Identification and epitope mapping of anti-p72 single-chain antibody against African swine fever virus based on phage display antibody library

African swine fever virus(ASFV)is a lethal pathogen that causes severe threats to the global swine industry and it has already had catastrophic socio-economic effects.To date,no licensed prophylactic vaccine exists.Limited knowledge exists about the major immunogens of ASFV and the epitope mapping of the key antigens.As such,there is a considerable requirement to understand the functional monoclonal antibodies(mAbs)and the epitope mapping may be of utmost importance in our understanding of immune responses and designing improved vaccines,therapeutics,and diagnostics.In this study,we generated an ASFV antibody phage-display library from ASFV convalescent swine PBMCs,further screened a specific ASFV major capsid protein(p72)single-chain antibody and fused with an IgG Fc fragment(scFv-83-Fc),which is a specific recognition antibody against ASFV Pig/HLJ/2018 strain.Using the scFv-83-Fc mAb,we selected a conserved epitope peptide(221MTGYKH226)of p72 retrieved from a phage-displayed random peptide library.Moreover,flow cytometry and cell uptake experiments demonstrated that the epitope peptide can significantly promote BMDCs maturation in vitro and could be effectively uptaken by DCs,which indicated its potential application in vaccine and diagnostic reagent development.Overall,this study provided a valuable platform for identifying targets for ASFV vaccine development,as well as to facilitate the optimization design of subunit vaccine and diagnostic reagents.

Phage Display技术在抗体库中的应用现状

PhageDisplay技术是将外源蛋白通过与丝状噬菌体外壳蛋白融合而将外源蛋白表达于噬菌体颗粒的表面。该技术已被应用于噬菌体抗体库中，为单克隆抗体的制备及鼠单抗的人源化提供了一条有效的途径。它可以使人们在体外模拟体内抗体产生的过程，构建总抗体库，不经细胞融合，甚至不经免疫制备针对任何抗原的单克隆抗体。本文综述了该技术近年来在抗体库中的应用进展。

Staphylococcus aureusβ-hemolysin-neutralizing single-domain antibody isolated from phage display library of Indian desert camel

Objective:To isolate and characterize Staphylococcus aureus(S.aureus)β-hemolysinneutralizing dAbs from phage display library of Indian desert camel.Methods:Phage display library of 5×10 dAb clones of LPS-immunized Indian desert camel constructed in our laboratory was used for selection of S.aureus exotoxin-specific clones by panning technique.Enrichment of Ag-specific clones in successive rounds of panning was assessed by phage-ELISA and phage titration.Different dAb clones binding to S.aureus exotoxin Ags were expressed with C-terminal 6×His tag in E.coli and purified by Ni-chelate chromatography.The expression was verified by SDS-PAGE and western blotting.The purified clones were tested for inhibition of ’hot-cold’ hemolytic activity in vitro.Resistance to thermal inactivation of the dAb clones was studied by observing the effect of heat treatment from 50℃to 99℃for 30 min on the ’hot-cold’ hemolytic activity in vitro.Results:Several dAb clones binding to S.aureus exotoxins were isolated and enriched by three rounds of panning.The soluble dAb clones were approximately～16 kDa in size and reacted with 6×His tag specific murine monoclonal antibody in western blot.One of the Ni-chelate affinity purified dAb.6×His clones,inhibited S.aureusβ-hemolysin activity in vitro and resisted thermal inactivation upto 991.Conclusions:An S.aureusβ-hemolysinneutralizing dAb clone of possible therapeutic potential has been isolated.

Phage display: development of nanocarriers for targeted drug delivery to the brain

The blood brain barrier represents a formidable obstacle for the transport of most systemati- cally administered neurodiagnostics and neurotherapeutics to the brain. Phage display is a high throughput screening strategy that can be used for the construction of nanomaterial peptide libraries. These libraries can be screened for finding brain targeting peptide ligands. Surface functionalization of a variety of nanocarriers with these brain homing peptides is a sophisticated way to develop nanobiotechnology-based drug delivery platforms that are able to cross the blood brain barrier. These efficient drug delivery systems raise our hopes for the diagnosis and treatment of various brain disorders in the future.

