54 research outputs found
Aging-induced stem cell mutations as drivers for disease and cancer
Aging is characterized by a decrease in genome integrity, impaired organ maintenance, and an increased risk of cancer, which coincide with clonal dominance of expanded mutant stem and progenitor cell populations in aging tissues, such as the intestinal epithelium, the hematopoietic system, and the male germline. Here we discuss possible explanations for age-associated increases in the initiation and/or progression of mutant stem/progenitor clones and highlight the roles of stem cell quiescence, replication-associated DNA damage, telomere shortening, epigenetic alterations, and metabolic challenges as determinants of stem cell mutations and clonal dominance in aging
Sod2 haploinsufficiency does not accelerate aging of telomere dysfunctional mice
Telomere
shortening represents a causal factor of cellular senescence. At the same
time, several lines of evidence indicate a pivotal role of oxidative DNA
damage for the aging process in vivo. A causal connection between
the two observations was suggested by experiments showing accelerated
telomere shorting under conditions of oxidative stress in cultured cells,
but has never been studied in vivo. We therefore have analysed
whether an increase in mitochondrial derived oxidative stress in response
to heterozygous deletion of superoxide dismutase (Sod2+/-)
would exacerbate aging phenotypes in telomere dysfunctional (mTerc-/-)
mice. Heterozygous deletion of Sod2 resulted in reduced SOD2 protein
levels and increased oxidative stress in aging telomere dysfunctional mice,
but this did not lead to an increase in basal levels of oxidative nuclear
DNA damage, an accumulation of nuclear DNA breaks, or an increased rate of
telomere shortening in the mice. Moreover, heterozygous deletion of Sod2
did not accelerate the depletion of stem cells and the impairment in organ
maintenance in aging mTerc-/- mice. In agreement
with these observations, Sod2 haploinsufficiency did not lead to a
further reduction in lifespan of mTerc-/- mice. Together,
these results indicate that a decrease in SOD2-dependent antioxidant
defence does not exacerbate aging in the context of telomere dysfunction
Regeneration in starved planarians depends on TRiC/CCT subunits modulating the unfolded protein response
Planarians are able to stand long periods of starvation by maintaining adult stem cell pools and regenerative capacity. The molecular pathways that are needed for the maintenance of regeneration during starvation are not known. Here, we show that down‐regulation of chaperonin TRiC/CCT subunits abrogates the regeneration capacity of planarians during starvation, but TRiC/CCT subunits are dispensable for regeneration in fed planarians. Under starvation, they are required to maintain mitotic fidelity and for blastema formation. We show that TRiC subunits modulate the unfolded protein response (UPR) and are required to maintain ATP levels in starved planarians. Regenerative defects in starved CCT‐depleted planarians can be rescued by either chemical induction of mild endoplasmic reticulum stress, which leads to induction of the UPR, or by the supplementation of fatty acids. Together, these results indicate that CCT‐dependent UPR induction promotes regeneration of planarians under food restriction
Telomere Shortening Impairs Regeneration of the Olfactory Epithelium in Response to Injury but Not Under Homeostatic Conditions
Atrophy of the olfactory epithelium (OE) associated with impaired olfaction and dry nose represents one of the most common phenotypes of human aging. Impairment in regeneration of a functional olfactory epithelium can also occur in response to injury due to infection or nasal surgery. These complications occur more frequently in aged patients. Although age is the most unifying risk factor for atrophic changes and functional decline of the olfactory epithelium, little is known about molecular mechanisms that could influence maintenance and repair of the olfactory epithelium. Here, we analyzed the influence of telomere shortening (a basic mechanism of cellular aging) on homeostasis and regenerative reserve in response to chemical induced injury of the OE in late generation telomere knockout mice (G3 mTerc−/−) with short telomeres compared to wild type mice (mTerc+/+) with long telomeres. The study revealed no significant influence of telomere shortening on homeostatic maintenance of the OE during mouse aging. In contrast, the regenerative response to chemical induced injury of the OE was significantly impaired in G3 mTerc−/− mice compared to mTerc+/+ mice. Seven days after chemical induced damage, G3 mTerc−/− mice exhibited significantly enlarged areas of persisting atrophy compared to mTerc+/+ mice (p = 0.031). Telomere dysfunction was associated with impairments in cell proliferation in the regenerating epithelium. Deletion of the cell cycle inhibitor, Cdkn1a (p21) rescued defects in OE regeneration in telomere dysfunctional mice. Together, these data indicate that telomere shortening impairs the regenerative capacity of the OE by impairing cell cycle progression in a p21-dependent manner. These findings could be relevant for the impairment in OE function in elderly people
Effect of Cytotoxic Chemotherapy on Markers of Molecular Age in Patients With Breast Cancer
Senescent cells, which express p16 INK4a, accumulate with aging and contribute to age-related pathology. To understand whether cytotoxic agents promote molecular aging, we measured expression of p16 INK4a and other senescence markers in breast cancer patients treated with adjuvant chemotherapy
p16 and ARF: activation of teenage proteins in old age
Cellular senescence induced by different stresses and telomere shortening appears to play an important role in the aging process. The products of the INK4a/ARF locus — p16(INK4a) and ARF — arrest cell proliferation at the senescence stage by exerting their effects on retinoblastoma protein– and p53-mediated responsive pathways. A study in this issue of the JCI provides experimental evidence of a specific upregulation of these cell cycle inhibitors in a variety of organs during mammalian aging
Quiescence: Good and Bad of Stem Cell Aging
Stem cells are required for lifelong homeostasis and regeneration of tissues and organs in mammals, but the function of stem cells declines during aging. To preserve stem cells during life, they are kept in a quiescent state with low metabolic and low proliferative activity. However, activation of quiescent stem cells - an essential process for organ homeostasis/regeneration - requires concerted and faithful regulation of multiple molecular circuits controlling biosynthetic processes, repair mechanisms, and metabolic activity. Thus, while protecting stem cell maintenance, quiescence comes at the cost of vulnerability during the process of stem cell activation. Here we discuss molecular and biochemical processes regulating stem cells' maintenance in and exit from quiescence and how age-related failures of these circuits can contribute to organism aging
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