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.

Mimotope peptides selected from phage display combinatorial library by serum antibodies of pigs experimentally infected with Taenia solium as leads to developing diagnostic antigens for human neurocysticercosis.

Neurocysticercosis is caused by penetration of the tapeworm Taenia solium larvae into the central nervous system resulting in a diverse range of neurologic complications including epilepsy in endemic areas that globalization spreads worldwide. Sensitive and specific immunodiagnosis is needed for the early detection and elimination of the parasite, but the lack of standardized, readily obtainable antigens is a challenge. Here, we used the phage display for resolving the problem. The rationale of the strategy rests on the concept that the screening of combinatorial libraries with polyclonal serum to pathogens reveals families of peptides mimicking the pathogen most immunodominant epitopes indispensable for the successful diagnosis. The screening of a 7mer library with serum IgG of four pigs experimentally infected with parasite followed by computer aided segregation of the selected sequences resulted in the discovery of four clusters of homologous sequences of which one presented a family of ten mimotopes selected by three infected pig serum IgGs; the common motif sequence LSPF carried by the family was considered to be the core of an immunodominant epitope of the parasite critical for the binding with the antibody that selected the mimotopes. The immunoassay testing permitted to select a mimotope whose synthetic peptide free of the phage with the amino acid sequence Leu-Ser-Fen-Pro-Ser-Val-Val that distinguished well a panel of 21 cerebrospinal fluids of neurocysticercosis patients from the fluids of individuals with neurological complications of other etiology. This peptide is proposed as a lead for developing a novel molecularly defined diagnostic antigen(s) for the neurocysticercosis.

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.

Immunogenic peptides from phage display libraries with potential of protecting mice against the Pseudorabies virus.

Phage display selection of combinatorial peptide libraries has demonstrated its almost unlimited potential in identifying binding ligands for many targets. The method shows promise for selection of immunogenic peptides against pathogens by antibodies. We have undertaken a study designed to select such mimics for one of the representatives of Herpesviridae, the Pseudorabies virus (PrV), infecting pigs and causing severe neurological complications known as Aujeszky's disease. By screening a 12mer linear and a 7mer cysteine-constrained libraries with immunoglobulins of a rabbit immunized with the virus, a family of 10 antigenic and immunogenic peptides was derived sharing a sequence motif K(L/P/V)GDP(R/K/L). Groups of six C57BL/6 mice were immunized with bacteriophages expressing peptides with this motif sequences. Some of the mice were found to be positive in seroneutralization assay; in a challenge setting, all but two immunized mice survived, albeit presenting some disease symptoms. We discuss the perspectives and limits of generating peptide leads by library screening with immune polyclonal antiserum for designing pure epitope-based vaccines to PrV in the future.

Phage display identifies two Caprine Arthritis Encephalitis Virus env epitopes.

Using phage display and IgG of a goat infected with Caprine Arthritis Encephalitis Virus (CAEV) we obtained families of 7 mer constrained peptides with consensus motifs LxSDPF/Y and SWN/KHWSY and mapped the epitopes mimicked by them at the Env 6-LISDPY-11 and 67-WNTYHW-72 sites of the mature gp135 amino acid sequence. The first epitope fell into the N-terminal immunogenic aa1-EDYTLISDPYGFS- aa14 site identified previously with a synthetic peptide approach; the second epitope has not been described previously. The first epitope is mostly conserved across CAEV isolates whereas the second newly described epitope is extremely conserved in Small Ruminant Lentiviruses env sequences. As being immunodominant, the epitopes are candidate targets for mimotope-mediated diagnosis and/or neutralization.

Constrained peptide models from phage display libraries highlighting the cognate epitope-specific potential of the anti-HIV-1 mAb 2F5.

The monoclonal antibody 2F5 (mAb 2F5), one of the most potent broadly neutralizing mAbs targeted to the HIV-1 gp41 membrane proximal exterior region (MPER), displays an unusually wide antigenic specificity, tolerating amino acid substitutions at virtually all positions of the 662-ELDKWAS-668 epitope sequence when presented by peptides. Investigating this phenomenon, Menendez et al. [22] concluded that the paratope of 2F5 contains two distinct binding compartments. One is specific and binds the DKW epitope core; the other is multi-specific and binds to the flanking DKW regions that can be distinct from the epitope sequence. Because the DKW-flanking amino acids are strongly conserved in viruses, it is not clear whether the DKW only satisfies the 2F5 epitope recognition demand. In this study, we demonstrate that the specificity of recognition of the epitope depends on the structural context in which the cognate epitope sequence is presented. The antibody does not tolerate any replacements of the DKW-flanking epitope amino acids and binds exclusively to the (L)DKWA sequence provided that it is presented by a 7-mer constrained peptide exposed by the M13 phage pIII protein. Our data propose a novel epitope recognition model in which the 2F5 mAb requires a sequence longer than DKW and no substitution of flanking amino acids for specific recognition of the peptide. Additionally, immunization data supports the notion that the binding and neutralizing immunogenic structural features of the described epitope model do not coincide.

Collection of phage-peptide probes for HIV-1 immunodominant loop-epitope.

Early diagnosis and prevention of human immunodeficiency virus type-1 (HIV-1) infection, which remains a serious public health threat, is inhibited by the lack of reagents that elicit antiviral responses in the immune system. To create mimotopes (peptide models of epitopes) of the most immunodominant epitope, CSGKLIC, that occurs as a loop on the envelope gp41 glycoprotein and is a key participant in infection, we used phage-display technology involving biopanning of large random libraries with IgG of HIV-1-infected patients. Under the conditions used, library screening with IgG from patient serum was directed to the CSGKLIC epitope. Three rounds of selection converted a 12 mer library of 10(9) sequences into a population in which up to 79% of phage bore a family of CxxKxxC sequences ("x" designates a non-epitope amino acid). Twenty-one phage clones displaying the most frequently selected peptides were obtained and were shown to display the principal structural (sequence and conformational), antigenic and immunogenic features of the HIV-1 immunodominant loop-epitope. Notably, when the mixture of the phage mimotopes was injected into mice, it induced 2- to 3-fold higher titers of antibody to the HIV-1 epitope than could be induced from individual mimotopes. The described approach could be applicable for accurately reproducing HIV-1 epitope structural and immunological patterns by generation of specialized viral epitope libraries for use in diagnosis and therapy.

Immunology of scorpion toxins and perspectives for generation of anti-venom vaccines.

Scorpions and other venomous animals contain concentrates of biologically active substances developed to block vital physiological and biochemical functions of the victims. These have contrasting human health concerns, provide important pharmacological raw material and pose a serious threat to human life and health in tropical and subtropical regions. Because only occasional and minor quantities of venom are introduced into the human organism with a scorpion sting and their mortal effect is an acute phenomenon these substances are unknown to the immune defense system and thus no immunity has appeared against them during evolution. Antidotes prepared from animal anti-sera are effective against some species of scorpions but depend on the manufacturer and the availability of product to the medical community. Although significant progress has been made in immunological studies of certain groups of toxins, few centers are dedicated to this research. Information is still insufficient to generate a comprehensive picture of the subject and to propose vaccines against venoms. A novel approach based on mimotopes selected from phage-displayed random peptide libraries show potential to impel further progress of toxin immunological studies and to provide putative vaccine resources. In this report we revise the "state of the art" in the field.

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.