Immunogenicity of loop-structured short synthetic peptides mimicking the antigenic site A of influenza virus hemagglutinin

Peptide Antibodies in Clinical Laboratory Diagnostics

Peptide antibodies, with their high specificities and affinities, are invaluable reagents for peptide and protein recognition in biological specimens. Depending on the application and the assay, in which the peptide antibody is to used, several factors influence successful antibody production, including peptide selection and antibody screening. Peptide antibodies have been used in clinical laboratory diagnostics with great success for decades, primarily because they can be produced to multiple targets, recognizing native wildtype proteins, denatured proteins, and newly generated epitopes. Especially mutation-specific peptide antibodies have become important as diagnostic tools in the detection of various cancers. In addition to their use as diagnostic tools in malignant and premalignant conditions, peptide antibodies are applied in all other areas of clinical laboratory diagnostics, including endocrinology, hematology, neurodegenerative diseases, cardiovascular diseases, infectious diseases, and amyloidoses.

Serological characterization of guinea pigs infected with H3N2 human influenza or immunized with hemagglutinin protein

Background

Recent and previous studies have shown that guinea pigs can be infected with, and transmit, human influenza viruses. Therefore guinea pig may be a useful animal model for better understanding influenza infection and assessing vaccine strategies. To more fully characterize the model, antibody responses following either infection/re-infection with human influenza A/Wyoming/03/2003 H3N2 or immunization with its homologous recombinant hemagglutinin (HA) protein were studied.

Results

Serological samples were collected and tested for anti-HA immunoglobulin by ELISA, antiviral antibodies by hemagglutination inhibition (HI), and recognition of linear epitopes by peptide scanning (PepScan). Animals inoculated with infectious virus demonstrated pronounced viral replication and subsequent serological conversion. Animals either immunized with the homologous HA antigen or infected, showed a relatively rapid rise in antibody titers to the HA glycoprotein in ELISA assays. Antiviral antibodies, measured by HI assay, were detectable after the second inoculation. PepScan data identified both previously recognized and newly defined linear epitopes.

Conclusions

Infection and/or recombinant HA immunization of guinea pigs with H3N2 Wyoming influenza virus resulted in a relatively rapid production of viral-specific antibody thus demonstrating the strong immunogenicity of the major viral structural proteins in this animal model for influenza infection. The sensitivity of the immune response supports the utility of the guinea pig as a useful animal model of influenza infection and immunization.

Antigenic characterization of recombinant hemagglutinin proteins derived from different avian influenza virus subtypes

Since the advent of highly pathogenic variants of avian influenza virus (HPAIV), the main focus of avian influenza research has been the characterization and detection of HPAIV hemagglutinin (HA) from H5 and H7 subtypes. However, due to the high mutation and reassortation rate of influenza viruses, in theory any influenza strain may acquire increased pathogenicity irrespective of its subtype. A comprehensive antigenic characterization of influenza viruses encompassing all 16 HA and 9 neuraminidase subtypes will provide information useful for the design of differential diagnostic tools, and possibly, vaccines. We have expressed recombinant HA proteins from 3 different influenza virus HA subtypes in the baculovirus system. These proteins were used to generate polyclonal rabbit antisera, which were subsequently employed in epitope scanning analysis using peptide libraries spanning the entire HA. Here, we report the identification and characterization of linear, HA subtype-specific as well as inter subtype-conserved epitopes along the HA proteins. Selected subtype-specific epitopes were shown to be suitable for the differentiation of anti-HA antibodies in an ELISA.

Structure-antigenicity of the V3 region of SIVmac envelope glycoprotein

The objective of this study was to analyze the immunogenicity and antigenicity of the V3 domain (Cys313-Cys346) of the external envelope glycoprotein gp125 of SIVmac251. The corresponding peptide was synthesized and characterized as linear and cyclic peptides. Our results showed that this region, as for HIV-1, contained an immunodominant epitope. The antigenicity was similar for the linear and cyclic peptides when tested against a panel of 15 sera from SIV infected macaques. Similarly, both peptide structures presented similar immunogenicity as shown by the characterization of the anti-peptide antibodies produced in rabbits against the cyclic and linear forms. But, unexpectedly, the antibodies produced against linear peptides recognized with a relatively higher intensity the native envelope gp140 than those produced against the cyclic structure. Furthermore, we showed that these antibodies recognized better the deglycosylated form of the glycoprotein. But, in contrast to the neutralizing activity obtained with anti-V3 peptides from HIV-1, no antiviral activity was obtained with antibodies generated against linear or cyclic SIVmac V3 peptides.

