Effects of genetic diversity on the allergenicity of peanut (Arachis hypogaea) proteins: identification of the hypoallergenic accessions using BALB/c mice model and in silico analysis of Ara h 3 allergen cross-reactivity

Abstract

This study investigated the effects of genetic diversity in the allergenicity of peanut and assessed the allergenic capacity of six Arachis hypogaea accessions using a Balb/c mouse model. It also explored potential cross-reactivities between Ara h 3 (peanut allergen) and Gly m (soybean allergen) using computational tools. Female Balb/c mice were injected with peanut protein extracts and alum. Serum-specific antibodies (IgE, IgGt, IgG1, IgG2a) were measured using ELISA, and allergic protein profiles were examined via western blot. Structural homology, B cell epitopes, and molecular interactions between Ara h 3 and Gly m with human IgE were also investigated. The mice developed high sIgE and sIgG1 responses, with antibodies recognizing 19 bands on western blot. Notably, Saharan accessions showed unique features such as no bands on western blot profiles, reduced anaphylactic symptoms, lower IgE titers, and less intestinal tissue damage. Molecular docking results suggest significant cross-allergenicity, supported by allergenicity predictions and structural homology analysis. This comprehensive analysis provides insights into shared epitopes, potential competition for binding sites, and molecular dynamics of cross-reactive responses, enhancing understanding of food allergen interactions. The study recommends using Algerian Sahara peanut accessions in breeding, genomics studies, and industry for safer peanut options for individuals with allergies.

Significance

The significance of this study lies in its contribution to addressing a major public health issue: peanut allergy, which represents a significant cause of anaphylaxis affecting numerous individuals and families worldwide. By exploring the genetic diversity of peanut proteins and identifying hypoallergenic accessions through experimental and computational approaches, this research offers valuable insights for mitigating allergic reactions. The findings highlight that certain accessions from the Saharan region exhibit reduced allergenicity, resulting in attenuated anaphylactic symptoms, lower IgE levels, and reduced intestinal damage in murine models. Furthermore, the study's in silico analysis sheds light on the issue of cross-reactivity between peanut and soybean allergens, providing crucial information for understanding allergen interactions at the molecular level. Overall, this research contributes to advancing knowledge in the field of food allergen research and has practical implications for improving the quality of life for individuals allergic to peanuts, particularly through the selection of safer peanut varieties and their cultivation.