Respiratory distress in severe malaria is associated with high mortality, but its pathogenesis remains unclear. The malaria pigment hemozoin (HZ) is abundant in target organs of severe malaria, including the lungs, and is known to be a potent innate immune activator of phagocytes. We hypothesized that HZ might also stimulate lung epithelial activation and thereby potentiate lung inflammation. We show here that airway epithelium stimulated with HZ undergoes global transcriptional reprogramming and changes in cell surface protein expression that comprise an epithelial activation phenotype. Proinflammatory signaling is induced, and key cytoadherence molecules are upregulated, including several associated with severe malaria, such as CD36 and ICAM1. Epithelial and extracellular matrix remodeling pathways are transformed, including induction of key metalloproteases and modulation of epithelial junctions. The overall program induced by HZ serves to promote inflammation and neutrophil transmigration, and is recapitulated in a murine model of HZ-induced acute pneumonitis. Together, our data demonstrate a direct role for hemozoin in stimulating epithelial activation that could potentiate lung inflammation in malaria.IMPORTANCE Respiratory distress (RD) is a complication of severe malaria associated with a particularly high risk for death in African children infected with the parasite Plasmodium falciparum The pathophysiology underlying RD remains poorly understood, and the condition is managed supportively. The parasite-derived factor HZ accumulates in target organs of severe malaria, including the lungs, and is a potent stimulator of immune cells. Our findings demonstrate that HZ causes global activation of lung epithelial cells, a response that directly promotes lung inflammation. HZ stimulates expression of key proinflammatory and cell surface molecules, alters signaling pathways involved in epithelial-matrix remodeling, and promotes neutrophil transmigration and airway inflammation. The lung epithelial activation induced by HZ mimics patterns seen in malarial lung injury and provides new insights into the molecular pathogenesis of RD.
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