Abstract
Ageing in the nematode Caenorhabditis elegans is unusual in terms of the severity and early onset of senescent pathology, particularly affecting organs involved in reproduction (Ezcurra et al., 2018; Garigan et al., 2002; Herndon et al., 2002). In post-reproductive C. elegans hermaphrodites, intestinal biomass is converted into yolk leading to intestinal atrophy and yolk steatosis (Ezcurra et al., 2018; Sornda et al., 2019). We recently showed that post-reproductive mothers vent yolk which functions as a milk (yolk milk), supporting larval growth that is consumed by larvae (Kern et al., 2020). This form of massive reproductive effort involving biomass repurposing leading to organ degeneration is characteristic of semelparous organisms (i.e. that exhibit only a single reproductive episode) ranging from monocarpic plants to Pacific salmon where it leads to rapid death (reproductive death) (Finch, 1990; Gems et al., 2020). Removal of the germline greatly increases lifespan in both C. elegans and Pacific salmon, in the latter case by suppressing semelparous reproductive death (Hsin and Kenyon, 1999; Robertson, 1961). Here we present evidence that reproductive death occurs in C. elegans, and that it is suppressed by germline removal, leading to extension of lifespan. Comparing three Caenorhabditis sibling species pairs with hermaphrodites and females, we show that lactation and massive early pathology only occurs in the former. In each case, hermaphrodites are shorter lived and only in hermaphrodites does germline removal markedly increase lifespan. Semelparous reproductive death has previously been viewed as distinct from ageing; however, drawing on recent theories of ageing (Blagosklonny, 2006; de Magalhães and Church, 2005; Maklakov and Chapman, 2019), we argue that it involves exaggerated versions of programmatic mechanisms that to a smaller extent contribute to ageing in non-semelparous species. Thus, despite the presence of reproductive death, mechanisms of ageing in C. elegans are informative about ageing in general.
In this study, using a comparative biology approach, we explore the hypothesis that C. elegans experience semelparous reproductive death (Gems et al., 2020; Kern et al., 2020). Protandrous hermaphroditism (where sperm are produced first and then oocytes) allows C. elegans to rapidly colonize new food patches, but at the cost of a very short reproductive span due to sperm depletion (Hodgkin and Barnes, 1991; Schulenburg and Félix, 2017). The capacity to convert somatic biomass into yolk milk to feed to offspring allows post-reproductive C. elegans to reduce this cost, and promote inclusive fitness (Kern et al., 2020). This predicts that, among species of Caenorhabditis, lactation will occur in androdioecious (hermaphrodite, male) but not gonochoristic (female, male) species. To test this, we compared three pairs of sibling species in this genus, where one is androdioecious and the other gonochoristic: C. elegans vs C. inopinata, C. briggsae vs C. nigoni, and C. tropicalis vs C. wallacei (Fig. 1a). These pairs represent three independent occurrences of the evolution of hermaphroditism from gonochoristic ancestors (Kiontke et al., 2011). For each pair, both yolk venting and copious laying of unfertilised oocytes (which act as vectors for yolk milk (Kern et al., 2020)) was seen in hermaphrodites but not females (Fig. 1b,c; Extended data Fig. 1a,b). As in C. elegans, vitellogenin (yolk protein) accumulation continued into later life to high levels in C. briggsae and C. tropicalis hermaphrodites, but not in C. inopinata, C. nigoni and C. wallacei females (Extended Data Fig. 1c,d). We also compared an androdioecious-gonochoristic sibling species pair from the free-living nematode genus Pristionchus and, again, only the former vented yolk milk and oocytes, and accumulated vitellogenin internally in later life (Fig. 1b,c, Extended Data Fig. 1a-d). Pristionchus proved to lack the larger vitellogenin species corresponding to YP170 in Caenorhabditis; instead accumulation of only the smaller species equivalent to Caenorhabditis YP115/YP88 was seen (Extended Data Fig. 1c,d).