Phage display creates innovative applications to combat hepatitis B virus

Hepatitis B virus(HBV) has killed countless lives in human history. The invention of HBV vaccines in the 20 th century has reduced significantly the rate of the viral infection. However, currently there is no effective treatment for chronic HBV carriers. Newly emerging vaccine escape mutants and drug resistant strains have complicated the viral eradication program. The entire world is now facing a new threat of HBV and human immunodeficiency virus co-infection. Could phage display provide solutions to these life-threatening problems? This article reviews critically and comprehensively the innovative and potential applications of phage display in the development of vaccines, therapeutic agents, diagnostic reagents, as well as gene and drug delivery systems to combat HBV. The application of phage display in epitope mapping of HBV antigens is also discussed in detail. Although this review mainly focuses on HBV, the innovative applications of phage display could also be extended to other infectious diseases.

Construction of Human ScFv Phage Display Library against Ovarian Tumor

In order to construct a single chain fragment variable （ScFv） phage display library against ovarian tumor, by using RT-PCR, the human heavy chain variable region genes （VH） and light chain variable region genes （VL） were amplified from lymphocytes of ovarian tumor patients and subsequently assembled into ScFv genes by SOE. The resulting ScFv genes were electrotransformed into E. coli TG1 and amplified with the co-infection of helper phage M13KO7 to obtain phage display library. The capacity and titer of the resulting library were detected. The phage antibody library with a capacity of approximately 3 × 10^9 cfu/μg was obtained. After amplification with helper phage, the titer of antibody library reached 5 μ 10^12 cfu/mL. Human ScFv library against ovarian tumor was constructed successfully, which laid a foundation for the screening of ovarian tumor specific ScFv for the radioimmunoimaging diagnosis of ovarian tumor.

Screening and Identification of a Novel Hepatocellular Carcinoma Cell Binding Peptide by Using a Phage Display Library

The purpose of this study was to screen peptides that can specifically bind to human hepatocellular carcinoma （hHCC） cells using phage display of random peptide library in order to develope a peptide-based carrier for the diagnosis or therapy of hHCC. A peptide 12-mer phage display library was employed and 4 rounds of subtractive panning were performed using the hHCC cell line HepG2 as the target. After panning, the phages that specifically bound to and internalized in hHCC cells were selected. The selected phages demonstrated highly specific affinity to HepG2 cells analyzed by ELISA and immunofluorescence analysis. 57.3% of the selected phage clones displayed repeated sequence FLLEPHLMDTSM, and 4 amino acid residues, FLEP were extremely conservative. Based on the sequencing results, a 16-mer peptide （WH-16） was synthesized. The competitive EL1SA showed that the binding of the phage clones displayed sequence FLLEPHLMDTSM to HepG2 cells was efficiently inhibited by WH-16. Our findings indicate that cellular binding of phage is mediated via its displayed peptide and the synthesized 16-mer peptide may have the potential to be a delivery carrier in target diagnosis or therapy for hHCC.

Construction of white spot syndrome virus (WSSV) whole genome phage display library

A rebuilt vector pCANTAB 5 EE was obtained by inserting a 34 bp double-stranded oligonucleotide which contained a EcoRV recognition sequence into pCANTAB 5 E. White spot syndrome virus （WSSV） genome DNA was fragmented by sonication to isolate fragments mainly in the range of 0.8 ～2.0 kb, then the fragments were blunt-ended with T4 DNA polymerase and cloned into the EcoRV site of pCANTAB 5 EE. The primary recombinant clone of the library was 3.0 × 10^5.Colony PCR of random selected recombinants showed that the size of the inserts was 0.12 ～ 1.77 kb. After the whole library recombinant phages infected Escherichia coli HB2151 cells, the extracellular and periplasmic extracts were dropped on PVDF membranes to perform dot blot, using polyclonal mouse anti-VP24 serum,anti-WSV026 serum,anti-WSV063 serum,anti-WSV069 serum,anti-WSV112 serum, anti WSV238 serum,anti-WSV303 serum and anti-VP26 serum as the primary antibody, respectively. The results showed that the display library could express the viral proteins.

Screening and Identification of a Targeting Peptide to nGLP-1R from Phage Display Peptide Library

In order to provide the structure information for designing new exendin-4 analogues, a phage display peptide library was screened by targeting the N-terminal extracellular domain of GLP-1R（nGLP-1R）. After four rounds of selection, nine sequences were obtained, four of them have higher affinity for nGLP-1R than the others. We chose two of them named X and Y peptides. Islet β-cell proliferation assay suggested that X and Y peptides didn＇t have any activity to increase islet β-cell proliferation. In other words, X and Y peptides were not agonists to GLP-1R. However, the conservative motifs of X and Y peptides provided us useful information to design new exendin-4 analogues.