Antibody recognition and conformational flexibility of a plaque-specific beta-amyloid epitope modulated by non-native peptide flanking regions

Here we report on the synthesis, antibody binding, and QSAR studies of a series of linear and cyclic peptides containing a beta-amyloid plaque-specific epitope (Abeta(4-10); FRHDSGY). In these constructs, two or three alpha- l-Ala, alpha- d-Ala, or beta-Ala residues were introduced at both N- and C-termini of the epitope as non-native flanking sequences. Cyclization of the linear Abeta(4-10) epitope peptide resulted in reduced antibody binding. However, the antibody binding could be fully compensated by insertion of alanine flanks into the corresponding cyclic peptides. These results indicate that the modification of a beta-amyloid plaque-specific epitope by combination of cyclization and flanking sequences could generate highly antigenic peptides compared to the native sequence. A novel 3D QSAR method, which explicitly handles conformational flexibility, was developed for the case of such molecular libraries. This method led to the prediction of the binding conformation for the common FRHDSGY sequence.

Immunogenically fit subunit vaccine components via epitope discovery from natural peptide libraries

Antigenic peptides that bind pathogen-specific Abs are a potential source of subunit vaccine components. To be effective the peptides must be immunogenically fit: when used as immunogens they must elicit Abs that cross-react with native intact pathogen. In this study, antigenic peptides obtained from phage display libraries through epitope discovery were systematically examined for immunogenic fitness. Peptides selected from random peptide libraries, in which the phage-displayed peptides are encoded by synthetic degenerate oligonucleotides, had marginal immunogenic fitness. In contrast, 50% of the peptides selected from a natural peptide library, in which phage display segments of actual pathogen polypeptides, proved very successful. Epitope discovery from natural peptide libraries is a promising route to subunit vaccines.

Native-like cyclic peptide models of a viral antigenic site: finding a balance between rigidity and flexibility

Antigenic site A of foot-and-mouth disease virus (serotype C) has been reproduced by means of cyclic versions of peptide A15, YTASARGDLAHLTTT, corresponding to residues 136-150 of envelope protein VP1. A structural basis for the design of the cyclic peptides is provided by crystallographic data from complexes between the Fab fragments of anti-site A monoclonal antibodies and A15, in which the bound peptide is folded into a quasi-cyclic pattern. Head-to-tail cyclizations of A15 do not provide peptides of superior antigenicity. Internal disulfide cyclization, however, leads to analogs which are recognized as one to two orders of magnitude better than linear A15 in both ELISA and biosensor experiments. CD and NMR studies show that the best antigen, CTASARGDLAHLTT-Ahx-C (disulfide), is very insensitive to environment-induced conformational change, suggesting that cyclization helps to stabilize a bioactive-like structure.

Synthetic peptides induce antibody against a host-protective antigen of Echinococcus granulosus

The immunogenicity of four synthetic peptides was investigated in sheep. The sequences of the peptides (6, 12/13, 21/22 and 24) were derived from linear, antibody-binding epitopes of the EG95 recombinant protein, a host-protective antigen of the parasite Echinococcus granulosus. Sheep were immunised with either free peptide or peptide conjugated to diphtheria toxoid. All sheep responded to both conjugated and unconjugated forms of the peptides. For two of the four peptides (6 and 21/22), the amount of antibody elicited was significantly greater for the conjugated form of the peptides than for the corresponding unconjugated forms. For the other two peptides (12/13 and 24), peak antibody levels to both forms of the peptide were equivalent. Maximal antibody titres against peptides 6, 12/13 and 21/22 were established after only one immunisation and were not boosted by a second dose. Antisera to all four peptides reacted with the recombinant antigen, and three of the four peptides generated antibodies, which bound to the native parasite oncosphere antigen. Antisera raised against the peptides were unable to kill the parasite in in vitro culture, although each of the peptides could be used to affinity purify lethal antibody from antisera raised against the recombinant protein. These results indicate that peptides 6, 12/13, 21/22 and 24 of the EG95 recombinant vaccine are immunogenic and suggest that they are associated with host-protective epitopes.

