Summary Chromatin and metabolic states both influence lifespan, but how they interact in lifespan regulation is largely unknown. The COMPASS chromatin complex, which trimethylates lysine 4 on histone H3 (H3K4me3), regulates lifespan in C. elegans. However, the mechanism by which H3K4me3 modifiers impact longevity, and whether it involves metabolic changes, remain unclear. Here we find that H3K4me3-methyltransferase deficiency, which extends lifespan, promotes fat accumulation with a specific enrichment of mono-unsaturated fatty acids (MUFAs). This fat metabolism switch in H3K4me3-methyltransferase deficient animals is mediated at least in part by downregulation of germline targets, including S6 kinase, and by activation of an intestinal transcriptional network that upregulates delta-9 fatty acid desaturases. Interestingly, MUFA accumulation is necessary for the lifespan extension of H3K4me3-methyltransferase deficient worms, and dietary MUFAs are sufficient to extend lifespan. Given the conservation of lipid metabolism, dietary or endogenous MUFAs could extend lifespan and healthspan in other species, including mammals.
Ageing is driven by a loss of transcriptional and protein homeostasis1–3 and is the key risk factor for multiple chronic diseases. Interventions that attenuate or reverse systemic dysfunction seen with age therefore have potential to reduce overall disease risk in the elderly. Pre-mRNA splicing is a fundamental link between gene expression and the proteome, and deregulation of the splicing machinery is linked to multiple age-related chronic diseases4,5. However, the role of splicing homeostasis in healthy ageing remains unclear. Here we demonstrate that pre-mRNA splicing homeostasis is a biomarker and predictor of life expectancy in Caenorhabditis elegans. Using transcriptomics and in-depth splicing analysis in young and old animals fed ad libitum or on dietary restriction (DR), we find defects in global pre-mRNA splicing with age that are reduced by DR via the branch point binding protein (BBP)/splicing factor 1 (SFA-1). We show that SFA-1 is specifically required for lifespan extension both by DR, and modulation of TORC1 pathway components AMPK, RAGA-1 and RSKS-1/S6 Kinase. Lastly, we demonstrate that overexpression of SFA-1 is sufficient to extend lifespan. Together, these data demonstrate a role for RNA splicing homeostasis in DR longevity and suggest modulation of specific spliceosome components can prolong healthy ageing.
Target of rapamycin complex 1 (TORC1) and AMP-activated protein kinase (AMPK) antagonistically modulate metabolism and aging. However, how they coordinate to determine longevity and if they act via separable mechanisms is unclear. Here, we show that neuronal AMPK is essential for lifespan extension from TORC1 inhibition, and that TORC1 suppression increases lifespan cell non autonomously via distinct mechanisms from global AMPK activation. Lifespan extension by null mutations in genes encoding raga-1 (RagA) or rsks-1 (S6K) is fully suppressed by neuronal-specific rescues. Loss of RAGA-1 increases lifespan via maintaining mitochondrial fusion. Neuronal RAGA-1 abrogation of raga-1 mutant longevity requires UNC-64/syntaxin, and promotes mitochondrial fission cell nonautonomously. Finally, deleting the mitochondrial fission factor DRP-1 renders the animal refractory to the pro-aging effects of neuronal RAGA-1. Our results highlight a new role for neuronal TORC1 in cell nonautonomous regulation of longevity, and suggest TORC1 in the central nervous system might be targeted to promote healthy aging.
We have generated a single-copy knock-in loci for defined gene expression (SKI LODGE) system to insert any DNA by CRISPR/Cas9 at defined safe harbors in the Caenorhabditis elegans genome. Utilizing a single crRNA guide, which also acts as a Co-CRISPR enrichment marker, any DNA sequence can be introduced as a single copy, regulated by different tissue-specific promoters. The SKI LODGE system provides a fast, economical, and effective approach for generating single-copy ectopic transgenes in C. elegans .
