Iris Lauer

Hazelnut (Corylus avellana) vicilin Cor a 11: molecular characterization of a glycoprotein and its allergenic activity.

In Europe, hazelnuts (Corylus avellana) are a frequent cause of food allergies. Several important hazelnut allergens have been previously identified and characterized. Specific N-glycans are known to induce strong IgE responses of uncertain clinical relevance, but so far the allergenic potential of glycoproteins from hazelnut has not been investigated. The aim of the study was the molecular characterization of the glycosylated vicilin Cor a 11 from hazelnut and the analysis of its allergenic activity. Although MALDI-TOF (matrix-assisted laser-desorption ionization-time-of-flight) MS showed that one of two potential glycosylation sites of Cor a 11 was glycosylated, CD spectroscopy indicated that recombinant and natural Cor a 11 share similar secondary structures. Thus to analyse the impact of the glycan residues of Cor a 11 on IgE binding, the allergenic activity of natural glycosylated Cor a 11 and recombinant Cor a 11 was compared. In addition, the IgE sensitization pattern to recombinant Cor a 11, Cor a 1, Cor a 2 and Cor a 8 of 65 hazelnut allergic patients was determined in vitro. The prevalence of IgE reactivity to hazelnut vicilin Cor a 11 was below 50%. Basophil histamine-release assays were used to determine the allergenic activity of both natural and recombinant Cor a 11 in comparison with Cor a 1, a birch (Betula verrucosa) pollen-related major hazelnut allergen. Both forms of Cor a 11 induced mediator release from basophils to a similar extent, indicating that the hazelnut allergic patients had cross-linking IgE antibodies binding to the protein backbone and not to carbohydrate structures. In comparison to Cor a 1, a 10000-fold higher concentration of Cor a 11 was required to induce similar basophil mediator release. In conclusion, the hazelnut vicilin Cor a 11 is a minor allergen both in regard to prevalence and allergenic potency, whereas its glycan does not contribute to its allergenic activity.

Reduced Allergenic Potency of VR9-1, a Mutant of the Major Shrimp Allergen Pen a 1 (Tropomyosin)

The major shrimp allergen, tropomyosin, is an excellent model allergen for studying the influence of mutations within the primary structure on the allergenic potency of an allergen; Pen a 1 allows systematic evaluation and comparison of Ab-binding epitopes, because amino acid sequences of both allergenic and nonallergenic tropomyosins are known. Individually recognized IgE Ab-binding epitopes, amino acid positions, and substitutions critical for IgE Ab binding were identified by combinatorial substitution analysis, and 12 positions deemed critical were mutated in the eight major epitopes. The mutant VR9-1 was characterized with regard to allergenic potency by mediator release assays using sera from shrimp-allergic subjects and sera from BALB/c, C57BL/6J, C3H/HeJ, and CBA/J mice sensitized with shrimp extract using alum, cholera toxin, and Bordetella pertussis, as adjuvants. The secondary structure of VR9-1 was not altered; however, the allergenic potency was reduced by 90–98% measuring allergen-specific mediator release from humanized rat basophilic leukemia (RBL) cells, RBL 30/25. Reduced mediator release of RBL-2H3 cells sensitized with sera from mice that were immunized with shrimp extract indicated that mice produced IgE Abs to Pen a 1 and to the same epitopes as humans did. In conclusion, data obtained by mapping sequential epitopes were used to generate a Pen a 1 mutant with significantly reduced allergenic potency. Epitopes that are relevant for human IgE Ab binding are also major binding sites for murine IgE Abs. These results indicate that the murine model might be used to optimize the Pen a 1 mutant for future therapeutic use.

The non‐specific lipid transfer protein, Ara h 9, is an important allergen in peanut

Background Plant food allergy in the Mediterranean area is mainly caused by non‐specific lipid transfer proteins (nsLTP). The aim of this study was to characterize peanut nsLTP in comparison with peach nsLTP, Pru p 3, and assess its importance in peanut allergy.

