Phage versus phagemid libraries for generation of human monoclonal antibodies

Non-immune (na?ve) phage antibody libraries have become an important source of antibodies for reagent, diagnostic, and therapeutic use. To date, reported na?ve libraries have been constructed in phagemid vectors as fusions to pIII, yielding primarily single copy (monovalent) display of antibody fragments. For this work, we subcloned the single chain Fv (scFv) gene repertoire from a na?ve phagemid antibody library into a true phage vector to create a multivalently displayed scFv phage library. Compared to monovalently displayed scFv, multivalent phage display resulted in improved efficiency of display as well as antibody selection. A greater number of antibodies were obtained and at earlier rounds of selection. Such increased efficiency allows the screening for binding antibodies after a single round of selection, greatly facilitating automation. Expression levels of antigen-binding scFv were also higher than from the phagemid library. In contrast, the affinities of scFv from the phage library were lower than from the phagemid library. This could be overcome by utilizing the scFv in a multivalent format, by affinity maturation, or by converting the library to monovalent display after the first round of selection.     

Multivalent scFv display of phagemid repertoires for the selection of carbohydrate-specific antibodies and its application to the Thomsen-Friedenreich antigen

The Thomsen-Friedenreich disaccharide (TF) is a promising target antigen for tumor immunotherapy, since it is almost exclusively expressed in carcinoma tissues. The TF-specific antibodies generated so far are IgMs of mouse origin with limited therapeutic potential. Phage-displayed scFv repertoires are an established source for recombinant antibodies; however, we were unable to identify scFvs binding to TF when applying libraries in the standard monovalent display format of phagemid systems. Here, we report on the successful selection of TF-specific antibody fragments using a multivalent scFv phagemid library format based on shortened linkers (one amino acid residue). The libraries were constructed from mice immunized with asialoglycophorin and selected using TF displayed on two different carrier molecules in combination with the proteolytically cleavable helper phage KM13. All isolated clones encoded the same framework genes and the same complementarity-determining regions. After affinity maturation only scFv with the founder sequence were selected from secondary repertoires. This indicates a very narrow sequence window for TF-specific antibodies. Investigating other linker-length formats revealed a clear inverse correlation between linker length and binding activity both as soluble proteins and displayed on phages. The highest affinity was obtained with the tetrameric format. The selected scFv was specific for TF on various carrier molecules and tumor cells and performed well in ELISA and immunohistochemistry. We postulate that scFv phagemid library formats with short linkers (i.e. multimeric scFvs) may, in general, be advantageous in selections for the generation of scFvs against carbohydrate epitopes or other epitopes associated with low intrinsic affinity per binding site), and expect that they will be superior in applications for diagnosis or therapy.     

Selection of tumor-specific internalizing human antibodies from phage libraries

Antibody internalization into the cell is required for many targeted therapeutics, such as immunotoxins, immunoliposomes, antibody-drug conjugates and for targeted delivery of genes or viral DNA into cells. To generate directly tumor-specific internalizing antibodies, a non-immune single chain Fv (scFv) phage antibody library was selected on the breast tumor cell line SKBR3. Internalized phage were recovered from within the cell and used for the next round of selection. After three rounds of selection, 40 % of clones analyzed bound SKBR3 and other tumor cells but did not bind normal human cells. Of the internalizing scFv identified, two (F5 and C1) were identified as binding to ErbB2, and one (H7) to the transferrin receptor. Both F5 and H7 scFv were efficiently endocytosed into SKBR3 cells, both as phage antibodies and as native monomeric scFv. Both antibodies were able to induce additional functional effects besides triggering endocytosis: F5 scFv induces downstream signaling through the ErbB2 receptor and H7 prevents transferrin binding to the transferrin receptor and inhibits cell growth. The results demonstrate the feasibility of selecting internalizing receptor-specific antibodies directly from phage libraries by panning on cells. Such antibodies can be used to target a variety of molecules into the cell to achieve a therapeutic effect. Furthermore, in some instances endocytosis serves as a surrogate marker for other therapeutic biologic effects, such as growth inhibition. Thus, a subset of selected antibodies will have a direct therapeutic effect.     

