All-D peptides recognized by an anti-carbohydrate antibody identified from a positional scanning library.

Monoclonal antibodies recognize antigens with high affinity and specificity, but the structural basis for molecular mimicry remains unclear. It is often assumed that cross-reactive antigens share some structural similarity that is specifically recognized by a monoclonal antibody. Recent studies using combinatorial libraries, which are composed of millions of sequences, have examined antibody cross-reactivity in a manner entirely different from traditional epitope mapping approaches. Here, peptide libraries were screened against an anti-carbohydrate monoclonal antibody for the identification of peptide mimics. Positional scanning libraries composed of all-l or all-d hexapeptides were screened for inhibition of monoclonal antibody HGAC 39.G3 binding to an antigen displaying N-acetyl-d-glucosamine (GlcNAc) residues on a polyrhamnose backbone. Inhibitory activity by mixtures from the all-d hexapeptide library was greater than the activity from the all-l libraries. The most active d-amino acid residues defined in each of the six positions of the library were selected to prepare 27 different individual hexapeptides. The sequence Ac-yryygl-NH2 was specifically recognized by mAb HGAC 39.G3 with a relative affinity of 300 nM when measured in a competitive binding assay. The contributions to overall specificity of the residues of the all-d peptide (Ac-yryygl-NH2) in binding to mAb HGAC 39.G3 were examined with a series of truncation, l and d-amino acid substitution, and retro analogs. Dimeric forms of the all-d peptide were recognized with tenfold to 100-fold greater affinities relative to the monomer. The all-d peptide was found to inhibit mAb HGAC 39.G3 binding to an anti-idiotype antibody with approximately 1000-fold greater affinity than GlcNAc. As demonstrated here, the study of immune recognition using combinatorial chemistry may offer new insights into the molecular basis of cross-reactivity.

Characterization of antigen-antibody interactions using single substitution analogs and mixture-based synthetic combinatorial libraries.

In an effort to use monoclonal antibodies (mAbs) as selective probes for early detection of breast cancer, the specificities of a number of antipeptide mAbs have been studied at the individual amino acid level using single substitution peptide analogs and peptide combinatorial libraries. In this study, the mapping results are presented for mAb172-12A4, which was raised against the haptenic peptide LGSGAFGTIYKG(C), corresponding to residues 138-149 of the oncogene v-erbB. This peptide is homologous with a region in epidermal growth factor receptor (EGFR) and human oncogene c-erbB-2, and contains the ATP binding motif that is common among protein kinases. The substitution profile of this interaction correlated well with the results from the screening of hexa- and decapeptide positional scanning libraries. Based on the results of this mAb's specificity for the antigenic determinant (-AFGTIYK-), proteins that have sequence homology were found from a database search of human sequences. Thirty-two unique peptide sequences, a majority of which was from protein kinases, were synthesized and tested for recognition by mAb 172-12A4. Eleven peptides had activities that differed from the original peptide by less than an order of magnitude, and the activities for 29 of the 32 (90%) could be accurately predicted based on the individual substitution analog results. While both epitope mapping approaches address the amino acid level of mAb specificity, positional scanning libraries offer an advantage of identifying the positional importance of each antigenic determinant residue without any prior knowledge of the mAb's specificity. The fine specificity mapping of peptide-specific mAbs using the synthetic tools illustrated here will be useful for the development of immunodiagnostics that detect cancer-related proteins in clinical samples.

Exploring antibody polyspecificity using synthetic combinatorial libraries.

Extensive mapping studies for seven antigen-antibody interactions have been carried out using both individual analogs and peptide libraries. With competitive ELISA, these studies have revealed that monoclonal antibodies exhibit a broad range of specificities, from antibodies that recognize only conservative substitutions for 1-2 positions of the antigenic determinant, to antibodies that recognize sequences that are completely unrelated to the parent antigen with comparable affinities. Synthetic combinatorial libraries, containing millions of peptide sequences, permit a more systematic and rapid evaluation of the extent of multiple-binding specificities of monoclonal antibodies than individual analogs. The peptide libraries used here comprise mixtures of compounds having specifically defined positions and mixture positions. The same diversity of sequences in different formats, which differ by the numbers of positions singularly defined and different locations defined within the sequence, can be examined. Comparison of the screening results, selection criteria of the most active mixtures, and different approaches used for the deconvolution of active individual compounds are discussed. Synthetic combinatorial libraries greatly facilitate the understanding of antigen-antibody interactions at the amino acid level and will assist in the development of improved immunodiagnostics.

