Epigenetic programming underpins B-cell dysfunction in peanut and multi-food allergy

Samira Imran; Melanie R Neeland; Jennifer Koplin; Shyamali Dharmage; Mimi Lk Tang; Susan Sawyer; Thanh Dang; Vicki McWilliam; Rachel Peters; Kirsten P Perrett; Boris Novakovic; Richard Saffery

doi:10.1002/cti2.1324

Epigenetic programming underpins B-cell dysfunction in peanut and multi-food allergy

Clin Transl Immunology. 2021 Aug 24;10(8):e1324. doi: 10.1002/cti2.1324. eCollection 2021.

Authors

Samira Imran¹, Melanie R Neeland¹, Jennifer Koplin¹, Shyamali Dharmage^{1

2}, Mimi Lk Tang^{1

3}, Susan Sawyer^{1

4}, Thanh Dang¹, Vicki McWilliam^{1

3}, Rachel Peters¹, Kirsten P Perrett^{1

3}, Boris Novakovic¹, Richard Saffery¹

Affiliations

¹ Murdoch Children's Research Institute, and Department of Paediatrics University of Melbourne Royal Children's Hospital Parkville VIC Australia.
² Allergy and Lung Health Unit Melbourne School of Population and Global Health University of Melbourne Carlton VIC Australia.
³ Department of Allergy and Immunology Royal Children's Hospital Melbourne VIC Australia.
⁴ Centre for Adolescent Health Royal Children's Hospital Melbourne VIC Australia.

Abstract

Objective: Rates of IgE-mediated food allergy (FA) have increased over the last few decades, and mounting evidence implicates disruption of epigenetic profiles in various immune cell types in FA development. Recent data implicate B-cell dysfunction in FA; however, few studies have examined epigenetic changes within these cells.

Methods: We assessed epigenetic and transcriptomic profiles in purified B cells from adolescents with FA, comparing single-food-allergic (peanut only), multi-food-allergic (peanut and ≥1 other food) and non-allergic (control) individuals. Adolescents represent a phenotype of persistent and severe FA indicative of a common immune deviation.

Results: We identified 144 differentially methylated probes (DMPs) and 116 differentially expressed genes (DEGs) that distinguish B cells of individuals with FA from controls, including differential methylation of the PM20D1 promoter previously associated with allergic disorders. Subgroup comparisons found 729 DMPs specific to either single-food- or multi-food-allergic individuals, suggesting epigenetic distinctions between allergy groups. This included two regions with increased methylation near three S100 genes in multi-food-allergic individuals. Ontology results of DEGs specific to multi-food-allergic individuals revealed enrichment of terms associated with myeloid cell activation. Motif enrichment analysis of promoters associated with DMPs and DEGs showed differential enrichment for motifs recognised by transcription factors regulating B- and T-cell development, B-cell lineage determination and TGF-β signalling pathway between the multi-food-allergic and single-food-allergic groups.

Conclusion: Our data highlight epigenetic changes in B cells associated with peanut allergy, distinguishing features of the epigenome between single-food- and multi-food-allergic individuals and revealing differential developmental pathways potentially underpinning these distinct phenotypes.

Keywords: B cells; epigenetics; multi‐food allergy; peanut allergy; transcriptomics.