Oxidized Human Beta2-Glycoprotein I: Its Impact on Innate Immune Cells
Abstract:Beta2-glycoprotein I (β2-GPI), an abundant 50 kDa plasma glycoprotein, is the most common target for antiphospholipid antibodies (aPLs). These autoantibodies are associated with thrombotic events in patients with anti-phospholipid antibody syndrome (APS) and systemic lupus erythematosus (SLE) and are proatherogenic. β2-GPI can also stimulate a vigorous adaptive cellular immune response in these patients. Although much is known about β2-GPI as a cofactor in autoimmune diseases, crucial information is still lacking to clarify why this abundant self plasma protein is the target of autoimmune responses. Throughout the years, a remarkable number of theories have been proposed to explain how the immune system recognises self. On the basis of a large variety of epidemiological, clinical and experimental evidence, it has been suggested that an unfortunate interplay of genetic susceptibility and environmental factors may play an important role in generating an abnormal immune response. Among the environmental factors, oxidative stress is one of the major events causing protein structural modifications, thus inducing the appearance of neo/cryptic epitopes of β2-GPI able to activate the immune system. In particular, oxidized β2-GPI is able to induce phenotypic and functional maturation of dendritic cells which represent the link between innate and adaptive immunity. Chronic activation of autoimmune reactions against this self protein modified by oxidative events may contribute to local and systemic inflammation, thus sustaining endothelial dysfunction in patients with APS, SLE and cardiovascular diseases. The role of oxidative stress in β2-GPI-mediated immune response is described in the light of our research experience and of relevant literature emerging in the field.
Keywords: Autoimmunity; anti-phospholipid antibody syndrome; antiphospholipid antibodies; apolipoprotein; atherosclerosis; beta2-glycoprotein I; coagulation system; dendritic cells; endothelial dysfunction; homeostasis; innate immunity; monocytes; oxidative stress; systemic lupus erythematosus; vascular biology
Document Type: Research Article
Publication date: December 1, 2011
- Current Molecular Medicine is an interdisciplinary journal focused on providing the readership with current and comprehensive reviews on fundamental molecular mechanisms of disease pathogenesis, the development of molecular-diagnosis and/or novel approaches to rational treatment. The reviews should be of significant interest to basic researchers and clinical investigators in molecular medicine. Periodically the journal will invite guest editors to devote an issue on a basic research area that shows promise to advance our understanding of the molecular mechanism(s) of a disease or has potential for clinical applications.