Abstract: Backbone modifications have been introduced into the melanoma derived peptide MART-1(27-35) to increase its binding to class I major histocompatibility complex HLA-A2 molecule, and ultimately to enhance its immunogenicity. Each analogue was obtained by replacing one peptide bond at a time in the natural epitope by the aminomethylene (CH2-NH) surrogate. All analogues displayed an increased resistance to proteolysis. Interestingly, the comparative results showed that five analogues bound more efficiently to HLA-A2 than the parent peptide. On the other hand, two pseudopeptide/HLA-A2 complexes were recognized by one melanoma-specific T cell clone. Close examination of the impact of such modifications at the molecular level provides useful supports for the rational design of stable compounds with applications in anti-tumour specific immunotherapy and in vaccine development.
Abstract: Recent investigations have suggested that pseudopeptides containing modified peptide bonds might advantageously replace natural peptides in therapeutic strategies. We have generated eight reduced peptide bond Psi(CH2-NH) analogues corresponding to the H-2Db-restricted CD8(+) T cell epitope (called GP33) of the glycoprotein of the lymphocytic choriomeningitis virus. One of these pseudopeptides, containing a reduced peptide bond between residues 6 and 7 (Psi(6-7)), displayed very similar properties of binding to major histocompatibility complex (MHC) and recognition by T cell receptor transgenic T cells specific for GP33 when compared with the parent peptide. We assessed in vitro and in vivo the proteolytic resistance of GP33 and Psi(6-7) and analyzed its contribution to the priming properties of these peptides. The Psi(6-7) analogue exhibited a dramatically increased proteolytic resistance when compared with GP33, and we show for the first time that MHC-peptide complexes formed in vivo with a pseudopeptide display a sustained half-life compared with the complexes formed with the natural peptide. Furthermore, in contrast to immunizations with GP33, three injections of Psi(6-7) in saline induced significant antiviral protection in mice. The enhanced ability of Psi(6-7) to induce antiviral protection may result from the higher stability of the analogue and/or of the MHC-analogue complexes.
Abstract: During the Fmoc solid-phase synthesis of reduced peptide bond analogues, we observed that the trityl protection of an asparagine residue in the vicinity of a reduced peptide bond is not cleaved completely after the final trifluoroacetic acid deprotection step. The relative position of the Asn side-chain amine and of the aminomethylene bond as well as the preferential protonation of the secondary amine can be used to explain this phenomenon. We show that longer deprotection times or the use of methyl-trityl protection partially improves the yield of the Asn-deprotected peptide whereas xanthenyl protection totally overcomes this problem.
Abstract: Peptides eluted from the MHC class I K(d) molecule are generally nonamers that display a strong preference for Tyr in position 2 and Ile or Leu in position 9. We investigated the binding ability of several synthetic peptides which did not fit this consensus motif. In our peptides, Tyr(2) was substituted by other amino acids, i.e. LeU, Ile or Met. These peptides were variants of the 252-260 K(d)-restricted peptide SYIPSAEKI derived from the Plasmodium berghei circumsporozoite protein. They bound to purified K(d) molecules in vitro with intermediate affinity. One of them was tested for in vivo stimulation of T cells and induced a cytotoxic response. These results demonstrate the importance of binding motif refinement to discover new binding characteristics and new ligands such as low-affinity peptides.
Abstract: To identify Kd-binding peptides, an approach based on small peptide libraries has been developed. These peptide libraries correspond to all possible single-amino acid variants of a particular Kd-binding peptide, SYIPSAEYI, an analog of the Plasmodium berghei 252-260 antigenic peptide SYIPSAEKI. In the parent sequence, each position is replaced by all the genetically encoded amino acids (except cysteine). The multiple analog syntheses are performed either by the Divide Couple and Recombine method or by the Single Resin method and generate mixtures containing 19 peptides. The present report deals with the synthesis, the purification, the chemical characterization by amino acid analysis and electrospray mass spectrometry (ES-MS), and the application of such mixtures in binding tests with a soluble, functionally empty, single-chain H-2Kd molecule denoted SC-Kd. For each mixture, bound peptides were eluted and analyzed by sequencing. Since the binding tests were realized in noncompetitive conditions, our results show that a much broader set of peptides bind to Kd than expected from previous studies. This may be of practical importance when looking for low affinity peptides such as tumor peptides capable of eliciting protective immune response.
Abstract: The specific interaction between biotin and avidin was exploited in the affinity purification of solid-phase synthesized peptide libraries. During peptide library synthesis, by means of the single-resin method in which coupling on variable positions is carried out using an equimolar mixture of amino acids, biotin was used to cap the unreacted amino groups remaining after coupling of the equimolar amino acid mixture. The following synthesis and deprotection procedures were performed as usual in tert,-butyloxycarbonyl chemistry. The purification of the peptide mixture containing N-biotinylated sequences was performed by affinity chromatography on an avidin-agarose column. The unwanted terminated sequences were retained in the avidin column while the purified peptide mixture was eluted as indicated by reverse-phase HPLC and MS analysis monitoring. The avidin column was regenerated and the biotinylated sequences were released under reversible denaturing conditions. The usefulness of biotinylation for peptide library purification is demonstrated here for the first time for a peptide mixture containing by-products that cannot be separated from the mixture by classical HPLC purification. This purification technique could be applied to all syntheses, presenting difficult reacting steps.
