screening of affinity peptide ligands from two soluble peptide libraries. Peptide library I consisted of octamers with glycine (G) at both termini of each peptide, i.e. GXXXXXXG. The six center positions were constructed using random sequences of six L-amino acids (Y, N, F, E, V, and L). Peptide library II also consisted of octamers but with glycine and valine (V) at both termini of each peptide (GVZZZZVG). The four variable center positions of peptide library II were random sequences of 18 L-amino acids. Peptides that were retained specifically on the immobilized S-protein column were eluted by 2% acetic acid. The peptides in the acid eluate were further separated using reversed-phase HPLC. Each separated peptide fraction was collected and the peptide sequences deconvoluted by mass spectrometry (MS/MS). The screenings of peptide libraries I and II resulted in 12 and 7 affinity peptides, respectively. Eight out of the twelve peptides from peptide library I contained the clear consensus sequence NFEV. Peptide library II resulted in affinity peptides with the sequences GVNFEVVG, GVNFTVVG and GVFFEL(I)VG. The advantages and limitations of affinity chromatography in peptide library screening are discussed.     

Constructing high complexity synthetic libraries of long ORFs using in vitro selection

We present a method that can significantly increase the complexity of protein libraries used for in vitro or in vivo protein selection experiments. Protein libraries are often encoded by chemically synthesized DNA, in which part of the open reading frame is randomized. There are, however, major obstacles associated with the chemical synthesis of long open reading frames, especially those containing random segments. Insertions and deletions that occur during chemical synthesis cause frameshifts, and stop codons in the random region will cause premature termination. These problems can together greatly reduce the number of full-length synthetic genes in the library. We describe a strategy in which smaller segments of the synthetic open reading frame are selected in vitro using mRNA display for the absence of frameshifts and stop codons. These smaller segments are then ligated together to form combinatorial libraries of long uninterrupted open reading frames. This process can increase the number of full-length open reading frames in libraries by up to two orders of magnitude, resulting in protein libraries with complexities of greater than 10(13). We have used this methodology to generate three types of displayed protein library: a completely random sequence library, a library of concatemerized oligopeptide cassettes with a propensity for forming amphipathic alpha-helical or beta-strand structures, and a library based on one of the most common enzymatic scaffolds, the alpha/beta (TIM) barrel.     

Simplified methods for construction, assessment and rapid screening of peptide libraries in bacteriophage.

An efficient strategy has been devised for the construction of diverse peptide libraries in bacteriophage vectors. This strategy was used to generate a library of 4 x 10(8) random decapeptide inserts in the pIII protein of bacteriophage fd. A novel method for evaluating the genetic diversity of bacteriophage libraries based on colony hybridization with partially degenerate oligonucleotides has been developed. The decapeptide library was affinity-selected with a previously characterized monoclonal antibody specific for the V3 loop of the gp120 protein of HIV-1. Immunological screening, an efficient technique for the rapid identification of putative binding bacteriophage, is described. Hexapeptide sequences similar to those obtained from affinity selection of a hexapeptide bacteriophage library were obtained from the decapeptide library in all five frames. Immunological screening of 20,000 clones from the two libraries after two rounds of affinity selection rapidly identified antibody-binding sequences; 93% and 86% of the sequences obtained from the hexapeptide and decapeptide libraries, respectively, had IC50 values < or = 10 mM as free peptides.     

A computer program for the estimation of protein and nucleic acid sequence diversity in random point mutagenesis libraries

A computer program for the generation and analysis of in silico random point mutagenesis libraries is described. The program operates by mutagenizing an input nucleic acid sequence according to mutation parameters specified by the user for each sequence position and type of point mutation. The program can mimic almost any type of random mutagenesis library, including those produced via error-prone PCR (ep-PCR), mutator Escherichia coli strains, chemical mutagenesis, and doped or random oligonucleotide synthesis. The program analyzes the generated nucleic acid sequences and/or the associated protein library to produce several estimates of library diversity (number of unique sequences, point mutations, and single point mutants) and the rate of saturation of these diversities during experimental screening or selection of clones. This information allows one to select the optimal screen size for a given mutagenesis library, necessary to efficiently obtain a certain coverage of the sequence-space. The program also reports the abundance of each specific protein mutation at each sequence position, which is useful as a measure of the level and type of mutation bias in the library. Alternatively, one can use the program to evaluate the relative merits of preexisting libraries, or to examine various hypothetical mutation schemes to determine the optimal method for creating a library that serves the screen/selection of interest. Simulated libraries of at least 10⁹ sequences are accessible by the numerical algorithm with currently available personal computers; an analytical algorithm is also available which can rapidly calculate a subset of the numerical statistics in libraries of arbitrarily large size. A multi-type double-strand stochastic model of ep-PCR is developed in an appendix to demonstrate the applicability of the algorithm to amplifying mutagenesis procedures. Estimators of DNA polymerase mutation-type-specific error rates are derived using the model. Analyses of an alpha-synuclein ep-PCR library and NNS synthetic oligonucleotide libraries are given as examples.