Development of recombinant single-chain variable fragment against hepatitis A virus and its use in quantification of hepatitis A antigen

Phage display technology has been utilized for identification of specific binding molecules to an antigenic target thereby enabling the rapid generation and selection of high affinity, fully human antibodies directed towards disease target appropriate for antibody therapy. In the present study, single chain Fv antibody fragment (scFv) to hepatitis A virus (HAV) was selected from phage displayed antibody library constructed from peripheral blood lymphocytes (PBLs) of a vaccinated donor. The variable heavy (V(H)) and light chains (V(L)) were amplified using cDNA as template, assembled into scFv using splicing by overlap extension PCR (SOE PCR) and cloned into phagemid vector as a fusion for display of scFv on bacteriophage. The phage displaying antibody fragments were subjected to three rounds of panning with HAV antigen on solid phase. High affinity antibodies reactive to hepatitis A virus were identified by phage ELISA and cloned into a bacterial expression vector pET20b. The scFv was purified by immobilized metal affinity chromatography (IMAC) on a nickel-nitrilotriacetic acid (NTA) agarose column and characterized. The binding activity and specificity of the scFv was established by its non-reactivity towards other human viral antigens as determined by ELISA and immunoblot analysis. The scFv was further used in the development of an in-house IC-ELISA format in combination with a commercially available mouse monoclonal antibody for the quantification of hepatitis A virus antigen in human vaccine preparations. The adjusted r2 values obtained by subjecting the values obtained by quantification of the NIBSC standards using the commercial and the in-house ELISA kits by regression analysis were 0.99 and 0.95. 39 vaccine samples were subjected to quantification using both the kits. Regressional statistical analysis through the origin of the samples indicated International Unit (IU) values of 0.0416x and 0.0419x, respectively for the commercial and in-house kit respectively.     

Filamentous bacteriophage display of a bifunctional protein A::scFv fusion

Filamentous bacteriophage display is a powerful and widely used technology for the selection of affinity ligands. However, the commonly used phagemid systems result in the production of a population of phage of which those displaying the ligand of interest represent only a small proportion. Through simple dilution and nonspecific binding effects, the presence of large numbers of ligand-free phage reduces the likelihood that weak binders will be successfully selected from a ligand library. To provide a means of avoiding such problems, we have introduced an affinity handle into the phage that permits the purification of ligand-displaying phage. The IgG binding domains ofStaphylococcus ciureus protein A (SpA) were fused to a ligand (single chain Fv[scFv]) which is displayed as a fusion with the phage surface protein ApIII. Phage-displaying SpA were separated by affinity chromatography using immobilized human IgG from non-displaying phage and the purified phage were shown to possess functional scFv. Comparisons of fusion proteins in which either the scFv or the affinity handle occupied the amino terminus of the fusion protein showed that, whereas SpA function was unaffected by position, scFv function was compromised when the scFv did not occupy the amino terminus.     

New display vector reduces biological bias for expression of antibodies in E. coli

We report the development of a novel phagemid vector, pKM19, for display of recombinant antibodies in single-chain format (scFv) on the surface of filamentous phage. This new vector improves efficacy of selection and reduces the biological bias against antibodies that can be harmful to host bacteria. It is useful for generation of large new antibody libraries, and for the subsequent maturation of antibody fragments. In comparison with commonly used plasmids, this vector is designed to have relatively low expression levels of cloned scFv antibodies due to the amber codon positioned in a sequence encoding for the PhoA leader peptide. Moreover, fusion of antibodies to the carboxy terminal part only of the gene III protein improves display of scFv on bacteriophage surface in this system. Despite the lower antibody expression, the functional test performed with a new scFv library derived from human peripheral blood lymphocytes demonstrates that specific antibodies can be easily isolated from the library, even after the second selection round. The use of the pKM19 vector for maturation of an anti-CEA antibody significantly improves the final results. In our previous work, an analogous selection through the use of a phagemid vector, with antibody expression under the control of a lacP promoter, led to isolation of anti-CEA phage antibodies with improved affinities, which were not producible in soluble form. Probably due to the toxicity for E. coli of that particular anti-CEA antibody, 70% of maturated clones contained suppressed stop codons, acquired during various selection/amplification rounds. The pKM19 plasmid facilitates an efficient maturation process, resulting in selection of antibodies with improved affinity without any stop codons.     

