Interestingness: 5
Paper by Christoph Richter in the Journal of Anti-Aging Medicine, Volume 2, Issue 3, Fall 1999.
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This paper starts by describing how mtDNA gets oxidised: superoxide radicals (O2-) are formed "when cytochrome oxidase is blocked, when cytochrome c is detached from the inner mitochondrial membrane, " ... and " when mitochondrial oxidative phosphorylation is inhibited". The superoxide radical then gives the electron to a water molecule, which forms hydrogen peroxide (H2O2), which then forms hydroxyl radical (OH.) in the presence of iron or copper (Fenton reaction). The hydroxyl radical is the bastard that then goes and reacts with everything.
It then mentions radical nitrogen species, usual description of mtDNA (16.3 kb pair coding for 13 peptides, 22 tRNAs and 2 rRNAs), how people started thinking of mtDNA damage as important for diseases, measurement of mtDNA damage (usually measuring 8-hydroxyguanine and strand breaks), sidetrack into azidothymidine (AZT, the anti-AIDS drug) causing problems in mitochondria, and Friedreich's ataxia (FA) probably being a problem with oxidation damage in mitochondria.
Now, interesting bit, measurements of amount of oxidative damage in mtDNA differ depending on methodology. Detection of 8-hydroxydeoxyguanosine (8-OHdG) gives big numbers (4 modifications per mtDNA molecule) while numbers from repair enzymes (dunno how it works) give much lower numbers. High number doubted also from seemingly high number of working mitochondria. They do analysis of mtDNA from rat's livers, detecting 8-OHdG. They get 0.051 picomole per microgram of DNA for circular mtDNA, which they say is about one 8-OHdG mutation every two mtDNA molecules, 0.014 picomole per microgram of DNA for nDNA, which is contamination in the sample, but 0.741 picomole per microgram in low molecular mtDNA, ie fractions of floating mtDNA. They don't know what the fractions of mtDNA are doing or why they are so highly oxidised. It could be that they are being actively degraded, or they could be new chunks being made. Having found these fragments, he then hypothesises that these fragments integrate with nDNA, and that this is the main mechanism of aging of mtDNA oxidation damage.
The part that follows is also interesting. Experimenting with iron overload into the mtDNA of rat's livers in vitro they find that it (iron, in the form of Fe3+ gluconate), relaxes mtDNA from the standard supercoiled form to the open circular form. Anti-oxidants prevent some of the change but not all. The iron forms colloids that bind to mtDNA, and there may be a purely physical mechanism of relaxation. They then repeat the experiment in vivo also observing more relaxed circular DNA compared to controls, as well as increased mitochondrial surface and volume density, increased intracellular ferritin and hemosiderin, and higher replication of mtDNA.
It then switches to mtDNA damage prevention, mentions caloric restriction as reducing 8-OHdG counts, AZT leading to higher urinary 8-OHdG but vitamins C and E reducing those levels in AZT-taking people (I thought vitamins C and E didn't enter the mitochondria). Finishes by looking at future studies, evidence that mtDNA inserts in nDNA are more common in tumours, Drosophila overexpressing superoxide dismutase and catalase having increased lifespan, and some wacky suggestion of using bacteria to transfect genes into mitochondria.
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Abstract follows:
Mitochondrial diseases have been known for more than three decades. A refinement of the free radical theory of aging states that oxidative damage to mitochondria, particularly to mitochondrial DNA (mtDNA), is responsible for aging. About 10 years ago, oxidative damage to mtDNA was first reported, and human diseases were related to mutations of mtDNA. Subsequent reports suggested that oxidative mtDNA damage is more pronounced in old individuals and during certain diseases. Studies of animal models indicated that oxidative mtDNA damage can be ameliorated by dietary antioxidants and caloric restriction, an established method to increase life span. More recent data indicate that fragmented mtDNA is the predominant carrier of oxidized mtDNA bases and that fragments constitute a substantial amount of the total mtDNA. This article discusses the emerging relationship among mtDNA oxidation, diseases, and aging, and suggests experiments by which such a relationship can be further substantiated.
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