Daprodustat prevents cyclosporine-A-mediated anemia and peritubular capillary loss.

Chronic Cyclosporine-A treatment is associated with serious side effects, including kidney toxicity and anemia. Although pathophysiology of Cyclosporine-A-induced kidney injury remains incompletely understood, hypoxia is likely involved. Here, we investigated the effect of the hypoxia inducible factor activator daprodustat on Cyclosporine-A -induced kidney toxicity. As Cyclosporine-A profoundly alters protein phosphorylation by inhibiting the phosphatase calcineurin, special attention was directed towards the kidney phospho-proteome. Mice received Cyclosporine-A with or without daprodustat for up to eight weeks. In kidney homogenates, 1360 selected proteins were analyzed at expression and phosphorylation levels. Of these, Cyclosporine-A changed the expression of 79 and the phosphorylation of 86 proteins. However, when Cyclosporine-A treatment was combined with daprodustat, the expression of 95 proteins and phosphorylation of only six proteins was altered suggesting that daprodustat prevented most protein phosphorylation brought about by Cyclosporine-A. Although daprodustat showed only marginal effect on its own, angiogenesis-related pathways were among the most profoundly impacted by daprodustat when given on top of Cyclosporine-A. Additionally, Cyclosporine-A lowered the blood hemoglobin concentration and caused kidney capillary rarefaction, which daprodustat prevented. Thus, combined daprodustat/Cyclosporine-A treatment prevented deleterious Cyclosporine-A effects on microcirculation and hemoglobin, and the protective action of daprodustat involves suppression of broad protein phosphorylation changes caused by Cyclosporine-A.

Burkholderia pseudomallei modulates host iron homeostasis to facilitate iron availability and intracellular survival.

BACKGROUND: The control over iron homeostasis is critical in host-pathogen-interaction. Iron plays not only multiple roles for bacterial growth and pathogenicity, but also for modulation of innate immune responses. Hepcidin is a key regulator of host iron metabolism triggering degradation of the iron exporter ferroportin. Although iron overload in humans is known to increase susceptibility to Burkholderia pseudomallei, it is unclear how the pathogen competes with the host for the metal during infection. This study aimed to investigate whether B. pseudomallei, the causative agent of melioidosis, modulates iron balance and how regulation of host cell iron content affects intracellular bacterial proliferation. PRINCIPAL FINDINGS: Upon infection of primary macrophages with B. pseudomallei, expression of ferroportin was downregulated resulting in higher iron availability within macrophages. Exogenous modification of iron export function by hepcidin or iron supplementation by ferric ammonium citrate led to increased intracellular iron pool stimulating B. pseudomallei growth, whereas the iron chelator deferoxamine reduced bacterial survival. Iron-loaded macrophages exhibited a lower expression of NADPH oxidase, iNOS, lipocalin 2, cytokines and activation of caspase-1. Infection of mice with the pathogen caused a diminished hepatic ferroportin expression, higher iron retention in the liver and lower iron levels in the serum (hypoferremia). In vivo administration of ferric ammonium citrate tended to promote the bacterial growth and inflammatory response, whereas limitation of iron availability significantly ameliorated bacterial clearance, attenuated serum cytokine levels and improved survival of infected mice. CONCLUSIONS: Our data indicate that modulation of the cellular iron balance is likely to be a strategy of B. pseudomallei to improve iron acquisition and to restrict antibacterial immune effector mechanisms and thereby to promote its intracellular growth. Moreover, we provide evidence that changes in host iron homeostasis can influence susceptibility to melioidosis, and suggest that iron chelating drugs might be an additional therapeutic option.