The influence of antibody fragment format on phage display based affinity maturation of IgG

Today, most approved therapeutic antibodies are provided as immunoglobulin G (IgG), whereas small recombinant antibody formats are required for in vitro antibody generation and engineering during drug development. Particularly, single chain (sc) antibody fragments like scFv or scFab are well suited for phage display and bacterial expression, but some have been found to lose affinity during conversion into IgG.

In this study, we compared the influence of the antibody format on affinity maturation of the CD30-specific scFv antibody fragment SH313-F9, with the overall objective being improvement of the IgG. The variable genes of SH313-F9 were randomly mutated and then cloned into libraries encoding different recombinant antibody formats, including scFv, Fab, scFabΔC, and FabΔC. All tested antibody formats except Fab allowed functional phage display of the parental antibody SH313-F9, and the corresponding mutated antibody gene libraries allowed isolation of candidates with enhanced CD30 binding. Moreover, scFv and scFabΔC antibody variants retained improved antigen binding after subcloning into the single gene encoded IgG-like formats scFv-Fc or scIgG, but lost affinity after conversion into IgGs. Only affinity maturation using the Fab-like FabΔC format, which does not contain the carboxy terminal cysteines, allowed successful selection of molecules with improved binding that was retained after conversion to IgG. Thus, affinity maturation of IgGs is dependent on the antibody format employed for selection and screening. In this study, only FabΔC resulted in the efficient selection of IgG candidates with higher affinity by combination of Fab-like conformation and improved phage display compared with Fab.     

The influence of antibody fragment format on phage display based affinity maturation of IgG

Today, most approved therapeutic antibodies are provided as immunoglobulin G (IgG), whereas small recombinant antibody formats are required for in vitro antibody generation and engineering during drug development. Particularly, single chain (sc) antibody fragments like scFv or scFab are well suited for phage display and bacterial expression, but some have been found to lose affinity during conversion into IgG.   In this study, we compared the influence of the antibody format on affinity maturation of the CD30-specific scFv antibody fragment SH313-F9, with the overall objective being improvement of the IgG. The variable genes of SH313-F9 were randomly mutated and then cloned into libraries encoding different recombinant antibody formats, including scFv, Fab, scFabΔC, and FabΔC. All tested antibody formats except Fab allowed functional phage display of the parental antibody SH313-F9, and the corresponding mutated antibody gene libraries allowed isolation of candidates with enhanced CD30 binding. Moreover, scFv and scFabΔC antibody variants retained improved antigen binding after subcloning into the single gene encoded IgG-like formats scFv-Fc or scIgG, but lost affinity after conversion into IgGs. Only affinity maturation using the Fab-like FabΔC format, which does not contain the carboxy terminal cysteines, allowed successful selection of molecules with improved binding that was retained after conversion to IgG. Thus, affinity maturation of IgGs is dependent on the antibody format employed for selection and screening. In this study, only FabΔC resulted in the efficient selection of IgG candidates with higher affinity by combination of Fab-like conformation and improved phage display compared with Fab.     

Biological effects of anti-ErbB2 single chain antibodies selected for internalizing function

Two internalizing monovalent single chain antibody fragments (scFv), C6.5 and F5, that recognize distinct ErbB2 extracellular domain (ECD) epitopes, and their bivalent forms dbC6.5 and F5(scFv')(2), were compared to the growth-inhibiting anti-ErbB2 antibody Herceptin/trastuzumab, in either its bivalent (Her) or monovalent (4D5Fab') form, for their abilities to induce biological responses in the ErbB2-overexpressing breast cancer cells, SkBr-3. Assays compared internalization by receptor-mediated endocytosis, effects on cell cycling and culture growth, and interference with intracellular MAPK and PI3K signaling pathways. We found no correlation between ErbB2 epitope affinity or valency on degree of antibody-induced endocytosis, since all the scFv were able to internalize better than Her. Unlike Her, neither the monovalent or bivalent forms of the internalizing scFv had any sustained effect on cell growth. Basal levels of MAPK and PI3K signaling in SkBr-3 cells were not inhibited by up to 8 h scFv treatment, while decreased MAPK and PI3K signals were noted within 8 h of Her treatment. In summary, antibody-induced ErbB2-mediated endocytosis is not a surrogate marker for resultant biological response, as it shows no correlation with cell cycle, culture proliferation, or intracellular kinase signal induction by internalizing antibodies. Thus, the enhanced endocytotic property of scFv like C6.6 and F5 in conjunction with their absence of any growth or signaling impact on ErbB2-overexpressing cells favors their choice as ErbB2 targeting moieties for intracellular delivery of novel cancer therapeutics.     