A comparative study of cyclization strategies applied to the synthesis of head-to-tail cyclic analogs of a viral epitope

A family of head-to-tail cyclic peptide models of the antigenic site A (G-H loop of viral protein 1) of foot-and-mouth disease virus has been designed on the basis of the three-dimensional structure adopted by the linear peptide YTASARGDLAHLTTT upon binding to neutralizing monoclonal antibodies. Three different methods of cyclization have been examined to access the peptides. Solution cyclization of a minimally protected linear precursor provided the expected products but required several purification steps that lowered the yields to approximately 10%. The two other approaches relied on side-chain anchoring of the peptide through the Asp residue and cyclization on the solid phase. A synthetic scheme combining Fmoc, tBu and OAI protections was practicable but inefficient when scaled-up. The combination of Boc, Bzl and OFm protections was more promising, but suffered from high epimerization during the initial esterification of Boc-Asp-OFm to benzyl alcohol-type resins. This problem was solved by performing the esterification via the cesium salt of Boc-Asp-OFm. With this improvement, the Boc/Bzl/OFm has become the method of choice for the preparation of cyclic head-to-tail peptides in satisfactory yields and with minimal purification.

Structure/antigenicity relationship of cyclic and linear peptides mimicking the V3 loop of HIV2 envelope glycoprotein

We report the structure and antigenicity of the third variable region (V3) of the HIV2 envelope glycoprotein by the use of linear and cyclic peptides. To this end, a peptide mimicking this region was synthesized and purified, both as an iodoacetamidated linear peptide and a disulphide-bridged cyclic peptide. The cross-reactivity of three monoclonal antibodies (mAbs) produced against the envelope glycoprotein gp140 with the linear and cyclic peptides was tested with ELISA. The results showed that the cyclic peptide is a better ligand for the 3 mAbs 125-F, 125-J and 125-K. The avidity of the mAb/peptide interaction was further analysed by determining the concentration of linear or cyclic peptide leading to 50% inhibition of mAb-peptide complex formation (K0.5). The K0.5 value of mAb 125-F, which displayed the best reactivity with gp140, was estimated to be 5 times higher for the linear (K0.5 = 1.5 x 10(-6) M) than for the cyclic peptide (K0.5 = 3 x 10(-7) M). This indicates a higher affinity of mAb 125-F for the cyclic peptide. mAb 125-J, which exhibited a lower avidity for the gp140 compared to mAb 125-F, had a similar affinity for the cyclic and the linear peptides (K0.5 = 3 x 10(-7) M). mAb 125-K had the lowest reactivity with gp140 and its binding to adsorbed peptide could not be inhibited by the soluble linear or cyclic peptide used up to 10(-5) M. These results suggest that cyclic peptides may have a higher propensity for adopting a native-like structure for the peptide/antibody interaction. Nuclear magnetic resonance experiments at 25 degrees C in phosphate buffer pH 5.4, however, showed that neither peptide displayed a well-defined structure.

Antigenicity of linear and cyclic peptides mimicking the disulfide loops in HIV-2 envelope glycoprotein: synthesis, reoxidation and purification

