Project description:Various anti-aging interventions exhibit potential in extending lifespan, yet most of these interventions are inefficacy or even have deleterious effects on healthspan. Ginkgolide B (GB) is a Ginkgo biloba-derived small molecule that reduces aging-related morbidities; however, the effects of GB on healthspan and longevity remain elusive. Here, we report that continuous oral GB administration in mice starting at 20 months extended their lifespan by 20% and reduced tumour incidence. Besides, GB administration significantly improved healthspan evidenced by enhancement in muscle quality, physical performance, grip strength, metabolism, frailty index, systemic inflammation, and senescence. Moreover, GB administration ameliorated aging-related pathologies without any apparent adverse effects. Single-nucleus RNA sequencing (snRNA-seq) revealed that GB improved aging-associated abnormal cell-type composition, intracellular signalling pathways, and cell-cell communication in skeletal muscles. GB also reduced the levels of aging-induced novel Runx1+ type 2B myonuclei, which are associated with apoptotic burden and aging-related signatures. Runx1 derived senescence, as shown by gain- and loss-of-function assays. Together, a new function of GB in extending the healthspan in aging is identified, which contributes to lifespan extension. The senomorphic effects of GB on the multifactorial aging process may provide new prospects for achieving healthy aging and longevity extension.

Project description:Targeting NAT10 enhances healthspan and lifespan in a mouse model of human accelerated aging syndrome.

Project description:Mitochondrial damage and mitophagy deregulation are hallmark features of aging and age-related pathologies. Urolithin A (UA), a potent mitophagy inducer, is known to confer neuroprotection, maintain muscle integrity, and extend healthspan and lifespan across diverse species. However, the molecular mechanisms underlying UA-mediated mitophagy remain largely unknown. Here, we demonstrate that UA treatment modulates cytosolic calcium levels, which are essential for initiating robust mitophagy in both neurons and muscles. Transcriptomic and proteomic analyses reveal that UA facilitates the reorganization of interorganellar communication between the endoplasmic reticulum (ER), lysosomes, and mitochondria, a process that is highly dependent on calcium signaling. Our findings suggest that calcium is released from the ER, subsequently enhancing lysosomal activity and facilitating mitochondrial entry, ultimately leading to mitochondrial fission and the successful execution of mitophagy. Notably, calcium chelation abolishes UA-induced mitophagy, leading to impaired muscle function and diminished lifespan extension, underscoring the indispensable role of calcium dynamics.We further found that UA-induced calcium elevation triggers mitochondrial biogenesis through the activation of UNC-43/CaMKII and SKN-1/Nrf2, mechanisms critical for healthspan and lifespan extension. In human cells, UA supplementation not only induces mitophagy but also enhances mitochondrial metabolism and prevents stress-induced senescence in a calcium-dependent manner. Ultimately, our findings uncover the mechanistic insights of UA-mediated geroprotection and underscore the central role of calcium dynamics in orchestrating the crosstalk between different cellular compartments, thereby sustaining energy homeostasis and overall organismal physiology.

Project description:Circular RNAs (circRNAs) accumulate with age, but their functional impact on aging remains elusive. In this study, we reveal a mechanism by which ribonuclease κ (RNASEK) prevents age-dependent circRNA accumulation by promoting its degradation. Through a genetic screen targeting ribonucleases, we identified RNASEK as a specific circRNA-cleaving ribonuclease. RNASEK is downregulated during aging, causing the age-dependent increase in circRNA levels. RNASEK is necessary and sufficient for lifespan extension and healthspan maintenance in Caenorhabditis elegans. Mammalian RNASEK also directly degrades circRNAs, and is required for preventing premature aging in cultured human cells and mice, indicating its evolutionarily conserved role. Notably, we demonstrate that circRNAs localize within stress granules, where RNASEK, in collaboration with HSP90, prevents toxic aggregation of circRNAs in aged organisms. Our study establishes RNASEK as a conserved regulator of aging and offers a framework for targeting circRNAs to mitigate age-associated diseases and to extend organismal healthspan.

Project description:Circular RNAs (circRNAs) accumulate with age, but their functional impact on aging remains elusive. In this study, we reveal a mechanism by which ribonuclease κ (RNASEK) prevents age-dependent circRNA accumulation by promoting its degradation. Through a genetic screen targeting ribonucleases, we identified RNASEK as a specific circRNA-cleaving ribonuclease. RNASEK is downregulated during aging, causing the age-dependent increase in circRNA levels. RNASEK is necessary and sufficient for lifespan extension and healthspan maintenance in Caenorhabditis elegans. Mammalian RNASEK also directly degrades circRNAs, and is required for preventing premature aging in cultured human cells and mice, indicating its evolutionarily conserved role. Notably, we demonstrate that circRNAs localize within stress granules, where RNASEK, in collaboration with HSP90, prevents toxic aggregation of circRNAs in aged organisms. Our study establishes RNASEK as a conserved regulator of aging and offers a framework for targeting circRNAs to mitigate age-associated diseases and to extend organismal healthspan.