Detection of weakly interacting anti-carbohydrate scFv phages using surface plasmon resonance

Methods to characterise and confirm specificity of scFv displayed on phages are important during panning procedures, especially when selecting for antibody fragments with weak affinities in the millimole to micromole range. In this report the surface plasmon resonance (SPR) biosensor was used to study and verify specificity of phages displaying weak anti-carbohydrate scFvs. The variable immunoglobulin light (VL) and heavy (VH) chain genes of the weak monoclonal antibody 39.5 were amplified and cloned into a phagemid and displayed as a scFv-pIII fusion protein on filamentous phage. This monoclonal antibody recognises with weak affinity the structural sequence Glcalpha1-4Glc present in a variety of carbohydrate molecules. Injection of the 39.5 phages over a biosensor chip immobilised with a (Glc)4-BSA conjugate confirmed selective binding of the scFv to its antigen. Inhibition studies verified the specificity. These results clearly show that SPR technology can be used to evaluate in terms of binding and specificity weakly interacting scFv displayed on the phage surface.     

天然兔源噬菌体单链抗体库的构建与鉴定

目的:构建天然兔源噬菌体单链抗体库。方法:采用RT-PCR法从未免疫的兔子脾脏中克隆得到抗体重链可变区(VH)与轻链可变区(VL)基因,重叠PCR将VH和VL拼接成scFv片段,将scFv连接到噬菌粒pComb3XSS上,电转入XL1-Blue菌中,得到单链抗体库,并用此抗体库筛选抗肌酸激酶抗体。结果:构建了容量为4×108,基因重组率95%的单链抗体库,DNA指纹图谱显示抗体库多样性良好。以肌酸激酶为抗原,从该库中筛到3株抗肌酸激酶的抗体。结论:分析表明构建的天然兔源单链抗体库质量良好,可用于快速筛选、制备多种单链抗体。     

De novo identification of cell-type specific antibody-antigen pairs by phage display subtraction. Isolation of a human single chain antibody fragment against human keratin 14.

The aim of this study was to identify novel antibodies directed against cytosolic keratinocyte-specific antigens from a phage display antibody repertoire by using phage display subtraction. Phage display is a method of displaying foreign molecules on the surface of filamentous bacteriophage particles. It allows the interaction between two cognate molecules to be analysed through affinity selections. Recently, large repertoires of phage displayed human antibody fragments have been constructed. From such repertoires, antibodies can be obtained in vitro without the need for immunization or the hybridoma technology. A novel subtractive strategy for selecting antibodies from phage libraries was applied. Phage antibodies were selected against immobilized crude lysates of cultured human keratinocytes, the target antigens being unknown beforehand. A competing cell lysate was used to reduce retrieval of phage antibodies with specificities to commonly non-differentially expressed antigens. A monoclonal single chain fragment variable (scFv) with specificity for crude lysates of cultured human keratinocytes was identified as demonstrated by ELISA assays and immunoblotting analysis. The cognate keratinocyte antigen was shown to be keratin 14 (K14) by using immunoblotting based on 2D PAGE and a corresponding 2D PAGE protein database. In accordance with the expected tissue localization of K14, the identified scFv stained the basal layer of human epidermis by indirect immunofluorescence analysis. Starting with crude cell lysates, phage display subtraction in combination with 2D PAGE and 2D PAGE protein databases can be used to identify antibody-antigen pairs that characterize a specific cell type.     

