Shijing Luo scite author profile

SUMMARY Reproductive cessation is perhaps the earliest aging phenotypes humans experience. Similarly, C. elegans’ reproduction ceases in mid-adulthood. Although somatic aging has been studied in both worms and humans, mechanisms regulating reproductive aging are not yet understood. Here we show that TGF-β Sma/Mab and Insulin/IGF-1 signaling regulate C. elegans reproductive aging by modulating multiple aspects of the reproductive process, including embryo integrity, oocyte fertilizability, chromosome segregation fidelity, DNA damage resistance, and oocyte and germline morphology. TGF-β activity regulates reproductive span and germline/oocyte quality non-cell-autonomously, and is temporally and transcriptionally separable from its regulation of growth. Chromosome segregation, cell cycle, and DNA damage response genes are upregulated in TGF-β mutant oocytes, decline in aged mammalian oocytes, and are critical for oocyte quality maintenance. Our data suggest that C. elegans and humans share many aspects of reproductive aging, including the correlation between reproductive aging and declining oocyte quality, and mechanisms determining oocyte quality.

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The C. elegans TGF-β Dauer Pathway Regulates Longevity via Insulin Signaling

Shaw

et al. 2007

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TGF-ß Sma/Mab Signaling Mutations Uncouple Reproductive Aging from Somatic Aging

et al. 2009

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Female reproductive cessation is one of the earliest age-related declines humans experience, occurring in mid-adulthood. Similarly, Caenorhabditis elegans' reproductive span is short relative to its total life span, with reproduction ceasing about a third into its 15–20 day adulthood. All of the known mutations and treatments that extend C. elegans' reproductive period also regulate longevity, suggesting that reproductive span is normally linked to life span. C. elegans has two canonical TGF-ß signaling pathways. We recently found that the TGF-ß Dauer pathway regulates longevity through the Insulin/IGF-1 Signaling (IIS) pathway; here we show that this pathway has a moderate effect on reproductive span. By contrast, TGF-ß Sma/Mab signaling mutants exhibit a substantially extended reproductive period, more than doubling reproductive span in some cases. Sma/Mab mutations extend reproductive span disproportionately to life span and act independently of known regulators of somatic aging, such as Insulin/IGF-1 Signaling and Dietary Restriction. This is the first discovery of a pathway that regulates reproductive span independently of longevity and the first identification of the TGF-ß Sma/Mab pathway as a regulator of reproductive aging. Our results suggest that longevity and reproductive span regulation can be uncoupled, although they appear to normally be linked through regulatory pathways.

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Stem cells expand potency and alter tissue fitness by accumulating diverse epigenetic memories

Gonzales

Polak

Matos

et al. 2021

Science

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Stem cells remember Tissue stem cells sense their surroundings, and this perception influences subsequent fate and function. Gonzales et al . observed that stem cells accumulate epigenetic memories of diverse environmental events (see the Perspective by Hoste). By wounding skin and monitoring the temporal steps involved in mobilizing stem cells of the hair follicle to repair the epidermis, the authors found that stem cells bear memories of their original niche, migration, encounters with inflammation, and adaptation to the new fate and tasks. During homeostasis, immigrant stem cells are functionally and transcriptionally analogous to native cells, but upon future assaults, they unleash discrete epigenetic memories to heighten physiological response and affect tissue fitness. —BAP

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Insulin Signaling Regulates Oocyte Quality Maintenance with Age via Cathepsin B Activity

et al. 2018

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A decline in female reproduction is one of the earliest hallmarks of aging in many animals, including invertebrates and mammals [1-4]. The insulin/insulin-like growth factor-1 signaling (IIS) pathway has a conserved role in regulating longevity [5] and also controls reproductive aging [2, 6]. Although IIS transcriptional targets that regulate somatic aging have been characterized [7, 8], it was not known whether the same mechanisms influence reproductive aging. We previously showed that Caenorhabditis elegans daf-2 IIS receptor mutants extend reproductive span by maintaining oocyte quality with age [6], but IIS targets in oocytes had not been identified. Here, we compared the transcriptomes of aged daf-2(-) and wild-type oocytes, and distinguished IIS targets in oocytes from soma-specific targets. Remarkably, IIS appears to regulate reproductive and somatic aging through largely distinct mechanisms, although the binding motif for longevity factor PQM-1 [8] was also overrepresented in oocyte targets. Reduction of oocyte-specific IIS targets decreased reproductive span extension and oocyte viability of daf-2(-) worms, and pqm-1 is required for daf-2(-)'s long reproductive span. Cathepsin-B-like gene expression and activity levels were reduced in aged daf-2(-) oocytes, and RNAi against cathepsin-B-like W07B8.4 improved oocyte quality maintenance and extended reproductive span. Importantly, adult-only pharmacological inhibition of cathepsin B proteases reduced age-dependent deterioration in oocyte quality, even when treatment was initiated in mid-reproduction. This suggests that it is possible to pharmacologically slow age-related reproductive decline through mid-life intervention. Oocyte-specific IIS target genes thereby revealed potential therapeutic targets for maintaining reproductive health with age.

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Shijing Luo

TGF-β and Insulin Signaling Regulate Reproductive Aging via Oocyte and Germline Quality Maintenance

The C. elegans TGF-β Dauer Pathway Regulates Longevity via Insulin Signaling

TGF-ß Sma/Mab Signaling Mutations Uncouple Reproductive Aging from Somatic Aging

Stem cells expand potency and alter tissue fitness by accumulating diverse epigenetic memories

Insulin Signaling Regulates Oocyte Quality Maintenance with Age via Cathepsin B Activity

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