Mitochondrial Dysfunction in Vascular Wall Cells and Its Role in Atherosclerosis.
Diana I SalnikovaVarvara OrekhovaAndrey GrechkoAntonina StarodubovaEvgeny E BezsonovTatyana PopkovaAlexander N OrekhovPublished in: International journal of molecular sciences (2021)
Altered mitochondrial function is currently recognized as an important factor in atherosclerosis initiation and progression. Mitochondrial dysfunction can be caused by mitochondrial DNA (mtDNA) mutations, which can be inherited or spontaneously acquired in various organs and tissues, having more or less profound effects depending on the tissue energy status. Arterial wall cells are among the most vulnerable to mitochondrial dysfunction due to their barrier and metabolic functions. In atherosclerosis, mitochondria cause alteration of cellular metabolism and respiration and are known to produce excessive amounts of reactive oxygen species (ROS) resulting in oxidative stress. These processes are involved in vascular disease and chronic inflammation associated with atherosclerosis. Currently, the list of known mtDNA mutations associated with human pathologies is growing, and many of the identified mtDNA variants are being tested as disease markers. Alleviation of oxidative stress and inflammation appears to be promising for atherosclerosis treatment. In this review, we discuss the role of mitochondrial dysfunction in atherosclerosis development, focusing on the key cell types of the arterial wall involved in the pathological processes. Accumulation of mtDNA mutations in isolated arterial wall cells, such as endothelial cells, may contribute to the development of local inflammatory process that helps explaining the focal distribution of atherosclerotic plaques on the arterial wall surface. We also discuss antioxidant and anti-inflammatory approaches that can potentially reduce the impact of mitochondrial dysfunction.
Keyphrases
- oxidative stress
- mitochondrial dna
- induced apoptosis
- copy number
- endothelial cells
- cardiovascular disease
- reactive oxygen species
- cell cycle arrest
- dna damage
- cell death
- endoplasmic reticulum stress
- anti inflammatory
- signaling pathway
- diabetic rats
- gene expression
- body mass index
- stem cells
- mesenchymal stem cells
- high glucose
- weight gain
- replacement therapy