C. elegans ageing is accelerated by a self

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Jun 05, 2023

C. elegans ageing is accelerated by a self

Nature Communications volume 14, Article number: 4381 (2023) Cite this article 3815 Accesses 97 Altmetric Metrics details In post-reproductive C. elegans, destructive somatic biomass repurposing

Nature Communications volume 14, Article number: 4381 (2023) Cite this article

3815 Accesses

97 Altmetric

Metrics details

In post-reproductive C. elegans, destructive somatic biomass repurposing supports production of yolk which, it was recently shown, is vented and can serve as a foodstuff for larval progeny. This is reminiscent of the suicidal reproductive effort (reproductive death) typical of semelparous organisms such as Pacific salmon. To explore the possibility that C. elegans exhibits reproductive death, we have compared sibling species pairs of the genera Caenorhabditis and Pristionchus with hermaphrodites and females. We report that yolk venting and constitutive, early pathology involving major anatomical changes occur only in hermaphrodites, which are also shorter lived. Moreover, only in hermaphrodites does germline removal suppress senescent pathology and markedly increase lifespan. This is consistent with the hypothesis that C. elegans exhibit reproductive death that is suppressed by germline ablation. If correct, this would imply a major difference in the ageing process between C. elegans and most higher organisms, and potentially explain the exceptional plasticity in C. elegans ageing.

The mechanisms of ageing are likely to differ between organisms with semelparous and iteroparous life histories. Semelparous species exhibit only a single reproductive episode, which often involves a degree of reproductive effort that is so intense that it leads to rapid death (reproductive death)1,2. Organisms exhibiting semelparous reproductive death range from monocarpic plants to Pacific salmon. By contrast, iteroparous species, which include most mammals, are capable of multiple rounds of reproduction and experience a more gradual ageing process.

To be precise about the meaning of the term semelparity: although some but not all organisms with a single reproductive episode exhibit reproductive death, the term semelparity is often used to specifically denote semelparous organisms that exhibit reproductive death. Concomitantly, the occurrence of reproductive death in organisms with only a single reproductive episode is definitive of semelparity in the second sense of the term.

Since the late 1970s, the nematode Caenorhabditis elegans has been used intensively as a model organism to attempt to understand the causes of ageing. This led to the discovery of a remarkably high degree of plasticity in ageing in this species3,4,5 with up to 10-fold increases in lifespan having been observed6. C. elegans is also unusual in the severity and singularly early appearance of senescent pathology, particularly affecting organs involved in reproduction7,8,9,10,11,12. In post-reproductive C. elegans hermaphrodites, intestinal biomass is converted into yolk leading to intestinal atrophy and yolk accumulation9,13. We recently showed that post-reproductive mothers vent yolk which can function as a milk (or “yolk milk”), that is consumed by larval progeny supporting growth and reproduction14.

This type of self-destructive reproductive effort, where biomass repurposing promotes organ degeneration, often occurs in semelparous organisms that undergo reproductive death. Removal of the germline greatly increases lifespan in both C. elegans and Pacific salmon, in the latter case by suppressing reproductive death5,15. Taken together with its single reproductive episode, these observations raise the possibility that the marked plasticity in C. elegans lifespan is a function of suppression of reproductive death, i.e. that this species is semelparous.

A further hypothetical possibility is that reproductive death has evolved in C. elegans as a consequence of hermaphroditism. Nematode species of the genus Caenorhabditis are either gonochoristic, with approximately equal numbers of females and males, or androdioecious, with self-fertilising hermaphrodites and rare males16. Protandrous hermaphroditism (where sperm are produced first and then oocytes) allows C. elegans to rapidly colonise new food patches, but at the cost of a shorter reproductive span due to depletion of self-sperm16,17. The capacity to convert somatic biomass into yolk to feed to offspring may allow post-reproductive C. elegans to reduce this cost, and promote inclusive fitness14. If correct, this predicts that reproductive death will occur in Caenorhabditis hermaphrodites but not females, where obligate reproduction by mating with males supports longer reproductive spans.

In this study we use a cross-species comparative approach to explore the possibility that reproductive death occurs in C. elegans and is suppressed by germline ablation. That C. elegans might be semelparous raises interesting questions about the relevance of mechanisms of ageing identified in this species to those operative in iteroparous species (such as humans).

The occurrence of self-destructive biomass repurposing to support yolk production for venting in post-reproductive C. elegans hermaphrodites is reminiscent of mechanisms operative in organisms with reproductive death2. If correct, the hypothesis that reproductive death evolved after the emergence of protandry in the ancestor of C. elegans predicts that, among species of Caenorhabditis, yolk venting will occur in androdioecious but not gonochoristic species. To test this, we compared three pairs of sibling species in this genus, where one is androdioecious (A) and the other gonochoristic (G): C. elegans (A) vs C. inopinata (G), C. briggsae (A) vs C. nigoni (G), and C. tropicalis (A) vs C. wallacei (G), respectively (Fig. 1a). These pairs represent three independent occurrences of the evolution of hermaphroditism from gonochoristic ancestors18. For each pair, both yolk venting and copious laying of unfertilised oocytes (which act as vectors for yolk14) was seen in hermaphrodites but not females (Fig. 1b, c; Supplementary 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 (Fig. 1d). We also compared an androdioecious-gonochoristic sibling species pair from the free-living nematode genus Pristionchus and, again, only the former vented yolk and oocytes, and accumulated vitellogenin internally in later life (Fig. 1b–d; Supplementary 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 (Supplementary Fig. 1c, d).

a Phylogenetic tree showing androdioecious and gonochoristic Caenorhabditis sibling species76. Estimate of the time since the origin of selfing in hermaphrodites: C. elegans, 0.35–7.2 MYA; C. briggsae, 0.2–3.5 MYA (ref. 77); C. tropicalis, still unknown. b Yolk venting present in hermaphrodites but not in females (n = 100 per trial). Top: major YP at the peak of venting. Bottom: Quantitative data normalised to total yolk on d4-6 in C. elegans. M = Marker. For full gel see Source Data. c Unfertilised oocytes are laid by hermaphrodites but not females (3 trials; n = 10 per trial). d Greater internal levels of major YP in Caenorhabditis hermaphrodites and P. pacificus hermaphrodites. YP bands normalised to myosin to adjust for species differences in body size. One-way ANCOVA (n = 10). For all internal YPs and gel image see Supplementary Fig. 1c, d. b, d Protein gel electrophoresis data with colloidal Coomassie blue staining. b-e Animals are unmated. b,c,d Mean ± s.e.m. of 3 trials with each dot representing one trial. b, c One-way ANOVA (Bonferroni correction) or two-tailed unpaired t-test. * p < 0.05, ** p < 0.01, *** p < 0.0001, **** p < 0.00001 (p value from left to right = b: 0.0014, 0.0145, 0.0012, 0.0070; c: 0.0010, 0.0033, 0.0080, 0.0087; d: 0.0000, 0.0133, 0.0133, 0.0000).