Screening of TACE Peptide Inhibitors from Phage Display PeptideLibrary

Summary： To obtain the recombinant tumor necrosis factor-α converting enzyme （TACE） ectodomain and use it as a selective molecule for the screening of TACE peptide inhibitors, the cDNA coding catalytic domain （TS00） and full-length ectodomain （T1300） of TACE were amplified by RT-PCR, and the expres.sion plasmids were constructed by inserting T800 and T1300 into plasmid pET-28a and pET-28c respectively. The recombinant TS00 and T1300 were induced by IPTG, and SDS-PAGE and Western blotting analysis results revealed that TS00 and T1300 were highly expressed in the form of inclusion body. After Ni^2＋-NTA resin affinity chromatography, the recombinant proreins were used in the screening of TACE-binding peptides from phage display peptide library respectively. After 4 rounds of biopanning, the positive phage clones were analyzed by ELISA, competitive inhibition assay and DNA sequencing. A common amino acid sequence （TRWLVYFSRPYLVAT） was found and synthesized. The synthetic peptide could inhibit the TNF-α release from LPS-stimulated human peripheral blood mononuclear cells （PBMC） up to 60.3%. FACS analysis revealed that the peptide mediated the accumulation of TNF-α on the cell surface. These results demonstrate that the TACE binding peptide is an effective antagonist of TACE.

Rapid Selection of Phage Se-scFv with GPX Activity via Combination of Phage Display Antibody Library with Chemical Modification

Glutathione peroxidase（GPX） plays an important role in scavenging reactive oxygen species. A series of catalytic antibodies with GPX activity have been generated by the authors of＇ this study. To obtain humanized catalytic antibodies, the phage-displayed human antibody library was used to select novel antibodies by repetitive screening, Phage antibodies, scFv-B8 and scFv-H6 with the GSH-binding site, were obtained from the library by enzyme-linked immu- nosorbent assay（ELISA） analysis with 4 rounds of scelection against their respective haptens, S-2,4-dinitriphenyl t-butyl ester（GStI-s-DNP-Bu） and S-2,4-dinit,-iphenyl t-hexyl ester（GSH-s-I）NP-He）. Nevertheless, several studies need to be condueted to determine whether scFv-B8 and seFv-tI6 possess GPX activity. 1＇o enhance the speed of the selection, selenocysteine（Sec, the catalytic group of GPX） was incorporated directly into the phages, scFv-B8 and seFv-H6, by chemical mutation to form the phages Se-scFv-B8 and Se-scFv-H6. The GPX activities were found to be 3012 units/μmol and 2102 units/μmol, respectively. To improve the GPX activity of the phage Se-scFv-B8, DNA shuffling was used to construct a secondary library and another positive phage antibody scFv-B9 was screened out by another panning against GSH-s-DNP-Bu. When Sec was incorporated via chemical mutation into the phage antibody scFv-B9, its GPX activity reached 3560 units/μmol, which is 1.17-fold higher than the phage antibody Se-scFv-B8 and almost approached the order of magnitude of native GPX. The rapid selection is the prerequisite for generating humanized Se-seFv with GPX activity.

Cost effective filamentous phage based immunization nanoparticles displaying a full-length hepatitis B virus surface antigen

Hepatitis B virus (HBV) is one of the major causes of chronic hepatitis, cirrhosis and liver cancer. In combating HBV infections, HBV diagnosis and vaccination are therefore critical. The hepatitis B virus surface antigen (HBsAg) is a key target molecule in developing vaccines and diagnostic systems. To date, although HBsAg has been expressed in bacteria, yeasts and mammalian cells, there are still limitations in the existing ones, which leave the necessity for searching new HBsAg production methods. In this study, a simple phage display-based method was developed to produce the purified full-length HBsAg molecules for further immunization studies. For this purpose, the HBsAg coding gene was cloned into a pCANTAB5E phagemid vector and expressed on the surface of M13 filamentous phages. The HBsAg-expressing phage nanosystem was then used as immunization agent in BALB/cJ mice. The ELISA results for sera obtained from mice immunized with HBsAg-displaying phage particles revealed an immune response against HBsAg. These results demonstrate the potential use of a full-length antigen to be displayed on phages as cost effective adjuvant-free immunization agents as an alternative to the highly purified and more expensive antigens conjugated with carrier molecules.

