Abstract
Aging (senescence) includes causal mechanisms (etiologies) of late-life disease, which remain poorly understood. According to the recently proposed hyperfunction theory, based on the older theory of antagonistic pleiotropy, senescent pathologies can arise from futile, post-reproductive run-on of processes that in early life promote fitness. Here we apply this idea to investigate the etiology of senescent pathologies in the reproductive system of Caenorhabditis elegans hermaphrodites, particularly distal gonad degeneration and disintegration. Hermaphrodite germ cells frequently undergo “physiological” (non-damage-induced) apoptosis (PA) to provision growing oocytes. Run-on of such PA is a potential cause of age-related gonad degeneration. We document the continuation of germline apoptosis in later life, and report that genetically blocking or increasing PA retards or accelerates degeneration, respectively. In wild-type males, which lack germ line apoptosis, gonad disintegration does not occur. However, mutational induction of PA in males does not lead to gonad disintegration. These results suggest that as germ-cell proliferation rate declines markedly in aging hermaphrodites (but not males), run-on of PA becomes a pathogenic mechanism that promotes gonad degeneration. This illustrates how hyperfunction, or non-adaptive run-on in later life of a process that promotes fitness in early life, can promote atrophic senescent pathology in C. elegans.
Highlights
Biogerontologists traditionally use lifespan as a measure of aging
Treatment from day 1 of adulthood with 5-fluoro-2’-deoxyuridine (FUdR, 25 μM), an inhibitor of DNA replication, markedly reduced the number of both hypertrophic oocytes (Figure 5D) and hypertrophic nuclei (Figure 5E). This is consistent with promotion by endomitotic run-on of hypertrophy in unovulated oocytes. These results support the hypothesis that runon of reproductive processes contribute to age-related pathogenesis in the C. elegans hermaphrodite gonad
We present evidence that post-reproductive physiological apoptosis promotes germline atrophy (Figure 6B), and that run-on of endomitosis promotes hypertrophy in un-ovulated oocytes
Summary
Biogerontologists traditionally use lifespan as a measure of aging. Aging leads to death by causing the development of senescent pathologies [1, 2]. Discovering the causes (etiologies) of such pathologies is key to understanding aging. Senescence causes numerous pathologies, and which pathologies limit life varies according to species, individual and environment. In a model organism like C. elegans, understanding how a given senescent pathology originates is of interest, whether it limits lifespan or not. This study focuses not on lifespan but on senescent pathology
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