Enhanced oxidative stress and damage in glycated erythrocytes
Identificadores
Identificadores
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Visualización o descarga de ficheros
Fecha de publicación
2020Título de revista
PLoS One
Tipo de contenido
Journal Article
DeCS
especies reactivas de oxígeno | eritrocitos | técnicas de cocultivo | deformabilidad de los eritrocitos | voluntarios sanos | cultivo celular primario | línea celular | glucosa sanguínea | humanos | estrés oxidativo | hemólisis | diabetes mellitus | células endotelialesMeSH
Cell Line | Humans | Erythrocytes | Blood Glucose | Healthy Volunteers | Primary Cell Culture | Diabetes Mellitus | Hemolysis | Coculture Techniques | Reactive Oxygen Species | Erythrocyte Deformability | Oxidative Stress | Endothelial CellsResumen
Diabetes is associated with a dramatic mortality rate due to its vascular complications. Chronic hyperglycemia in diabetes leads to enhanced glycation of erythrocytes and oxidative stress. Even though erythrocytes play a determining role in vascular complications, very little is known about how erythrocyte structure and functionality can be affected by glycation. Our objective was to decipher the impact of glycation on erythrocyte structure, oxidative stress parameters and capacity to interact with cultured human endothelial cells. In vitro glycated erythrocytes were prepared following incubation in the presence of different concentrations of glucose. To get insight into the in vivo relevance of our results, we compared these data to those obtained using red blood cells purified from diabetics or non-diabetics. We measured erythrocyte deformability, susceptibility to hemolysis, reactive oxygen species production and oxidative damage accumulation. Altered structures, redox status and oxidative modifications were increased in glycated erythrocytes. These modifications were associated with reduced antioxidant defence mediated by enzymatic activity. Enhanced erythrocyte phagocytosis by endothelial cells was observed when cultured with glycated erythrocytes, which was associated with increased levels of phosphatidylserine-likely as a result of an eryptosis phenomenon triggered by the hyperglycemic treatment. Most types of oxidative damage identified in in vitro glycated erythrocytes were also observed in red blood cells isolated from diabetics. These results bring new insights into the impact of glycation on erythrocyte structure, oxidative damage and their capacity to interact with endothelial cells, with a possible relevance to diabetes.