Identification and Characterization of Peptides Binding AgEG1 from a Phage Display Library

Endoglucanases are the main cellulolytic enzymes digestion as well as its good kinetic properties make it an attractive of Anoplophora glabripennis. Their high activities in cellulose target for development of cellulase inhibitors. In this study, random pepfide phage display technology was employed to identify peptides that bound the AgEG1, a member of endoglucanase isozymes. Phage clones with peptide LPPNPTK and XPP （X is residue T, L, A or H） motif frequently occurred in the selected phage population and showed a higher phage recovery than other clones. Peptide LPPNPTK was chemically synthesized and characterized tor its binding activities to AgEG1. The synthetic peptide exhibited high specificity for AgEG1. The peptide LPPNPTK has the potential to be developed into inhibitors of the endoglucanase of A. glabripennis.

Screening of scFvs against cTnI from Phage Display Antibody Library and Their Expression in E.coli Rosetta

The single chain variable fragments of antibodies(scFvs) against cTnI were screened from the phage display antibody library by using cTnI as the target antigen. After four rounds of panning, four clones(H2, G5, A9, B9) from the phage display antibody library were verified to show higher binding affinity for cTnI by ELISA and to contain the variable region genes of the light and heavy chains of scFvs by sequencing. The variable region genes of scFvs H2 and G5 were successfully amplified by polymerase chain reactions(PCR) and cloned into expression vector pPELB and expressed as a soluble protein in E.coli Rosetta, whose expression yield was about 2% of total proteins. The expressed proteins were purified by nickel(Ni) affinity chromatography and a single band is shown in the position of 28 kDa on SDS-PAGE. The western blot analysis result verifies that the expressed scFv proteins are capable of binding with monoclonal antibodies against hexa-histidine, indicating that they are hexa-histidin-tagged aim proteins. The immunoassay demonstrates that the expressed scFv proteins are able to specifically react with cTnI molecules. The association constant(K_A) values range from 1.2×10 4 to 1.7 ×10 5 L/mol that are correspondent to the affinities of polyclonal antibodies against cTnI from rabbits. These antibodies can be valuable reagents for the immunoassay of cTnI.

Construction of a Multipurpose M13KE Phage Display System

In this study, a multipurpose M13KE phage display vector was constructed from wild-type M13KE phage for long peptide or protein display libraries without helper phage to expand the scope of targeted high-throughput screening. Based on the relationship between the structure and function of minor coat protein of wild-type MI3KE （wt-plII）, a truncated gene III （tglll） encoding minor coat protein from M13KE phage was cloned. A fusion gene fragment harboring a hw/tac promoter, signal peptide and C-terminal region sequence of gill was assembled with SOEing-PCR （splice-overlapping-extension polymerase chain reaction） method and inserted into M13KE vector. SDS-PAGE and Western blot analysis with anti-M13 pIII moneclonal antibody were employed to detect the expression of re- combinant protein, c-Myc and HA tag sequences were fused into the recombinant protein. The results showed that tglll was inserted into an unessential region of M13KE. According to the results of SDS-PAGE and Western blot with anti-M13 pIII antibody, pIII was expressed by wt-gIII and tgIII, glII harboring two tags ex- pressed both c-Myc and HA peptides using SDS-PAGE and Western blot with the corresponding monoclonal antibodies. In this study, a multipurpose M13KE phage display system was successfully constructed, which could express both short and long peptide libraries without helper phage. In future, the obtained M13KE phage display system may be used for targeted high-throughput screening of long peptide libraries without helper phage.

Phage Display Technology, Phage Display System, Antibody Library, Prospects and Challenges

Phage display technology is a unique gene recombination expression technology, and it is also a simple and effective screening tool. Through panning, a protein or peptide with high affinity and selectivity to the target is obtained. Antibody phage display has become the first and most widely used in vitro screening technology. Phage display derivatives play an important role in the diagnosis and treatment of diseases. This article reviews the phage display system of phage display technology, the size and classification of antibody libraries and their applications, and discusses the application prospects and challenges of phage display technology. This thesis lays the foundation for the theoretical and experimental research of bacteriophages.