抗EGFRvIII噬菌体抗体库的构建和筛选

目的：应用噬菌体展示技术筛选针对表皮生长因子受体突变体Ш (epidermal growth factor receptor variant type Ⅲ, EGFRvIII)的单链抗体 (single chain Fv, scFv)。方法：利用原核表达纯化的人EGFRvIIIex蛋白和高表达EGFRvIIIex的小鼠成纤维细胞系NIH3T3免疫小鼠,扩增VH和VL片段并拼装成scFv 基因,连接至噬菌粒pCANTAB 5E,电击转化Hpd3cells,构建噬菌体单链抗体库,并进行3轮富集筛选。在第4轮筛选时,采用了降低抗原浓度的方法。然后将筛选得到的阳性克隆测序分析,转化E.coli HB2151,IPTG 诱导可溶性scFv 的表达。结果：构建了库容为7.9×107 的噬菌体单链抗体库。经过第4轮低浓度抗原筛选,得到了较高亲和力的克隆。取单个阳性克隆测序分析结果表明,该抗EGFRvIII scFv 基因序列长807 bp,编码268个氨基酸。IPTG诱导后表达的可溶性scFv 可分别与纯化的EGFRvIIIex抗原以及细胞表面的EGFRvIIIex结合。结论：利用噬菌体抗体库筛选得到了高亲和力的抗EGFRvIII scFv,为开发针对EGFRvIII的抗体药物提供了靶向载体分子。     

鼠源抗B型肉毒毒素单链抗体噬菌体文库的构建筛选及抗体免疫学活性的初步研究

B型肉毒毒素重链C-端片段(BoNTB/Hc)经金属螯和层析法纯化后免疫Balb/c小鼠,从其脾淋巴细胞中提取总RNA,反转录成cDNA,用抗体可变区混合引物进行全套抗体重、轻链可变区基因的扩增,体外随机装配成单链抗体(scFv)。将其克隆至pCANTAB5E中,构建单链抗体噬菌体抗体库。结果表明经过4轮"吸附-洗脱-扩增"的富集过程,筛选获得高亲和力的克隆。序列测定符合抗体可变区结构特点。     

An efficient method for variable region assembly in the construction of scFv phage display libraries using independent strand amplification

Phage display library technology is a common method to produce human antibodies. In this technique, the immunoglobulin variable regions are displayed in a bacteriophage in a way that each filamentous virus displays the product of a single antibody gene on its surface. From the collection of different phages, it is possible to isolate the virus that recognizes specific targets. The most common form in which to display antibody variable regions in the phage is the single chain variable fragment format (scFv), which requires assembly of the heavy and light immunoglobulin variable regions in a single gene.

In this work, we describe a simple and efficient method for the assembly of immunoglobulin heavy and light chain variable regions in a scFv format. This procedure involves a two-step reaction: (1) DNA amplification to produce the single strand form of the heavy or light chain gene required for the fusion; and (2) mixture of both single strand products followed by an assembly reaction to construct a complete scFv gene. Using this method, we produced 6-fold more scFv encoding DNA than the commonly used splicing by overlap extension PCR (SOE-PCR) approach. The scFv gene produced by this method also proved to be efficient in generating a diverse scFv phage display library. From this scFv library, we obtained phages that bound several non-related antigens, including recombinant proteins and rotavirus particles.     

Exploiting recombination in single bacteria to make large phage antibody libraries

The creation of large phage antibody libraries has become an important goal in selecting antibodies against any antigen. Here we describe a method for making libraries so large that the complete diversity cannot be accessed using traditional phage technology. This involves the creation of a primary phage scFv library in a phagemid vector containing two nonhomologous lox sites. Contrary to the current dogma, we found that infecting Cre recombinase-expressing bacteria by such a primary library at a high multiplicity of infection results in the entry of many different phagemid into the cell. Exchange of Vh and Vl genes between such phagemids creates many new V h/Vl combinations, all of which are functional. On the basis of the observed recombination, the library is calculated to have a diversity of 3x1011. A library created using this method was validated by the selection of high affinity antibodies against a large number of different protein antigens.     

An efficient method for variable region assembly in the construction of scFv phage display libraries using independent strand amplification

Phage display library technology is a common method to produce human antibodies. In this technique, the immunoglobulin variable regions are displayed in a bacteriophage in a way that each filamentous virus displays the product of a single antibody gene on its surface. From the collection of different phages, it is possible to isolate the virus that recognizes specific targets. The most common form in which to display antibody variable regions in the phage is the single chain variable fragment format (scFv), which requires assembly of the heavy and light immunoglobulin variable regions in a single gene. In this work, we describe a simple and efficient method for the assembly of immunoglobulin heavy and light chain variable regions in a scFv format. This procedure involves a two-step reaction: (1) DNA amplification to produce the single strand form of the heavy or light chain gene required for the fusion; and (2) mixture of both single strand products followed by an assembly reaction to construct a complete scFv gene. Using this method, we produced 6-fold more scFv encoding DNA than the commonly used splicing by overlap extension PCR (SOE-PCR) approach. The scFv gene produced by this method also proved to be efficient in generating a diverse scFv phage display library. From this scFv library, we obtained phages that bound several non-related antigens, including recombinant proteins and rotavirus particles.     

