A rapid novel strategy for screening of antibody phage libraries for production,purification, and functional characterization of amber stop codons containing single-chain antibody fragments

Phage display antibody (PDA) libraries, allows the rapid isolation and characterization of high specificity monoclonal antibodies for therapeutic and diagnostic applications. However, selection of positive binding clones from synthetic and semi-synthetic libraries has an inherent bias towards clones containing randomly generated amber stop codons, complicating the identification of high affinity binding antibodies. We screened Tomlinson I and J library against receptor binding domain (RBD) of SARS CoV2, eight clones which showed positive binding in phage ELISA, contained one or more amber stop codons in their single-chain antibody fragment (scFv) gene sequences. The presence of amber stop codons within the antibody sequence causes the premature termination of soluble form of scFv expression in nonsuppressor Escherichia coli strain. In the present study, we have used a novel strategy that allows soluble expression of scFvs having amber stop codon in their gene sequences (without phage PIII protein fusion), in the suppressor strain. This strategy of introduction of Ochre (TAA) codon at the junction of scFv and PIII gene, speeds up the initial screening process which is critical for selecting the right scFvs for further studies. Present strategy leads to the identification of a scFv, B8 that binds specifically with nanomolar affinity toward SARS CoV 2 RBD, which otherwise lost in terms of traditional methodology.     

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.     

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.     

A practical kinetic model for efficient isolation of useful antibodies from phage display libraries

To isolate phages displaying a practical and useful antibody with a high k_on value and/or a low k_off value from phage display antibody libraries, we developed a rational strategy based on a kinetic model. In the model, the recovery of a phage displaying an antibody after a round of biopanning is expressed as a function of five parameters, the apparent association rate constant of the phage antibody to the immobilized antigen (k_on′), the apparent dissociation rate constant of the phage antibody from the immobilized antigen (k_off′), the effective antigen concentration (C), the time for the binding process (t_b) and the time for the washing process (t_w). An optimum set of operating parameters (C, t_b and t_w) for isolating phages displaying an antibody with a high k_on value was designed based on the model. Three rounds of biopanning were carried out under the designed conditions, against a phage library in which the hypervariable regions of an original antibody were randomized. All isolated phages displayed an antibody with a higher k_on value and one displayed an antibody with a 30-fold greater k_on value than that of the original antibody. Experimental conditions which improve the efficiency of conventional off-rate selections are also described.     

In vitro system for high-throughput screening of random peptide libraries for antimicrobial peptides that recognize bacterial membranes.

Antibacterial peptides have been isolated from a wide range of species. Some of these peptides act on microbial membranes, disrupting their barrier function. With the increasing development of antibiotic resistance by bacteria, these antibacterial peptides, which have a new mode of action, have attracted interest as antibacterial agents. To date, however, few effective high-throughput approaches have been developed for designing and screening peptides that act selectively on microbial membranes. In vitro display techniques are powerful tools to select biologically functional peptides from peptide libraries. Here, we used the ribosome display system to form peptide-ribosome-mRNA complexes in vitro from nucleotides encoding a peptide library, as well as immobilized model membranes, to select specific sequences that recognize bacterial membranes. This combination of ribosome display and immobilized model membranes was effective as an in vitro high-throughput screening system and enabled us to identify motif sequences (ALR, KVL) that selectively recognized the bacterial membrane. Owing to host toxicity, it was not possible to enrich any sequence expected to show antimicrobial activity using another in vitro system, e.g. phage display. The synthetic peptides designed from these enriched motifs acted selectively on the bacterial model membrane and showed antibacterial activity. Moreover, the motif sequence conferred selectivity onto native peptides lacking selectivity, and decreased mammalian cell toxicity of native peptides without decreasing their antibacterial activity.     

Directed evolution, phage display and combination of evolved mutants: a strategy to recover the neutralization properties of the scFv version of BCF2 a neutralizing monoclonal antibody specific to scorpion toxin Cn2

