HIV-1 V3 loop crown epitope-focused mimotope selection by patient serum from random phage display libraries: implications for the epitope structural features.

The crown region of the V3 loop in HIV-1 that contains the conserved amino acid sequence GPGR/G is known as the principal neutralizing determinant due to the extraordinary ability of antibodies to this region to neutralize the virus. To complement the existing peptide models of this epitope, we describe a family of 18 phage-displayed peptides, which include linear 12mer and constrained 7mer peptides that was selected by screening random libraries with serum from HIV-1 subtype B-infected patients. The 7mer constrained peptides presented two conserved amino acid sequences: PR-L in N-terminus and GPG in the C-terminus. On the basis of these peptides we propose a mimotope model of the V3 crown epitope in which the PR-L and GPG sequences represent the two known epitope binding sites. The GPG, has the same function as the V3 crown GPGR sequence but without the involvement of the "R" despite its being considered as the signature of the epitope in B-subtype viruses. The PR-L contains a proline not existing in the epitope that is postulated to induce kinks in the backbones of all peptides and create a spatial element mimicking the N-terminal conformationally variable binding site. Rabbit serum to these mimotopes recognized the V3 peptides and moderately decreased the fusion between HIV-1 Env- and CD4-expressing Jurkat cells. This study proposes the efficient generation by means of patient sera of V3 epitope mimics validated by interaction with the antibodies to contemporary viruses induced in patients. The serum antibody-selectable mimotopes are sources of novel information on the fine structure-function properties of HIV-1 principal neutralizing domain and candidate anti-HIV-1 immunogens.

Synthetic peptide-targeted selection of phage display mimotopes highlights immunogenic features of α-helical vs non-helical epitopes of Taenia solium paramyosin: implications for parasite- and host-protective roles of the protein.

Paramyosin of the pig-human parasite Taenia solium (TPmy) is a α-helical protein located on the worm surface that is suggested to fulfill an immunomodulatory role protecting the parasite against host immune system. Besides, in challenging experiments the protein shows a vaccine potential. These observations imply that TPmy harbors antigenic determinants for each of these contrasting actions. However the suggestion was not given a support from experimental data because respective epitopes have not been described thus far. To circumvent this difficulty, we use synthetic peptides with sequences of regions composed of α-helical or linear structure to induce rabbit antibody responses for phage-display mapping of epitope core amino-acid sets. Antibodies to α-helical regions were weak binders and M13 phage-displayed peptides selected by them from two different libraries exhibited no amino-acid similarities with the original protein site. In contrast, the antibodies produced in response to non-helical segment within α-helical structure were better binders and selectors of perfect structural mimics of the protein site. This first phage display epitope analysis of TPmy supports the notion that the rod-like α-helix, which encompasses over 90% of the total amino acids, may serve as an immunomodulatory shield that protects the parasite. Further, the seven non-helical segments of the TPmy molecule may represent the only anti-parasite discrete immunogenic epitopes whose representative mimotopes can be utilized in development of pure epitope vaccines.

Potential of peptides selected from random phage-displayed libraries to mimic conformational epitopes: a study on scorpion toxin Cn2 and the neutralizing monoclonal antibody BCF2.

Many conformational epitopes cannot be mapped by the use of a phage display approach due to the lack of amino acid similarity with the selected peptides. Exploring the potential of the method, we selected mimotopes of the discontinuous, highly conformational epitope of scorpion neurotoxin Cn2, whose 3D structure is known, using its generic neutralizing monoclonal antibody BCF2. With an exhaustive selection procedure, we isolated from a 12-mer phage library a large collection of mimotopes that reproduce the antigenic and immunogenic specificity of the Cn2-epitope. The selected peptides presented three sequence motifs, the most abundant of which, RD(N)XXGF, appeared in 15 different sequence contexts displayed by 97 out of 206 clones. In the most reactive mimotope, displayed by 24 (25%) clones, the motif was flanked by two Cys residues allowing the adoption of a cyclic conformation. Motifs QL(H,M)L(M) and (S/T)WHLP were selected with less efficiency. Comparison of the motifs with the primary and three-dimensional structure of Cn2 as well as with a model of the Cn2-BCF2(Fv) complex suggests that RD(N)XXGF, which does not share sequence similarity with the epitope, mimics its central structural element, turn 7-11, by using an alternative amino acid combination nevertheless keeping the nature of its interactions with BCF2. The QL(H,M)L(M) is assumed to mimic the hydrophobic part of the epitope. The principles of the conformational mimicry by phage-displayed peptides are discussed.

Molecular localization and crossreactivity of two epitopes of noxiustoxin from scorpion Centruroides noxius, identified by a panel of monoclonal antibodies and peptide mimotopes.

Mimotopes derived from peptide phage display libraries may reproduce basic functions of epitopes including their antigenicity. In case of toxins, this property makes phage displayed mimotopes highly specific vaccine components free of the toxicity. To explore the potential of mimotopes for vaccine development, their ability of substituting the whole toxin molecule deserves a detailed characterization. We used mimotopes of noxiustoxin (NTX), a neurotoxin from scorpion Centruroides noxius, for studying its epitopes recognized by a panel of six monoclonal antibodies (mAbs), as well as their crossreactivity with homologous toxins from other species of the Centruroides genus. Although competitive (displacement) immunoassay showed that all six mAbs inhibit each other for binding to whole NTX molecule, the mimotopes used as specific probes allowed separation of the mAbs into two functional groups recognizing distinct non-overlapping epitopes mapped on the opposite sites of the three-dimensional structure of the toxin. The use of mimotopes permitted a precise specificity analysis of a panel of antibodies raised against this toxin, that may be very important for immunological characterization of other scorpion toxins and for vaccine development.