The hypothesis that yolk venting is indicative of semelparity, together with the presence of yolk venting in hermaphrodites but not females, predicts that only the former will exhibit reproductive death, i.e. that females will be longer lived and show greatly reduced pathology relative to hermaphrodites. Consistent with this, lifespan was longer in females than in hermaphrodites for the C. tropicalis (A)/C. wallacei (G) and C. briggsae (A)/C. nigoni (G) pairs but, as previously reported19, this was not the case for the C. elegans (A)/C. inopinata (G) pair (Supplementary Fig. 2a, b).

To exclude possible species differences in susceptibility to infection by the E. coli food source20, lifespan was measured in the presence of an antibiotic (carbenicillin), and here females were longer lived in all three sibling species pairs (Fig. 2a, b; Supplementary Fig. 2a, b); this result suggests that C. inopinata are hyper-susceptible to bacterial infection, perhaps reflecting their distinct natural environment (syconia of fig trees). The optimal culture temperature for C. inopinata is higher (25–29 °C) than that for C. elegans (20–22 °C)21, 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 (Fig. Supplementary 2c), arguing against this possibility. Similarly, in the Pristionchus sibling species pair, the hermaphrodites were shorter lived (Fig. 2a, Supplementary Fig. 2a, b), consistent with a previous report of greater longevity in Pristionchus females22.

a Females are longer lived than sibling species hermaphrodites (unmated, with antibiotic). Mean ± s.e.m. of 3 trials. Log-rank (Mantel-Cox) test. b Female C. inopinata are longer-lived than C. elegans when bacterial infection is prevented using an antibiotic (carbenicillin) (this figure; combined data of 3 trials; n = 100 per trial) or UV irradiation of E. coli (Supplementary Fig. 2d). a, b For statistical details, see Supplementary Table 1, and for raw lifespan, data see Source Data File. c Intestinal atrophy is constitutive in hermaphrodites and mating-induced in females. Mean ± s.e.m. of 3 trials (n = 10 per trial per time point). One-way ANCOVA with score normalised to d1 to determine the change in percentage of intestinal mass. Trial terms were not statistically significant across all pathologies and, therefore, trial was not considered further a variable. For details of statistic tests see the methods section. For measurement of pathologies, statistical comparisons between species and treatments, and representative images of pathologies used for scoring, see Supplementary Fig. 4. d Reproductive death-associated pathologies are constitutive in hermaphrodites and induced in females by mating. The heat map compares differences in pathology progression across species and treatments by transforming calculated gradients from pathology measurements through time into Z-scores (c.f. Supplementary Fig. 4a, d; 3 trials, where n = 10 per time point per trial, with 5 time points up to d14, when pathology peaks for C. elegans). This allows comparison between different pathologies by normalising levels of a given pathology to the average level of that pathology in the group (represented by a Z-score of 0, with a Z-score of +2 representing the maximum pathology severity in the group and −2 the healthiest animals). Hierarchical clustering is based on pair-wise Euclidean distances. e Intestinal atrophy (blue) and yolk pool accumulation (yellow) in ageing C. elegans but not C. inopinata (d14, unmated). Representative Nomarski images. Scale 25 µm. f Severe degeneration of intestinal ultrastructure in ageing C. elegans but not C. inopinata (day 14, unmated). Note loss of organelles and ground substance. Representative TEM cross-section images through the intestine. mv, microvilli; au, autophagosome-like structure, L, lipid droplets; G, yolk or gut granules (tentative identification). Scale 1 µm (20,000x). g Correspondence between pathology severity and lifespan. Linear regression of the median of all pathology Z-scores (c.f. Fig. 2d) with lifespan. Y axis shows mean lifespan of each species (antibiotic treated). A line of best fit is drawn to connect points for the Caenorhabditis species; based on this a hypothetical line is drawn for the Pristionchus species. For regression of individual pathologies against lifespan, see Supplementary Fig. 2e. **** p < 0.00001.

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 tumors, gonadal atrophy and fragmentation, pharyngeal deterioration, as well as intestinal atrophy coupled with yolk accumulation7,8,9,23,24,25. Senescent pathologies seen in C. elegans were also seen in the other two hermaphroditic species of Caenorhabditis, but were largely absent from females, and this was true also of the Pristionchus sibling species pair (Fig. 2c–e). Striking degeneration of intestinal ultrastructure was seen in older Caenorhabditis hermaphrodites, consistent with earlier observations of C. elegans7,26 and C. briggsae27, including prominent autophagosomes (Fig. 2f; Supplementary Fig. 3). Such changes were not seen in females. Thus, females are longer lived and free of the major anatomical changes characteristic of senescent hermaphrodites.

The severity of early senescent pathology in hermaphrodites varied between species, with the ranking C. elegans > C. tropicalis > C. briggsae (Fig. 2c, d), and hermaphrodite longevity showed the inverse ranking (Supplementary Table 1). The graded variation of pathology level with lifespan is consistent with possible existence of a continuum between presence and absence of reproductive death (i.e. between semelparity and iteroparity; see below) (Fig. 2g). This could imply that C. elegans and C. briggsae represent late and early stages, respectively, in the evolution of constitutive reproductive death. Notably, the estimated time since the origin of selfing in hermaphrodites is longer ago for C. elegans (0.35–7.2 MYA) than for C. briggsae (0.2–3.5 MYA). Moreover, C. briggsae/C. nigoni inter-species mating can produce offspring28, consistent with 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 in principle reflect the presence/absence of progeny production, though it should be noted that prevention of self-progeny production per se does not affect lifespan in C. elegans3,4,29. To investigate this possibility, we compared lifespan and senescent pathology in mated animals of the different species. Mating (including exposure to male pheromones as well as copulation) shortened lifespan in most species, as previously seen in C. elegans30,31, and abrogated the greater longevity of females (Fig. 3a; Supplementary Fig. 5a, b). 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 (Figs. 2c; 3b, c). A comparable 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 pathology severity, and Pristionchus species showed the same trend (Fig. 2d).

