BACKGROUND: The generation of IgE-mediated food allergy in humans is silent and only diagnosed upon manifestation of clinical symptoms. While experimental models have been used to investigate some mechanisms of allergic sensitization, the generation of humoral immunity and memory remains to be elucidated. Here, we defined the evolution of allergen-specific B-cell responses during epicutaneous sensitization to foods. METHODS: Wild-type and genetic knockout animals, and drug or antibody strategies for cell depletion and immunoglobulin signaling blockade were used to investigate epicutaneous sensitization and disease progression; we analyzed allergen-specific germinal centers and IgG1+ memory B cells by flow cytometry, evaluated humoral responses, and determined clinical reactivity (anaphylaxis). RESULTS: Epicutaneous sensitization caused microscopic skin damage, inflammation, and recruitment of activated dendritic cells to the draining lymph nodes. This process generated allergen-specific IgG1+ germinal center B cells, serum IgG1, and anaphylaxis that was mediated by the alternative pathway. Whether we used peanut and/or ovalbumin from the egg white for sensitization, the allergen-specific IgG1+ memory compartment predominantly exhibited an immature, pro-germinal center phenotype (PDL-2- CD80- CD35+ CD73+ ). Subsequent subclinical exposures to the allergen induced IgE+ germinal center B cells, serum IgE, and likely activated the classical pathway of anaphylaxis. CONCLUSIONS: Our data demonstrate that IgG1+ B-cell immunity against food allergens in epicutaneous sensitization precedes the generation of IgE responses. Therefore, the assessment of allergen-specific cellular and humoral IgG1+ immunity may help to identify individuals at risk of developing IgE-mediated food allergy and hence provide a window for therapeutic interventions.
BACKGROUND: The generation of IgE-mediated food allergy in humans is silent and only diagnosed upon manifestation of clinical symptoms. While experimental models have been used to investigate some mechanisms of allergic sensitization, the generation of humoral immunity and memory remains to be elucidated. Here, we defined the evolution of allergen-specific B-cell responses during epicutaneous sensitization to foods. METHODS: Wild-type and genetic knockout animals, and drug or antibody strategies for cell depletion and immunoglobulin signaling blockade were used to investigate epicutaneous sensitization and disease progression; we analyzed allergen-specific germinal centers and IgG1+ memory B cells by flow cytometry, evaluated humoral responses, and determined clinical reactivity (anaphylaxis). RESULTS: Epicutaneous sensitization caused microscopic skin damage, inflammation, and recruitment of activated dendritic cells to the draining lymph nodes. This process generated allergen-specific IgG1+ germinal center B cells, serum IgG1, and anaphylaxis that was mediated by the alternative pathway. Whether we used peanut and/or ovalbumin from the egg white for sensitization, the allergen-specific IgG1+ memory compartment predominantly exhibited an immature, pro-germinal center phenotype (PDL-2- CD80- CD35+ CD73+ ). Subsequent subclinical exposures to the allergen induced IgE+ germinal center B cells, serum IgE, and likely activated the classical pathway of anaphylaxis. CONCLUSIONS: Our data demonstrate that IgG1+ B-cell immunity against food allergens in epicutaneous sensitization precedes the generation of IgE responses. Therefore, the assessment of allergen-specific cellular and humoral IgG1+ immunity may help to identify individuals at risk of developing IgE-mediated food allergy and hence provide a window for therapeutic interventions.
Authors: Christopher C Udoye; Christina N Rau; Sarah M Freye; Larissa N Almeida; Sarah Vera-Cruz; Kai Othmer; Rabia Ü Korkmaz; Ann-Katrin Clauder; Timo Lindemann; Markus Niebuhr; Fabian Ott; Kathrin Kalies; Andreas Recke; Hauke Busch; Anke Fähnrich; Fred D Finkelman; Rudolf A Manz Journal: Mucosal Immunol Date: 2022-09-16 Impact factor: 8.701
Authors: Isabel J Skypala; Ricardo Asero; Domingo Barber; Lorenzo Cecchi; Arazeli Diaz Perales; Karin Hoffmann-Sommergruber; Elide A Pastorello; Ines Swoboda; Joan Bartra; Didier G Ebo; Margaretha A Faber; Montserrat Fernández-Rivas; Francesca Gomez; Anastasios P Konstantinopoulos; Olga Luengo; Ronald van Ree; Enrico Scala; Stephen J Till Journal: Clin Transl Allergy Date: 2021-05-18 Impact factor: 5.871
Authors: Carmen Riggioni; Pasquale Comberiati; Mattia Giovannini; Ioana Agache; Mübeccel Akdis; Magna Alves-Correia; Josep M Antó; Alessandra Arcolaci; Ahmet Kursat Azkur; Dilek Azkur; Burcin Beken; Cristina Boccabella; Jean Bousquet; Heimo Breiteneder; Daniela Carvalho; Leticia De Las Vecillas; Zuzana Diamant; Ibon Eguiluz-Gracia; Thomas Eiwegger; Stefanie Eyerich; Wytske Fokkens; Ya-Dong Gao; Farah Hannachi; Sebastian L Johnston; Marek Jutel; Aspasia Karavelia; Ludger Klimek; Beatriz Moya; Kari C Nadeau; Robyn O'Hehir; Liam O'Mahony; Oliver Pfaar; Marek Sanak; Jürgen Schwarze; Milena Sokolowska; María J Torres; Willem van de Veen; Menno C van Zelm; De Yun Wang; Luo Zhang; Rodrigo Jiménez-Saiz; Cezmi A Akdis Journal: Allergy Date: 2020-07-20 Impact factor: 14.710
Authors: Rodrigo Jiménez-Saiz; Varun C Anipindi; Heather Galipeau; Yosef Ellenbogen; Roopali Chaudhary; Joshua F Koenig; Melissa E Gordon; Tina D Walker; Talveer S Mandur; Soumeya Abed; Alison Humbles; Derek K Chu; Jonas Erjefält; Kjetil Ask; Elena F Verdú; Manel Jordana Journal: Front Immunol Date: 2020-02-13 Impact factor: 7.561