BCF2, a monoclonal antibody raised against scorpion toxin Cn2, is capable of neutralizing both, the toxin and the whole venom of the Mexican scorpion Centruroides noxius Hoffmann. The single chain antibody fragment (scFv) of BCF2 was constructed and expressed in Escherichia coli. Although its affinity for the Cn2 toxin was shown to be in the nanomolar range, it was non-neutralizing in vivo due to a low stability. In order to recover the neutralizing capacity, the scFv of BCF2 was evolved by error-prone PCR and the variants were panned by phage display. Seven improved mutants were isolated from three different libraries. One of these mutants, called G5 with one mutation at CDR1 and another at CDR2 of the light chain, showed an increased affinity to Cn2, as compared to the parental scFv. A second mutant, called B7 with a single change at framework 2 of heavy chain, also had a higher affinity. Mutants G5 and B7 were also improved in their stability but they were unable to neutralize the toxin. Finally, we constructed a variant containing the changes present in G5 and B7. The purpose of this construction was to combine the increments in affinity and stability borne by these mutants. The result was a triple mutant capable of neutralizing the Cn2 toxin. This variant showed the best affinity constant (KD=7.5x10(-11) M), as determined by surface plasmon resonance (BIAcore). The k(on) and k(off) were improved threefold and fivefold, respectively, leading to 15-fold affinity improvement. Functional stability determinations by ELISA in the presence of different concentrations of guanidinium hydrochloride (Gdn-HCl) revealed that the triple mutant is significantly more stable than the parental scFv. These results suggest that not only improving the affinity but also the stability of our scFv were important for recovering its neutralization capacity. These findings pave the way for the generation of recombinant neutralizing antisera against scorpion stings based on scFvs.     

Optimal construction of non-immune scFv phage display libraries from mouse bone marrow and spleen established to select specific scFvs efficiently binding to antigen

Monoclonal antibodies (MAbs) are widely applied in basic research, medicine, and the pharmaceutical industry. Recently, applications and generations of MAbs have been increasingly attracting attention in many research areas since MAbs could be produced in large quantities with the development of genetic technology and antibody engineering. On the other hand, in recent years, phage display system has been developed for high-throughput isolation and generation of novel MAbs that have high affinity with various antigens. This technology is capable of constructing "Library" containing billions of phage repertoires displaying various antibody fragments, and rapid selection of a specific MAb from this phage library. Additionally, this technology has a great advantage that MAbs can be generated without immunization to animals. However, there are still relatively few reports confirming that useful MAbs can be derived from non-immune antibody libraries. The latter, as undertaken by current methods, seem unable to achieve the high quality required to produce useful MAbs for any desired antigen because cloning of antibody gene from non-immune donors is inefficient. This problem is caused by the fact that their RT-PCR primer sets, PCR conditions, and efficiency of subcloning through construction of antibody gene library cannot encompass all the antibody diversity. In an attempt to overcome some of these earlier problems, here we describe an optimized method to establish a high quality, non-immune library from mouse bone-marrow and spleen, and assess its diversity in terms of content of multiple antibodies for a wide antigenic repertoire. As an example of the application of the methodology, we describe the selection of specific MAbs binding to Luciferase and identify at least 18 different clones. Using this non-immune mouse antibody library, we also obtained MAbs for VEGF, VEGF receptor 2, TNF-alpha, and Pseudomonas Exotoxin, confirming the high quality of the library and its suitability for this application.     

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.     

人IgG四亚类对噬菌体展示Ig结合蛋白单结构域随机组合文库的体外进化筛选

金黄色葡萄球菌蛋白A(Staphylococcal protein A,SpA)和链球菌蛋白G(Streptococcal protein G,SpG)是细菌产生的特异结合宿主抗体的细菌免疫球蛋白结合蛋白(Immunoglobulin(Ig)-binding proteins,IBPs)的代表分子。SpA和SpG均包含由多个序列高度同源的结合结构域重复组成的抗体结合区,各单结构域都具有完全的结合IgG的功能。为研究这些单结构域随机组合能否产生具有新结合特性的组合分子,将SpA的A、B、C、D、E以及SpG的B2、B3共7个单结合结构域随机组合构建成噬菌体展示文库后,应用人IgG1、2、3、4为诱饵分子对该文库进行4轮筛选,获得了SpA天然分子中不存在的单结构域排列组合分子D-C。在筛选过程中,阴性对照噬菌体的逐渐减少、展示两个结构域以上的噬菌体比例不断增多,尤其是D-C组合的选择性富集和其随机连接肽的严格筛选都显示了筛选的有效性和D-C组合的重要性。噬菌体ELISA进一步证实D-C与人IgG四亚类的结合能力远强于天然SpA分子。该研究应用分子进化技术首次获得了一种与人IgG四亚类具有结合优势的新型组合分子D-C,不仅可为IgG纯化、制备、检测等方面的应用提供新的候选分子,还为细菌IBP结构功能的进一步研究提供新的手段。     

Rabbit immune repertoires as sources for therapeutic monoclonal antibodies: the impact of kappa allotype-correlated variation in cysteine content on antibody libraries selected by phage display