a Mating in females significantly reduces lifespan, as previously shown for C. elegans30,31,41. Mean ± s.d. of 2 trials. Log-rank between mated and unmated animals. For statistical details, see Supplementary Table 2, and for raw lifespan data see Source Data File. b Representative TEM cross-section showing a reduction in intestinal size in C. inopinata upon mating. Scale 5 μm (5,000x). c Representative high magnification TEM images showing degenerative ultrastructural changes in the intestine in C. inopinata upon mating, with loss of ground structure similar to unmated C. elegans, and in contrast to unmated C. inopinata, observed (c.f. Fig. 2f). Scale 1 μm (20,000x). d No effect of self-sperm on senescent pathology in Caenorhabditis hermaphrodites in most cases. The main exception is uterine tumours which appear sooner due to earlier appearance of unfertilised oocytes in the uterus, but then develop more slowly, as previously described for C. elegans24. Also, in C. tropicalis a slight increase in intestinal atrophy is observed. Trials were performed at 25 °C because RNAi induced sterility in C. tropicalis at this temperature. Mean ± s.e.m. of 3 trials (n = 5–10 per time point in each trial). Cumulative Link Model with gamma link function for pharyngeal degeneration, gonadal degeneration and uterine tumours which are scored ordinals. One-way ANCOVA with score normalised to d1 to determine change in percentage of intestinal mass, and one-way ANCOVA with no normalisation for yolk pools. Trial terms were not statistically significant across all pathologies and, therefore, trial was not considered further a variable. For details of statistic tests see methods section. e Presence of self-sperm weakly reduces lifespan in some contexts. Trials conducted at 25 °C (see d) and with carbenicillin included to avoid possible confounding effects of species differences in susceptibility to bacterial infection. In previous studies of C. elegans fog-2(q71) females were found to be long lived in one case (25 °C, live E. coli)19 and short lived in another (20 °C, live E. coli)20; the reason for the discrepancy is unclear. Combined data of 3 trials. Statistical test (log-rank), comparison to wild-type females: blue stars; comparison to wild-type hermaphrodites: red stars. For survival curves for all trials see Supplementary Fig. 5c, for statistical details see Supplementary Table 3, and for raw lifespan data see Source Data File. * p < 0.05, ** p < 0.01, *** p < 0.0001, **** p < 0.00001.

These findings could imply that reproductive death is induced by mating in females. This would provide a possible explanation for how such similar patterns of pathogenesis evolved independently in the three androdioecious species: as the consequence of a switch from mating-induced reproductive death in females to constitutive reproductive death in hermaphrodites, whether or not (in the latter) reproduction by self-fertilisation has taken place. If mating induces reproductive death in females, one might expect that it would also induce yolk venting: critically, for reproductive death to be occurring, in line with semelparity, it must involve some form of fitness benefit. However, only very low levels of vented yolk were detected in mated females (Supplementary Fig. 1a). In C. elegans mating reduced vented yolk levels, as it did in all hermaphroditic species, likely due to increased uptake of yolk into oocytes that are subsequently fertilised. These results could imply that in females reproductive death is coupled to yolk production for egg provisioning only, but the existence of such a benefit remains unproven; thus, it remains unclear whether mating-induced pathology in females is coupled to a reproductive benefit, i.e. whether mated females exhibit reproductive death.

According to this model, the evolution of reproductive death in hermaphrodites requires constitutive activation of processes that normally require mating to be induced. The evolution of hermaphroditism in C. elegans likely began when females developed the capacity to generate and activate self sperm32. One possibility is that the emergence of self-sperm was sufficient for reproductive death to become constitutive. To investigate this we tested whether abrogating self-sperm production in Caenorhabditis hermaphrodites would suppress senescent pathology and extend lifespan. Interventions used were fog-2(q71) and fem-3(e2006) in C. elegans33,34, she-1(v35) and she-1(v49) in C. briggsae35, and RNAi of a putative fem-3 orthologue (Csp11.Scaffold629.g10847, Ctr-fem-3) in C. tropicalis.

Blocking self-sperm production did not suppress the development of senescent pathology (Fig. 3d). However, it did increase lifespan in several instances - in C. elegans with fog-2 but not fem-3, consistent in both cases with earlier findings4,19, and in C. briggsae with she-1 - but in no case to the extent of sibling species female longevity (Fig. 3e). In C. tropicalis Ctr-fem-3 RNAi strongly reduced lifespan, possibly reflecting pleiotropic effects. These results imply that constitutive reproductive death is not a simple consequence of the evolution of self-fertilisation. They do, however, leave open the possibility that the appearance of self-sperm contributes in a multi-step evolutionary process. The possibility that reproductive death in self-fertilising hermaphrodites is a consequence of reproduction itself was ruled out by the early observation that sterile hermaphrodites (e.g. due to fertilisation-defective sperm) are not long-lived3,29. Thus, while reproduction per se does not shorten lifespan, the presence of self-sperm might to an extent.

In semelparous species where reproductive death is triggered upon reproductive maturity, pre-empting reproduction can greatly increase lifespan1,2. For example, removal of flowers prior to pollination can increase lifespan in soybean from 119 to 179 days36, and gonadectomy of Pacific salmon before spawning can increase maximum lifespan from 4 years to up to 8 years15. Similarly, prevention of germline development in C. elegans hermaphrodites greatly increases lifespan5 and suppresses intestinal atrophy9.

One possibility is that germline ablation extends C. elegans lifespan by suppressing reproductive death. Given the absence of putative 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 microsurgery5 suppressed major pathologies (Fig. 4a, b) and caused large increases in lifespan in hermaphrodites, but only marginal increases in lifespan in females (Fig. 4c). Ablation of the entire C. elegans gonad does not suppress intestinal atrophy (Supplementary Fig. 6c). This implies that germline ablation effects on senescent pathology require the presence of the somatic gonad, as is the case for effects on lifespan5. This suggests that reproductive death is suppressed by signals from the somatic gonad; notably, life-extending effects of the somatic gonad involves signalling to the DAF-12 steroid hormone receptor5,37.

a Germline ablation strongly suppresses pathology progression in hermaphrodites (c.f. Fig. 2d; n = 5–10 per time point). For full pathology measurements see Supplementary Fig. 6a, and for pathology progression in germline-deficient mutants see Supplementary Fig. 6b. b Representative Nomarski microscopy images taken for the purpose of scoring pathologies. c Germline ablation strongly increases lifespan in hermaphrodites but not female nematode species. Similarly, blocking reproductive death in semelparous species strongly increases lifespan, while gonadectomy in iteroparous species overall does not. For Caenorhabditis and Pristionchus species, mean ± s.e.m. of 3 trials is shown (stars, log-rank test for ablated vs control animals, and Cox proportional hazard test to compare effect in hermaphrodites vs females). Values for other species are taken from a recent review2; for multiple studies of the same species, only references with both male and female data are included, and for A. anguila (eel) data from the most recent source78. For data on pathology after ablation of the entire gonad see Supplementary Fig. 6c. For individual trials, details on statistics and raw lifespan data, see Supplementary Fig. 7, Supplementary Table 4 and Source Data File, respectively. * p < 0.05, ** p < 0.01, **** p < 0.00001.

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. 3c). Hermaphrodite and female lifespans of germline-ablated animals in each sibling species pair were similar (Supplementary Fig. 7), supporting the hypothesis that the shorter lifespan of hermaphrodites is attributable to reproductive death.

Results presented in this study, taken together with earlier findings, show that a number of properties of C. elegans fit the criteria used to define reproductive death in semelparous species, i.e. provide support for the hypothesis that it exhibits reproductive death. C. elegans hermaphrodites exhibit major anatomical changes of a clearly pathological nature (degeneration, tumours) in organs linked to reproduction relatively early in adulthood, some of which result from biomass repurposing for yolk production2,9,14,38, 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 hypothesis that germline removal, like gonadectomy in Pacific salmon, increases lifespan by preventing reproductive death.

