Malaria-associated acute respiratory distress syndrome (MA-ARDS) is a deadly complication of malaria, and its pathophysiology is insufficiently understood. Both in humans and in murine models, MA-ARDS is characterized by marked pulmonary inflammation. We investigated the role of hemozoin in MA-ARDS in C57Bl/6 mice infected with Plasmodium berghei NK65, P. berghei ANKA, and P. chabaudi AS. By quantifying hemozoin in the lungs and measuring the disease parameters of MA-ARDS, we demonstrated a highly significant correlation between pulmonary hemozoin concentrations, lung weights, and alveolar edema. Histological analysis of the lungs demonstrated that hemozoin is localized in phagocytes and infected erythrocytes, and only occasionally in granulocytes. Species-specific differences in hemozoin production, as measured among individual schizonts, were associated with variations in pulmonary pathogenicity. Furthermore, both pulmonary hemozoin and lung pathology were correlated with the number of infiltrating inflammatory cells, an increased pulmonary expression of cytokines, chemokines, and enzymes, and concentrations of alveolar vascular endothelial growth factor. The causal relationship between hemozoin and inflammation was investigated by injecting P. falciparum-derived hemozoin intravenously into malaria-free mice. Hemozoin potently induced the pulmonary expression of proinflammatory chemokines (interferon-γ inducible protein-10/CXC-chemokine ligand (CXCL)10, monocyte chemotactic protein-1/CC-chemokine ligand 2, and keratinocyte-derived chemokine/CXCL1), cytokines (IL-1β, IL-6, IL-10, TNF, and transforming growth factor-β), and other inflammatory mediators (inducible nitric oxide synthase, heme oxygenase-1, nicotinamide adenine dinucleotide phosphate- oxidase-2, and intercellular adhesion molecule-1). Thus, hemozoin correlates with MA-ARDS and induces pulmonary inflammation.
The 15q24/25 locus in nAChR is associated with the presence and severity of emphysema. This association was independent of pack-years smoking, suggesting that nAChR is causally involved in alveolar destruction as a potentially shared pathogenic mechanism in lung cancer and COPD.
Malaria is a global disease that clinically affects more than two hundred million people annually. Despite the availability of effective antimalarials, mortality rates associated with severe complications are high. Hepatopathy is frequently observed in patients with severe malarial disease and its pathogenesis is poorly understood. Previously, we observed high amounts of hemozoin or malaria pigment in livers from infected mice. In this study, we investigated whether hemozoin is associated with liver injury in different mouse malaria models. C57BL/6J mice infected with the rodent parasites Plasmodium berghei ANKA, P. berghei NK65 or P. chabaudi AS had elevated serum liver enzymes without severe histological changes in the liver, in line with the observations in most patients. Furthermore, liver enzymes were significantly higher in serum of P. chabaudi AS-infected mice compared to mice infected with the P. berghei parasite strains and a strong positive correlation was found between hepatic hemozoin levels, hepatocyte damage and inflammation in the liver with P. chabaudi AS. The observed liver injury was only marginally influenced by the genetic background of the host, since similar serum liver enzyme levels were measured in infected C57BL/6J and BALB/c mice. Intravenous injection of P. falciparum-derived hemozoin in malaria-free C57BL/6J mice induced inflammatory gene transcription in the liver, suggesting that hemozoin may be involved in the pathogenesis of malaria hepatopathy by inducing inflammation.
Malaria reduces host fitness and survival by pathogen-mediated damage and inflammation. Disease tolerance mechanisms counter these negative effects without decreasing pathogen load. Here, we demonstrate that in four different mouse models of malaria, adrenal hormones confer disease tolerance and protect against early death, independently of parasitemia. Surprisingly, adrenalectomy differentially affects malaria-induced inflammation by increasing circulating cytokines and inflammation in the brain but not in the liver or lung. Furthermore, without affecting the transcription of hepatic gluconeogenic enzymes, adrenalectomy causes exhaustion of hepatic glycogen and insulin-independent lethal hypoglycemia upon infection. This hypoglycemia is not prevented by glucose administration or TNF-α neutralization. In contrast, treatment with a synthetic glucocorticoid (dexamethasone) prevents the hypoglycemia, lowers cerebral cytokine expression and increases survival rates. Overall, we conclude that in malaria, adrenal hormones do not protect against lung and liver inflammation. Instead, they prevent excessive systemic and brain inflammation and severe hypoglycemia, thereby contributing to tolerance.
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