In response to stressful conditions, eukaryotic cells launch an arsenal of regulatory programs to protect the proteome. One major protective response involves the arrest of protein translation and the formation of stress granules, cytoplasmic ribonucleoprotein complexes containing the conserved RNA-binding proteins TIA-1 and TIAR. The stress granule response is thought to preserve mRNA for translation when conditions improve. For cells of the germline—the immortal cell lineage required for sexual reproduction—protection from stress is critically important for perpetuation of the species, yet how stress granule regulatory mechanisms are deployed in animal reproduction is incompletely understood. Here, we show that the stress granule protein TIAR-1 protects the Caenorhabditis elegans germline from the adverse effects of heat shock. Animals containing strong loss-of-function mutations in tiar-1 exhibit significantly reduced fertility compared to the wild type following heat shock. Analysis of a heat-shock protein promoter indicates that tiar-1 mutants display an impaired heat-shock response. We observed that TIAR-1 was associated with granules in the gonad core and oocytes during several stressful conditions. Both gonad core and oocyte granules are dynamic structures that depend on translation; protein synthesis inhibitors altered their formation. Nonetheless, tiar-1 was required for the formation of gonad core granules only. Interestingly, the gonad core granules did not seem to be needed for the germ cells to develop viable embryos after heat shock. This suggests that TIAR-1 is able to protect the germline from heat stress independently of these structures.
Advances in public health in the last century have seen a sharp increase in human life expectancy. With these changes have come increased incidence of age-related pathologies and health burdens in the elderly. Patient age is the biggest risk factor for multiple chronic conditions that often occur simultaneously within one individual. An alternative to disease centric therapeutic approaches is that of ‘geroscience’, which aims to define molecular mechanisms that link age to overall disease risk. One such mechanism is deregulation of CREB-regulated transcriptional coactivators, CRTCs. Initially identified for their role in modulating CREB transcription, the last five years has seen an expansion in knowledge of new cellular regulators and roles of CRTCs beyond CREB. CRTCs have been shown to modulate organismal aging in C. elegans and to impact age-related diseases in humans. Here, we discuss CRTC deregulation as a new driver of aging, and integrating link between age and disease risk.
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Apoptosis is an important mechanism for maintaining germ line health. In Caenorhabditis elegans, germ cell apoptosis occurs under normal conditions to sustain gonad homeostasis and oocyte quality. Under stress, germ cell apoptosis can be triggered via different pathways, including the following: (i) the CEP-1/p53 pathway, which induces germ cell apoptosis when animals are exposed to DNA damage; (ii) the mitogen-activated protein kinase kinase (MAPKK) pathway, which triggers germ cell apoptosis when animals are exposed to heat shock, oxidative stress, or osmotic stress; and (iii) an unknown mechanism that triggers germ cell apoptosis during starvation. Here, we address how starvation induces germ cell apoptosis. Using polysomal profiling, we found that starvation for 6 h reduces the translationally active ribosomes, which differentially affect the mRNAs of the core apoptotic machinery and some of its regulators. During starvation, lin-35/Rb mRNA increases its expression, resulting in the accumulation of this protein. As a consequence, LIN-35 downregulates the expression of the antiapoptotic gene ced-9/Bcl-2. We observed that the reduced translation of ced-9/Bcl-2 mRNA during food deprivation together with its downregulation drastically affects its protein accumulation. We propose that CED-9/Bcl-2 downregulation via LIN-35/Rb triggers germ cell apoptosis in C. elegans in response to starvation. Many germ cells (known in many organisms as nurse cells) are needed to produce a single oocyte. Once they have served their purpose, nurse cells are eliminated by apoptosis. An unsolved question in the germ cell field is how apoptosis is triggered to produce and sometimes protect germ cells. Adult Caenorhabditis elegans nematodes that encounter food deprivation enter a diapause stage that allows them to survive for a few months and put off fertility (1, 2). Later, when animals are subjected to better conditions, they exit adult diapause and restore fertility. Germ cell apoptosis is a key element to protect gonads from starvation, as exhibited by mutants of the caspase CED-3 that are unable to restore fertility after adult diapause (1). Previously, we found that starvation triggers germ cell apoptosis (3), and in this study we proposed a model to explain how this response is regulated in C. elegans.In C. elegans, apoptosis occurs in somatic tissues during embryonic and postembryonic development (developmental apoptosis) (4, 5) and in the adult hermaphrodite gonad (physiological germ cell apoptosis) (6). In this nematode, apoptosis is executed via a conserved pathway that consists of the proteins CED-3 (a caspase), CED-4 (APAF1-like adaptor protein), and CED-9 (BCL2 ortholog) (reviewed in references 7 and 8). Developmental apoptosis is initiated when the protein EGL-1 (BH3-only) disrupts the CED-9/CED-4 complex, thereby triggering CED-3 activation.The mechanism that induces physiological germ cell apoptosis is independent of EGL-1 (6) and is partially induced by the ortholog of the human retinoblastoma gene (Rb) lin-35, which...
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