The external envelope glycoprotein (gp125) of human immunodeficiency virus type 2 (HIV-2) contains 22 cysteine residues. The positions of the 11 disulfide bridges in HIV-2 gp125 were determined by analogy with the experimental position of the disulfide bonds found in the gp120 of HIV-1. Peptides expected to mimic all 11 disulfide-bonded domains containing from 13 to 47 amino acids were synthesized by the solid-phase method according to 9-fluorenylmethoxycarbonyl strategy, except for peptide 5, which was assembled according to t-butoxycarbonyl (Boc) strategy. Analysis of all the crude peptides showed that the expected peptides were obtained with good yields, between 75% and 85%. Peptides were purified further by high-performance liquid chromatography (HPLC) on an Aquapore RPC30 C8 column. Peptide homogeneity was more than 90%. For each peptide, linear peptides (L) were SH-iodoacetamidated, whereas cyclization of peptides (C) was performed by air oxidation. Oxidation kinetics was followed with the Ellman test and HPLC. Cyclic peptides were purified by HPLC and characterized by fast atom bombardment mass spectrometry. This analysis showed that a small quantity (<10%) of dimeric peptides (2 and 8) and cyclic peptides containing oxidized methionine or tryptophan residues (4, 9 and 10) were formed. To assess the relevance of conformation for the antigenicity of disulfide-bonded loops of HIV-2 gp125, the antigenicity of linear and cyclic peptides was tested against a set of 76 HIV-2 positive human sera by enzyme-linked immunosorbent assay. Peptides 2, 4 and 9, mimicking the V1, V2 and V3 regions of the external envelope glycoprotein (gp 125) of HIV-2, were the most highly reactive with HIV-2 positive human sera tested at the dilution of 1:50. Cyclic peptides generally were recognized more than linear peptides, as shown by their greater inhibition (2 to 10 times more) of antigen-antibody complexes. Structure-antigenicity of peptide V3, the most reactive peptide (75% of the HIV-2 positive sera tested), was analyzed further. Cyclic peptide 9C had a higher affinity for anti-gp125 antibodies than linear peptide 9L. In addition, circular dichroism showed that linear and cyclic peptides 9 had a similar structure, but when analyzed in aqueous solution or in trifluoroethanol (TFE), the structural difference shown with antibodies was not confirmed. No significant difference was observed between the antigenicity of linear and cyclic peptides 1, 8 and 11, mimicking the C1, C2 and C4 regions of HIV-1 gp125. These peptides were weakly reactive with HIV-2 positive sera. This result agrees with the low immunogenicity of conserved regions.

Linear and cyclic peptides mimicking the disulfide loops in HIV-2 envelope glycoprotein induced antibodies with different specificity

The aim of this study was to compare the immunogenicity and antigenicity of cyclic and linear peptides that mimic the disulfide loops in HIV-2ROD gp125. Based on the hypothetical assignment of intrachain disulfide bonds in HIV-2 envelope glycoprotein, peptides expected to mimic all 11 disulfide-bonded domains were synthesized, oxidized or cysteine-alkylated; they were then purified and characterized. Rabbits were immunized with either linear cysteine-alkylated peptides (L1-L11) or cyclic oxidized peptides (C1-C11). All peptides except 7L elicited antibodies with titers between 10(3) and 5 x 10(6). Anti-peptide C (2, 3, 4, 7, 8, 9, 11) and anti-peptide L (2, 3, 8, 9, 11) antibodies recognized the native HIV-2 gp 125. Moreover, we found that cyclization of the peptides significantly increased the level of anti-peptide antibodies reacting with the intact antigen protein. Deglycosylation increased the level of protein reactivity of anti-peptide antibodies and rendered the epitopes in peptides 5, 6, 10 accessible, which were masked in the native protein. Peptide 1 induced antibodies reacting only with the denatured reduced gp125 HIV-2. In addition, while anti-peptide L antibodies reacted better with L peptide (called "linear" structural specificity), anti-peptide C antibodies reacted similarly with L and C peptides (called "broad" structural specificity). Interestingly, the "broad" structural specificity of antibodies correlated with reactivity against native gp125. Although none of these anti-peptide antisera displayed neutralizing activity against HIV-2ROD, these results support the hypothesis that the structural restriction of peptides have a major influence upon the generation of more specific antibodies for recognizing the intact protein.

A cyclic disulfide peptide reproduces in solution the main structural features of a native antigenic site of foot-and-mouth disease virus

A cyclic disulfide peptide corresponding to the G-H loop sequence 134-155 [replacement Tyr136 and Arg153 with Cys] of the capsid protein VP1 of foot-and-mouth disease virus (FMDV) isolate C-S8c1 was examined by proton 2D-NMR spectroscopy in water and in 25% HFIP/water. In water, NMR data supported the presence of a non-canonical turn in the central, conserved cell adhesion RGD motif and suggested the presence of a nascent helix in the C-terminal part, stabilized and slightly extended upon addition of 25% HFIP, a secondary structure stabilizing cosolvent. The formation of the C-terminal helix was evidenced by combined analysis of NOE connectivities, H alpha chemical shifts, 3JNH-H alpha coupling constants and amide temperature coefficients. Surprisingly, these global structural features of the cyclic peptide in solution show similarities to previous X-ray structure analysis of (a) a shortened linear peptide complexed with a antivirus antibody and (b) the G-H loop represented on the chemical reduced viral surface of a different serotype. Thus, even in entirely different biological environments the cyclic peptide reflect similar structural features, reinforcing the concept that this viral loop behaves as an independent structural and functional unit.