Identification of a plane pollen lipid transfer protein (Pla a 3) and its immunological relation to the peach lipid-transfer protein, Pru p 3

Background An association between plane tree pollen allergy and plant food allergy has been described, but the cross‐reacting allergens have not yet been identified. The aim of this study was the identification of homologous non‐specific lipid‐transfer proteins (nsLTPs) in plane pollen, and to investigate its immunological relationship with the peach LTP, Pru p 3.

Relevance of IgE binding to short peptides for the allergenic activity of food allergens

BACKGROUND Analysis of IgE antibody binding to epitopes provides information for food allergy diagnosis and management and construction of hypoallergenic candidate vaccines, but the contribution of sequential epitopes to functionally relevant IgE binding is not fully understood. OBJECTIVES We sought to study the impact of IgE-binding peptides described as major sequence epitopes in the literature on IgE-binding capacity of 2 selected food allergens. METHODS IgE-binding peptides of the food allergens Ara h 2 (peanut) and Pen a 1 (shrimp) were identified. Synthetic soluble peptides representing the identified sequences were assessed for their capacity to inhibit IgE binding to the parent allergens by means of ELISA and in mediator release assay. The IgE-binding capacity of unfolded recombinant (r) Ara h 2 was analyzed. A hybrid tropomyosin carrying the IgE-binding regions of Pen a 1 grafted into the structural context of the nonallergenic mouse tropomyosin was applied in ELISA inhibition experiments and ImmunoCAP analysis. RESULTS Although IgE-binding peptides representing sections of the allergen sequences were detected, no relevant capacity to inhibit the IgE binding to the parent allergen in ELISA or basophil activation test was observed. Unfolded rAra h 2 showed reduced IgE-binding capacity compared with folded rAra h 2 and failed to elicit mediator release. Hybrid tropomyosin bound less IgE than rPen a 1 in ImmunoCAP analysis and revealed marginal inhibitory capacity. CONCLUSION Peptides identified as major sequence epitopes on Pen a 1 and Ara h 2 show little contribution to the IgE binding of the allergens studied.

Structural, immunological and functional properties of natural recombinant Pen a 1, the major allergen of Brown Shrimp, Penaeus aztecus

Background Recombinant allergens are considered the basis for new diagnostic approaches and development of novel strategies of allergen‐specific immunotherapy. As Pen a 1 from brown shrimp Penaeus aztecus is the only major allergen of shrimp and binds up to 75% of all shrimp‐specific IgE antibodies this molecule may be an excellent model for the usage of allergens with reduced IgE antibody‐binding capacity for specific immunotherapy.

Protein unfolding strongly modulates the allergenicity and immunogenicity of Pru p 3, the major peach allergen

BACKGROUND Allergen-specific immunotherapy for food allergies, including peach allergy, has not been established. Use of allergens with reduced allergenic potential and preserved immunogenicity could improve the safety and efficacy of allergen-specific immunotherapy. OBJECTIVE We sought to create a hypoallergenic derivative of the major peach allergen Pru p 3 and to characterize its biochemical and immunologic properties. METHODS A Pru p 3 folding variant generated by means of reduction and alkylation was investigated for structural integrity and stability to gastrointestinal enzymes. IgE reactivity and allergenic potency were determined by means of immunoblotting, ELISA, and in vitro mediator release assay with sera from patients with peach allergy. T-cell immunogenicity was investigated by using human allergen-specific T cells and CBA/J mice immunized with either native Pru p 3 (nPru p 3) or reduced and alkylated (R/A) Pru p 3. Pru p 3 processing by endolysosomal fractions of dendritic cells and antigenicity was examined in mice. RESULTS Unfolding of Pru p 3 reduced its high resistance to gastrointestinal proteolysis and almost completely abrogated its IgE reactivity and allergenic potency. However, R/A Pru p 3 was capable of stimulating human and murine T cells. Endolysosomal degradation of R/A Pru p 3 was accelerated in comparison with nPru p 3, but similar peptides were generated. IgG and IgE antibodies raised against nPru p 3 showed almost no cross-reactivity with R/A Pru p 3. Moreover, the antigenicity of R/A Pru p 3 was strongly reduced. CONCLUSION Unfolded Pru p 3 showed reduced allergenicity and antigenicity and preserved T-cell immunogenicity. The hypoallergenic variant of Pru p 3 could be a promising vaccine candidate for specific immunotherapy of peach allergy.

