"Affinity maturation" of ligands for HCV-specific serum antibodies

Identification of peptide mimotopes of Trypanosoma brucei gambiense variant surface glycoproteins

Background

The current antibody detection tests for the diagnosis of gambiense human African trypanosomiasis (HAT) are based on native variant surface glycoproteins (VSGs) of Trypanosoma brucei (T.b.) gambiense. These native VSGs are difficult to produce, and contain non-specific epitopes that may cause cross-reactions. We aimed to identify mimotopic peptides for epitopes of T.b. gambiense VSGs that, when produced synthetically, can replace the native proteins in antibody detection tests.

Methodology/Principal Findings

PhD.-12 and PhD.-C7C phage display peptide libraries were screened with mouse monoclonal antibodies against the predominant VSGs LiTat 1.3 and LiTat 1.5 of T.b. gambiense. Thirty seven different peptide sequences corresponding to a linear LiTat 1.5 VSG epitope and 17 sequences corresponding to a discontinuous LiTat 1.3 VSG epitope were identified. Seventeen of 22 synthetic peptides inhibited the binding of their homologous monoclonal to VSG LiTat 1.5 or LiTat 1.3. Binding of these monoclonal antibodies to respectively six and three synthetic mimotopic peptides of LiTat 1.5 and LiTat 1.3 was significantly inhibited by HAT sera (p<0.05).

Conclusions/Significance

We successfully identified peptides that mimic epitopes on the native trypanosomal VSGs LiTat 1.5 and LiTat 1.3. These mimotopes might have potential for the diagnosis of human African trypanosomiasis but require further evaluation and testing with a large panel of HAT positive and negative sera.

The control of human African trypanosomiasis or sleeping sickness, a deadly disease in sub-Saharan Africa, mainly depends on a correct diagnosis and treatment. The aim of our study was to identify mimotopic peptides (mimotopes) that may replace the native proteins in antibody detection tests for sleeping sickness and hereby improve the diagnostic sensitivity and specificity. We selected peptide expressing phages from the PhD.-12 and PhD.-C7C phage display libraries with mouse monoclonal antibodies specific to variant surface glycoprotein (VSG) LiTat 1.3 or LiTat 1.5 of Trypanosoma brucei gambiense. The peptide coding genes of the selected phages were sequenced and the corresponding peptides were synthesised. Several of the synthetic peptides were confirmed as mimotopes for VSG LiTat 1.3 or LiTat 1.5 since they were able to inhibit the binding of their homologous monoclonal to the corresponding VSG. These peptides were biotinylated and their diagnostic potential was assessed with human sera. We successfully demonstrated that human sleeping sickness sera recognise some of the mimotopes of VSG LiTat 1.3 and LiTat 1.5, indicating the diagnostic potential of such peptides.

Phage display selection, analysis, and prediction of B cell epitopes

Combinatorial phage display libraries of random peptides can be used to discover the epitopes of antibodies through a procedure termed "biopanning." The affinity isolation of phage-displayed epitope peptidomimetics allows molecular definition of the epitopes of monoclonal antibodies (MAbs). Panels of MAb-specific peptides allow computational prediction of B cell epitopes. Epitope profiles recognized by polyclonal serum samples can also be generated. Detailed step by step protocols and discussion of applications are provided.

Phage display selection and analysis of Ab-binding epitopes

The identification and characterization of B cell epitopes by combinatorial phage display peptide analyses is based on the principle that unique peptides can be affinity-purified from an enormous collection of random peptides. Moreover, once selected, the peptide sequence can be elucidated; filamentous bacteriophages have been genetically engineered to incorporate the DNA template corresponding to the peptide displayed on its surface. This unit begins with a discussion of some of the factors that distinguish available libraries. Protocols are then provided for affinity selection of antibody-specific phages, determination of phage titer, confirmation and amplification of positive phages, phage characterization, and construction of custom-tailored phages. The selection protocol in this unit is specific and designed for libraries that are used in the authors' laboratory and are based on the fth1 or fd-tet derived vectors. However, information is included for adapting these protocols to the specific requirements of other phage display libraries.

