Low hydrogen peroxide production in mitochondria of the long‐lived <i><scp>A</scp>rctica islandica</i>: underlying mechanisms for slow aging

Munro, Daniel; Pichaud, Nicolas; Paquin, Frédérique; Kemeid, Vincent; Blier, Pierre

doi:10.1111/acel.12082

Cited by 46 publications

(36 citation statements)

References 43 publications

(53 reference statements)

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“…An additional finding that contradicts the rate of living theory is that peak metabolic rate during flight is positively, rather than negatively correlated with lifespan in M. cinxia (Niitepõld & Hanski, 2013). Furthermore, ROS production is highly variable among tissues and species and is apparently not directly proportional to metabolic rate (Hulbert et al, 2007;Robert et al, 2007;Burton et al, 2011;Boardman et al, 2012;Selman et al, 2012;Speakman & Garratt, 2014; but see Hou, 2013) or in some cases to longevity as well (Lewis et al, 2012;Montgomery, Hulbert & Buttemer, 2012a; but see Archer et al, 2012;Munro et al, 2013), thus undermining a key proposed link between metabolic rate and longevity, although other mechanisms may be involved (Van Raamsdonk et al, 2010;Pulliam, Bhattacharya & Van Remmen, 2012). The cave salamander Proteus anguinus Laurenti highlights this problem because it has an unusually long lifespan (mean = 68.5 years), despite having a small body size (15-20 g), and an unexceptional metabolic rate and levels of antioxidant activity and age-related cellular damage (Voituron et al, 2011).…”

Section: (4) Ageingmentioning

confidence: 95%

“…Moreover, recent statistical analyses have shown that maximal lifespan in various vertebrates is unrelated to resting metabolic rate after controlling for differences in body size and taxonomic affinity (Speakman, 2005;de Magalhães, Costa & Church, 2007;Robert, Brunet-Rossinni & Bronikowski, 2007;Valencak & Ruf, 2007;Furness & Speakman, 2008;Montgomery, Hulbert & Buttemer, 2012b). Furthermore, ROS production is highly variable among tissues and species and is apparently not directly proportional to metabolic rate (Hulbert et al, 2007;Robert et al, 2007;Burton et al, 2011;Boardman et al, 2012;Selman et al, 2012;Speakman & Garratt, 2014; but see Hou, 2013) or in some cases to longevity as well (Lewis et al, 2012;Montgomery, Hulbert & Buttemer, 2012a; but see Archer et al, 2012;Munro et al, 2013), thus undermining a key proposed link between metabolic rate and longevity, although other mechanisms may be involved (Van Raamsdonk et al, 2010;Pulliam, Bhattacharya & Van Remmen, 2012). An additional finding that contradicts the rate of living theory is that peak metabolic rate during flight is positively, rather than negatively correlated with lifespan in M. cinxia (Niitepõld & Hanski, 2013).…”

Section: (4) Ageingmentioning

confidence: 99%

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Is metabolic rate a universal ‘pacemaker’ for biological processes?

2014

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A common, long-held belief is that metabolic rate drives the rates of various biological, ecological and evolutionary processes. Although this metabolic pacemaker view (as assumed by the recent, influential 'metabolic theory of ecology') may be true in at least some situations (e.g. those involving moderate temperature effects or physiological processes closely linked to metabolism, such as heartbeat and breathing rate), it suffers from several major limitations, including: (i) it is supported chiefly by indirect, correlational evidence (e.g. similarities between the body-size and temperature scaling of metabolic rate and that of other biological processes, which are not always observed) - direct, mechanistic or experimental support is scarce and much needed; (ii) it is contradicted by abundant evidence showing that various intrinsic and extrinsic factors (e.g. hormonal action and temperature changes) can dissociate the rates of metabolism, growth, development and other biological processes; (iii) there are many examples where metabolic rate appears to respond to, rather than drive the rates of various other biological processes (e.g. ontogenetic growth, food intake and locomotor activity); (iv) there are additional examples where metabolic rate appears to be unrelated to the rate of a biological process (e.g. ageing, circadian rhythms, and molecular evolution); and (v) the theoretical foundation for the metabolic pacemaker view focuses only on the energetic control of biological processes, while ignoring the importance of informational control, as mediated by various genetic, cellular, and neuroendocrine regulatory systems. I argue that a comprehensive understanding of the pace of life must include how biological activities depend on both energy and information and their environmentally sensitive interaction. This conclusion is supported by extensive evidence showing that hormones and other regulatory factors and signalling systems coordinate the processes of growth, metabolism and food intake in adaptive ways that are responsive to an organism's internal and external conditions. Metabolic rate does not merely dictate growth rate, but is coadjusted with it. Energy and information use are intimately intertwined in living systems: biological signalling pathways both control and respond to the energetic state of an organism. This review also reveals that we have much to learn about the temporal structure of the pace of life. Are its component processes highly integrated and synchronized, or are they loosely connected and often discordant? And what causes the level of coordination that we see? These questions are of great theoretical and practical importance.

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Section: (4) Ageingmentioning

confidence: 95%

Section: (4) Ageingmentioning

confidence: 99%

Is metabolic rate a universal ‘pacemaker’ for biological processes?

