Mitochondrial DNA damage can promote atherosclerosis independently of reactive oxygen species through effects on smooth muscle cells and monocytes and correlates with higher-risk plaques in humans

Autor: Lauren Baker, Nick E.J. West, Nichola Figg, Antonio Vidal-Puig, Daniel R. Obaid, Sheetal Kumar, John Mercer, Martin R. Bennett, Emma Yu, James Harrison, Murray C.H. Clarke, Patrick A. Calvert, Michael P. Murphy, Angela Logan, Julie C. Wang, Liam A. Hurst
Rok vydání: 2013
Předmět:
Apolipoprotein E
Male
Pathology
Vascular smooth muscle
Apolipoprotein B
Apoptosis
DNA-Directed DNA Polymerase
Muscle
Smooth
Vascular
Monocytes
Mice
DNA Adducts
Hyperlipidemia
Leukocytes
Medicine
Cells
Cultured
Adiposity
chemistry.chemical_classification
Mice
Knockout
biology
Middle Aged
Plaque
Atherosclerotic
Mitochondria
DNA Polymerase gamma
Radiation Chimera
Cytokines
Female
Cardiology and Cardiovascular Medicine
Risk
Adult
Mitochondrial DNA
medicine.medical_specialty
Myocytes
Smooth Muscle
Hyperlipidemias
DNA
Mitochondrial
Electron Transport
Apolipoproteins E
Oxygen Consumption
Physiology (medical)
Animals
Humans
Aged
Reactive oxygen species
business.industry
medicine.disease
Atherosclerosis
Molecular biology
Transplantation
Mice
Inbred C57BL
chemistry
biology.protein
business
Reactive Oxygen Species
DNA Damage
DOI: 10.17863/cam.22796
Popis: Background— Mitochondrial DNA (mtDNA) damage occurs in both circulating cells and the vessel wall in human atherosclerosis. However, it is unclear whether mtDNA damage directly promotes atherogenesis or is a consequence of tissue damage, which cell types are involved, and whether its effects are mediated only through reactive oxygen species. Methods and Results— mtDNA damage occurred early in the vessel wall in apolipoprotein E–null (ApoE −/− ) mice, before significant atherosclerosis developed. mtDNA defects were also identified in circulating monocytes and liver and were associated with mitochondrial dysfunction. To determine whether mtDNA damage directly promotes atherosclerosis, we studied ApoE −/− mice deficient for mitochondrial polymerase-γ proofreading activity (polG −/− /ApoE −/− ). polG −/− /ApoE −/− mice showed extensive mtDNA damage and defects in oxidative phosphorylation but no increase in reactive oxygen species. polG −/− /ApoE −/− mice showed increased atherosclerosis, associated with impaired proliferation and apoptosis of vascular smooth muscle cells, and hyperlipidemia. Transplantation with polG −/− /ApoE −/− bone marrow increased the features of plaque vulnerability, and polG −/− /ApoE −/− monocytes showed increased apoptosis and inflammatory cytokine release. To examine mtDNA damage in human atherosclerosis, we assessed mtDNA adducts in plaques and in leukocytes from patients who had undergone virtual histology intravascular ultrasound characterization of coronary plaques. Human atherosclerotic plaques showed increased mtDNA damage compared with normal vessels; in contrast, leukocyte mtDNA damage was associated with higher-risk plaques but not plaque burden. Conclusions— We show that mtDNA damage in vessel wall and circulating cells is widespread and causative and indicates higher risk in atherosclerosis. Protection against mtDNA damage and improvement of mitochondrial function are potential areas for new therapeutics.
Databáze: OpenAIRE
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