Dynamical studies of peptide motifs in the Plasmodium falciparum circumsporozoite surface protein by restrained and unrestrained MD simulations

The immunodominant region on the circumsporozoite surface (CS) protein of the malaria parasite Plasmodium falciparum contains 37 repeated copies of a asparagine-alanine-asparagine-proline (NANP) motif NMR studies of linear synthetic peptides containing one, two or three repeat units provided evidence for nascent type I beta-turns within the NPNA cadence in aqueous solution. The beta-turns could be stabilised upon substituting proline for alpha-methylproline (p(Me)) in the dodecamer (NP(Me)NA)3, without loss of the ability to elicit antibodies cross-reactive with P. falciparum sporozoites. In this work, four 4 ns MD simulations of the dodecapeptide Acetyl-(NP(Me)NA)3, in water, using NOE distance restraints, using 3J-coupling constant restraints, using both these restraints and without restraints, were carried out to determine the conformations of this peptide in aqueous solution. An unrestrained MD simulation of the unmethylated Ac-(NPNA)3 peptide in water was also carried out to investigate the effect of the additional methyl groups on the structure and dynamics of the peptide. The application of NOE distance restraints and 3J-coupling constant restraints leads to contradictory results, probably due to different averaging time scales inherent to the measurement of these data, which exceed the 100 ps averaging applied in the simulations. The additional methyl groups lead to more compact structures, which display enhanced local fluctuations. The central tetrapeptide adopts a type I beta-turn, while the outer motifs display more conformational variability. The three motifs in the methylated dodecamer peptide, however, adopt frequently in the distance restrained MD simulation a compact structure such that the outer motifs appear to form a hydrophobic core by stacking of their two proline rings. This arrangement also suggests how a peptide containing multiple tandemly linked copies of a stable beta-turn NPNA motif might adopt a folded stem-like structure, which conceivably may be of biological relevance in the native CS protein.

Immunogenicity and antigenicity of synthetic peptides derived from the mite allergen Der p I

As an immunogen must contain both B- and T-cell epitopes, small peptides are usually reported as non-immunogenic unless coupled to a protein carrier. In this study, the immunogenicity of the Der p I synthetic uncoupled peptides (p52-71, p89-104, p117-133 and p176-187) previously reported as B-cell epitopes, was evaluated. Different schedules of immunization were used. Results indicated that by using the Vaitukaikis' method three injections of the same peptide without protein carrier was sufficient to induce an specific anti-peptide IgG antibody response (evaluated by ELISA). Indeed, the 16-20 amino-acid long peptides p52-71, p117-133 and p89-104 were revealed highly immunogenic in rabbits. Furthermore anti-peptide p52-71 and p117-133 antibodies were shown by Western-blotting or by neutralization assay to recognize the Der p I molecule either in denaturated or native form as well as Der f I (major allergen of Dermatophagoides farinae). Finally, taking into account the location of Der p I-derived peptides in the three-dimensional model of Der p I, the antigenicity and immunogenicity of peptides were discussed.

Antigenic analysis of bean pod mottle virus using linear and cyclized synthetic peptides

The antigenic structure of the comovirus bean pod mottle virus (BPMV) was studied using synthetic peptides selected on the basis of the exposed location of certain regions of the viral protein. Three regions of domain A, four regions of domain B and two regions of domain C of BPMV coat protein were studied. Each of four regions were synthesized in the form of linear and cyclized peptides while the others were synthesized as linear peptides only. The peptides were tested for their ability to be recognized by antibodies directed against BPMV. The peptides were also used for producing rabbit antisera, which were tested for their ability to react with various BPMV antigens as well as with the linear and cyclized peptides. All the peptides were found to correspond to epitopes of BPMV coat protein. Several of the antigenic sites of BPMV located on exposed loops of the coat protein occupy positions which correspond to known epitopes in the structurally related picornaviruses. Only in some cases did cyclization sufficiently improve the level of conformational mimicry between peptides and the viral protein to allow cross-reactions between them to be observed.