Selection of novel nickel-binding peptides from flagella displayed secondary peptide library

Nickel (Ni) performs its biological or toxic functions in nickel-protein coordination form. Novel Ni-binding peptides were isolated from a random dodecapeptide library displayed on the flagella of Escherichia coli against immobilized ions. On the basis of isolated sequences rich in histidine residues, two secondary libraries were constructed respectively. By consequent selection, more Ni-chelating peptides were identified and the consensus motif RHXHR (where X was always H) was deduced. The result suggested that not only histidine, but also arginine, play an important role in Ni-binding. Furthermore, two selected clones (1035 and 2022) were chosen for further identification. They exhibited similar relative binding affinity, which was about nine times that of the original library derived clones and statistically much more significant than the positive control with polyhistidine insert. Free nickel ions could almost completely inhibit the binding of the clones 1035 and 2022 to immobilized nickel, implicating that the peptides were able to chelate nickel ions. These studies reveal that bacterial surface displayed peptide libraries may have promising future potential for the development of metal bioadsorbents. Furthermore, novel Ni-binding peptides may provide lead molecules for Ni-chelation and applications thereof.

Importin beta: a novel autoantigen in human autoimmunity identified by screening random peptide libraries on phage

By screening random peptide libraries (RPLs) with sera of Type 1 diabetes (T1D) patients, we previously identified 5 disease-specific 'mimotopes' displayed on phages (phagotopes). We already characterised 1 phagotope (CH1p), as an epitope of human osteopontin, an autoantigen expressed within the somatostatin cells of human islets. In this paper, we report the characterization of the second phagotope, 195Dyn, by immunohistochemistry, Western Blotting and screening of a human islet cDNA library using rabbit anti-195Dyn antibodies. The 195Dyn mimotope was detected in human islets. The screening of a lambdagt11 cDNA library from human islets has identified a clone, which corresponded to human importin beta. ELISA detected autoantibodies against this protein in sera of around 60% of TD1 patients and in 30% of patients affected by other autoimmune diseases. In summary, RPLs technology proved again successful in identifying another novel autoantigen (importin beta), whose significance in the autoimmune process remains to be fully elucidated.

Bioactive peptides from libraries

New ligands for a variety of biological targets can be selected from biological or synthetic combinatorial peptide libraries. The use of different libraries to select novel peptides with potential therapeutic applications is reviewed. The possible combination of molecular diversity provided by combinatorial libraries and a rational approach derived from computational modeling is also considered. Advantages and disadvantages of different approaches are compared. Possible strategies to bypass loss of peptide bioactivity in the transition from ligand selection to in vivo use are discussed.

Characterization of mimotopes mimicking an immunodominant conformational epitope on the hepatitis C virus NS3 helicase

The hepatitis C virus (HCV) nonstructural 3 (NS3) protein is composed of an amino terminal protease and a carboxyl terminal RNA helicase. NS3 contains major antigenic epitopes. The antibody response to NS3 appears early in the course of infection and is focused on the helicase region. However, this response cannot be defined by short synthetic peptides indicating the recognition of conformation-dependent epitopes. In this study, we have screened a dodecapeptide library displayed on phage with anti-NS3 mouse monoclonal antibodies (mAbs) that compete with each other and human anti-HCV NS3 positive sera. Two peptides (mimotopes) were selected that appeared to mimic an immunodominant epitope since they were recognized specifically by the different anti-NS3 mAbs of the study and by human sera from HCV infected patients. Homology search between the two mimotopes and the NS3 sequence showed that one of the two peptides shared amino acid similarities with NS3 at residues 1396-1398 on a very accessible loop as visualized on the three-dimensional structure of the helicase domain whereas the other one had two amino acids similar to nearby residues 1376 and 1378. Reproduced as synthetic dodecapeptides, the two mimotopes were recognized specifically by 19 and 22, respectively, out of 49 sera from HCV infected patients. These mimotopes allowed also the detection of anti-NS3 antibodies in sera of HCV patients at the seroconversion stage. These results suggest that the two NS3 mimotopes are potential tools for the diagnosis of HCV infection.

