Robust erythrophagocytosis leads to macrophage apoptosis via a hemin-mediated redox imbalance: role in hemolytic disorders.

MP from the RES are responsible for the clearance of senescent RBC. Although the frequency of senescent RBC is low under steady-state conditions, it increases dramatically during hemolytic disorders, resulting in enhanced erythrophagocytosis. As erythrophagocytosis has been involved in MP dysfunction and as certain hemolytic disorders associate to MP apoptosis, a possible link between erythrophagocytosis and the viability of phagocytes was investigated herein. To mimic hemolytic disorders, two distinct in vitro models, artificially oxidized RBC and DSRBC, were chosen to study the erythrophagocytosis impact on the viability of J774A.1 MP. Although CRBC were weakly phagocytosed and did not affect MP viability significantly, erythrophagocytosis of oxidized RBC and DSRBC was robust and resulted in a sharp decrease of MP viability via apoptosis. Under these conditions, Hb-derived HE was shown to be involved in the induction of apoptosis. Moreover, oxidized RBC, DSRBC, and HE generated ROS species, which were responsible for the apoptosis of MP. Furthermore, HO-1, strongly induced in response to treatment with oxidized RBC, DSRBC, or HE, was shown to protect MP partially against apoptosis, suggesting that robust erythro-phagocytosis may exceed the detoxification capabilities of MP. Taken together, these results suggest that enhanced erythrophagocytosis associated to hemolytic disorders leads to MP apoptosis in vitro and may have critical implications for the control of malaria infection and for the exacerbated susceptibility to bacterial infections during hemolytic disorders.

The IL-12p70/IL-10 interplay is differentially regulated by free heme and hemozoin in murine bone-marrow-derived macrophages.

The outcome of malarial anemia is determined by a complex interplay between pro-inflammatory and anti-inflammatory cytokines, its severity associated with accumulation of hemozoin (Hz) in macrophages, elevated IL-10 responses and impaired IL-12 production. Although free heme contributes to malarial anemia by inducing oxidative damage of red blood cells (RBCs) and enhancing their clearance by phagocytes, its impact on IL-12/IL-10 interactions has not been fully characterized. Herein, the effect of hemin (HE) on IL-12 and IL-10 responses was studied in murine bone marrow-derived macrophages (BMDM) and compared with synthetic Hz. Our data reveal that HE induces modest inhibition of IL-12p70 responses to lipopolysaccharide (LPS) whereas Hz significantly impairs IL-12p70 responses to IFNgamma/LPS through down-regulation of IL-12p35 and p40 gene expression. Although reactive oxygen species (ROS) are generated after short-term exposure to HE and Hz, prolonged exposure to these iron protoporphyrins has opposite effects on the cellular redox status, HE being the only compound able to promote persistent ROS production. Accordingly, the inhibitory effect of HE on IL-12p70 seems sustained by redox-dependent induction of IL-10 and is partially controlled by the p38 mitogen-activated protein kinase (MAPK) signalling pathway. Indeed, treatment with n-acetylcysteine (NAC) or with the p38 MAPK inhibitor SB203580 inhibits IL-10 responses and significantly restores IL-12p70 responses to IFNgamma/LPS in HE-conditioned BMDM. Our results suggest that oxidant stress induced by free heme may potentially contribute to sustained production of IL-10 and down-regulation of IL-12 responses in malaria.

Association of ion-channel genotype and macrocyclic lactone sensitivity traits in Haemonchus contortus.

Resistance to macrocyclic lactones in the strongylid parasite of sheep, Haemonchus contortus, is associated with specific alleles of several genes, including those encoding ligand-gated chloride-channels. While previous functional studies of the ion-channels encoded by these resistant alleles have revealed alterations in ligand binding and response to the anthelmintics, we still do not know how these alleles are contributing to resistance in vivo. To understand the phenomenon of anthelmintic resistance in detail we need to link changes in the genes of individual parasites with their ability to resist the effects of anthelmintic exposure. We have determined the genotype of individual adult and larval H. contortus with respect to the glc-5 and lgc-37 genes linked with macrocyclic lactone resistance. In these same individuals, we measured feeding and movement, two characteristics targeted by the drug, which are believed to contribute to parasite killing. Both genes are linked with altered behavior in the absence of drug, providing evidence that genetic resistance may be associated with alterations in parasite biology. In the presence of macrocyclic lactones, both genes are associated with a degree of protection against drug action. Whether this protection may be effective under the application of anthelmintic as part of normal farm practice and whether this could explain the evolution of resistance remain unclear.