The rabbit immune repertoire has long been a rich source of diagnostic polyclonal antibodies. Now it also holds great promise as a source of therapeutic monoclonal antibodies. On the basis of phage display technology, we recently reported the first humanization of a rabbit monoclonal antibody. The allotypic diversity of rabbit immunoglobulins prompted us to compare different rabbit immune repertoires for the generation and humanization of monoclonal antibodies that bind with strong affinity to antigens involved in tumor angiogenesis. In particular, we evaluated the diversity of unselected and selected chimeric rabbit/human Fab libraries that were derived from different kappa light chain allotypes. Most rabbit light chains have an extra disulfide bridge that links the variable and constant domains in addition to the two intrachain disulfide bridges shared with mouse and human kappa light chains. Here we evaluate the impact of this increased disulfide bridge complexity on the generation and selection of chimeric rabbit/human Fab libraries. We demonstrate that rabbits with mutant bas and wild-type parental b9 allotypes are excellent sources for therapeutic monoclonal antibodies. Featured among the selected clones with b9 allotype is a rabbit/human Fab that binds with a dissociation constant of 1nM to both human and mouse Tie-2, which will facilitate its evaluation in mouse models of human cancer. Examination of 228 new rabbit antibody sequences allowed for a comprehensive comparison of the LCDR3 and HCDR3 length diversity in rabbits. This study revealed that rabbits exhibit an HCDR3 length distribution more closely related to human antibodies than mouse antibodies.     

Use of phage display and high-density screening for the isolation of an antibody against the 51-kDa subunit of complex I

Monoclonal antibodies play an increasingly important role in structural biology. In this report, we develop the use of phage display technology for the isolation of an antibody that binds to a specific subunit of a macromolecular assembly. Antibodies that bind to the intact complex are selected from a phage display library and screened with a high-density Western blot to identify a subunit-specific binder. Conventional Western blotting and competition ELISA are then used to confirm the identity of the target subunit and that the antibody binds to the native protein complex and not to an epitope that is only revealed when the antibody is immobilized for phage selection. Using this technique, monoclonal scFv and Fab fragments have been produced that bind to the 51-kDa subunit of bovine complex I, a large integral membrane protein complex from mitochondria.     

The phage display of Bacillus subtilis Lipase A significantly enhances catalytic activity due to altered nanoscale distribution in colloidal solution

Screening libraries of mutant proteins by phage display is now relatively common. However, one unknown factor is how the bacteriophage scaffold itself influences the properties of the displayed protein. This communication evaluates the effect of solution parameters on the catalytic activity of phage displayed Bacillus subtilis Lipase A (BSLA), compared to the free enzyme in solution. While the pH- and temperature-activity profiles of BSLA were not intrinsically affected by phage display, the nanoscale distribution of BSLA within the micellar assay buffer was. This lead to a pronounced increase of activity of phage–BSLA relative to the free enzyme, owing to the accumulation of phage–BSLA at the substrate-rich micelles. Considering this result obtained for BSLA, caution is warranted and similar effects should be considered when selecting other enzymes/proteins by phage display, as the activity of the displayed protein may differ from that of the free protein.     

Isolation of ScFv antibodies of rP27~(Kip1) from phage display libraries constructed from immunized and non-immunized repertoires

Through mRNA extract, RT and a series of PCR, phage antibody libraries were constructed from rP27~(Kipl)immunized and non-immunized mice. After only one round of selection with rP27~(Kipl), clones from each library were chosen randomly and digested by Taq I and Hinf I. 11 of 64 clones from the immunized animal had consistent restriction pattern, while none of the 64 clones from the non-immunized animal had, except that one had the same fragments pattern as that of the 11 clones. The 12 fragments were expressed in E. coli BL21(DE3)/pET-28b( ) system. ELISA showed that some of the fragments could bind to rP27~(Kipl) specifically. All these results implied that specific antibody can be obtained by genetic engineering without hybridoma or many rounds of growth and panning selection.     

