Abstract
Pulmonary type 2 innate lymphoid cells (ILC2s) exhibit immune memory, termed "trained immunity," which enhances their activation following exposure to an independent protease-containing allergen. The role of prostaglandin I2 (PGI2), a cyclooxygenase (COX) pathway metabolite, in modulating these trained ILC2 responses remains unclear. PGI2 acts through its G protein-coupled receptor IP. We hypothesized that IP signaling inhibits ILC2 training. To test this hypothesis, we used a mouse ILC2 training model in which we challenged wild-type (WT) and IP knockout (KO) mice with Alternaria alternata extract (Alt) to induce ILC2 activation and training. After a 33-d resting period, ILC2 responses subsided to a homeostatic level. Mice were then intranasally challenged with papain to evaluate responses to an unrelated allergen. IP KO mice displayed significantly heightened ILC2 interleukin (IL)-13 expression and with concomitant increased eosinophilia in the lungs post-papain challenge compared with WT control mice. Notably, neither WT nor IP KO mice challenged with papain only, devoid of ILC2 training, exhibited lung type 2 responses. The augmented type 2 inflammation observed in IP KO mice following both Alt and papain challenges correlated with increased numbers and percentages of IL-13-producing ILC2s and greater mean fluorescence intensity of IL-13 compared with WT mice. Furthermore, RNA sequencing of sorted ILC2s from WT and IP KO mice following Alt-papain challenges revealed heightened activation of immune response pathways and mitochondrial respiratory pathways in IP-deficient ILC2s. These findings reveal an inhibitory role of PGI2 signaling in trained ILC2 responses, emphasizing its pivotal contribution to innate immune responses and allergic inflammation.