In line with this, C. elegans males resemble Caenorhabditis females in not exhibiting major degenerative pathologies such as intestinal atrophy and gonad disintegration9,23, and germline removal in wild-type C. elegans males has little effect on lifespan39. Moreover, prevention of reproductive maturity by gonadectomy or other means typically causes large increases in lifespan in semelparous organisms but not iteroparous organisms2,38 (Fig. 4c).

A characteristic feature of semelparous organisms that exhibit reproductive death is that their lifespan after reproduction is very short. While in relative terms (i.e. as a proportion of their total lifespan), selfing hermaphrodites have a long post-reproductive lifespan, in absolute terms this span is very short (~2 weeks, under standard culture conditions). Moreover, sperm-depleted hermaphrodites are not necessarily post-reproductive given the occurrence of yolk venting14.

Mating with males induces pathological changes in females similar to those seen in unfertilised hermaphrodites (Figs. 2c, d; 3b, c), suggesting the possibility that reproductive death also occurs in mated females. However, while in hermaphrodites there is evidence that intestinal degeneration is coupled with the production of vented yolk in a fitness trade-off9,14, evidence for a similar trade-off in mated females is currently lacking; mating does not induce yolk venting (Supplementary Fig. 1). One possible candidate for such a benefit is increased yolk production for oocyte provisioning.

That life-shortening effects of exposure to males are promoted by both seminal fluid31 and male pheromone40,41 has been interpreted as indicative of sexual conflict42. Another possibility is that the life-shortening effects of males on females/hermaphrodites is a cost linked to a mutually beneficial increase in fitness arising from reproductive death. These two possibilities are not mutually exclusive; notably, the presence of self-sperm protects against the life-shortening effects of male exposure43,44, consistent with sexual conflict. This protective mechanism is mediated by several signalling components, including the CEH-18 transcription factor, the VAB-1 ephrin receptor43, insulin-like peptides and the mTOR-TFEB pathway44.

The occurrence of reproductive death (i.e. semelparity) in C. elegans would have 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. It was previously proposed that some senescent pathologies are the result of a vitellogenic quasi-programme45,46, i.e. futile run-on of a yolk production programme after reproduction7,9,13. While this is still possible, if later yolk production provides a fitness benefit then such senescent pathologies would instead represent reproductive costs. Such benefits could accrue from yolk feeding by larvae either when they hatch inside the mother, or when external larvae consume vented yolk (indicating a cost of “lactation”)14. However, fitness-promoting processes to which uterine tumour formation is coupled have not (yet) been identified; thus, like the ovarian teratomas that they resemble24, uterine tumours do appear to be the result of quasi-programmes. Thus, both costly programmes46 and quasi-programmes are likely operative in C. elegans hermaphrodite senescence.

As specified in the introduction, the word semelparous has two overlapping meanings: (i) having only a single bout of reproduction, and (ii) reproducing once followed by reproductive death. Regarding the first sense: arguably, the distinction between semelparity and iteroparity can be difficult to apply to organisms with very short lifespans, such as Caenorhabditis species47. However, the very brief reproductive span of C. elegans combined with the evidence of reproductive death presented here is evidence of semelparity in the second sense of the word and, by extension, the first.

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 belief that ageing rate is a function of somatic maintenance48, this suggested that similar plasticity might exist in humans, affecting the entire ageing process, and provide a possible 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 may have occurred in C. elegans49,50,51. Suppression of such programmatic aetiologies 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 similar core mechanism of ageing as a whole exists that is amenable to manipulation to produce dramatic deceleration of ageing. Sadly, our findings might, in certain respects, explain away the mystique of C. elegans lifespan plasticity.

Would 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 such as Pacific salmon1,2. However, it has been recognised 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 pathology45,52,53,54. 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, respectively6,55,56.

Given the evolutionary conservation of the role of these pathways in ageing, we suggest that mechanisms of reproductive death evolve by repurposing programmatic mechanisms that affect ageing to a small extent in iteroparous organisms2,38. It has been argued that semelparous and iteroparous life histories are not isolated phenomena but rather represent a continuum57. Supporting this is the observed gradient between the presence and absence of putative 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. 5). Thus, even if C. elegans does undergo reproductive death, it remains a good model for understanding programmatic mechanisms of ageing contributing to senescent multimorbidity that are universal across metazoan organisms46.

Correlation between reproductive death-associated pathologies and lifespan in different species and following different treatments in C. elegans, supporting the presence of a semelparity-iteroparity continuum. X axis, median pathology Z-score. Y axis, mean lifespan (unmated, antibiotic treated). Other data sources: RNAi pathology and lifespan13; lifespan of mutants79. For mutant pathology measurements, see Supplementary Fig. 8.

No statistical methods were used to predetermine the sample size. The experiments were not randomised. The investigators were not blinded to allocation during experiments and outcome assessment unless otherwise stated. All statistical tests were performed on raw data using GraphPad Prism 8.0 unless otherwise stated.

Maintenance of C. elegans and other species was performed using standard protocols58. Unless otherwise stated, all strains and species were grown at 20 °C on nematode growth media (NGM) with plates seeded with E. coli OP50 to provide a food source. For C. elegans, a N2 hermaphrodite stock recently obtained from the Caenorhabditis Genetics Center was used as wild type (N2H) (ref. 59). Genotypes of C. elegans mutant strains used are described in Wormbase (www.wormbase.org), and included CB3844 fem-3(e2006), CB4037 glp-1(e2141), GA14 fog-2(q71), GA114 daf-16(mgDf50); daf-2(e1370), GA1928 daf-2(e1370), GR1307 daf-16(mgDf50) and SS104 glp-4(bn2). Unless otherwise stated, strains for other nematode species were VT847 C. briggsae, NK74SC C. inopinata, JU1325 C. nigoni, JU1373 C. tropicalis, JU1873 C. wallacei, RS5522 P. exspectatus and RS2333 P. pacificus. C. briggsae female mutants RE665 she-1(v35) and RE770 she-1(v49) were also used, and compared to C. briggsae (AF16) from which these mutants are derived35. C. inopinata were raised at 25 °C until the L4 stage and then transferred to 20 °C since at the latter temperature they exhibit a very slow development rate21. Temperature-sensitive mutants ( glp-1, glp-4, she-1) and accompanying controls were raised at 15 °C until the L4 stage and then shifted to 25 °C, the non-permissive temperature.