A food matrix reduces digestion and absorption of food allergens in vivo

SCOPE Food allergy is caused by primary (class 1) food allergens, e.g. Bos d 5 (cows milk) and Cor a 8 (hazelnut) or secondary (class 2) food allergens, e.g. Mal d 1 (apple). The latter cannot sensitize susceptible individuals but can cause allergy due to immunological cross-reactivity with homologous respiratory allergens. Here, we studied the effects of food matrix on gastrointestinal proteolysis, epithelial transport and in vivo absorption of class 1 and class 2 food allergens. METHODS AND RESULTS Mal d 1 lost its IgE-reactivity immediately after simulated gastric digestion whereas Bos d 5 and Cor a 8 did not. Only Cor a 8 maintained IgE-binding capacity after simulated intestinal proteolysis. The presence of hazelnut and peanut extracts, which served as protein-rich model food matrices, delayed gastrointestinal degradation and reduced epithelial transport rates of all allergens through CaCo-2 monolayers. Finally, IgE-reactive allergens were assessed at different time points in sera from rats fed with all three allergens with or without hazelnut extract. The levels of all allergens peaked 2 h after animals were fed without matrix and increased over 8 h after feeding. CONCLUSIONS A protein-rich food matrix delays gastrointestinal digestion and epithelial transport of food allergens and thereby may affect their sensitizing capacity and clinical symptoms.

Enhancement of hazelnut extract for IgE testing by recombinant allergen spiking

Background:  Hazelnuts are a common cause of food allergic reactions. Most hazelnut allergic individuals in central and northern Europe are sensitized to Cor a 1, a member of the PR‐10 protein family, while the lipid transfer protein Cor a 8 acts as a major allergen in the south of Europe. Other allergens, including profilin and seed storage proteins, may be important in subgroups of patients. Reliable detection of specific IgE in the clinical diagnosis of food allergy requires allergen reagents with a sufficient representation of all relevant allergen components. Some reported observations suggest that natural hazelnut extract may not be fully adequate in this respect.

Comparison of IgE-binding capacity, cross-reactivity and biological potency of allergenic non-specific lipid transfer proteins from peach, cherry and hazelnut.

Background: Whether the observed clinical pattern of non-specific lipid transfer protein (nsLTP)-mediated food allergies is attributable to a primary sensitization by Pru p 3 from peach and subsequent cross-reactivity with Rosaceae- and non-Rosaceae-derived foods expressing homologous allergens is still unclear. Objective: To investigate the allergenic properties of nsLTPs from Rosaceae and non-Rosaceae foods. Methods: In peach-, cherry- or hazelnut-allergic patients, prevalence of sensitization, IgE-binding capacity, cross-reactivity and allergenic potency of Pru p 3 was compared with Pru av 3 (cherry) and Cor a 8 (hazelnut). Results: Frequency of sensitization to corresponding nsLTPs was 88, 85, and 77% in peach-, hazelnut- and cherry-allergic patients, respectively. Concomitant allergic reactions to cherry and hazelnut were reported in 51 and 44% of peach-allergic patients, respectively. In contrast to cherry allergy, hazelnut allergy was not strictly associated to peach allergy. Sensitization to Cor a 8 or Pru av 3 was strongly correlated with IgE reactivity to Pru p 3, even when subjects tolerated peach. Specific IgE was highest for Rosaceae LTPs, and cross-inhibition experiments confirmed a stronger IgE-binding capacity of Pru p 3 than Cor a 8. The biological potency of Pru p 3 and Pru av 3 was similar but stronger for both nsLTPs than that of Cor a 8. Conclusion: Clinical cross-reactivity of food-allergic patients in the Mediterranean area is likely attributed to a primary sensitization to Pru p 3 and serological cross-reactivity with homologous food nsLTPs. In comparison to Cor a 8, Rosaceae nsLTPs showed a stronger IgE-binding capacity and allergenic potency indicating a different epitope pattern.