2014

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“…This excess can enhance oxygen affinity [49,50], regulate the redox state [51], and preserve the oxidized state of upstream ETS complexes [52]. Bivalves are often subject to wide changes in oxygen availability in the intertidal zone or in burrows [53], and the upregulation of CIV has been described during conditions where O 2 is scarce [54]. The maintenance of a high CIV excess capacity in bivalves could improve kinetic trapping of O 2 during hypoxic conditions and decrease the reducing charge stored in the upstream ETS enzymes and the consequent potential burst of ROS production during reoxygenation [52].…”

Section: (B) Intraspecific Analysesmentioning

confidence: 99%

Metabolic remodelling associated with mtDNA: insights into the adaptive value of doubly uniparental inheritance of mitochondria

et al. 2019

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Mitochondria produce energy through oxidative phosphorylation (OXPHOS), which depends on the expression of both nuclear and mitochondrial DNA (mtDNA). In metazoans, a striking exception from strictly maternal inheritance of mitochondria is doubly uniparental inheritance (DUI). This unique system involves the maintenance of two highly divergent mtDNAs (F-and M-type, 8-40% of nucleotide divergence) associated with gametes, and occasionally coexisting in somatic tissues. To address whether metabolic differences underlie this condition, we characterized the OXPHOS activity of oocytes, spermatozoa, and gills of different species through respirometry. DUI species express different gender-linked mitochondrial phenotypes in gametes and partly in somatic tissues. The M-phenotype is specific to sperm and entails (i) low coupled/uncoupled respiration rates, (ii) a limitation by the phosphorylation system, and (iii) a null excess capacity of the final oxidases, supporting a strong control over the upstream complexes. To our knowledge, this is the first example of a phenotype resulting from direct selection on sperm mitochondria. This metabolic remodelling suggests an adaptive value of mtDNA variations and we propose that bearing sex-linked mitochondria could assure the energetic requirements of different gametes, potentially linking male-energetic adaptation, mitotype preservation and inheritance, as well as resistance to both heteroplasmy and ageing.

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“…This differs from the expression pattern seen for S. glomerata transcripts which are part of the mitochondrial respiratory chain, where NADH dehydrogenase [ubiquinone] iron-sulfur protein 2 (complex I protein), cytochrome b-c1 complex subunit 7 (complex III protein) and alternative oxidase were 4-fold and higher up-regulated and cytochrome c oxidase subunit 5A mitochondrial (complex IV protein) 4-fold and higher down-regulated in the elevated treatment when compared to control oysters (Additional file 7: Table S2). Both, complex I and complex III are considered to be the major sources of ROS production in the mitochondrial respiratory chain [65,66], suggesting that upregulation of mitochondrial respiration in CO 2 challenged S. glomerata would lead to an increase in ROS production, elevating the risk of oxidative damage to the tissues of the oysters. However, this appears to be counteracted by two measures in the S. glomerata exposed to the elevated CO 2 treatment.…”

Section: Respiration and Antioxidant Defencementioning

confidence: 99%

“…However, this appears to be counteracted by two measures in the S. glomerata exposed to the elevated CO 2 treatment. Firstly, alternative oxidase (Additional file 7: Table S2), located in the inner mitochondrial membrane, allows the animal to circumvent complex III by transferring electrons from coenzyme Q to oxygen and therefore limits the amount of ROS produced during cellular respiration [66,67]. Secondly, ROS originating from complex I are thought to be removed by mitochondrial matrix antioxidants such as glutathione peroxidase and catalase [65].…”

Section: Respiration and Antioxidant Defencementioning

confidence: 99%

Molecular analysis of the Sydney rock oyster (Saccostrea glomerata) CO2 stress response

Ertl

O’Connor

Wiegand

et al. 2016

Clim Chang Responses

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Background: Human activities have led to a substantial increase in carbon dioxide (CO 2 ) emission, with further increases predicted. A RNA-Seq study on adult Saccostrea glomerata was carried out to examine the molecular response of this bivalve species to elevated pCO 2 . Results: A total of 1626 S. glomerata transcripts were found to be differentially expressed in oysters exposed to elevated pCO 2 when compared to control oysters. These transcripts cover a range of functions, from immunity (e.g. pattern recognition receptors, antimicrobial peptides), to respiration (e.g. antioxidants, mitochondrial respiratory chain proteins) and biomineralisation (e.g. carbonic anhydrase). Overall, elevated levels of CO 2 appear to have resulted in a priming of the immune system and in producing countermeasures to potential oxidative stress. CO 2 exposure also seems to have resulted in an increase in the expression of proteins involved in protein synthesis, whereas transcripts putatively coding for proteins with a role in cilia and flagella function were down-regulated in response to the stressor. In addition, while some of the transcripts related to biomineralisation were up-regulated (e.g. carbonic anhydrase 2, alkaline phosphatase), a small group was down-regulated (e.g. perlucin). Conclusions: This study highlighted the complex molecular response of the bivalve S. glomerata to expected near-future ocean acidification levels. While there are indications that the oyster attempted to adapt to the stressor, gauged by immune system priming and the increase in protein synthesis, some processes such cilia function appear to have been negatively affected by the elevated levels of CO 2 .

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Low hydrogen peroxide production in mitochondria of the long‐lived Arctica islandica: underlying mechanisms for slow aging

Cited by 46 publications

References 43 publications

Is metabolic rate a universal ‘pacemaker’ for biological processes?

Is metabolic rate a universal ‘pacemaker’ for biological processes?

Metabolic remodelling associated with mtDNA: insights into the adaptive value of doubly uniparental inheritance of mitochondria

Molecular analysis of the Sydney rock oyster (Saccostrea glomerata) CO2 stress response

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