Cyclic disulfide model of the major antigenic site of serotype-C foot-and-mouth disease virus. Synthetic, conformational and immunochemical studies

A cyclic disulfide peptide representing antigenic site A of foot-and-mouth disease virus (FMDV) strain C-S8c1 (residues 134 to 155 of viral protein 1 (VP1) with Tyr136 and Arg153 replaced by cystine; TTCTASARGDLAHLTTTHACHL) was synthesized by solid phase methods. Formation of the cyclic disulfide was carried out by air oxidation of the fully deprotected and reduced bis-cysteine precursor, under high dilution conditions. The identity of the cyclic peptide was confirmed by both physical and enzymatic methods. A conformational study of the cyclic peptide and of its linear parent structure (YTASARGDLAHLTTTHARHLP, residues 136-156 of VP1 of FMDV C-S8c1) by circular dichroism in the presence of a structure-inducing solvent showed the cyclic disulfide analog to adopt lower levels of alpha-helix than its linear counterpart. In competitive ELISA assays both peptides reacted with similar affinity against a representative panel of neutralizing monoclonal antibodies directed towards antigenic site A. Thus, a high inherent flexibility of this loop may preclude a conformational restriction strong enough to alter recognition by anti-virus antibodies.

A model of the rabies virus glycoprotein active site

The glycoprotein from the neurotropic rabies virus shows a significant homology with the alpha neurotoxin that binds to the nicotinic acetylcholine receptor. The crystal structure of the alpha neurotoxins suggests that the Arg 37 guanidinium group and the Asp 31 side-chain carboxylate of the erabutoxin have stereochemical features resembling those of acetylcholine. Conformational studies on the Asn194-Ser195-Arg196-Gly197 tetrapeptide, an essential part of the binding site of the rabies virus glycoprotein, indicate that the side chains of Asn and Arg could also mimic the acetylcholine structure. This observation is consistent with the recently proposed mechanism of the viral infection.

Correlation between the location of antigenic sites and the prediction of turns in proteins

In the present study, we developed new turn scales based on the occurrence of amino acids at each of the four positions of a turn using a structural database comprised of 87 proteins. We found that the scales correctly predicted a fraction of the turn regions in proteins with approximately 80% confidence. We used the turn scales for predicting the location of antigenic sites in proteins. The method was developed with the specific aim of predicting only a few peaks for each protein (two or three). We found that it leads to a high level of accurate prediction (70% of correct prediction of known epitopes). Our method should be useful for selecting protein regions to be synthesized in order to produce anti-peptide antibodies cross-reacting with the parent protein.

Immunogenicity of peptides having pre-determined alpha-helical and alpha-alpha fold topologies

A panel of three synthetic peptides based on the 310-327 region of mouse LDH-C4 was used to examine the effect of peptide conformation on immunogenicity. The peptides, without prior conjugation to carrier molecules, were injected into outbred mice and the antisera were assayed for peptide- and LDH-C4-reactive antibodies by ELISA. An 18-residue random coil peptide (alpha N) and an 18-residue amphipathic alpha-helix peptide (alpha 1) were weakly immunogenic. A conformationally stable 40-residue alpha-alpha fold peptide (alpha 3) was highly immunogenic. The antibodies elicited by alpha 3 reacted strongly with the native molecule by ELISA. Solution-phase binding assays were used to further characterize the specificity of the sera from two mice immunized with alpha 3. Antibodies from one of the mice appeared to recognize the helical portion of the peptides, while antibodies from the other mouse reacted only with the immunogen and may be specific for the non-natural beta bend residues or possibly a topographic determinant peculiar to the anti-parallel helices. Serum from neither mouse was able to recognize the native molecule in solution. Peptides intended to mimic topographic determinants for the purpose of synthetic vaccine development may have to be more complex than those used in this study in order to induce high-affinity antibodies capable of exerting a significant biological effect.

Antigenic properties and protective capacity of a cyclic peptide corresponding to site A of influenza virus haemagglutinin

Two cyclic peptide analogues corresponding to residues 139-146 (site A) of influenza A virus haemagglutinin (strain X31) were synthesized. The ability of these peptides to react with anti-influenza virus antibodies was found to depend on the conformation of the loop and on the orientation in which the peptide was presented to antibodies. Antibodies raised to the peptides were able to bind in ELISA with influenza virus antigen that had been allowed to dry on the microtitre plate. When OF1 mice were immunized with cyclic peptides, approximately 80% of the animals were protected against an intranasal challenge with influenza virus.

