Author(s): Sanz A, Stefanatos RK
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Abstract The Mitochondrial Free Radical Theory of Aging (MFRTA) proposes that mitochondrial free radicals, produced as by-products during normal metabolism, cause oxidative damage. According to MFRTA, the accumulation of this oxidative damage is the main driving force in the aging process. Although widely accepted, this theory remains unproven, because the evidence supporting it is largely correlative. For example, long-lived animals produce fewer free radicals and have lower oxidative damage levels in their tissues. However, this does not prove that free radical generation determines life span. In fact, the longest-living rodent -Heterocephalus glaber- produces high levels of free radicals and has significant oxidative damage levels in proteins, lipids and DNA. At its most orthodox MFRTA proposes that these free radicals damage mitochondrial DNA (mtDNA) and in turn provoke mutations that alter mitochondrial function (e.g. ATP production). According to this, oxidative damage to mtDNA negatively correlates with maximum life span in mammals. However, in contrast to MFRTA predictions, high levels of oxidative damage in mtDNA do not decrease longevity in mice. Moreover, mice with alterations in polymerase gamma (the mitochondrial DNA polymerase) accumulate 500 times higher levels of point mutations in mtDNA without suffering from accelerated aging. Dietary restriction (DR) is the only non-genetic treatment that clearly increases mean and maximum life span. According to MFRTA caloric restricted animals produce fewer mitochondrial reactive oxygen species (mtROS). However, DR alters more than free radical production (e.g. it decreases insulin signalling) and therefore the increase in longevity cannot be exclusively attributed to a decrease in mtROS generation. Thus, moderate exercise produces similar changes in free radical production and oxidative damage without increasing maximum life span. In summary, available data concerning the role of free radicals in longevity control are contradictory, and do not prove MFRTA. In fact, the only way to test this theory is by specifically decreasing mitochondrial free radical production without altering other physiological parameters (e.g. insulin signalling). If MFRTA is true animals producing fewer mtROS must have the ability to live much longer than their experimental controls.
This article was published in Curr Aging Sci
and referenced in Brain Disorders & Therapy