The p66shc adaptor protein controls oxidative stress response and life span in mammals

Migliaccio, Enrica; Giorgio, Marco; Mele, Simonetta; Pelicci, Giuliana; Reboldi, Paolo; Pandolfi, Pier Paolo; Lanfrancone, Luisa; Pelicci, Pier Giuseppe

doi:10.1038/46311

Cited by 1,607 publications

(1,454 citation statements)

References 28 publications

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“…For study 2, a DR group that was supplemented with EAAs, without methionine ( n = 20), was also established, and its phenotype was compared with those of simple DR ( n = 25) and DR plus EAAs ( n = 30) groups. Based on previous reports (Bluher, Kahn, & Kahn, 2003; Forster et al., 2003; Migliaccio et al., 1999; Mitchell et al., 2016; Weindruch & Walford, 1982), the survival rate of male C57BL/6 mice is approximately 50%–60% at 24 months old. Thus, we decided to use 24 months as the end‐point of this study, which enabled us to analyze the effect of each dietary regimen on survival, cardiac function, glucose metabolism, muscle function, histology, and serum parameters in living middle aged and older mice, but not in very old mice.…”

Section: Methodsmentioning

confidence: 99%

Role of dietary amino acid balance in diet restriction‐mediated lifespan extension, renoprotection, and muscle weakness in aged mice

et al. 2018

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SummaryExtending healthy lifespan is an emerging issue in an aging society. This study was designed to identify a dietary method of extending lifespan, promoting renoprotection, and preventing muscle weakness in aged mice, with a focus on the importance of the balance between dietary essential (EAAs) and nonessential amino acids (NEAAs) on the dietary restriction (DR)‐induced antiaging effect. Groups of aged mice were fed ad libitum, a simple DR, or a DR with recovering NEAAs or EAAs. Simple DR significantly extended lifespan and ameliorated age‐related kidney injury; however, the beneficial effects of DR were canceled by recovering dietary EAA but not NEAA. Simple DR prevented the age‐dependent decrease in slow‐twitch muscle fiber function but reduced absolute fast‐twitch muscle fiber function. DR‐induced fast‐twitch muscle fiber dysfunction was improved by recovering either dietary NEAAs or EAAs. In the ad libitum‐fed and the DR plus EAA groups, the renal content of methionine, an EAA, was significantly higher, accompanied by lower renal production of hydrogen sulfide (H2S), an endogenous antioxidant. Finally, removal of methionine from the dietary EAA supplement diminished the adverse effects of dietary EAA on lifespan and kidney injury in the diet‐restricted aged mice, which were accompanied by a recovery in H2S production capacity and lower oxidative stress. These data imply that a dietary approach could combat kidney aging and prolong lifespan, while preventing muscle weakness, and suggest that renal methionine metabolism and the trans‐sulfuration pathway could be therapeutic targets for preventing kidney aging and subsequently promoting healthy aging.

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Section: Methodsmentioning

confidence: 99%

Role of dietary amino acid balance in diet restriction‐mediated lifespan extension, renoprotection, and muscle weakness in aged mice

et al. 2018

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“…The beneficial effects of mitochondria‐targeted drugs such as plastoquinone derivatives (Anisimov et al., 2008, 2011) or MitoTEMPO (Miura et al., 2017; Owada et al., 2017) and of endogenous indoleamine melatonine (Escames et al., 2010; Paradies, Paradies, Ruggiero, & Petrosillo, 2017) reinforce this theory. Similarly, mice deleted for the gene of the p66shc adaptor protein have reduced ROS generation and delayed aging (Migliaccio et al., 1999; Napoli et al., 2003). However, new recent data challenged this hypothesis as they show that ROS can be beneficial and extend lifespan at least in lower organisms such as flies and worms (Sanz, 2016; Sena & Chandel, 2012).…”

Section: Regulating Factors Of Mptp and Agingmentioning

confidence: 99%

Mitochondria and aging: A role for the mitochondrial transition pore?

2018

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SummaryThe cellular mechanisms responsible for aging are poorly understood. Aging is considered as a degenerative process induced by the accumulation of cellular lesions leading progressively to organ dysfunction and death. The free radical theory of aging has long been considered the most relevant to explain the mechanisms of aging. As the mitochondrion is an important source of reactive oxygen species (ROS), this organelle is regarded as a key intracellular player in this process and a large amount of data supports the role of mitochondrial ROS production during aging. Thus, mitochondrial ROS, oxidative damage, aging, and aging‐dependent diseases are strongly connected. However, other features of mitochondrial physiology and dysfunction have been recently implicated in the development of the aging process. Here, we examine the potential role of the mitochondrial permeability transition pore (mPTP) in normal aging and in aging‐associated diseases.

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“…A number of "aging genes" have been identified for which mutations significantly increase mouse lifespan and delay the onset of age-related disease (Prop1, Pit1, Ghr,Ghrhr,Irs1,Irs2,PappA,Clk1,Shc1,Igf1r,Kl,Adcy5,Surf1,Insr,Ucp2,Gpx4) (Brown-Borg et al, 1996;Kopchick and Laron, 1999;Migliaccio et al, 1999;Flurkey et al, 2001;Bluher et al, 2003;Holzenberger et al, 2003;Kurosu et al, 2005;Liu et al, 2005;Conti et al, 2006;Conover and Bale, 2007;Dell'Agnello et al, 2007;Ran et al, 2007;Taguchi et al, 2007;Yan et al, 2007;Selman et al, 2008). The extent to which these genes interact with CR-regulated pathways is unclear (Miller et al, 2002;Tsuchiya et al, 2004;Bonkowski et al, 2006;Swindell, 2007).…”

Section: Other "Aging Genes" Lack Unique Network Propertiesmentioning

confidence: 99%

Genes regulated by caloric restriction have unique roles within transcriptional networks

Swindell

2008

Mechanisms of Ageing and Development

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Caloric restriction (CR) has received much interest as an intervention that delays age-related disease and increases lifespan. Whole-genome microarrays have been used to identify specific genes underlying these effects, and in mice, this has led to the identification of genes with expression responses to CR that are shared across multiple tissue types. Such CR-regulated genes represent strong candidates for future investigation, but have been understood only as a list, without regard to their broader role within transcriptional networks. In this study, co-expression and network properties of CR-regulated genes were investigated using data generated by more than 600 Affymetrix microarrays. This analysis identified groups of co-expressed genes and regulatory factors associated with the mammalian CR response, and uncovered surprising network properties of CR-regulated genes. Genes downregulated by CR were highly connected and located in dense network regions. In contrast, CR-upregulated genes were weakly connected and positioned in sparse network regions. Some network properties were mirrored by CR-regulated genes from invertebrate models, suggesting an evolutionary basis for the observed patterns. These findings contribute to a systems-level picture of how CR influences transcription within mammalian cells, and point towards a comprehensive understanding of CR in terms of its influence on biological networks.

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The p66shc adaptor protein controls oxidative stress response and life span in mammals

Cited by 1,607 publications

References 28 publications

Role of dietary amino acid balance in diet restriction‐mediated lifespan extension, renoprotection, and muscle weakness in aged mice

Role of dietary amino acid balance in diet restriction‐mediated lifespan extension, renoprotection, and muscle weakness in aged mice

Mitochondria and aging: A role for the mitochondrial transition pore?

Genes regulated by caloric restriction have unique roles within transcriptional networks

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