Supercomplex organization of the electron transfer system in marine bivalves, a model of extreme longevity

Abstract The mitochondrial oxidative stress theory of aging (MOSTA) suggests that the organelle’s decay contributes to the aging phenotype via exacerbated oxidative stress, loss of organ coordination and energetics, cellular integrity and activity of the mitochondrial electron transfer system (ETS). Recent advances in understanding the structure of the ETS show that the enzymatic complexes responsible for oxidative phosphorylation are arranged in supramolecular structures called supercomplexes that lose organization during aging. Their exact role and universality among organisms are still under debate. Here, we take advantage of marine bivalves as an aging model to compare the structure of the ETS among species ranging from 28 to 507 years in maximal lifespan. Our results show that regardless of lifespan, the bivalve ETS is arrayed as a set of supercomplexes. However, bivalve species display varying degrees ETS supramolecular organization with the highest supercomplex structures found in A. islandica, the longest-lived of the bivalve species under study. We discuss this comparative model in light of differences in the nature and stoichiometry of these complexes, and highlight the potential link between the complexity of these superstructures and longer lifespans.

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Divergences in the control of mitochondrial respiration are associated with lifespan variation in marine bivalves

The Journals of Gerontology Series A ◽

10.1093/gerona/glaa301 ◽

2020 ◽

Author(s):

Enrique Rodríguez ◽

Mohammed Hakkou ◽

Tory M Hagen ◽

Hélène Lemieux ◽

Pierre U Blier

Keyword(s):

Oxidative Stress ◽

Electron Transfer ◽

Complex Iii ◽

Control Analysis ◽

Transfer System ◽

Complex Iv ◽

Flux Control ◽

Electron Transfer System ◽

Marine Bivalves ◽

Strong Control

Abstract The role played by mitochondrial function in the aging process has been a subject of intense debate in the past few decades, as part of the efforts to understand the mechanistic basis of longevity. The mitochondrial oxidative stress theory of aging (MOSTA) suggests that a progressive decay of this organelle’s function leads to an exacerbation of oxidative stress, with deleterious impact on mitochondrial structure and DNA, ultimately promoting aging. Among the traits suspected to be associated with longevity is the variation in regulation of oxidative phosphorylation, potentially impacting the management of oxidative stress. Longitudinal studies using the framework of metabolic control analysis have shown age-related differences in flux control of respiration, but this approach has seldom been taken on a comparative scale. Using four species of marine bivalves exhibiting a large range of maximum lifespans (from 28y to 507y), we report lifespan-related differences in flux control at different steps of the electron transfer system. Increased longevity was characterized by a lower control by NADH- (complex I-linked) and Succinate- (complex II- linked) pathways, while respiration was strongly controlled by complex IV when compared to shorter-lived species. Complex III exterted a strong control over respiration in all species. Furthermore, high longevity was associated with higher citrate synthase activity, and lower ATP synthase activity. Relieving the control exerted by the electron entry pathways could be advantageous for reaching a higher longevity, leading to an increased control by complex IV, the final electron acceptor in the electron transfer system.

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