MAPPING EPITOPES OF HUMAN PAPILLOMAVIRUS TYPE 16 L1 PROTEIN WITH A PHAGE DISPLAY EPITOPE LIBRARY

The objective of this study is to map epitopes on HPMAPV16 L1 protein and provide information to the design of HPV16 prophylactic peptide vaccine. The epitopes on L1 protein were screenedby polyclonal and two monoclonal antibodies (BS and F4G3) against RPV16 L1 protin from a 6-merfd phage display epitope library with the method or immuuo-afrinity screening (Biopauuing). Aferthree rounds or Bio-Panning, the Positive phages were detected by L1 antibodies again with ELISA.The positive phages reacted strongly with L1 antibodies were then identified by DNA sequencing.Three mimotopes have been screened by polycloual and two monoclonal antibodies. The mimotope(LSLFSC) reacted with mouoclonal antibody B8 showed 50% pomology with the sequence 270275a. a (DSLFFY) of prototype HPV16 L1. Another mimotope (LTSSYS) reacted with polyclonalantibodies had 66% pomology with the L1 sequence 516~521a. A(TTSSTS), also a mimotope (DRWDRF) was found had the bomologic RF with the known L1 sequence 441 ~446a. a. The mimotopesLSLFSC and DRWDRF were adjacent to the epitopes at 267~269a. a and 422~441 a. a reported byother researchers Previously. Our results suggest that there might be a batch of epitopes on HPV16L1 ppotein, and the predominant epitopes of HPV16 L1 protein are located in the above two domains. These results will be helpful for design or HPV16 prophylactic peatide vaccines and HPVpolyvalent vaccines.

Application of M13 Phage Coat Proteins

M13 phage＇is a filamentous bacteriophage containing a circular single-stranded DNA molecular, which is surrounded by approximately 2 800 copies of protein PVIII. In addition, there are five copies of each of proteins PVII and PXI in one end, and five copies of each of proteins PVI and PUI on the other. These coat proteins have play an important role in the infection and assembly of M13 phage. With the development of phage display technology, these five coat proteins all can be used in phage display, which plays an increasingly important role in molecular detection and treatment.

Use of LPS Extracts to Validate Phage Oligopeptide That Binds All <i>Salmonella enterica</i>Serovars

Phage Display technology provides a mechanism for us to make bio-recognition elements on biosensors for detection of Salmonella enterica serovars. In the procedure, the filamentous M13 bacteriophage is used for acquiring peptides that have a high affinity for the target recognition. Our approach in this study was to develop peptide structures in the pIII region of this thread-shaped virus. A phage pIII library was used to perform biopanning for the phage clones to bind the target Salmonella serovars. The clones were bound, washed, eluted and amplified four times. Then, the phage peptides were sequenced tested for specificity using ELISA procedures. In this project to make a biosensor for all relevant Salmonella enterica serovars, we used common LPS salmonellae antigens as targets in the biopanning procedure. This enabled us to have a phage probe specific for all serovars of Salmonella enterica excluding the typhoid organisms. The final phage was then immobilized onto an electromagnetic platform to complete the biosensor, which gives us the real-time ability to measure resonance changes that indicate mass loading. The mass loading is an indication of binding to the target cells. Our current data with an ELISA procedure show the phage probe’s high affinity for salmonellae, very low cross-reactivity with Escherichia coli, Shigella, and no cross-reactivity to Staphylococcus aureus and Listeria monocytogenes. The biosensor with the phage showed that the capture ability for Salmonella serovars is thirty times higher than the control sensor. This biosensor is a candidate for detection of Salmonella in food and other settings.

A resistin binding peptide selected by phage display inhibits 3T3-L1 preadipocyte differentiation

Background Resistin, a newly discovered cysteine-rich hormone secreted mainly by adipose tissues, has been proposed to form a biochemical link between obesity and type 2 diabetes. However, the resistin receptor has not yet been identified. This study aimed to identify resistin binding proteins/receptor. Methods Three cDNA fragments with the same 11 bp 5＇ sequence were found by screening a cDNA phage display library of rat multiple tissues. As the reading frames of the same 11 bp 5＇ sequence were interrupted by a TGA stop codon, plaque lift assay was consequently used to prove the readthrough phenomenon. The stop codon in the same 11 bp 5＇ sequence was replaced by tryptophan, and the binding activity of the coded peptide [AWIL, which was designated as resistin binding peptide （RBP）] with resistin was identified by the confocal microscopy technique and the affinity chromatography experiment, pDual GC-resistin and pDual GC-resistin binding peptide were co-transfected into 3T3-L1 cells to confirm the function of resistin binding peptide. Results Three cDNA fragments with the same 11 bp 5＇ sequence were found. The TGA stop codon in reading frames of the same 11 bp 5＇ sequence was proved to be readthroughed. The binding activity of RBP with resistin was consequently identified. The expression of the resistin binding peptide in 3T3-L1 preadipocytes expressing pDual G-C-resistin significantly inhibited the adipogenic differentiation. Conclusion RBP could effectively rescue the promoted differentiation of resistin overxepressed 3T3-L1 preadipocyte.