Browsing by Author "F. Omodeo-Salè"

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    Dysregulation of L-arginine metabolism and bioavailability associated to free plasma heme
    (2010-07-01) F. Omodeo-Salè; L. Cortelezzi; Z. Vommaro; D. Scaccabarozzi; A. M. Dondorp; Universita degli Studi di Milano; Mahidol University; Churchill Hospital
    Severe Plasmodium falciparum malaria is associated with hypoargininemia, which contributes to impaired systemic and pulmonary nitric oxide (NO) production and endothelial dysfunction. Since intravascular hemolysis is an intrinsic feature of severe malaria, we investigated whether and by which mechanisms free heme [Fe(III)-protoporphyrin IX (FP)] might contribute to the dysregulation of L-arginine (L-Arg) metabolism and bioavailability. Carrier systems "y+" [or cationic amino acid transporter (CAT)] and "y+L" transport L-Arg into red blood cells (RBC), where it is hydrolyzed to ornithine and urea by arginase (isoform I) or converted to NO•and citrulline by endothelial nitric oxide synthase (eNOS). Our results show a significant and dose-dependent impairment of L-Arg transport into RBC pretreated with FP, with a strong inhibition of the system carrier y+L. Despite the impaired L-Arg influx, higher amounts of L-Arg-derived urea are produced by RBC preexposed to FP caused by activation of RBC arginase I. This activation appeared not to be mediated by oxidative modifications of the enzyme. We conclude that L-Arg transport across RBC membrane is impaired and arginase-mediated L-Arg consumption enhanced by free heme. This could contribute to reduced NO production in severe malaria. Copyright © 2010 the American Physiological Society.
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    Oxidative stress and rheology in severe malaria
    (2003-12-01) Arjen M. Dondorp; F. Omodeo-Salè; K. Chotivanich; D. Taramelli; N. J. White; Mahidol University; Nuffield Department of Clinical Medicine; Universita degli Studi di Milano
    There is mounting evidence that the release of haemozoin (β-haematin), which is produced in large amounts during malaria infection and is released into the circulation during schizont rupture, is associated with damage to cell membranes through an oxidative mechanism. The red blood cell membrane is thus oxidised, causing rigidity of the cell. This can contribute to the pathophysiology of severe malaria, since red blood cells will have to deform considerably in order to squeeze through the microcirculation, the patency of which is disturbed by sequestered red blood cells containing the mature forms of the parasite. Rigidity of red blood cells forms a new target for intervention. Since this seems to be caused by oxidative damage to the red blood cell membrane, the anti-oxidant N-acetylcysteine is a promising candidate for adjunctive treatment in severe malaria, which still has a mortality rate as high as 20%.