Project description:Circular RNAs (circRNAs) accumulate with age, but their functional impact on aging remains elusive. In this study, we reveal a mechanism by which ribonuclease κ (RNASEK) prevents age-dependent circRNA accumulation by promoting its degradation. Through a genetic screen targeting ribonucleases, we identified RNASEK as a specific circRNA-cleaving ribonuclease. RNASEK is downregulated during aging, causing the age-dependent increase in circRNA levels. RNASEK is necessary and sufficient for lifespan extension and healthspan maintenance in Caenorhabditis elegans. Mammalian RNASEK also directly degrades circRNAs, and is required for preventing premature aging in cultured human cells and mice, indicating its evolutionarily conserved role. Notably, we demonstrate that circRNAs localize within stress granules, where RNASEK, in collaboration with HSP90, prevents toxic aggregation of circRNAs in aged organisms. Our study establishes RNASEK as a conserved regulator of aging and offers a framework for targeting circRNAs to mitigate age-associated diseases and to extend organismal healthspan.

Project description:The mitochondrial unfolded protein response (UPRmt) is one of the mito-nuclear regulatory circuits that restores mitochondrial function upon stress conditions, promoting metabolic health and longevity. However, the complex gene interactions that govern this pathway and its role in aging and healthspan remain to be fully elucidated. Here, we activated the UPRmt using doxycycline (Dox) in a genetically diverse C. elegans population comprising 85 strains and observed large variation in Dox-induced lifespan extension across these strains. Through multi-omic data integration, we identified an aging-related molecular signature that was partially reversed by Dox. To identify the mechanisms underlying Dox-induced lifespan extension, we applied quantitative trait locus (QTL) analyses and found one novel UPRmt modulator, fipp-1/FIP1L1, which was functionally validated in C. elegans and humans. In the human UK Biobank, FIP1L1 was associated with metabolic homeostasis, underscoring its translational relevance. Overall, our findings demonstrate a novel UPRmt modulator across species and provide insights into potential translational research.

Project description:The SIRT1 deacetylase is one of the best-studied potential mediators of some of the anti-aging effects of calorie restriction (CR); but its role in CR-dependent lifespan extension has not been demonstrated. We previously found that mice lacking both copies of SIRT1 displayed a shorter median lifespan than wild type mice on an ad libitum diet. Here we report that median lifespan extension in CR heterozygote SIRT1+/- mice was identical (51%) to that observed in wild type mice but SIRT1+/- mice displayed a higher frequency of some certain pathologies. Although larger studies in different genetic backgrounds are necessary , these results provide strong initial evidence for the requirement of SIRT1 for the anti-aging effects of CR, but suggest that its high expression is not required for CR-induced lifespan extension. Key words: SIRT1, caloric restriction, lifespan, anti-aging 2-5 month old male mice of 3 different genotypes (SIRT1+/+, SIRT1+/-, and SIRT1-/-) that had normal, reduced or no expression of SIRT1 were treated with either a 40% caloric restricted diet (CR) or an ad libitum diet (AL). 2-4 replicates of each experimental condition were used in the analysis.

Project description:Dietary intervention constitutes a feasible approach for modulating metabolism and improving healthspan and lifespan. Methionine restriction (MR) delays the appearance of age-related diseases and increases longevity in normal mice. However, the effect of MR on premature aging remains to be elucidated. Here, we describe that MR extends lifespan in two different mouse models of Hutchinson-Gilford progeria syndrome (HGPS) by reversing the transcriptome alterations in inflammation and DNA-damage response genes present in this condition. Further, MR improves the lipid profile and alters the levels of bile acids, both in wild-type and in progeroid mice. Notably, treatment with the bile acid cholic acid improves healthspan and lifespan in vivo. These results suggest the existence of a metabolic pathway involved in the longevity extension achieved by MR and support the possibility of dietary interventions for treating progeria.

Project description:A key challenge in aging research is to extend lifespan in tandem with slowing down functional decline so that the life with good health (healthspan) can be extended. Here, we show that clearance of a small number of cells, which highly express p21Cip1 (p21high), starting from 20 months improves cardiac and metabolic function, and extends both median and maximum lifespan in mice. Importantly, by assessing health and physical function of these mice monthly until death, we show that clearance of p21high cells improves physical function at all remaining stages of life, suggesting morbidity compression and healthspan extension. Mechanistically, p21high cells encompass several cell types, with a conserved pro-inflammatory signature. Clearance of p21high cells reduces inflammation, and rejuvenates transcriptomic signatures of various tissues to younger states. These findings demonstrate the feasibility of morbidity compression in mice, and indicate p21high cells as a therapeutic target for healthy aging.