Polycomb repressive complex 2 is a critical mediator of allergic inflammation
Christine R. Keenan, Nadia Iannarella, Alexandra L. Garnham, Alexandra C. Brown, Richard Y. Kim, Jay C. Horvat, Philip M. Hansbro, Stephen L. Nutt, Rhys S. Allan
Christine R. Keenan, Nadia Iannarella, Alexandra L. Garnham, Alexandra C. Brown, Richard Y. Kim, Jay C. Horvat, Philip M. Hansbro, Stephen L. Nutt, Rhys S. Allan
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Research Article Immunology Inflammation

Polycomb repressive complex 2 is a critical mediator of allergic inflammation

Abstract

Strategies that intervene with the development of immune-mediated diseases are urgently needed, as current treatments mostly focus on alleviating symptoms rather than reversing the disease. Targeting enzymes involved in epigenetic modifications to chromatin represents an alternative strategy that has the potential to perturb the function of the lymphocytes that drive the immune response. Here, we report that 2 major epigenetic silencing pathways are increased after T cell activation. By specific inactivation of these molecules in the T cell compartment in vivo, we demonstrate that the polycomb repressive complex 2 (PRC2) is essential for the generation of allergic responses. Furthermore, we show that small-molecule inhibition of the PRC2 methyltransferase, enhancer of zeste homolog 2 (Ezh2), reduces allergic inflammation in mice. Therefore, by systematically surveying the pathways involved in epigenetic gene silencing we have identified Ezh2 as a target for the suppression of allergic disease.

Authors

Christine R. Keenan, Nadia Iannarella, Alexandra L. Garnham, Alexandra C. Brown, Richard Y. Kim, Jay C. Horvat, Philip M. Hansbro, Stephen L. Nutt, Rhys S. Allan

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Figure 2

Ezh2 is essential for T cells to drive allergic inflammation.

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Ezh2 is essential for T cells to drive allergic inflammation. (A) Experi...
(A) Experimental protocol of OVA-induced allergic inflammation. (B) Representative forward-scatter (FSC) versus side-scatter (SSC) flow cytometric plots of bronchoalveolar lavage (BAL) samples from Ezh2fl/fl Cd4Cre and WT C57BL/6 (Bl/6) mice following OVA-induced allergic inflammation. Data shown are representative of n = 2 (WT/alum), n = 8 (Ezh2fl/fl Cd4Cre/alum), n = 12 (WT/OVA), n = 11 (Ezh2fl/fl Cd4Cre/OVA). (C) Gating strategy identifying individual leukocyte populations in BAL samples from OVA-sensitized and -challenged Ezh2fl/fl control and Ezh2fl/fl Cd4Cre animals. (D) Quantification of the results in C. Individual data points as well as mean and SEM shown. OVA-sensitized Ezh2fl/fl (n = 6) and Ezh2fl/fl Cd4Cre (n = 6) groups were compared by Mann-Whitney U test. Unchallenged Bl/6 (n = 2) shown for comparative purposes. (E) Representative histological analysis of the airways of Ezh2fl/fl CD4Cre and Bl/6 mice following OVA-induced allergic inflammation. Scale bars: 100 μm. (F) Quantification of PAS+ cells and inflammation score. OVA refers to initial sensitization with all mice exposed to nebulized OVA challenge. Mean and SEM as well as individual data points shown for n = 12 (Bl/6/OVA), n = 4 (Ezh2fl/fl/OVA), n = 13 (Ezh2fl/flCd4Cre/OVA), n = 7 (Ezh2fl/fl Cd4Cre/alum). Statistical significance was determined by Kruskal-Wallis H test with Dunn’s post hoc test. (G) Airway resistance (Rn) following OVA-induced allergic inflammation in Ezh2fl/fl (n = 7 for 0–10 mg/ml methacholine [MCh], n = 6 for 30 mg/ml MCh) and Ezh2fl/fl Cd4Cre mice (n = 7). Unchallenged Bl/6 mice (n = 6 for 0–3 mg/ml MCh, n = 5 for 10–30 mg/ml MCh) were included to indicate baseline bronchoconstriction in response to MCh. Mean and SEM together with individual data points are shown. Data were analyzed by 2-way ANOVA with Bonferroni’s post hoc test. *P < 0.05 with specific comparisons denoted in central and right-hand panels.