Based on our semelparity hypothesis, the presence of lactation in hermaphrodites but not females predicts that only the former will exhibit reproductive death, i.e. that females should be longer lived and show greatly reduced pathology. Consistent with this, lifespan was longer in females than in hermaphrodites for the C. tropicalis/C. wallacei and C. briggsae/C. nigoni pairs but, as previously reported (Woodruff et al., 2018), this was not the case for the C. elegans/C. inopinata pair (Extended Data Fig. 2a,b). To exclude possible species differences in susceptibility to infection by the E. coli food source (Gems and Riddle, 2000), lifespan was measured in the presence of antibiotics, and here females were longer lived in all three sibling species pairs (Fig. 1d, e, Extended Data Fig. 2a,b); this result suggests that C. inopinata are hyper-susceptible to bacterial infection, perhaps reflecting their distinct natural environment (syconia on Okinawan fig trees). The optimal culture temperature for C. inopinata is higher (25-29°C) than that for C. elegans (20-22°C) (Kanzaki et al., 2018), raising the possibility that culture of C. inopinata at the sub-optimally low temperature of 20°C might cause a disproportionately low rate of living, thereby increasing lifespan relative to C. elegans; however, C. inopinata was also longer lived than C. elegans at 25°C (Extended Data Fig. 2c), arguing against this possibility. Similarly, in the Pristionchus sibling species pair, the hermaphrodites were shorter lived (Fig. 1d, Extended Data Fig. 2a,b), consistent with a previous report of greater longevity in Pristionchus females (Weadick and Sommer, 2016).
Next we compared patterns of senescent pathology in the three sibling Caenorhabditis species pairs using Nomarski microscopy and transmission electron microscopy. Early, severe senescent pathologies in C. elegans adult hermaphrodites include prominent uterine tumours, gonadal atrophy and fragmentation, pharyngeal deterioration, as well as intestinal atrophy coupled to yolk steatosis (de la Guardia et al., 2016; Ezcurra et al., 2018; Garigan et al., 2002; Herndon et al., 2002; Wang et al., 2018). Senescent pathologies seen in C. elegans were also seen in the other two hermaphroditic species, but were largely absent from females, and this was true also of the Pristionchus sibling species pair (Fig. 2a,b,c). Striking degeneration of intestinal ultrastructure was seen in older Caenorhabditis hermaphrodites but not in females, consistent with earlier observations of C. elegans (Herndon et al., 2002; Herndon et al., 2018) and C. briggsae (Epstein et al., 1972), including prominent autophagosomes (Fig. 2d, Extended Data Fig. 3). Thus, females are longer lived and free of the severe pathology present in hermaphrodites.
The severity of early senescent pathology in hermaphrodites varied between species, with the ranking C. elegans > C. tropicalis > C. briggsae (Fig. 2a,b), and hermaphrodite longevity showed the inverse ranking (Extended data Table 1). Notably, the graded variation of pathology level with lifespan implies a continuum between presence and absence of reproductive death (i.e. between semelparity and iteroparity; see below) (Fig. 2e). This suggests that C. elegans and C. briggsae represent late and early stages, respectively, in the evolution of reproductive death. Notably, C. briggsae/C. nigoni inter-species mating can produce offspring (Baird et al., 1992), implying relatively recent divergence of these two species from a common ancestor.
The above comparisons were performed using unmated animals, meaning that hermaphrodites produced progeny but females did not. Thus, the differences observed could reflect the presence/absence of progeny production. To assess this hypothesis, we compared lifespan and senescent pathology in mated animals of the different species. Mating shortened lifespan in most species, as previously seen in C. elegans (Gems and Riddle, 1996; Shi and Murphy, 2014), and abrogated the greater longevity of females (Extended Data Fig. 5a-c). Mating also induced intestinal atrophy in females and enhanced it in hermaphrodites, and mated animals of all six species showed similar levels of intestinal atrophy (Fig. 2a). A similar effect of mating was also seen on a range of other pathologies, where similar levels of deterioration were seen in mated females and hermaphrodites, as shown by cluster analysis of quantified severity in pathology (Fig. 2b). These findings suggest that reproductive death is induced by mating in females. This provides a potential explanation for how such similar patterns of pathogenesis evolved independently in the three androdioecious species: as the consequence of a switch from facultative (mating-induced) reproductive death in females to constitutive reproductive death in hermaphrodites.