Mapping the detailed specificity of a calcium-dependent monoclonal antibody through the use of soluble positional scanning combinatorial libraries: identification of potent calcium-independent antigens.

The detailed specificity of monoclonal antibody M1, which has been reported to bind in a calcium-dependent manner to the 'FLAG' sequence DYKDDDDK-NH2, was examined using soluble hexa- and decapeptide positional scanning synthetic combinatorial libraries (PS-SCLs) made up of 52 x 10(6) and 4 x 10(12) different sequences, respectively. To study the influence of calcium on the specificity of this antigen-antibody interaction, each PS-SCL was screened in the presence and absence of calcium using a competitive ELISA. Overall, peptide mixtures had greater inhibitory activity against mAb M1 binding to FLAG in the absence of calcium. A total of 16 individual hexapeptides were identified, all of which contained the motif-DYK_K_(-), and were recognized by mAb M1 in the absence of calcium with 50- to 100-fold higher affinity than the FLAG octapeptide (IC50 = 273 nM). On average, the same set of peptides bound 10-fold less effectively in the presence of calcium. Upon screening the decapeptide PS-SCL in the absence of calcium, lysine was also more active in the fifth position than the original aspartic acid. Based on the screening results, 24 individual decapeptides were prepared and were found to have activities 10- to 100-fold higher than the FLAG octapeptide in the absence of calcium. The specificity of lysine at the fifth position in the antigen-antibody interaction was further examined by synthesizing and assaying substitution analogs at this position for the octapeptide and hexapeptide forms of the FLAG sequence, as well as for two hexapeptides identified from the PS-SCL. Truncation analog analysis was also carried out on the FLAG octapeptide to determine optimal antigen length for antibody binding. Overall, lysine at the fifth position could be substituted with ornithine with no significant loss in activity, and peptide length was not a critical factor for antibody binding in the absence of calcium. Also, the octapeptide having lysine at the fifth position in place of the aspartic acid had the same activity in the presence or absence of calcium. This study demonstrates the ease and effectiveness of PS-SCLs over individual peptide analogs for the examination of the degree of cross-reactivity for a given monoclonal antibody as well as for the identification of novel, high-affinity peptides.

Two antipeptide monoclonal antibodies that recognize adhesive sequences in fibrinogen: identification of antigenic determinants and unrelated sequences using synthetic combinatorial libraries.

The fine specificity of two different monoclonal antibodies raised against synthetic peptides, each representing one of the two Arg-Gly-Asp (RGD) sequences in fibrinogen, was examined using synthetic combinatorial libraries (SCLs). The monoclonal antibodies (mAb), mAb LJ-134B/29 and mAb LJ-155B/16, recognize both the immunogenic peptide and native fibrinogen. The specificity of mAb LJ-134B29 was mapped using hexa- and decapeptide positional scanning SCLs (PS-SCLs) and competitive ELISA. The most active amino acids at each position of the two libraries were identified from a single screening. Individual hexa- and decapeptides were synthesized and assayed to determine their binding affinities. The 16 individual hexapeptides represented single and multiple substitutions of the antigenic determinant sequence, -GDSTFE-, eight of which had affinities less than 10nM. Four of the twelve individual decapeptides were found to have binding affinities of approximately 300nM, or nearly three-fold less than the peptide immunogen. A dual-defined hexapeptide library was screened against mAb LJ-155B/16, and individual peptides were obtained through an iterative selection and synthesis process. Surprisingly, one of the most active sequences was Ac-WWYESW-NH2 (IC50 = 40nM), which showed no similarity to the sequence of the immunizing peptide. Further mapping of the specificity of this antibody revealed that the antigenic determinant within the peptide immunogen was not completely linear. Recognition of this unrelated sequence by mAb LJ-155B/16 was confirmed in a direct binding assay using biotinylated peptide. The use of SCLs for the elucidation of high affinity peptides recognized by these two antibodies may provide additional information on the molecular mechanisms of fibrinogen binding to different integrin receptors.