Evaluation of phage display system and leech-derived tryptase inhibitor as a tool for understanding the serine proteinase specificities

A small combinatorial library of LDTI mutants (5.2 x 10(4)) restricted to the P1-P4' positions of the reactive site was displayed on the pCANTAB 5E phagemid, and LDTI fusion phages were produced and selected for potent neutrophil elastase and plasmin inhibitors. Strong fusion phage binders were analyzed by ELISA on enzyme-coated microtiter plates and the positive phages had their DNA sequenced. The LDTI variants: 29E (K8A, I9A, L10F, and K11F) and 19E (K8A, K11Q, and P12Y) for elastase and 2Pl (K11W and P12N), 8Pl (I9V, K11W, and P12E), and 10Pl (I9T, K11L, and P12L) for plasmin were produced with a Saccharomyces cerevisiae expression system. New strong elastase and plasmin inhibitors were 29E and 2Pl, respectively. LDTI-29E was a potent and specific neutrophil elastase inhibitor K(i) =0.5 nM), affecting no other tested enzymes. LDTI-2Pl was the strongest plasmin inhibitor ( K(i) =1.7nM) in the LDTI mutant library. This approach allowed selection of new specific serine proteinase inhibitors for neutrophil elastase and plasmin (a thrombin inhibitor variant was previously described), from a unique template molecule, LDTI, a Kazal type one domain inhibitor, by only 2-4 amino acid replacements. Our data validate this small LDTI combinatorial library as a tool to generate specific serine proteinase inhibitors suitable for drug design and enzyme-inhibitor interaction studies.     

Generation of antibodies recognizing an aberrant glycoform of human tissue inhibitor of metalloproteinase-1 (TIMP-1) using decoy immunization and phage display

Aberrant glycosylation of human tissue inhibitor of metalloproteinase-1 (TIMP-1) by N-acetylglucosaminyltransferase-V (GnT-V) was previously reported to be related to cancer progression. Here, we report on the antibodies recognizing the structural features initiated by an addition of N-linked β(1,6)-N-acetylglucosamine (GlcNAc) branch by GnT-V on TIMP-1. Two glycoforms of TIMP-1, TIMP1-L produced in Lec4 cells without GnT-V activity and TIMP1-B in GnT-V overexpressing transfectant cells, were purified from culture supernatant and used for generation of antibodies. TIMP1-L was injected in the left hind footpad of mice as decoy and TIMP1-B in the right hind footpad as immunogen. Phage-displayed scFv library was constructed from the B cells retrieved from the right popliteal lymph nodes and subjected to panning and screening. Phage ELISA of individual clones revealed the scFv clones with preferential binding activity to TIMP1-B, and they were converted into an scFv-Fc format for further characterization of binding specificity. Glycan binding assay of an antibody, 1-9F, revealed its differential specificity toward an extension of glycan structure initiated with β(1,6)-GlcNAc linkage and terminally decorated with a sialic acid. This study demonstrates feasibility of a new strategy combining decoy immunization with phage display for the efficient generation of antibodies tracking down structural features of different glycoforms.     

质控血清09CS中13个肺炎球菌荚膜多糖抗体IgG含量检测范围的确定

目的 建立09CS作为质控血清用于13价肺炎球菌多糖蛋白结合疫苗(13PCV)临床血清样本检测中的检测值范围。方法 用WHO推荐的检测人血清中抗肺炎球菌荚膜多糖抗体IgG的定量ELISA,以国际人肺炎球菌标准血清007sp为标准,将09CS作为待测血清,检测其在13个血清型(1、3、4、5、6A、6B、7F、9V、14、18C、19A、19F、23F型)中抗荚膜多糖抗体IgG含量的值。连续检测09CS血清100余次,计算99%置信区间的各血清型几何平均抗体浓度、标准偏差(SD)和变异系数(CV)。结果 检测得到09C中13个血清型抗荚膜多糖IgG抗体含量以及在99%置信区间(CI)下±2.58倍SD的检测值范围;13个血清型检测结果的CV分别为10.86%、12.52%、13.96%、14.98%、28.77%、11.16%、14.96%、9.31%、10.43%、7.28%、10.86%、12.52%、13.96%,除6A型外,各型CV均低于15%,表明试验间精密度良好;检测次数异常率低于10%。结论 09CS可作为质控血清,用于13价肺炎球菌结合疫苗临床血清中抗荚膜多糖抗体IgG含量的ELISA检测。     

Heterogeneous distribution of nuclear triiodothyronine receptors in liver and preadipose cells as evidenced by their reactivity to antibodies against different protein products of erb A oncogenes

Polyclonal antibodies raised in rabbits against bacterially produced peptides in the C-terminal region of v-erb A or human c-erb A oncogenes recognize the nuclear triiodothyronine (T3) receptors in the T3-sensitive Ob 17 mouse preadipocyte cell line and not in mouse or rat liver. The results confirm the existence of different T3 receptors in different tissues. The results also suggest a heterogeneous receptor distribution within the preadipose cell line, with a predominance of c-erb A-type species. Antibodies raised against domain 149–227, but not against domain 245–325, impair T3 binding, suggesting a role for this domain in ligand binding.