The Aging Metabolome—Biomarkers to Hub Metabolites

Sharma, Rishi; Ramanathan, Arvind

doi:10.1002/pmic.201800407

Cited by 58 publications

(53 citation statements)

References 98 publications

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“…Additionally, there are several examples of the metabolic ability of metformin to facilitate (or impede) the transition from one cell type to another, including neuronal [52][53][54], osteogenic [55][56][57][58], adipogenic [39,59], myofibroblast and myoblast [60,61] differentiation, or monocyte-to-macrophage differentiation [62], among others. The fact that metformin targets a set of core "hub" metabolites with epigenetic properties and with emerging roles as central mediators of aging strongly supports the notion that it can regulate cell fate transitions by changing metabolite levels that allow the reorganization of specific chromatin marks [63]. Accordingly, a link between metformin-induced changes in specific metabolites (e.g., α-ketoglutarate and succinate) and the epigenetic control of cell fate transitioning has been established in a few cases [39,41,64].…”

Section: Metformin: a Metabolic Landscaper Of The Epigenomementioning

confidence: 82%

“…Metformin restores the global levels of H3K27me3 in fibroblasts of aged individuals or from patients with premature aging syndromes such as Hutchinson-Gilford progeria or Werner syndrome, likely by directly targeting the H3K27me3 demethylase KDM6A/UTX [24]. A decrease in repression-associated H3K27me3 (and an increased activity of KDM6A/UTX) is a key feature of the global chromatin reconfiguration that takes place not only in somatic cells during physiological aging but also in the prematurely aging cells from patients with Hutchinson-Gilford progeria or Werner syndrome [63,116,117]. Gain of H3K27me3 (and loss of KDM6A/UTX activity) has been linked to extended longevity in Caenorhabditis elegans, thus suggesting that metformin-driven preservation of high levels of H3K27me3 by inhibiting KDM6A/UTX may be critical for maintaining a youthful epigenetic landscape [63,[128][129][130].…”

Section: Metformin: Remolding and Preserving The Epigenetic Landscapementioning

confidence: 99%

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Metformin: Sentinel of the Epigenetic Landscapes That Underlie Cell Fate and Identity

Menendez

2020

Biomolecules

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The biguanide metformin is the first drug to be tested as a gerotherapeutic in the clinical trial TAME (Targeting Aging with Metformin). The current consensus is that metformin exerts indirect pleiotropy on core metabolic hallmarks of aging, such as the insulin/insulin-like growth factor 1 and AMP-activated protein kinase/mammalian Target Of Rapamycin signaling pathways, downstream of its primary inhibitory effect on mitochondrial respiratory complex I. Alternatively, but not mutually exclusive, metformin can exert regulatory effects on components of the biologic machinery of aging itself such as chromatin-modifying enzymes. An integrative metabolo-epigenetic outlook supports a new model whereby metformin operates as a guardian of cell identity, capable of retarding cellular aging by preventing the loss of the information-theoretic nature of the epigenome. The ultimate anti-aging mechanism of metformin might involve the global preservation of the epigenome architecture, thereby ensuring cell fate commitment and phenotypic outcomes despite the challenging effects of aging noise. Metformin might therefore inspire the development of new gerotherapeutics capable of preserving the epigenome architecture for cell identity. Such gerotherapeutics should replicate the ability of metformin to halt the erosion of the epigenetic landscape, mitigate the loss of cell fate commitment, delay stochastic/environmental DNA methylation drifts, and alleviate cellular senescence. Yet, it remains a challenge to confirm if regulatory changes in higher-order genomic organizers can connect the capacity of metformin to dynamically regulate the three-dimensional nature of epigenetic landscapes with the 4th dimension, the aging time.

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Section: Metformin: a Metabolic Landscaper Of The Epigenomementioning

confidence: 82%

Section: Metformin: Remolding and Preserving The Epigenetic Landscapementioning

confidence: 99%

Metformin: Sentinel of the Epigenetic Landscapes That Underlie Cell Fate and Identity

Menendez

2020

Biomolecules

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“…Furthermore, it is not surprising that “tRNA charging pathway” (predicted as several amino acids were different between old and young groups) was the pathway most altered by age in both ischemic and control group as tRNAs are regulators of key biological processes such as protein biosynthesis and gene expression (Raina & Ibba, 2014). Of note, cellular and circulating amino acids play several roles both in young and old age such as fueling the tricarboxylic acid cycle (the Krebs cycle) in mitochondria, an organelle known to be affected by aging and by I/R injury (Ham and Raju, (2017); Martínez‐Reyes & Chandel, 2020; Sharma & Ramanathan, 2020). Impaired circulating amino acid levels may be strictly related to the altered mitochondrial function in aged mice (Ham and Raju, (2017); Martínez‐Reyes & Chandel, 2020; Sharma & Ramanathan, 2020).…”

