Age-related diseases as vicious cycles

Belikov, Aleksey V.

doi:10.1016/j.arr.2018.11.002

Cited by 66 publications

(40 citation statements)

References 336 publications

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“…The human population is rapidly growing older [1,2], with a concomitant increase in agerelated diseases [2,3] and societal challenges. Much of the recent increase in human life span can be attributed to improved sanitation and medical advances; however, there is also a genetic component.…”

Section: Introductionmentioning

confidence: 99%

Context-dependent genetic architecture of Drosophila life span

et al. 2020

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Understanding the genetic basis of variation in life span is a major challenge that is difficult to address in human populations. Evolutionary theory predicts that alleles affecting natural variation in life span will have properties that enable them to persist in populations at intermediate frequencies, such as late-life-specific deleterious effects, antagonistic pleiotropic effects on early and late-age fitness components, and/or sex-and environment-specific or antagonistic effects. Here, we quantified variation in life span in males and females reared in 3 thermal environments for the sequenced, inbred lines of the Drosophila melanogaster Genetic Reference Panel (DGRP) and an advanced intercross outbred population derived from a subset of DGRP lines. Quantitative genetic analyses of life span and the micro-environmental variance of life span in the DGRP revealed significant genetic variance for both traits within each sex and environment, as well as significant genotype-by-sex interaction (GSI) and genotype-by-environment interaction (GEI). Genome-wide association (GWA) mapping in both populations implicates over 2,000 candidate genes with sex-and environment-specific or antagonistic pleiotropic allelic effects. Over 1,000 of these genes are associated with variation in life span in other D. melanogaster populations. We functionally assessed the effects of 15 candidate genes using RNA interference (RNAi): all affected life span and/or micro-environmental variance of life span in at least one sex and environment and exhibited sex-and environment-specific effects. Our results implicate novel candidate genes affecting life span and suggest that variation for life span may be maintained by variable allelic effects in heterogeneous environments.

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Section: Introductionmentioning

confidence: 99%

Context-dependent genetic architecture of Drosophila life span

et al. 2020

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“…These differences suggest that may be cell-specific changes in autophagy during senescence. Nonetheless, it appears that in the liver, autophagy likely decreases with aging and may be involved in many age-related diseases such as NAFLD and Type 2 DM [1,3,11,12,36]. In this connection, we found that both senescent AML12 cells and livers from aged mice showed late autophagy block associated with increased intracellular fat content (Figure 5a-g).…”

Section: Senescent Cells Are Metabolically Hyperactive and Display A mentioning

confidence: 76%

“…Moreover, the mRNA expression of senescence marker genes, P53, P21 and P16 were increased in the senescent AML12 cells compared to control AML12 cells (Figure 1d). Similarly, the expression of these genes also was increased in livers from old mice (100-108 week age) compared to those from young mice (12)(13)(14)(15)(16)(17)(18)(19)(20) week age) (Figure 1e). Furthermore, multiple H2O2 treatments increased senescence since there was increased activated -Gal (SA -Gal)-positive cells (Figure 2a,b) and H2A.X-positive cells containing condensed chromatin in larger nuclei (Figure 2c,d).…”

Section: Senescence Induction and Validation In Aml12 Cellsmentioning

confidence: 82%

“…Such a tool would not only enable better understanding of the molecular and metabolic defects associated with aging, but also could potentially help identify druggable targets to treat age-associated chronic hepatic diseases such as fatty liver, steatohepatitis, Type 2 diabetes, hepatic fibrosis in a time-and cost-efficient manner [3, 5-7, 16, 23]. Cellular senescence and the number of senescent cells significantly increases in most tissues during aging [9,12,24]. Previous in vitro senescence models have utilized primary fibroblasts or hepatic carcinoma cells that were subjected to oxidative stress conditions or irradiation [17][18][19][20][21][22][23].…”

Section: Discussionmentioning

confidence: 99%

“…It is characterized by permanent cell cycle arrest, resistance to apoptosis, and a senescence-associated secretory phenotype [5]. Under pathological stress conditions, excessive accumulation of senescence cells in affected tissues adversely affects the tissue's regenerative ability and creates a proinflammatory environment that can resemble various age-related disorders such as Alzheimer's disease, cancer, arthritis, cataracts, osteoporosis, atherosclerosis, hypertension, cardiovascular disease, Type 2 diabetes, and chronic liver disorders [3,5,7,[9][10][11][12]. Targeting senescent cells has the potential to delay age-associated disorders and/or reverse pathological metabolic phenotypes [3,[13][14][15][16].…”

Section: Introductionmentioning

confidence: 99%

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Development of an in vitro senescent hepatic cell model for metabolic studies in aging

Singh

Tripathi

Yen

et al. 2020

Preprint

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Although in vitro senescence models have been developed using primary fibroblasts, they may not be applicable for the study of metabolically active organs such as the liver. We thus developed an in vitro protocol to induce senescence in AML12 nontransformed hepatocyte cell lines derived from mice transgenic for transforming growth factor alpha. Sequential oxidative stress with hydrogen peroxide induced premature senescence in these cells as they exhibited molecular and metabolic signatures, had increased SA-Gal and H2A.X staining, and elevated senescence and pro-inflammatory gene expression that resembled the livers from aged mice.Metabolic phenotyping showed fuel switching towards more glycolysis, mitochondrial glutamine oxidation, and impaired energy production that also was similar to the livers from aged mice. Additionally, Senescence Activated Secretory Proteins (SASPs) sensitized normal AML12 cells to palmitate-induced toxicity, a known pathological effect of hepatic aging. In summary, we have generated an in vitro senescent AML12 cell model that not only show the molecular hallmarks of aging, but also recapitulates the aberrant metabolic phenotype found in aged liver. As such, they represent a novel and useful model to study nutritional, pharmacological, or genetic factors on hepatic metabolism during aging.

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