Human-specific bacterial pore-forming toxins induce programmed necrosis in erythrocytes.

UNLABELLED: A subgroup of the cholesterol-dependent cytolysin (CDC) family of pore-forming toxins (PFTs) has an unusually narrow host range due to a requirement for binding to human CD59 (hCD59), a glycosylphosphatidylinositol (GPI)-linked complement regulatory molecule. hCD59-specific CDCs are produced by several organisms that inhabit human mucosal surfaces and can act as pathogens, including Gardnerella vaginalis and Streptococcus intermedius. The consequences and potential selective advantages of such PFT host limitation have remained unknown. Here, we demonstrate that, in addition to species restriction, PFT ligation of hCD59 triggers a previously unrecognized pathway for programmed necrosis in primary erythrocytes (red blood cells [RBCs]) from humans and transgenic mice expressing hCD59. Because they lack nuclei and mitochondria, RBCs have typically been thought to possess limited capacity to undergo programmed cell death. RBC programmed necrosis shares key molecular factors with nucleated cell necroptosis, including dependence on Fas/FasL signaling and RIP1 phosphorylation, necrosome assembly, and restriction by caspase-8. Death due to programmed necrosis in RBCs is executed by acid sphingomyelinase-dependent ceramide formation, NADPH oxidase- and iron-dependent reactive oxygen species formation, and glycolytic formation of advanced glycation end products. Bacterial PFTs that are hCD59 independent do not induce RBC programmed necrosis. RBC programmed necrosis is biochemically distinct from eryptosis, the only other known programmed cell death pathway in mature RBCs. Importantly, RBC programmed necrosis enhances the growth of PFT-producing pathogens during exposure to primary RBCs, consistent with a role for such signaling in microbial growth and pathogenesis. IMPORTANCE: In this work, we provide the first description of a new form of programmed cell death in erythrocytes (RBCs) that occurs as a consequence of cellular attack by human-specific bacterial toxins. By defining a new RBC death pathway that shares important components with necroptosis, a programmed necrosis module that occurs in nucleated cells, these findings expand our understanding of RBC biology and RBC-pathogen interactions. In addition, our work provides a link between cholesterol-dependent cytolysin (CDC) host restriction and promotion of bacterial growth in the presence of RBCs, which may provide a selective advantage to human-associated bacterial strains that elaborate such toxins and a potential explanation for the narrowing of host range observed in this toxin family

Plasmodium falciparum glycolipid synthesis: constant and variant molecules of isolates and of strains with differing knob and cytoadherence phenotype.

Plasmodium falciparum-infected erythrocytes were metabolically labeled with tritiated glucosamine. Lipid extracts were analyzed by high-performance thin-layer chromatography to compare labeled molecules of eleven isolates from patients, six cytoadherent in vitro strains, and two knobbed and two knobless strains from Aotus monkeys. Up to nineteen labeled bands were identified. Glycolipid GL1, previously identified in Malayan Camp, was present in all isolates and strains. Other molecules, between CG and GM1 and between GM1 and GD1a, varied in mobility or presence. There was no apparent association between labeled molecules and the presence of knobs or the property of cytoadherence

Studies of the receptors on melanoma cells for Plasmodium falciparum infected erythrocytes.

We investigated whether thrombospondin plays a role in the binding of Plasmodium falciparum parasitized erythrocytes to C32 melanoma cells. Twelve patient isolates bound variably to melanoma cells, with good correlation between the degree of binding to cells and binding to thrombospondin. With a synchronous preparation of asexual parasites, acquisition of the capacity to bind to thrombospondin occurred at the same parasite stage as binding to melanoma cells. Development of parasites to trophozoites and schizonts correlated with binding of parasitized erythrocytes to thrombospondin and melanoma cells. The infected erythrocyte receptor for thrombospondin was destroyed by mild trypsinization, as was the receptor for melanoma cells. Although these results suggest similarity in the melanoma cell receptor and thrombospondin receptor for infected cells, other results showed that thrombospondin cannot alone be the melanoma cell receptor. Binding to other melanoma cell lines did not correlate with thrombospondin secretion: the RPMI 8252 and G361 cell lines bound few or no infected cells, yet secreted 50-100% as much thrombospondin as C32 cells. Iodinated thrombospondin bound in similar amounts to C32 cells and to noncytoadherent C361 melanoma cells. Binding and nonbinding melanoma cells did not differ in quantity of surface thrombospondin by radioimmunoassay. Thus, although purified, immobilized, thrombospondin binds parasitized erythrocytes, expression of thrombospondin alone on melanoma cells is not sufficient to mediate adherence

Thrombospondin binding by parasitized erythrocyte isolates in falciparum malaria.

Toward understanding the pathogenesis of vascular sequestration in falciparum malaria, we investigated binding of Plasmodium falciparum parasitized erythrocyte isolates to thrombospondin and other adhesive proteins. Blood samples with rings from 12 patients with falciparum malaria were cultured 30 hr until parasites were mature trophozoites and schizonts. All parasitized erythrocyte isolates bound to thrombospondin, but not to fibronectin, laminin, vitronectin, or factor VIII/von Willebrand factor. Parasitized erythrocyte binding varied among isolates, ranging from 192 to 6,725 per mm2, average 2,953. There was good correlation between trophozoite plus schizont % parasitemia and thrombospondin binding (r = 0.884, P less than 0.001). In two patients with stupor, 3,642 and 2,864 parasitized erythrocytes bound per mm2, in proportion to parasitemia, suggesting cerebral malaria is not due to increased binding affinity. These results indicate there is a conserved function among isolates from this geographic region, known to be antigenically diverse at the parasitized erythrocyte membrane surface. These results support the hypothesis that specific binding to an endothelial receptor, possibly involving thrombospondin, plays a role in vascular sequestration in falciparum malaria