Analysis of mitochondrial DNA heteroplasmic mutations A1555G, C3256T, T3336C, С5178А, G12315A, G13513A, G14459A, G14846А and G15059A in CHD patients with the history of myocardial infarction.

The present study was undertaken in order to advance our earlier studies directed to define genetic risk of atherosclerotic vascular lesion development on a base on the analysis of sets of mutational load relevant to the mitochondrial genome mutations. A comparative evaluation of the two study participants' populations (that included coronary heart disease (CHD) patients who underwent myocardial infarction and apparently healthy donors with no clinical manifestations of coronary heart disease) on heteroplasmy levels of nine mutations of the mitochondrial genome (A1555G, C3256T, T3336C, С5178А, G12315A, G13513A, G14459A, G14846А and G15059A) that were shown previously to be associated with risk factors for atherosclerosis was performed. Close associations with the risk of cardiovascular disease were confirmed for mutation C3256T (gene MT-TL1), G12315A (gene MT-TL2), G13513A (gene MT-ND5) and G15059A (gene MT-CYB) by RT-PCR.

Mutations of mitochondrial DNA in atherosclerosis and atherosclerosis-related diseases.

Atherosclerosis, the primary cause of cardiovascular disease, is a complex and multifactorial pathology resulted from the harmful interactions between genetic and environmental factors. There is a growing body of evidence in support of the role of mitochondrial factors in the pathogenesis of atherosclerosis. Impaired mitochondrial function and structural and qualitative changes in mitochondrial components such as mitochondrial DNA (mtDNA) damage may be directly involved in the development of multiple mechanisms of atherogenesis. Recent findings show that several heteroplasmic mutations of mtDNA are related to atherosclerosis, coronary heart disease and several atherosclerosis-related diseases such as arterial hypertension and diabetes mellitus. Therefore, heteroplasmic mtDNA mutations could represent a promising molecular biomarker of genetic susceptibility to atherosclerosis and related pathologies. This review is focused on the latest findings in the studies of mutations of mitochondrial genome, which are associated with atherosclerosis and atherosclerosis- related diseases.

Quantitative assessment of heteroplasmy of mitochondrial genome: perspectives in diagnostics and methodological pitfalls.

The role of alterations of mitochondrial DNA (mtDNA) in the development of human pathologies is not understood well. Most of mitochondrial mutations are characterized by the phenomenon of heteroplasmy which is defined as the presence of a mixture of more than one type of an organellar genome within a cell or tissue. The level of heteroplasmy varies in wide range, and the expression of disease is dependent on the percent of alleles bearing mutations, thus allowing consumption that an upper threshold level may exist beyond which the mitochondrial function collapses. Recent findings have demonstrated that some mtDNA heteroplasmic mutations are associated with widely spread chronic diseases, including atherosclerosis and cancer. Actually, each etiological mtDNA mutation has its own heteroplasmy threshold that needs to be measured. Therefore, quantitative evaluation of a mutant allele of mitochondrial genome is an obvious methodological challenge, since it may be a keystone for diagnostics of individual genetic predisposition to the disease. This review provides a comprehensive comparison of methods applicable to the measurement of heteroplasmy level of mitochondrial mutations associated with the development of pathology, in particular, in atherosclerosis and its clinical manifestations.