According to this model, the evolution of reproductive death in hermaphrodites requires only its activation in the absence of mating. Evolution of hermaphroditism in C. elegans likely began when females developed the capacity to generate and activate self sperm (Baldi et al., 2009). One possibility is that the emergence of self sperm was sufficient for reproductive death to become constitutive. However, spermless fog-2(q71) and fem-2(e2006) female mutant C. elegans showed no detectable reduction in intestinal atrophy (Extended Data Fig. 5f), arguing against this hypothesis. This result and the less severe senescent pathology seen in C. briggsae suggest that the evolution of constitutive reproductive death is a complex, multi-step process.
In semelparous species where reproductive death is triggered upon reproductive maturity, pre-empting reproduction can greatly increase lifespan (Finch, 1990; Gems et al., 2020). For example, removal of flowers prior to pollination can increase lifespan in soybean from 119 to 179 days (Leopold et al., 1959), and gonadectomy of Pacific salmon before spawning can increase maximum lifespan from 4 years to up to 8 years (Robertson, 1961). Similarly, prevention of germline development in C. elegans hermaphrodites greatly increases lifespan (Hsin and Kenyon, 1999) and suppresses intestinal atrophy (Ezcurra et al., 2018). One possibility is that germline ablation extends C. elegans lifespan by suppressing reproductive death. Given the absence of reproductive death in unmated Caenorhabditis and Pristionchus females, this predicts that germline ablation will increase lifespan more in hermaphrodites than in females, and this proved to be the case. Germline ablation using laser microsurgery (Hsin and Kenyon, 1999) suppressed major pathologies and caused large increases in lifespan in hermaphrodites, but only marginal increases in lifespan in females (Fig. 3a,b). We also surveyed published reports that have assessed effects on lifespan of gonadectomy or, for some semelparous species, prevention of reproductive death by other means. This confirmed that large increases in lifespan are typical of semelparous but not iteroparous organisms (Fig. 3b). Lifespans of germline-ablated animals in each sibling species pair were similar (Extended Data Fig. 6), supporting the view that the shorter lifespan of hermaphrodites is attributable to reproductive death.
Results presented in this study, taken together with earlier findings, show that properties of C. elegans fit the criteria used to define reproductive death in semelparous species, i.e. that it exhibits reproductive death. C. elegans develop massive, severe pathology in organs linked to reproduction relatively early in adulthood, some of which result from biomass repurposing for yolk milk production (Ezcurra et al., 2018; Gems et al., 2020; Kern et al., 2020), while none of this is seen in unmated females. Hermaphrodites are shorter lived than females of their sister species, but not after germline removal, which causes large increases in lifespan only in hermaphrodites. This is consistent with the view that germline removal, like gonadectomy in Pacific salmon, increases lifespan by preventing reproductive death. Consistent with this, C. elegans males resemble Caenorhabditis females in not exhibiting major degenerative pathologies such as intestinal atrophy and gonad disintegration (de la Guardia et al., 2016; Ezcurra et al., 2018), and germline removal in wild-type C. elegans males has little effect on lifespan (McCulloch, 2003). Moreover, prevention of reproductive maturity by gonadectomy or other means typically causes large increases in lifespan in semelparous organisms but not iteroparous organisms (with multiple rounds of reproduction) (Gems et al., 2020) (Fig. 2b).
The occurrence of reproductive death in C. elegans has profound implications both in terms of understanding the biology of ageing, and what one can learn from C. elegans as a model for ageing in general. Insofar as senescent pathologies develop as a cost of lactation (Kern et al., 2020), they are not the result of futile run-on of programmes that promoted fitness earlier in life (or quasi-programmes (Blagosklonny, 2006)), as was previously suggested (Ezcurra et al., 2018; Herndon et al., 2002; Sornda et al., 2019). However, fitness-promoting processes to which uterine tumour formation is coupled have not (yet) been identified; thus, like the ovarian teratomas that they resemble (Wang et al., 2018), uterine tumours do appear to the be result of quasi-programmes. Thus, both costly programmes (Gems et al., 2020) and quasi-programmes are operative in C. elegans hermaphrodite senescence.