Identification of C. tropicalis orthologues of C. elegans fog-2 and fem-3 was performed using Wormbase ParaSite60,61. Following protein and DNA sequence alignment62, C. tropicalis Csp11.Scaffold629.g10847 was designated as the C. elegans fem-3 orthologue. No orthologue of C. elegans fog-2 was found in C. tropicalis, which is consistent with differences in the regulation of sperm function in these two species63. Three RNAi targeting regions were designed to enhance the efficiency of knockdown. In order to synthesis dsRNA for microinjection, three PCR products for in vitro transcription were generated with specific primers with T7 promoter sequences (TAATACGACTCACTATAGGG) included at the 5’ ends. PCR cycle conditions were 95 °C 30 sec, 47 °C 30 sec, 72 °C 60 sec for 30 cycles. PCR products were purified through gel extraction using a QIAquick Gel Extraction Kit (QIAGEN). dsRNAs were synthesised in vitro using a MAXIscript T7 Transcription Kit (ThermoFisher), and this was followed by RNA gel electrophoresis to analyse product size and quality. Next, the three dsRNAs were mixed at a ratio of 1:1:1, at a final concentration of 0.1 μg/μl, and then injected into both arms of the gonad of a 1-day-old adult C. tropicalis64. Injected nematodes were recovered and allowed to lay eggs for 6 hr at 25 °C to obtain developmentally synchronised progeny. These were then transferred individually to wells of a 24 well plate with NGM seeded with OP50 and grown to adulthood. Approximately 50% proved to be sterile and otherwise of a normal size and appearance and were used for experimental trials. Progeny of non-injected C. tropicalis hermaphrodites was used as negative controls. See also Supplementary Fig. 9 and Supplementary Tables 5–7.

Live nematodes were placed on 2% agar pads, and anaesthetised with a drop of 0.2% levamisole. Images were captured using either a Zeiss Axioskop 2 plus microscope with a Hamamatsu ORCA-ER digital camera C4742-95 and Velocity 6.3 software (Macintosh version) for image acquisition; or an ApoTome.2 Zeiss microscope with a Hamamatsu digital camera C13440 ORCA-Flash4.0 V3 and Zen software. Brightness and contrast were adjusted equally across the entire image, and where applicable applied equally to controls.

Nematode sample preparation was based on standard protocol65 (protocol 8). Briefly, animals were washed twice in M9 buffer, placed in fixing solution (2.5% glutaraldehyde, 1% paraformaldehyde in 0.1 M sucrose, 0.05 M cacodylate) and, to increase staining dye penetration, cut below the pharynx to remove the heads using a 30 G hypodermic needle. They were then rinsed 3 times in 0.2 M cacodylate, fixed in 0.5% OsO4 and 0.5% KFe(CN)6 in 0.1 M cacodylate on ice and sequentially washed in 0.1 M cacodylate and 0.1 M sodium acetate. Nematodes were then stained in 1% uranyl acetate in 0.1 M sodium acetate (pH 5.2) for 60 min, rinsed 3 times in 0.1 M sodium acetate and then rinsed overnight in Milli-Q water. Samples were then embedded in 3% seaplaque agarose, dehydrated and infiltrated using ethanol and propylene-resin series and then cured at 60 °C for 3 days.

Serial 1 μm sections were taken for light microscopy, and, from a region posterior to the posterior uterus, ultra-thin sections (70–80 nm) were cut using a diamond knife on a Reichert ultramicrotome. Comparative low-magnification images showing halves of nematode sibling species pairs were taken from approximately the same region of the animals containing the posterior intestine. Sections were collected on formvar-coated 2×1 mm slot grids which allowed low magnification images to be taken without grid bars and stained with lead citrate before being viewed and imaged in a Joel 1010 transmission electron microscope. Images were recorded using a Gatan Orius CCD camera, and obtained using Gatan imaging software. Brightness and contrast were adjusted equally across the entire image, and where applicable applied equally to controls.

Animals were maintained at a density of 25–30 per plate from the egg stage to minimise the population density-associated effects on ageing that occur in C. elegans66, and without the addition of FUDR. Nematode cohorts were scored every 2–3 days for the dead, and all animals transferred daily during the reproductive period, and every 6–7 days thereafter. Worms were scored as alive if they were motile or responded at all to gentle touch with a platinum worm-pick. For survival assays on UV-irradiated bacteria, 80 μl of E. coli OP50 was added to each NGM plate and left overnight at 20 °C. Plates were then exposed to UV for 30 min in a Stratalinker UV oven. Nematodes were raised on UV-treated bacteria from aseptic eggs. Raw mortality data for all trials is provided in Ziehm tables67 in the Source Data File to enable close scrutiny of data (including future reanalysis). Survival plots show combined lifespan data and individual trials, with the L4 stage of development taken as day 0. Animals which disappeared from the plate, were accidently killed during handling, died due to desiccation on the Petri dish wall, ruptured through the vulva or died due to internal hatching of larvae were recorded as censored. Censored values were taken into account in statistical analysis. Tests for statistically significant differences between the survival of cohorts employed the log-rank test, and for significant differences in the magnitude of effects of two treatments Cox proportional hazard analysis, in both cases performed using JMP software, version 14.0 (SAS Institute, Inc.).

L4 larvae were maintained individually on 35 mm NGM plates with E. coli OP50 lawns (n = 10 per trial), and transferred every 24 hrs until unfertilised oocyte production ceased, with a minimum of 12 days scored for all worms. For scoring, the open Petri dish was placed on an inverted plate bearing a grid of parallel lines, allowing the plate to be efficiently scored with a series of vertical sweeps. Where clumps of oocytes were seen, these were carefully separated using a worm pick, to count individual oocytes. P. pacificus and P. exspectatus also laid some dead eggs, consistent with previous observations (R.J. Sommer, personal communication), which were discounted.

Quantitation of vented yolk protein was performed as previously described14. Briefly, 100–200 L4 larvae were maintained on 35 mm plates with E. coli OP50 lawns and transferred daily to new plates. Following transfer, vented yolk was washed off with 1 ml of M9 containing 0.001% NP-40 to solubilise vitellogenin, as described68, and 2 μg/ml BSA as an external standard. It was then centrifuged to separate out fractions prior to lyophilisation. After lyophilisation yolk was resuspended in a solution made up of 30 μl 4% SDS solution pH 9, 10 μl DTT, 1 ml 1 M Tris HCL pH 8, 10 μl 0.5 M EDTA, 5 ml Milli-Q water, and 12 mg bromophenol blue.

Quantitation of internal (non-vented) yolk used a protocol similar to that previously described13. Briefly, 10 animals per condition per treatment were transferred to NGM plates lacking bacteria and allowed to crawl for 30–60 s to remove bacteria from the nematode surface. They were then transferred to 25 µl M9 and immediately frozen at −80 °C until used.

Samples were mixed with 25 μl of 2× Laemmli sample buffer (Sigma-Aldrich), incubated at 70 °C and vortexed periodically for 15 min, and then incubated at 95 °C for 5 min and centrifuged at 6,000 rpm for 15 min. For all samples, sodium dodecyl sulphate–polyacrylamide gel electrophoresis (SDS-PAGE) was then performed, using Criterion XT Precast Gels 4–12% Bis-Tris (Invitrogen) and XT MOPS (Invitrogen) as a running buffer (7:1 ratio with Milli-Q water) at 90 V. Gels were stained with colloidal Coomassie blue as described69, using 5% aluminum sulphate-(14-18)-hydrate and 2% orthophosphoric acid (85%) to create colloidal particles. Gels were analyzed using ImageQuant LAS 4000 (GE Healthcare). Protein band identification was based on published data70. Within lanes, vented YPs were normalised to the BSA that had been added during sample collection as an external standard. For samples of internal YPs, YP bands were normalised to myosin as a standard to account for protein loss during gel loading, as well as to allow for normalisation to nematode size when comparing different species.