Section: Discussionmentioning

confidence: 99%

“…Of note, cellular and circulating amino acids play several roles both in young and old age such as fueling the tricarboxylic acid cycle (the Krebs cycle) in mitochondria, an organelle known to be affected by aging and by I/R injury (Ham and Raju, (2017); Martínez‐Reyes & Chandel, 2020; Sharma & Ramanathan, 2020). Impaired circulating amino acid levels may be strictly related to the altered mitochondrial function in aged mice (Ham and Raju, (2017); Martínez‐Reyes & Chandel, 2020; Sharma & Ramanathan, 2020). Pyridoxal 5′‐phosphate savage pathway, essential cofactor of numerous metabolic enzymes and mainly involved in amino acid metabolism, was also changed with age in our study (Bode and Berg, 1991).…”

Section: Discussionmentioning

confidence: 99%

Effects of myocardial ischemia/reperfusion injury on plasma metabolomic profile during aging

et al. 2020

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BackgroundHeart disease is a frequent cause of hospitalization and mortality for elderly patients. A common feature of both heart disease and aging itself is the involvement of metabolic organ alterations ultimately leading to changes in circulating metabolite levels. However, the specific contribution of aging and ischemic injury to the metabolic dysregulation occurring in older adults with ischemic heart disease is still unknown.AimTo evaluate the effects of aging and ischemia/reperfusion (I/R) injury on plasma metabolomic profiling in mice.MethodsYoung and aged mice were subjected to a minimally invasive model of I/R injury or sham operation. Complete evaluation of cardiac function and untargeted plasma metabolomics analysis were performed.ResultsWe confirmed that aged mice from the sham group had impaired cardiac function and augmented left ventricular (LV) dimensions compared to young sham‐operated mice. Further, we found that ischemic injury did not drastically reduce LV systolic/diastolic function and dyssynchrony in aged compared to young mice. Using an untargeted metabolomics approach focused on aqueous metabolites, we found that ischemic injury does not affect the plasma metabolomic profile either in young or old mice. Our data also demonstrate that age significantly affects circulating metabolite levels (predominantly amino acids, phospholipids and organic acids) and perturbs several pathways involved in amino acid, glucid and nucleic acid metabolism as well as pyridoxal‐5′‐phosphate salvage pathway in both sham and ischemic mice.ConclusionsOur approach increases our understanding of age‐associated plasma metabolomic signatures in mice with and without heart disease excluding confounding factors related to metabolic comorbidities.

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“…A gradual slowing down of metabolism with age is also documented. A very recent review on the "aging metabolome" enumerated the set of biomarkers and hub metabolites of aging, indicating critical roles for nicotinamide adenine dinucleotide (NAD + ), reduced nicotinamide dinucleotide phosphate (NADPH), αketoglutarate, and β−hydroxybutyrate with a central role of the TCA cycle in signaling and metabolic dysregulation associated with aging (Sharma and Ramanathan, 2020). As very recently commented by Di Ciaula and Portincasa, "successful aging could begin during in utero life" (Di Ciaula and Portincasa, 2020).…”

Section: Introductionmentioning

confidence: 99%

The Chemical Exposome of Human Aging

Misra

2020

Front. Genet.

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Aging is an inevitable biological phenomenon displayed by single cells and organs to entire organismal systems. Aging as a biological process is characterized as a progressive decline in intrinsic biological function. Understanding the causative mechanisms of aging has always captured the imagination of researchers since time immemorial. Although both biological and chronological aging are well defined and studied in terms of genetic, epigenetic, and lifestyle predispositions, the hallmarks of aging in terms of small molecules (i.e., endogenous metabolites to chemical exposures) are limited to obscure. On top of the endogenous metabolites leading to the onset and progression of healthy aging, human beings are constantly exposed to a natural and anthropogenic “chemical” environment round the clock, from conception till death, affecting one’s physiology, health and well-being, and disease predisposition. The research community has started gaining sizeable insights into deciphering the aging factors such as immunosenescence, nutrition, frailty, inflamm-aging, and diseases till date, without much input from their interaction with exogenous chemical exposures. The “exposome” around us, mostly, accelerates the process of aging by affecting the internal biological pathways and signaling mechanisms that result in the deterioration of human health. However, the entirety of exposome on human aging is far from established. This review intends to catalog the known and established associations of the exposome from past studies focusing on aging in humans and other model organisms. Further discussed are the current technologies and informatics tools that enable the study of aging exposotypes, and thus, provide a window of opportunities and challenges to study the “aging exposome” in granular details.

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The Aging Metabolome—Biomarkers to Hub Metabolites

Cited by 58 publications

References 98 publications

Metformin: Sentinel of the Epigenetic Landscapes That Underlie Cell Fate and Identity

Metformin: Sentinel of the Epigenetic Landscapes That Underlie Cell Fate and Identity

Effects of myocardial ischemia/reperfusion injury on plasma metabolomic profile during aging

The Chemical Exposome of Human Aging

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