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SFN2024: Venez rencontrer notre équipe sur le stand 876 à Chicago Authors
Philipp Starkl, Ferdinand Felix, Durga Krishnamurthy, Caroline Stremnitzer, Franziska Roth-Walter, Sara R. Prickett et al.
Lab
Medical University of Vienna, Vienna, Austria / The Alfred Hospital and Monash University, Melbourne, Australia
Journal
Clinical & Experimental Allergy
Abstract
Background
Peanut allergy causes severe type 1 hypersensitivity reactions and conventional immunotherapy against peanut allergy is associated with a high risk of anaphylaxis.
Objective
Our current study reports proof of concept experiments on the safety of a stably denatured variant of the major peanut allergen Ara h 2 for immunotherapy. We determined the impact of structure loss of Ara h 2 on its IgE binding and basophil degranulation capacity, T-cell reactivity as well as anaphylactic potential.
Methods
The secondary structure of untreated and reduced/alkylated Ara h 2 variants was determined by circular dichroism spectroscopy. We addressed human patient IgE binding to Ara h 2 by ELISA and Western blot experiments. RBL-SX38 cells were used to test the degranulation induced by untreated and reduced/alkylated Ara h 2. We assessed the anaphylactic potential of Ara h 2 variants by challenge of sensitized BALB/c mice. T cell reactivity was investigated using human Ara h 2 specific T cell lines and splenocytes isolated from sensitized mice.
Results
Reduction/alkylation of Ara h 2 caused a decrease in IgE binding capacity, basophil degranulation and anaphylactic potential in vivo. However, the human T cell response to reduced/alkylated and untreated Ara h 2 was comparable. Mouse splenocytes showed higher metabolic activity upon stimulation with reduced/alkylated Ara h 2 and released similar IL-4, IL-13, and IFN? levels upon treatment with either Ara h 2 variant.
Conclusion and Clinical Relevance
Reduced/alkylated Ara h 2 might be a safer alternative than native Ara h 2 for immunotherapeutic treatment of peanut allergic patients.