Selection of functional human antibodies from retroviral display libraries

Antibody library technology represents a powerful tool for the discovery and design of antibodies with high affinity and specificity for their targets. To extend the technique to the expression and selection of antibody libraries in an eukaryotic environment, we provide here a proof of concept that retroviruses can be engineered for the display and selection of variable single-chain fragment (scFv) libraries. A retroviral library displaying the repertoire obtained after a single round of selection of a human synthetic scFv phage display library on laminin was generated. For selection, antigen-bound virus was efficiently recovered by an overlay with cells permissive for infection. This approach allowed more than 10³-fold enrichment of antigen binders in a single selection cycle. After three selection cycles, several scFvs were recovered showing similar laminin-binding activities but improved expression levels in mammalian cells as compared with a laminin-specific scFv selected by the conventional phage display approach. Thus, translational problems that occur when phage-selected antibodies have to be transferred onto mammalian expression systems to exert their therapeutic potential can be avoided by the use of retroviral display libraries.     

Targeted gene delivery to mammalian cells by filamentous bacteriophage.

We report that prokaryotic viruses can be re-engineered to infect eukaryotic cells resulting in expression of a reporter gene inserted into the bacteriophage genome. Phage capable of binding mammalian cells expressing the growth factor receptor ErbB2 and undergoing receptor-mediated endocytosis were isolated by selection of a phage antibody library on breast tumor cells and recovery of infectious phage from within the cell. As determined by immunofluorescence, F5 phage were efficiently endocytosed into 100 % of ErbB2 expressing SKBR3 cells. To achieve reporter gene expression, F5 phage were engineered to package the green fluorescent protein (GFP) reporter gene driven by the CMV promoter. These phage when applied to cells underwent ErbB2-mediated endocytosis leading to GFP expression. GFP expression occurred only in cells overexpressing ErbB2, was dose-dependent reaching, 4 % of cells after 60 hours and was detected with phage titers as low as 2.0 x 10(7) cfu/ml (500 phage/cell). The results demonstrate that bacterial viruses displaying the appropriate antibody can bind to mammalian receptors and utilize the endocytic pathway to infect eukaryotic cells, resulting in expression of a reporter gene inserted into the viral genome. This represents a novel method to discover targeting molecules capable of delivering a gene intracellularly into the correct trafficking pathway for gene expression by directly screening phage antibodies. This should significantly facilitate the identification of appropriate targets and targeting molecules for gene therapy or other applications where delivery into the cytosol is required. This approach can be adapted to directly select, rather than screen, phage antibodies for targeted gene expression. The results also demonstrate the potential of phage antibodies as an in vitro or in vivo targeted gene delivery vehicle.     

A comprehensive analysis of filamentous phage display vectors for cytoplasmic proteins: an analysis with different fluorescent proteins

Filamentous phage display has been extensively used to select proteins with binding properties of specific interest. Although many different display platforms using filamentous phage have been described, no comprehensive comparison of their abilities to display similar proteins has been conducted. This is particularly important for the display of cytoplasmic proteins, which are often poorly displayed with standard filamentous phage vectors. In this article, we have analyzed the ability of filamentous phage to display a stable form of green fluorescent protein and modified variants in nine different display vectors, a number of which have been previously proposed as being suitable for cytoplasmic protein display. Correct folding and display were assessed by phagemid particle fluorescence, and with anti-GFP antibodies. The poor correlation between phagemid particle fluorescence and recognition of GFP by antibodies, indicates that proteins may fold correctly without being accessible for display. The best vector used a twin arginine transporter leader to transport the displayed protein to the periplasm, and a coil-coil arrangement to link the displayed protein to g3p. This vector was able to display less robust forms of GFP, including ones with inserted epitopes, as well as fluorescent proteins of the Azami green series. It was also functional in mock selection experiments.