Yeast longevity promoted by reversing aging-associated decline in heavy isotope content

Li, Xiyan

doi:10.1038/npjamd.2016.4

Cited by 24 publications

(49 citation statements)

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“…A hypothesis has been put forward that the increased uptake of the heavy isotope in a biological system would affect the kinetics of biochemical reactions, increase the stability of the biomolecules and organism longevity [9,10]. Supporting this view, the relative abundance of heavy isotope-containing metabolites in yeast exhibited an ageing-associated trend, with most abundant amino acids declining in their 13 C and 2 H content in senescent cultures [11]. The authors hypothesized that cells might gradually lose the ability to retain heavy metabolites with ageing and, by introducing D 2 O in the culture medium, they were able to slow down this metabolic deterioration and ageing.…”

Section: Introductionmentioning

confidence: 99%

Shifts in rotifer life history in response to stable isotope enrichment: testing theories of isotope effects on organismal growth

Gorokhova

2017

R. Soc. open sci.

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In ecology, stable isotope labelling is commonly used for tracing material transfer in trophic interactions, nutrient budgets and biogeochemical processes. The main assumption in this approach is that the enrichment with a heavy isotope has no effect on the organism growth and metabolism. This assumption is, however, challenged by theoretical considerations and experimental studies on kinetic isotope effects in vivo. Here, I demonstrate profound changes in life histories of the rotifer Brachionus plicatilis fed 15N-enriched algae (0.4–5.0 at%); i.e. at the enrichment levels commonly used in ecological studies. These findings support theoretically predicted effects of heavy isotope enrichment on growth, metabolism and ageing in biological systems and underline the importance of accounting for such effects when using stable isotope labelling in experimental studies.

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Section: Introductionmentioning

confidence: 99%

Shifts in rotifer life history in response to stable isotope enrichment: testing theories of isotope effects on organismal growth

Gorokhova

2017

R. Soc. open sci.

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“…We normalized metabolite extraction against tissue weight to ensure that metabolite measurements across different organs and age groups are directly comparable in this study. Untargeted liquid chromatography-mass spectrometry (LCMS) was performed to simultaneously assess the metabolite composition and heavy isotope contents in metabolites, as previously described (Li and Snyder, 2016b). When operating at a mass resolution of 100,000 and acquired in profile mode, monoisotopic mass peaks can be discerned and measured around the M+1 mass peaks for heavy isotopes 13 C, 2 H, 15 N, and 33 S, and around the M+2 mass peaks for heavy isotopes 18 O and 34 S. One example for the metabolite taurine is shown in Fig.…”

Section: Study Design and Measurement Of Heavy Isotope Content In Metmentioning

confidence: 99%

“…Since our clustering analysis using only the amino acid profiles could, at least in part, separate different organs of different ages from each other, we wonder whether the common HICs in amino acids could show certain age-related changes, which might also reflect a global change of other metabolites. Taking the advantage of high mass resolution used in our LCMS acquisition, we quantified the common HICs in amino acids as previously described (Li and Snyder, 2016b). As an example, the quantification of total metabolites (total count), as well as the relative abundance of 13 C, 15 N and 34 S isotopic forms of methionine in three organs of three different ages was shown in Fig.…”

Section: Age-related Decline In Heavy Isotope Content Of Amino Acidsmentioning

confidence: 99%

“…Living organisms have, besides the heavy hydrogen deuterium, many other types of heavy isotopes. Through a metabolomics study, we have previously examined in amino acids the heavy isotopes for four common organic elements, namely 13 C, 2 H, 15 N and 24 S, in yeast cells that underwent chronological aging (Li and Snyder, 2016b). We found an overall trend of decline, which occurred when yeast cells get old, and elevating the HIC for hydrogen through heavy water feeding extended yeast lifespan by 84%.…”

Section: Introductionmentioning

confidence: 99%

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Age-related decline in metabolite heavy isotope content in rodent organs

2019

Preprint

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Heavy isotopes are discriminated by biological systems due to kinetic isotopic effects at the biochemical/metabolic levels. How these heavy isotopes are enriched or depleted over a long term is unclear, but artificial manipulation of heavy isotope content in various organisms has produced significant impacts on biological functions, suggesting the origin may arise with intrinsic mechanisms for a functional outcome. Our previous study has revealed an age-associated decline in metabolite heavy isotope content (HIC) in the budding yeast, which could be reversed in part by supplementing heavy water, and consequently, also increased yeast lifespans. In the current study, we report a similar age-dependent decline in HIC from three types of mouse tissues: brain, heart, and skeletal muscles. Furthermore, individual tissues exhibited different patterns of HIC change over age, which appeared to match their development and maturation timelines. These results have demonstrated that age-dependent decline in HIC also exists in mammals, which is likely a traceable feature of development and perhaps aging. Thus, we believe that reversing the decline in HIC could have the potential to extend the healthspan of humans. P values from two-tailed t-test (unequal variance, Welch's correction) were calculated in Graphpad and omitted for clarity.

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“…Calorie restriction is found to extend chorological lifespan through moderate increase of hydrogen peroxide that leads to activation of superoxide dismutase and inhibition of superoxide anions (Mesquita et al, 2010; Weinberger et al, 2010). Heavy water can suppress endogenous ROS and extend yeast CLS (Li & Synder, 2016). …”

Section: Introductionmentioning

confidence: 99%

Hydrogen peroxide induced loss of heterozygosity correlates with replicative lifespan and mitotic asymmetry inSaccharomyces cerevisiae

Güven

Parnell

Jackson

et al. 2016

PeerJ

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Cellular aging in Saccharomyces cerevisiae can lead to genomic instability and impaired mitotic asymmetry. To investigate the role of oxidative stress in cellular aging, we examined the effect of exogenous hydrogen peroxide on genomic instability and mitotic asymmetry in a collection of yeast strains with diverse backgrounds. We treated yeast cells with hydrogen peroxide and monitored the changes of viability and the frequencies of loss of heterozygosity (LOH) in response to hydrogen peroxide doses. The mid-transition points of viability and LOH were quantified using sigmoid mathematical functions. We found that the increase of hydrogen peroxide dependent genomic instability often occurs before a drop in viability. We previously observed that elevation of genomic instability generally lags behind the drop in viability during chronological aging. Hence, onset of genomic instability induced by exogenous hydrogen peroxide treatment is opposite to that induced by endogenous oxidative stress during chronological aging, with regards to the midpoint of viability. This contrast argues that the effect of endogenous oxidative stress on genome integrity is well suppressed up to the dying-off phase during chronological aging. We found that the leadoff of exogenous hydrogen peroxide induced genomic instability to viability significantly correlated with replicative lifespan (RLS), indicating that yeast cells’ ability to counter oxidative stress contributes to their replicative longevity. Surprisingly, this leadoff is positively correlated with an inverse measure of endogenous mitotic asymmetry, indicating a trade-off between mitotic asymmetry and cell’s ability to fend off hydrogen peroxide induced oxidative stress. Overall, our results demonstrate strong associations of oxidative stress to genomic instability and mitotic asymmetry at the population level of budding yeast.

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Yeast longevity promoted by reversing aging-associated decline in heavy isotope content

Cited by 24 publications

References 48 publications

Shifts in rotifer life history in response to stable isotope enrichment: testing theories of isotope effects on organismal growth

Shifts in rotifer life history in response to stable isotope enrichment: testing theories of isotope effects on organismal growth

Age-related decline in metabolite heavy isotope content in rodent organs

Hydrogen peroxide induced loss of heterozygosity correlates with replicative lifespan and mitotic asymmetry inSaccharomyces cerevisiae

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