Abstract
All presently known geroprotective chemical compounds of plant and microbial origin are caloric restriction mimetics because they can mimic the beneficial lifespan- and healthspan-extending effects of caloric restriction diets without the need to limit calorie supply. We have discovered a geroprotective chemical compound of mammalian origin, a bile acid called lithocholic acid, which can delay chronological aging of the budding yeast Saccharomyces cerevisiae under caloric restriction conditions. Here, we investigated mechanisms through which lithocholic acid can delay chronological aging of yeast limited in calorie supply. We provide evidence that lithocholic acid causes a stepwise development and maintenance of an aging-delaying cellular pattern throughout the entire chronological lifespan of yeast cultured under caloric restriction conditions. We show that lithocholic acid stimulates the aging-delaying cellular pattern and preserves such pattern because it specifically modulates the spatiotemporal dynamics of a complex cellular network. We demonstrate that this cellular network integrates certain pathways of lipid and carbohydrate metabolism, some intercompartmental communications, mitochondrial morphology and functionality, and liponecrotic and apoptotic modes of aging-associated cell death. Our findings indicate that lithocholic acid prolongs longevity of chronologically aging yeast because it decreases the risk of aging-associated cell death, thus increasing the chance of elderly cells to survive.
Highlights
The budding yeast Saccharomyces cerevisiae is a unicellular eukaryote that has been successfully used as a model organism to identify genes and signaling pathways involved in aging; after being discovered in S. cerevisiae, these genes and signaling pathways have been shown to affect cellular and organismal aging in multicellular eukaryotes across phyla [1,2,3,4,5]
We examined mechanisms underlying the ability of lithocholic acid (LCA) to regulate the spatiotemporal dynamics of these other cellular processes confined to several compartments of yeast cells limited in calorie supply
We found that the dga1Δ, are1Δ and are2Δ mutations have the following effects: 1) since the middle of PD phase of cell culturing, each of them significantly increases the percentage of cells exhibiting propidium iodide (PI) positive staining typical of necrotic cell death (Figure 7A); 2) since the middle of PD phase of cell culturing, each of them significantly increases cell susceptibility to liponecrotic regulated cell death (RCD) caused by a 2-h treatment with palmitoleic acid (POA) (Figure 7D); 3) each of them significantly increases the cellular concentration of free fatty acids (FFA) (Figures 3E, 3J and 3O for dga1Δ, are1Δ and are2Δ [respectively])
Summary
The budding yeast Saccharomyces cerevisiae is a unicellular eukaryote that has been successfully used as a model organism to identify genes and signaling pathways involved in aging; after being discovered in S. cerevisiae, these genes and signaling pathways have been shown to affect cellular and organismal aging in multicellular eukaryotes across phyla [1,2,3,4,5]. In multicellular eukaryotes across phyla, organismal aging can be delayed, and the onset of aging-associated diseases can be postponed by CR and by certain chemical compounds of plant and microbial origin These geroprotective chemical compounds include resveratrol, rapamycin, curcumin, fisetin, quercetin, caffeine and spermidine; all of them exhibit beneficial effects on organismal lifespan and healthspan only under non-CR conditions [1, 19,20,21,22,23,24,25,26,27,28,29]. In S. cerevisiae, these geroprotectors slow down the replicative and chronological modes of aging under nonCR conditions by controlling information flow along a network that integrates an evolutionarily conserved set of signaling pathways and protein kinases [1, 19,20,21,22,23,24,25,26, 30,31,32,33,34,35,36,37,38,39,40,41,42,43]
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