Nomarski microscopy images of senescent pathologies in cohorts of worms (n = 5–10 per time point per condition per trial) were captured on days 1, 4, 7, 11 and 14 and images analysed either quantitatively (intestine, yolk pools), or semi-quantitatively and blind (pharyngeal deterioration, gonad atrophy and fragmentation, uterine tumours) by several trained observers as described8,9,71. In brief, intestinal atrophy was quantified by measuring the intestinal width at a point between the posterior gonad and anus, subtracting the width of the intestinal lumen, and dividing by the body width to obtain an estimate of intestinal cross-sectional width normalised to body size. Yolk pool accumulation was measured by dividing the area of yolk pools by the area of the body visible in the field of view at 630x magnification. For pharyngeal deterioration, gonad atrophy and fragmentation and uterine tumours, images were assigned scores of 1–5, where 1 = youthful, healthy appearance; 2 = subtle signs of deterioration; 3 = clearly discernible, mild pathology; 4 = well developed pathology; and 5 = tissue so deteriorated as to be barely recognisable (e.g., gonad completely disintegrated), or reaching a maximal level (e.g. large tumour filling the entire body width).

Scoring was adapted to the different nematode species as follows. Scoring of pharyngeal senescence in Pristionchus species took into account the normal absence of a grinder72. For scoring of gonadal senescence, the criteria for a healthy gonad included whether the two arms of the gonad touch one another (which they do in young adults). Animals where the gonad arms do not touch, or which show narrowing on the gonad arms were given a score of 2, both features a score of 3, and in addition gonad arm fragmentation a score of 4. For uterine tumour scoring in young unmated females an empty uterus lacking eggs as was given a score of 1.

In order to prepare data for modelling, data were pre-processed for the following reasons. Peak pathology level for C. elegans and most mated animals (which shows maximum pathology progression rate) is mostly reached by day 14, after which pathology levels plateau. Thus, pathology data after day 14 obscures the calculation of gradients representing initial rate of pathology progression. Intestine scores for each combination of species and treatment were normalised to the respective mean intestine score on day 1. Therefore, normalised intestinal pathology scores represent the change in percentage of intestinal volume, accounting for differences in terms of the ratio of intestinal width to whole body width between species. For yolk pool scores no normalisation was used because percentage of the body cavity containing yolk pools was measured. Yolk pools were analysed as score + 1, in order to ensure all data were positive (a requirement for Gamma regression). Generalised linear models (GLMs) were applied to the data to test the effect of species, treatment and trial on pathology progression. Interactions terms between these variables were also included. Different model families and link functions were systematically applied to each pathology dataset according to the type of data recorded. For positive, continuous variables (intestine and yolk pools), pathology scores were modelled as Gaussian and Gamma distributed variables. For ordinal variables (tumour, gonad and pharynx), cumulative link models were applied to the data using the ordinal package in R (ref. 73).

The following models were selected for each pathology based on minimisation of the Akaine Information Criterion (AIC), meaning that these models explained the most variance in pathology progression using the fewest number of terms: (i) intestine: Gaussian distributed response variable with inverse link function; (ii) yolk pools: Gamma distributed response variable with identity link function; and (iii) tumour, gonad and pharynx: ordinal distributed response variable with log-gamma link function. The vast majority of trial terms were not statistically significant across all pathologies, indicating that differences in pathology progression were reproducible and robust. Hence, trial was not considered further as a variable. In order to compare whether differences in pathology progression between combinations of species and treatment were statistically significant, t-tests were applied explicitly to comparisons of interest using the multcomp package in R (ref. 74).

For all sample images displayed, experiments were repeated a minimum of three times independently and checked to ensure the reproducibility of results.

In order to compare differences in pathology progression across species and treatments, the gradients from each model were transformed into Z-scores (which describe a value’s relationship to the mean of a group of values), necessary to compare pathologies to one another. The pathology Z-scores are displayed and compared as heatmaps, using pairwise Euclidean differences to cluster pathologies and species/treatments according to profile similarity. In order to model the impact of pathology Z-scores on lifespan, linear regression was performed, using the pathology Z-score as the independent variable and the inverse of mean lifespan as the dependent variable. In order to assess the combined impact of all pathologies on lifespan, the median of the pathology Z-scores was used as the independent variable. The Z-scores for all pathologies were found to be statistically significant, and the median pathology Z-score was found to perform better than the individual pathologies.

Live L1 larvae were mounted on a glass slide on a 5% agar pad with levamisole as anaesthetic. The concentration of levamisole and M9 buffer/Milli-Q water ratio was optimised for each sibling species pair: 0.2 mM levamisole in M9 for C. elegans, C. inopinata, C. tropicalis and C. wallacei; 0.2 mM levamisole in a 1:1 ratio of M9 to Milli-Q water for C. briggsae and C. nigoni; and 0.1 mM levamisole in M9 for P. pacificus and P. exspectatus. Ablations were performed using a Zeiss Axioplan 2 fitted with an Andor MicroPoint laser unit (CE N2 Laser with Ctlr/PSU/IntLk) at 440 nm and Dye Cell 435 nm filter. Germline precursor cells (Z2 and Z3) were identified by morphology and position with Nomarski optics and ablated in newly-hatched L1 animals using a standard protocol75.

Following ablation, larvae were transferred to fresh plates by washing them off with M9 buffer (30 μl) for all the pairs of species except for C. briggsae and C. nigoni which were recovered in a 1:1 ratio of M9 to Milli-Q water (total 30 μl). All ablated animals were then allowed to recover to day 1 of adulthood and checked under a Nikon SMZ645 microscope for both a lack of egg laying, indicating that the ablation was successful, as well as the presence of a vulva, indicating that the Z1 and Z4 cells were intact. For unmated females which do not lay eggs, 15–20 randomly selected worms per condition per trial were checked using Nomarski microscopy (×100 magnification with a ×10 air objective, without anaesthesia) on an NGM plate for the presence of a fully developed gonad, and none were found to have one. Mock treatment animals underwent the same manipulations as ablated animals apart from being shot with the laser microbeam. Ablation of the somatic gonad (by removing the Z1-4 gonad precursor cells) was performed in a similar manner; the resulting adult worms were checked to confirm absence of a vulva.

Further information on research design is available in the Nature Portfolio Reporting Summary linked to this article.

The data generated in this study are provided in the article and its Supplementary Information files. Source data are provided with this paper.

Finch C. E. Rapid senescence and sudden death. In: Longevity, Senescence and the Genome). University of Chicago Press (1990).

Gems, D., Kern, C. C., Nour, J. & Ezcurra, M. Reproductive suicide: similar mechanisms of aging in C. elegans and Pacific salmon. Front Cell Dev. Biol. 9, 688788 (2021).

