Metabolic imprinting drives epithelial memory during mucosal fungal infection.

Epithelial cells at barrier sites are emerging as active participants in innate immune memory, yet the underlying metabolic and epigenetic mechanisms remain unclear. Here, we uncover a previously unrecognized form of trained immunity in oral epithelial cells that enhances protection against fungal infection. Using a mouse model, we show that mucosal exposure to Candida albicans confers sustained protective memory that is independent of adaptive immunity and myeloid cells. Mechanistically, mucosal memory is driven by proline catabolism via proline dehydrogenase (Prodh) in epithelial cells, which sustains mitochondrial function, epigenetic remodeling, and promotes cytokine production upon secondary challenge. Unlike classical trained immunity in immune cells, epithelial memory is independent of glycolysis but partially sustained by fatty acid oxidation via carnitine palmitoyltransferase-I (CPT1). These findings uncover a distinct metabolic-epigenetic axis that underlines long-term epithelial memory in the oral mucosa and reveal novel non-hematopoietic mechanisms of mucosal defense against fungal pathogens.