The most exciting thing about the discovery of interventions producing large increases in lifespan in C. elegans was the implied existence of mechanisms with powerful effects on ageing as a whole. Combined with the notion that ageing rate was a function of somatic maintenance (Kirkwood and Rose, 1991), this suggested that similar plasticity might exist in humans, affecting the entire ageing process, and providing a target for future interventions to greatly decelerate ageing. Here we present evidence that lifespan in C. elegans is limited by reproductive death; we have also argued elsewhere that reproductive death is permissive for the evolution of the rare phenomenon of programmed adaptive death, which further shortens lifespan, and that this has happened in C. elegans (Galimov and Gems, 2020a, b; Lohr et al., 2019). Suppression of such programmatic etiologies of ageing provides a potential explanation for the unusually large magnitude of increases in lifespan seen in C. elegans. This raises the possibility that in iteroparous organisms no core mechanisms of ageing as a whole exist that are amenable to manipulation to produce dramatic deceleration of ageing. Sadly, our findings in certain respects explain away the mystique of C. elegans ageing.
Does the occurrence of reproductive death mean that C. elegans die from mechanisms unrelated to those operative in most other organisms? We believe not. In the past, a sharp distinction was drawn between true ageing, caused by stochastic damage accumulation, and programmed ageing as observed in plants (e.g. leaf senescence) and semelparous species like Pacific salmon (Finch, 1990; Gems et al., 2020). However, it has been recognized that evolutionarily conserved regulators of phenotypic plasticity in ageing, such as the insulin/IGF-1 and mechanistic target of rapamycin (mTOR) pathways, can act through programmatic mechanisms to promote senescent pathology (Blagosklonny, 2006; de Magalhães and Church, 2005; Gems and de la Guardia, 2013; Maklakov and Chapman, 2019). Inhibiting these pathways can cause large increases in C. elegans lifespan but also smaller effects in higher animals; for example, mutation of phosphatidylinositol 3-kinase can increase median lifespan by up to ~10-fold in C. elegans, but only ~1.07-fold and ~1.02-fold in Drosophila and mouse, respectively (Ayyadevara et al., 2008; Foukas et al., 2013; Slack et al., 2011). Given the evolutionary conservation of the role of these pathways in ageing, we suggest that mechanisms of reproductive death evolve by repurposing of programmatic mechanisms that affect ageing in iteroparous organisms (Gems et al., 2020). It has been argued that semelparous and iteroparous life histories are not isolated phenomena but rather represent a continuum (Hughes, 2017). Supporting this is the observed gradient between the presence and absence of reproductive death across nematode species, and in C. elegans across interventions that suppress pathologies of reproductive death and extend lifespan, including germline ablation and reduced IIS (Fig. 3c). Thus, C. elegans is a good model for understanding programmatic mechanisms of ageing that lead to senescent multimorbidity that are universal across metazoan organisms.
Author contributions
D.G. supervised the project. C.C.K. and D.G. conceived the project, designed the experiments and data analysis, and wrote the manuscript. C.C.K., N.H., M.E., S.S. and V.T. performed experiments. D.M., N.H., M.E. and V.T. performed the pathology data capture and analysis. N.H. assisted with the collection and measurement of internal and vented proteins. S.S. scored lifespans. S.S. and N.H. performed laser ablations. S.T. and J.B. performed and interpreted quantitative analysis of pathology and comparison to lifespan.
Acknowledgments
We are grateful to V. Konstantellos for technical assistance, M. Turmaine for help with electron microscopy, A. Barrios and R.J. Poole for access to laser ablation facilities, N. Kanzaki and T. Kikuchi (F.F.P.R.I. Tsukuba) for providing C. inopinata, and R.J. Sommer (M.P.I. Developmental Biology, Tübingen) for providing Pristionchus species. We also thank A.D. Cutter (University of Toronto), M.-Q. Dong and C. Zhai (N.I.B.S. Beijing), D. Hall (Albert Einstein College of Medicine), R.J. Sommer (Tübingen), V. Rottiers (U.C. Berkeley) and E.R. Galimov, Y. de la Guardia and other members of the Gems lab for advice and useful discussion and/or comments on the manuscript. Some strains were provided by the Caenorhabditis Genetics Center, which is funded by NIH Office of Research Infrastructure Programs (P40 OD010440). S.T. was supported by a Boehringer Ingelheim Fonds PhD Fellowship. This work was supported by a Wellcome Trust Strategic Award (098565/Z/12/Z) and a Wellcome Trust Investigator Award (215574/Z/19/Z) to D.G..