t-BOOH-induced oxidative damage in sickle red blood cells and the role of flavonoids.

Sickle cell anemia is a genetic disease characterized byan increase in generation of reactive oxygen species, abnormal iron release and low antioxidant activity which can lead to cell injury. Several therapies have been used to decrease the oxidative damage in these patients. In this study, we investigated the effect of flavonoids (quercetin and rutin) on the oxidation of red blood cells (RBC) from sickle cell anemia patients following exposure of the cells to tert-butyl hydroperoxide (t-BOOH). Quercetin provided greater protection against Hb oxidation, the binding of Hb to membrane and lipid peroxidation than did rutin. Quercetin (150 microM) reduced Hb oxidation by 30% and increased the level of oxyHb from 17.5 to 29 microM. Rutin prevented Hb oxidation only at concentrations higher than 200 microM and did not prevent the binding of Hb to RBC membrane. These distinct effects of the flavonoids probably reflect their structural characteristics. Thus, quercetin, which possesses a suitable structure for free-radical scavenging and ion quelation, was a more effective antioxidant than rutin. The presence of rutinose at position C(3) in rutin may impair its antioxidant effect. The presence of ascorbic acid enhanced the protective effect of quercetin and rutin against oxidative stress in sickle Hb and lipid peroxidation. This synergistic action helped to maintain a constant supply of flavonoids and thus, rescue the cells from the injury caused by free radicals and iron ions.

Functional behavior of tortoise hemoglobin Geochelone denticulata

The hemolysate from Geochelone denticulata contains two main hemoglobin components, as shown by ion exchange chromatography and polyacrylamide gel electrophoresis (PAGE). Electrophoresis under dissociating conditions showed three types of globin chains. The apparent molecular mass, as determined by gel filtration on Sephadex G-200, was compatible with tetrameric Hb, which was unable to polymerize. The G. denticulata Hb has a P50 value of 9.56 mm Hg at pH 7.4. The Hb oxygenation appears to be under the control of organic phosphates and hydrogen ion since it is strongly affected by those species. In the presence ATP or IHP the P50 values increased to 29.51 mm Hg and 54.95 mm Hg, respectively, at pH 7.4. The n50 was generally lower than 1.5 in stripped Hb, suggesting a dissociation of tetramers. In the presence of organic phosphates n50 values increased to approximately 2.5. The Bohr effect was evident in oxygen equilibrium experiments. The hematocrit (32 percent) and Hb concentration (5.7 mM as heme) of G. denticulata blood were substantially larger than those of G. carbonaria, but the methemoglobin levels were similar in both species, approximately 1 percent. Thus, the oxygen capacity of blood appears to be higher in G. denticulata than in G. carbonaria, particularly considering the functional properties of their Hbs, which would guarantee the survival of animals

Functional behavior of tortoise hemoglobin Geochelone denticulata.

The hemolysate from Geochelone denticulata contains two main hemoglobin components, as shown by ion exchange chromatography and polyacrylamide gel electrophoresis (PAGE). Electrophoresis under dissociating conditions showed three types of globin chains. The apparent molecular mass, as determined by gel filtration on Sephadex G-200, was compatible with tetrameric Hb, which was unable to polymerize. The G. denticulata Hb has a P50 value of 9.56 mm Hg at pH 7.4. The Hb oxygenation appears to be under the control of organic phosphates and hydrogen ion since it is strongly affected by those species. In the presence ATP or IHP the P50 values increased to 29.51 mm Hg and 54.95 mm Hg, respectively, at pH 7.4. The n50 was generally lower than 1.5 in stripped Hb, suggesting a dissociation of tetramers. In the presence of organic phosphates n50 values increased to approximately 2.5. The Bohr effect was evident in oxygen equilibrium experiments. The hematocrit (32%) and Hb concentration (5.7 mM as heme) of G. denticulata blood were substantially larger than those of G. carbonaria, but the methemoglobin levels were similar in both species, approximately 1%. Thus, the oxygen capacity of blood appears to be higher in G. denticulata than in G. carbonaria, particularly considering the functional properties of their Hbs, which would guarantee the survival of animals.