Synthesis of cyclic peptides on solid support. Application to analogs of hemagglutinin of influenza virus

In order to mimic a well-known loop structure (site A) of the hemagglutinin of influenza virus, a series of cyclic peptides derived from the region 139-147 were synthesized. The lactam analogs cyclised between the N-terminus Cys 139 and the beta-carboxyl of aspartic acid 148 (small loop) or the epsilon-NH2 of lysine 148 via succinimidyl linker (large loop) were synthesized by the solid phase method. Cyclisation was directly performed on the solid support prior to final cleavage of the peptide. We describe two protection schemes which allow us to obtain different loop sizes derived from the same sequence. Eight of the analogs contained relatively large ring structures (up to 38 membered). For protection of the side chain of aspartic acid in combination with N-alpha-Fmoc protection, the cyclohexyl ester was more satisfactory than the benzyl ester with respect to imide formation. When the rate of cyclodimerisation, as a function of resin substitution, was compared to the rate of cyclic monomer formation, it was found that dimerisation was proportional to the charge of the resin. Furthermore, a comparison of the recently reported BOP reagent over the classical DIPC/HOBt method for the cyclisation reaction shows that in our case the reaction proceeded more rapidly by the BOP procedure although it gave a less pure crude product.

Fine manipulation of antibody affinity for synthetic epitopes by altering peptide structure: antibody binding to looped peptides*

Linear peptides weakly imitate antibody binding sites on globular proteins when the peptides are shown to be effective at all. As a step toward enhancing the ability of peptides to mimic epitopes, we have examined the effects of various alterations in peptide structure on antibody binding. Synthetic peptides containing the core amino acid sequence of residues 41 to 48 from horse cytochrome c were examined for their ability to bind antibodies elicited against the 41-48 peptide coupled to bovine serum albumin (BSA). Since residues 41-48 in native cytochrome c are part of an omega loop, in some peptides cysteines were incorporated for intrachain disulfide bonding to stabilize loop structure. In additional cases, glycine was incorporated as a spacer between the natural sequence and the cysteine residues with the intent of relaxing loop structure slightly. Eleven analogues containing the 41-48 sequence were tested. These included native cytochrome c and the 1-80 and 1-65 cyanogen bromide-cleaved fragments. The native protein did not bind the anti-41-48 antibodies. The other analogues differed by over three orders of magnitude in their binding. The affinity of binding was inversely related to the extent of predicted loop structure indicating that the antibodies were elicited against the 41-48 sequence in a more unfolded conformation despite the Pro Gly sequence at positions 44 and 45 that generally favors a beta turn. Surprisingly, the immunizing peptide, containing residues 41-48 only, was the poorest binding peptide. The relative impotence of 41-48 was shown to be largely due to differences at the amino terminus between the free and BSA-coupled peptides as the antibodies were elicited against the latter. The distinctions among the synthetic peptides containing the 41-48 sequence show the exquisite sensitivity of antibody binding to amino acid changes that may occur outside of an epitope and suggest modifications in peptide structure at the periphery of an epitope that can lead to desired changes in antibody affinity.

The structural basis of allergenicity: recombinant DNA-based strategies for the study of allergens

The use of recombinant DNA techniques for the study of allergenicity of proteins is a viable, and in many ways a preferred, alternative to the traditional procedures of protein purification, digestion and analysis of peptides for both allergenicity and amino acid sequence. The process of protein purification can be difficult and in many instances workers are forced to use only partially pure fractions that make the identification of the allergenic proteins uncertain. Furthermore, the purification and sequencing of peptides and their testing for retention of allergenic properties, represents a substantial and time-consuming work load. The synthesis of families of synthetic peptides to characterize the amino acids important for allergenic properties is also expensive and time-consuming. On the other hand, the preparation of a cDNA library from an allergen source is today a relatively easy and inexpensive task. The isolation and purification of cDNA clones is comparatively trivial compared to protein purification. Using the techniques described in this text, it can be seen that the molecular biological approach, although in some respects similar in principle to those of the protein chemist to study allergens, provides the capability to study several clones at the same time, and to compare clones for the presence of conserved regions corresponding to allergenic determinants. In addition, the techniques for generating mutant sequences provides perhaps the most powerful and simple set of procedures available for defining the amino acid structures essential for proteins or peptides to behave as allergens.