Human erythrocyte damage at the initial stages of oxidative stress.

Specific fluorescent probes have been used to monitor changes in erythrocyte membranes in the first stages of the hemolytic process induced by irradiation with visible light in the presence of protoporphyrin IX. Although no change, or even a slight increase of fluorescence anisotropy, occurred with two probes having a preferential binding to membrane proteins, such as fluorescamine and 3-pyrene maleimide, the fluorescence anisotropy of two lipophilic probes, namely diphenyl-hexatriene and anilino-naphthalene sulfonate, underwent a substantial decrease upon irradiation. Concomitantly, a dramatic decrease of ATPase activity and an increase of thiobarbituric-reacting substances were observed in erythrocyte membranes. Instead, there was no effect on the activities of the intracellular enzymes glucose-6-phosphate dehydrogenase and pyruvate kinase. These findings are consistent with the hypothesis that protoporphyrin-sensitized irradiation induces, primarily in the erythrocyte membrane, the peroxidation of the lipid component, which results in an increase of the fluidity of the bilayer. Hemolysis eventually occurs because of an osmotic imbalance resulting from the combination of increased passive diffusion and decreased active ion transport.

Fluorescence studies of the aged erythrocyte membranes.

The most important purpose of this research is to characterize by means of fluorescence polarization the structural and functional changes which occur in the membrane of the human erythrocytes during aging process. Our results provide evidence of a significant increase of membrane fluidity in the deep lipid core and in the lipid/protein boundary, in the aged erythrocytes. These features are associated with a rigidity of the membrane surface, as revealed by the anisotropy increase of a specific probe suitable for monitoring the membrane protein behaviour. These modifications could be considered as one of the mechanisms which contribute to alter erythrocyte rheological properties sufficiently to be recognised and removed within circulation.