Article PubMed PubMed Central Google Scholar

Friedman, D. B. & Johnson, T. E. A mutation in the age-1 gene in Caenorhabditis elegans lengthens life and reduces hermaphrodite fertility. Genetics 118, 75–86 (1988).

Article CAS PubMed PubMed Central Google Scholar

Kenyon, C., Chang, J., Gensch, E., Rudener, A. & Tabtiang, R. A. C. elegans mutant that lives twice as long as wild type. Nature 366, 461–464 (1993).

Article ADS CAS PubMed Google Scholar

Hsin, H. & Kenyon, C. Signals from the reproductive system regulate the lifespan of C. elegans. Nature 399, 362–366 (1999).

Article ADS CAS PubMed Google Scholar

Ayyadevara, S., Alla, R., Thaden, J. J. & Shmookler Reis, R. J. Remarkable longevity and stress resistance of nematode PI3K-null mutants. Aging Cell 7, 13–22 (2008).

Article CAS PubMed Google Scholar

Herndon, L. A. et al. Stochastic and genetic factors influence tissue-specific decline in ageing C. elegans. Nature 419, 808–814 (2002).

Article ADS CAS PubMed Google Scholar

Garigan, D. et al. Genetic analysis of tissue aging in Caenorhabditis elegans: a role for heat-shock factor and bacterial proliferation. Genetics 161, 1101–1112 (2002).

Article CAS PubMed PubMed Central Google Scholar

Ezcurra, M. et al. C. elegans eats its own intestine to make yolk leading to multiple senescent pathologies. Curr. Biol. 28, 2544–2556 (2018).

Article CAS PubMed PubMed Central Google Scholar

Luo, S., Kleemann, G. A., Ashraf, J. M., Shaw, W. M. & Murphy, C. T. TGF-beta and insulin signaling regulate reproductive aging via oocyte and germline quality maintenance. Cell 143, 299–312 (2010).

Article CAS PubMed PubMed Central Google Scholar

McGee, M. D., Day, N., Graham, J. & Melov, S. cep-1/p53-dependent dysplastic pathology of the aging C. elegans gonad. Aging 4, 256–269 (2012).

Article CAS PubMed PubMed Central Google Scholar

Scharf, A., Pohl, F., Egan, B. M., Kocsisova, Z. & Kornfeld, K. Reproductive aging in Caenorhabditis elegans: from molecules to ecology. Front Cell Dev. Biol. 9, 718522 (2021).

Article PubMed PubMed Central Google Scholar

Sornda, T. et al. Production of YP170 vitellogenins promotes intestinal senescence in C. elegans. J. Gerontol. A 74, 1180–1188 (2019).

Article CAS Google Scholar

Kern, C. C. et al. C. elegans feed yolk to their young in a form of primitive lactation. Nat. Commun. 12, 5801 (2021).

Article ADS CAS PubMed PubMed Central Google Scholar

Robertson, O. H. Prolongation of the life span of kokanee salmon (Oncorhynchus nerka kennerlyi) by castration before the beginning of gonad development. Proc. Natl Acad. Sci. USA 47, 609–621 (1961).

Article ADS CAS PubMed PubMed Central Google Scholar

Schulenburg, H. & Félix, M. A. The natural biotic environment of Caenorhabditis elegans. Genetics 206, 55–86 (2017).

Article CAS PubMed PubMed Central Google Scholar

Hodgkin, J. & Barnes, T. M. More is not better: brood size and population growth in a self-fertilizing nematode. Proc. R. Soc. Lond. B. 246, 19–24 (1991).

Article ADS CAS Google Scholar

Kiontke, K. et al. A phylogeny and molecular barcodes for Caenorhabditis, with numerous new species from rotting fruits. BMC Evol. Biol. 11, 339 (2011).

Article CAS PubMed PubMed Central Google Scholar

Woodruff, G. C., Johnson, E. & Phillips, P. C. A large close relative of C. elegans is slow-developing but not long-lived. BMC Evol. Biol. 19, 74 (2019).

Article PubMed PubMed Central Google Scholar

Gems, D. & Riddle, D. L. Genetic, behavioral and environmental determinants of male longevity in Caenorhabditis elegans. Genetics 154, 1597–1610 (2000).

Article CAS PubMed PubMed Central Google Scholar

Kanzaki, N. et al. Biology and genome of a newly discovered sibling species of Caenorhabditis elegans. Nat. Commun. 9, 3216 (2018).

Article ADS PubMed PubMed Central Google Scholar

Weadick, C. J. & Sommer, R. J. Mating system transitions drive life span evolution in Pristionchus nematodes. Am. Nat. 187, 517–531 (2016).

Article PubMed Google Scholar

de la Guardia, Y. et al. Run-on of germline apoptosis promotes gonad senescence in C. elegans. Oncotarget 7, 39082–39096 (2016).

Article PubMed PubMed Central Google Scholar

Wang, H. et al. A parthenogenetic quasi-program causes teratoma-like tumors during aging in wild-type. C. elegans. NPJ Aging Mech. Dis. 4, 6 (2018).

Article PubMed Google Scholar

Zhai, C. et al. Fusion and expansion of vitellogenin vesicles during Caenorhabditis elegans intestinal senescence. Aging Cell 21, e13719 (2022).

Article CAS PubMed PubMed Central Google Scholar

Herndon L. A., Wolkow C. A., Driscoll M., Hall D. H. Introduction to Aging in C. elegans. In: WormAtlas) (2018).

Epstein, J., Himmelhoch, S. & Gershon, D. Studies on aging in nematodes III. Electronmicroscopical studies on age-associated cellular damage. Mech. Ageing Dev. 1, 245–255 (1972).

Article Google Scholar

Baird, S. E., Sutherlin, M. E. & Emmons, S. W. Reproductive isolation in Rhabditidae (Nematoda: Secernentea); mechanisms that isolate six species of three genera. Evolution 46, 585–594 (1992).

Article PubMed Google Scholar

Klass, M. R. Aging in the nematode Caenorhabditis elegans: major biological and environmental factors influencing life span. Mech. Ageing Dev. 6, 413–429 (1977).

Article CAS PubMed Google Scholar

Gems, D. & Riddle, D. L. Longevity in Caenorhabditis elegans reduced by mating but not gamete production. Nature 379, 723–725 (1996).

Article ADS CAS PubMed Google Scholar

Shi, C. & Murphy, C. T. Mating induces shrinking and death in Caenorhabditis mothers. Science 343, 536–540 (2014).

Article ADS CAS PubMed Google Scholar

Baldi, C., Cho, S. & Ellis, R. E. Mutations in two independent pathways are sufficient to create hermaphroditic nematodes. Science 326, 1002–1005 (2009).

Article ADS CAS PubMed Google Scholar

Schedl, T. & Kimble, J. fog-2, a germ-line-specific sex determination gene required for hermaphrodite spermatogenesis in Caenorhabditis elegans. Genetics 119, 43–61 (1988).

Article CAS PubMed PubMed Central Google Scholar

Hodgkin, J. Sex determination in the nematode C. elegans: analysis of tra-3 suppressors and characterization of fem genes. Genetics 114, 15–52 (1986).

