Abstract
This review focuses on the question of how oxidative stress in cells populating atherosclerotic
lesions stimulates gene expression, cell proliferation, and cell death, and how these
events contribute to the initiation, progression, and destablization of the lesions.
It is hypothesized that oxidative stress in endothelial cells, macrophages, and smooth
muscle cells occurs as a result of the depletion cellular content of reduced glutathione.
Glutathione becomes oxidized in response to the accumulation of oxidized lipids, the
formation of reactive oxygen species released from the mitochondria and generated
as part of the activation-induced respiratory burst, and the generation of nitric
oxide, peroxynitrite, and thiol radicals. Both in vitro and in vivo evidence suggests
that these cells can take up modified lipoproteins that become trapped within the
artery wall leading to the overaccumulation of oxidized fatty acids and oxidized forms
of cholesterol. The cells also generate oxidized lipids via the activity of lipoxygenases,
cyclooxygenases, and myeloperoxidase. A sublethal oxidative stress can activate redox-sensitive
kinase cascades and transcription factors such as NFB and AP-1, with resulting increases
in the expression of factors associated with an inflammatory response and cellular
proliferation. There is also accumulating evidence that suggests that oxidative stress
may be associated with the induction of cell death either via stimulation of apoptosis
and/or necrosis and that increased cell death contributes to the formation of a necrotic
core, the hallmark of an advanced, unstable lesion.
Keywords:
Atherosclerosis - oxidative stress - glutathione - gene expression - proliferation
- apoptosis
