Neutrophil Extracellular Traps Induced by Shiga Toxin and Lipopolysaccharide-Treated Platelets Exacerbate Endothelial Cell Damage.

Hemolytic uremic syndrome (HUS) is the most common cause of acute renal failure in the pediatric population. The etiology of HUS is linked to Gram-negative, Shiga toxin (Stx)-producing enterohemorrhagic bacterial infections. While the effect of Stx is focused on endothelial damage of renal glomerulus, cytokines induced by Stx or bacterial lipopolysaccharide (LPS) and polymorphonuclear cells (PMNs) are involved in the development of the disease. PMN release neutrophil extracellular traps (NETs) to eliminate pathogens, although NETs favor platelets (Plts) adhesion/thrombus formation and can cause tissue damage within blood vessels. Since thrombus formation and occlusion of vessels are characteristic of HUS, PMN-Plts interaction in the context of Stx may promote netosis and contribute to the endothelial damage observed in HUS. The aim of this study was to determine the relevance of netosis induced by Stx in the context of LPS-sensitized Plts on endothelial damage. We observed that Stx2 induced a marked enhancement of netosis promoted by Plts after LPS stimulation. Several factors seemed to promote this phenomenon. Stx2 itself increased the expression of its receptor on Plts, increasing toxin binding. Stx2 also increased LPS binding to Plts. Moreover, Stx2 amplified LPS induced P-selectin expression on Plts and mixed PMN-Plts aggregates formation, which led to activation of PMN enhancing dramatically NETs formation. Finally, experiments revealed that endothelial cell damage mediated by PMN in the context of Plts treated with LPS and Stx2 was decreased when NETs were disrupted or when mixed aggregate formation was impeded using an anti-P-selectin antibody. Using a murine model of HUS, systemic endothelial damage/dysfunction was decreased when NETs were disrupted, or when Plts were depleted, indicating that the promotion of netosis by Plts in the context of LPS and Stx2 plays a fundamental role in endothelial toxicity. These results provide insights for the first time into the pivotal role of Plts as enhancers of endothelial damage through NETs promotion in the context of Stx and LPS. Consequently, therapies designed to reduce either the formation of PMN-Plts aggregates or NETs formation could lessen the consequences of endothelial damage in HUS.

Additive apoptotic effect of STI571 with the cytoprotective agent amifostine in K-562 cell line.

PURPOSE: To study the apoptotic effect of the 2-phenylaminopyrimidine derivative STI571 in combination with antioxidant agents on K-562 cell line derived from a Philadelphia chromosome-positive chronic myeloid leukemia patient. MATERIALS AND METHODS: K-562 (BCR/ABL+), U-937, and HL60 (BCR/ABL-) leukemic cell lines were incubated with STI571 and the antioxidant agents catalase, glutathione, superoxide dismutase, and amifostine (AMI). Apoptotic effect was analyzed by morphological and flow cytometric criteria. RESULTS: STI571 at concentrations higher than 0.25 mumol L(-1) produced apoptosis (P<0.05) in K-562 cells only after treatment for 72 h. At the mentioned concentrations, STI571 also induced an increase in the loss of mitochondrial transmembrane potential from 24.6 to 40%. Combination of STI571 (0.5 micromol L(-1)) with antioxidant agents showed that the cytoprotective agent AMI (0.75 mg mL(-1)) produced an additive effect in the proapoptotic activity of STI571 in K-562 cells at nuclear (58.8%+/-2.0 vs. 28.9%+/-3.3) and mitochondrial (53.3%+/-3.6 vs. 29.5%+/-1.2) levels. CONCLUSIONS: Our results show that only AMI in combination with STI571, at submicromolar concentration, has an additive effect in K-562 cell line, and it does not have severe toxic effects on Philadelphia chromosome negative cells.

Enhanced uptake of antisense oligonucleotides using cationic liposomes and the apoptotic effect of idarubicin in K-562 cell line.

We have evaluated the apoptotic and DNA damaging activity of Idarubicin (IDA) on K-562 cells alone and following the uptake of modified antisense-oligodeoxynucleotides (AS-ODNs) targeting b3a2 mRNA of bcr/abl hybrid gene, after treatment with AS-ODNs/DCChol-DOPE (liposomes) complexes. The uptake of FITC-labeled oligonucleotide-liposomes complexes (FITC-ODNs/DCChol-DOPE) was analyzed by flow cytometry and fluorescence microscopy. Both techniques indicated cytoplasmic accumulation of labeled liposome complexes following 24h of exposure. In absence of liposomes, AS-ODNs uptake was minimal. Pre-treatment of cells with AS-ODNs/DCChol-DOPE increased the capability of IDA to induce apoptosis as determined by morphology and the comet assay. In contrast, the use of a non-sense oligodeoxynucleotide conjugated with liposomes, in the presence of IDA, did not increase K-562 cell apoptosis. Nevertheless, DNA damage in IDA treated cells was not related to ODNs/liposomes pre-treatment, as determined by the comet assay. Our data suggests that DCChol-DOPE increases the uptake of ODNs in K-562 cells, and these modified AS-ODNs increase IDA induced apoptosis by decreasing p210(bcr/abl) levels in K-562 cells.