Peter Schmid-Grendelmeier

Recombinant allergens for skin testing.

Skin testing is a basic diagnostic procedure widely used to explore immediate-type reactions to allergen preparations in vivo. Despite their reliability, if standardized extracts are used, skin tests suffer from limited reproducibility due to difficulties in preparing consistently standardized extracts from natural raw material. Starting from allergen-encoding cDNAs, large amounts of highly pure allergens with a high batch-to-batch consistency satisfying the quality requirements of medicinal products manufactured by recombinant DNA technology can be produced. These reagents are expected to be qualitatively superior to the commercially available allergen preparations used for the in vitro and in vivo diagnosis of allergic conditions. In this article the current literature available on skin testing with such recombinant allergens (rAllergens) is reviewed and critically analyzed. To date many different rAllergens of various pollens, moulds, mites, bee venom, latex and celery have been used in skin testing in more than 1,600 allergic and control individuals. Skin prick tests as well as intradermal skin tests with rAllergens prove to be highly specific and safe. The diagnostic sensitivity of single rAllergens is generally lower than those obtained with allergen extracts, but can be considerably increased by using rAllergen panels covering the most important allergenic structures present in a given complex allergenic extract. Moreover, quantitative skin testing with single rAllergens allows interesting insights into correlations between the in vivo and in vitro sensitization to a given allergen. In conclusion, skin testing with rAllergens offers a highly specific and safe additional diagnostic tool to elucidate patient- and disease-specific sensitization patterns which will be needed for the development of patient-tailored immunotherapeutic treatments.

Prevention of allergy by a recombinant multi-allergen vaccine with reduced IgE binding and preserved T cell epitopes

Novel approaches for the prevention of allergy are required, because of the inevitably increasing prevalence of allergic diseases during the last 30 years. Here, a recombinant chimeric protein, which comprises the whole amino acid sequences of three bee venom major allergens has been engineered and used in prevention of bee venom sensitization in mice. Phospholipase A2 (Api m 1), hyaluronidase (Api m 2) and melittin (Api m 3) fragments with overlapping amino acids were assembled in a different order in the Api m (1/2/3) chimeric protein, which preserved entire T cell epitopes, whereas B cell epitopes of all three allergens were abrogated. Accordingly, IgE cross‐linking leading to mast cell and basophil mediator release was profoundly reduced in humans. Supporting these findings, the Api m (1/2/3) induced 100 to 1000 times less type‐1 skin test reactivity in allergic patients. Treatment of mice with Api m (1/2/3) led to a significant reduction of specific IgE development towards native allergen, representing a protective vaccine effect in vivo. These results demonstrate a novel prototype of a preventive allergy vaccine, which preserves the entire T cell epitope repertoire, but bypasses induction of IgE against native allergen, and side effects related to mast cell/basophil IgE FcϵRI cross‐linking in sensitized individuals.

Nuclear transport factor 2 represents a novel cross-reactive fungal allergen

Background: Ubiquitously occuring moulds are important allergenic sources known to elicit IgE‐mediated allergic diseases and to share cross‐reactive allergens. Limited information is available about the molecular structures involved in cross‐reactivity. We aimed to clone and characterize cross‐reactive mould allergens.

Human CD8 T cells of the peripheral blood contain a low CD8 expressing cytotoxic/effector subpopulation

Heterogeneity of lymphocyte populations demonstrates the diversity of cellular immune responses and provide a better understanding of the immune system. CD3+ CD8+ T cells exhibit a low CD8 expressing (CD8low) population in flow cytometric analysis of peripheral blood T cells. In healthy donors, this population consists of 0·2–7·0% of all CD8 T cells. The majority of the CD8low T cell population showed an elevated expression of CD25, CD45RA, and CD95L, and low levels of CD28, CD62L and CD45RO. Circulating CD8low T cells resemble cytotoxic effector cells because they express cytolytic mediators and are able to execute cytotoxicity. A restricted T cell receptor profile with increased Vβ9, Vβ14 and Vβ23 expression was observed and the CD8low T cell population contain Epstein–Barr virus‐specific T cells. Therefore, the CD8low population represent a subset of activated CD8 effector T cells, resulting most probably from a continous and/or balanced immune response to intracellular pathogens.