Pathophysiological mechanisms of redox inbalance in neointimal vascular cells

Formation of a neointimal layer is the hallmark of most vascular diseases, such as atherosclerosis and restenosis after angioplasty. Neointimal cells display an undifferentiated noncontractile smooth muscle phenotype with marked extracellular matrix secretion. Their origin can be multiple. Among factors that govern the (de)differentiation, proliferation and migration of neointimal cells, there is evidence for a key role of redox processes, but the underlying mechanisms are unclear. Advancing the knowledge about such redox mechanisms has been difficulted by the absence of a reproducible method of neointimal cell culture. The objectives of this work are: 1) To develop a model of neointimal cell culture, in which cells are harvested from rabbit iliac arteries 14 days after overdistention balloon injury. 2) To assess the redox status in such neointimal cells and the possible enzymatic source of reactive oxygen, with emphasis in the NAD(P)H oxidase complex. 3) To investigate the expression of endoplasmic reticulum stress markers and their corralation with redox status. 4) To investigate the effects of proapoptotic stimuli such as serum deprivation, endoplasmic reticulum stressors and particularly the exogenous administration of nitric oxide in viability and redox status of neointimal cells. Our results show that it is possible to harvest and cultivate neointimal cells after balloon injury. The neointimal cells in culture, even after several passages, exhibit increased indexes of oxidative stress. Oxidative stress in such cells is associated with increased activation of the vascular NAD(P)H oxidase complex. Contrarily to what was observed in healing arteries harvested from in vivo rabbits, markers of ER stress did not show any change when compared with primary smooth muscle cells kept in similar conditions. Oxidative stress response was increased after NADPH oxidase agonists; in particular, exposure to exogenous nitric oxide markedly increased superoxide radical production in neointimal cells. Cell viability curves showed increased sensitivity to ER stressors, NO donors and, particularly, exogenous oxidants. Therefore, the neointimal phenotype is a phenotype of intrinsic sustained oxidative stress even after several passages in culture. Such oxidative stress is due at least in part to activation of the NAD(P)H oxidase complex in the context of adaptation to an integrated stress response. This data provide new perspectives to understand redox mechanisms associated with neointimal pathophysiology and can lead to development of rational therapeutic interventions. (AU)