Selection of phage-displayed peptides recognised by monoclonal antibodies directed against the lipopolysaccharide of Brucella

Panning and screening of various phage display libraries with monoclonal antibodies (mAbs) directed against the O-chain of the lipopolysaccharide (LPS) of Brucella sp. allowed the identification of peptidic mimotopes of some O-chain epitopes. Four mAbs were tested. The A76-12G12 mAb, which is specific for LPS of all strains of Brucella, either A- or M-dominant, did not yield any peptidic mimotope, despite a specific yield enrichment during the rounds of panning. The B66-4F9 mAb, that recognises an epitope common to both Brucella sp. and Yersinia enterocilitca O:9 strains, allowed the selection of only one phage clone that was shown to be an antigenic but not immunogenic mimotope. The B66-2C8 and A15-6B3 mAbs, respectively, specific for the LPS of A-dominant and M-dominant Brucella sp., yielded several sequences, which allowed the determination of consensus sequences. These consensus will be of high interest for the construction of second generation libraries. For the best binding peptides, competition with LPS for the binding to the mAb is detected, which suggests that the peptides bind to the paratope of the mAb. The phages selected from the libraries were used to immunise mice, and a weak antibody response directed against LPS has been observed for some peptides. These data suggest that a subset of the selected peptides are immunogenic mimotopes of the LPS epitopes.

The intracellular antibody capture technology (IACT): towards a consensus sequence for intracellular antibodies

We describe the application of an intracellular antibody capture technology (IACT) as a generic in vivo selection procedure for isolating intracellular antibodies or ICAbs. IACT was applied to the de novo selection of functional ICAbs against the microtubule-associated protein TAU, found in neurofibrillary lesions of Alzheimer's disease brains. A panel of 17 different ICAbs was created which bind TAU inside cells and the epitopes recognized by the selected ICAbs have been determined by an in vivo epitope mapping procedure. Finally, sequence analysis showed that the IACT-derived ICAbs are characterized by a common signature of conserved amino acid residues, suggesting that the IACT naturally selects a sort of "captured consensus sequence" for intracellular antibodies. The development of IACT, together with the possibility of scaling up in a high throughput and automated format, makes IACT a new enabling tool for target validation in functional genomics and global proteomics.

Targeted gene transduction of mammalian cells expressing the HER2/neu receptor by filamentous phage

Screening a random peptide library displayed on phage as fusion to the major capsid protein pVIII identified a ligand binding the human epidermal growth factor receptor 2 (HER2) specifically. By mutating the sequence of this ligand, a "secondary" library was generated, whose panning on HER2-positive cells isolated a phage-borne peptide with increased specific binding to HER2 (phage NL1.1). The same peptide recognised HER2 specifically when expressed as an N-terminal fusion to the minor coat protein pIII. Phage NL1.1 was engineered to include a mammalian expression cassette for a reporter gene within its genome. This modified phage transduced HER2-expressing cells with very high specificity (more than 1000-fold that of parental HER2-negative cells) and with an efficiency comparable to that of chemical transfection protocols. The gene delivery process was remarkably fast, requiring less than 15 minutes incubation of phage with target cells to generate detectable levels of gene expression.

Dissection of the humoral immune response toward an immunodominant epitope of HIV: a model for the analysis of antibody diversity in HIV+ individuals

Understanding the dynamics of the humoral immune response to HIV epitopes in the presence of genetic drift and antigenic variation of the virus may reveal critical elements of protective immunity against HIV. Analysis of antibody maturation and diversity is difficult to study at the molecular level in humans. We used a combinatorial phage display peptide library to elucidate antibody diversity in HIV-infected individuals to a single immunodominant epitope in gp41. A serum sample derived from an HIV+ individual was used to screen a phage display a 12 mer cysteine-constrained loop peptide library. In doing so, we isolated mimotope-presenting phages corresponding to the immunodominant gp41 epitope CSGKLIC (residues 603-609). The mimotopes and control phages expressing epitope variants were reacted with a panel of 30 HIV+ sera. The patients showed distinct and variable recognition patterns compared with one another. Subfractions of the polyclonal sera were affinity purified and analyzed for epitope specificities. These analyses illustrated that epitope variants can be used to decipher antibody diversity. Elucidation of the plasticity of the humoral response and its polyclonality toward discrete epitopes contributes to our understanding of the antibody maturation process in individuals infected with viruses such as HIV.

ADAM-HCV, a new-concept diagnostic assay for antibodies to hepatitis C virus in serum

We screened phage libraries using sera from noninfected individuals and patients infected by hepatitis C virus (HCV). By applying different selection and maturation strategies, we identified a wide collection of efficient phage-borne ligands for HCV-specific antibodies. The selected ligands retained their antigenic properties when expressed as multimeric synthetic peptides. Peptides that mimic several immunodominant epitopes of the virus were used to develop a novel type of diagnostic assay which efficiently detects antibodies to HCV in serum. This type of analysis provides a conclusive diagnosis for many patients identified as indeterminate according to presently available serological assays.