Article CAS PubMed PubMed Central Google Scholar

Guo, Y., Lang, S. & Ellis, R. E. Independent recruitment of F box genes to regulate hermaphrodite development during nematode evolution. Curr. Biol. 19, 1853–1860 (2009).

Article CAS PubMed Google Scholar

Leopold, A. C., Niedergang-Kamien, E. & Janick, J. Experimental modification of plant senescence. Plant Physiol. 34, 570–573 (1959).

Article CAS PubMed PubMed Central Google Scholar

Yamawaki, T. et al. The somatic reproductive tissues of C. elegans promote longevity through steroid hormone signaling. PLoS Biol. 8, e1000468 (2010).

Article PubMed PubMed Central Google Scholar

Gems, D. & Kern, C. C. Semelparous death as one element of iteroparous aging gone large. Front Genet 13, 880343 (2022).

Article PubMed PubMed Central Google Scholar

McCulloch D. Sex differences in ageing in the nematode Caenorhabditis elegans. In: Department of Biology). University College London (2003).

Ludewig, A. H. et al. An excreted small molecule promotes C. elegans reproductive development and aging. Nat. Chem. Biol. 15, 838–845 (2019).

Article CAS PubMed PubMed Central Google Scholar

Maures, T. et al. Males shorten the life span of C. elegans hermaphrodites via secreted compounds. Science 343, 541–544 (2014).

Article ADS CAS PubMed Google Scholar

Sutphin, G. L. A new defense in the battle of the sexes. eLife 8, e50140 (2019).

Article PubMed PubMed Central Google Scholar

Booth, L. N., Maures, T. J., Yeo, R. W., Tantilert, C. & Brunet, A. Self-sperm induce resistance to the detrimental effects of sexual encounters with males in hermaphroditic nematodes. eLife 8, e46418 (2019).

Article PubMed PubMed Central Google Scholar

Shi, C., Booth, L. N. & Murphy, C. T. Insulin-like peptides and the mTOR-TFEB pathway protect Caenorhabditis elegans hermaphrodites from mating-induced death. eLife 8, e46413 (2019).

Article PubMed PubMed Central Google Scholar

Blagosklonny, M. V. Aging and immortality: quasi-programmed senescence and its pharmacologic inhibition. Cell Cycle 5, 2087–2102 (2006).

Article CAS PubMed Google Scholar

Gems, D. Understanding hyperfunction: an emerging paradigm for the biology of aging. Ageing Res Rev. 74, 101557 (2022).

Article PubMed PubMed Central Google Scholar

Gems, D. Longevity and ageing in parasitic and free-living nematodes. Biogerontology 1, 289–307 (2000).

Article CAS PubMed Google Scholar

Kirkwood, T. B. L. & Rose, M. R. Evolution of senescence: late survival sacrificed for reproduction. Philos. Trans. R. Soc. 332, 15–24 (1991).

Article ADS CAS Google Scholar

Galimov, E. R. & Gems, D. Shorter life and reduced fecundity can increase colony fitness in virtual C. elegans. Aging Cell 19, e13141 (2020).

Article CAS PubMed PubMed Central Google Scholar

Galimov, E. R. & Gems, D. Death happy: Adaptive death and its evolution by kin selection in organisms with colonial ecology. Philos. Trans. R. Soc. B 376, 20190730 (2021).

Article CAS Google Scholar

Lohr, J., Galimov, E. R. & Gems, D. Does senescence promote fitness in Caenorhabditis elegans by causing death? Ageing Res Rev. 50, 58–71 (2019).

Article PubMed PubMed Central Google Scholar

de Magalhães, J. P. & Church, G. M. Genomes optimize reproduction: aging as a consequence of the developmental program. Physiology 20, 252–259 (2005).

Article PubMed Google Scholar

Gems, D. & de la Guardia, Y. Alternative perspectives on aging in C. elegans: reactive oxygen species or hyperfunction? Antioxid. Redox Signal 19, 321–329 (2013).

Article CAS PubMed PubMed Central Google Scholar

Maklakov, A. A. & Chapman, T. Evolution of ageing as a tangle of trade-offs: energy versus function. Proc. Biol. Sci. 286, 20191604 (2019).

CAS PubMed PubMed Central Google Scholar

Slack, C., Giannakou, M. E., Foley, A., Goss, M. & Partridge, L. dFOXO-independent effects of reduced insulin-like signaling in Drosophila. Aging Cell 10, 735–748 (2011).

Article CAS PubMed Google Scholar

Foukas, L. C. et al. Long-term p110alpha PI3K inactivation exerts a beneficial effect on metabolism. EMBO Mol. Med 5, 563–571 (2013).

Article CAS PubMed PubMed Central Google Scholar

Hughes, P. W. Between semelparity and iteroparity: empirical evidence for a continuum of modes of parity. Ecol. Evol. 7, 8232–8261 (2017).

Article PubMed PubMed Central Google Scholar

Brenner, S. The genetics of Caenorhabditis elegans. Genetics 77, 71–94 (1974).

Article CAS PubMed PubMed Central Google Scholar

Zhao, Y., Wang, H., Poole, R. J. & Gems, D. A. fln-2 mutation affects lethal pathology and lifespan in C. elegans. Nat. Commun. 10, 5087 (2019).

Article ADS PubMed PubMed Central Google Scholar

Howe, K. L., Bolt, B. J., Shafie, M., Kersey, P. & Berriman, M. WormBase ParaSite − a comprehensive resource for helminth genomics. Mol. Biochem Parasitol. 215, 2–10 (2017).

Article CAS PubMed PubMed Central Google Scholar

Howe, K. L. et al. WormBase 2016: expanding to enable helminth genomic research. Nucleic Acids Res 44, D774–D780 (2016).

Article CAS PubMed Google Scholar

Waterhouse, A. M., Procter, J. B., Martin, D. M. A., Clamp, M. & Barton, G. J. Jalview Version 2 - A multiple sequence alignment editor and analysis workbench. Bioinformatics 25, 1189–1191 (2009).

Article CAS PubMed PubMed Central Google Scholar

Wei, Q. et al. Co-option of alternate sperm activation programs in the evolution of self-fertile nematodes. Nat. Commun. 5, 5888 (2014).

Article ADS CAS PubMed Google Scholar

Maeda, I., Kohara, Y., Yamamoto, M. & Sugimoto, A. Large-scale analysis of gene function in Caenorhabditis elegans by high-throughput RNAi. Curr. Biol. 11, 171–176 (2001).

Article CAS PubMed Google Scholar

Shaham S. WormBook: Methods in Cell Biology. In: WormBook (ed The C. elegans Research Community) (2006).

Ludewig, A. H. et al. Larval crowding accelerates C. elegans development and reduces lifespan. PLoS Genet 13, e1006717 (2017).

Article PubMed PubMed Central Google Scholar

Zhao, Y. et al. Two forms of death in aging Caenorhabditis elegans. Nat. Commun. 8, 15458 (2017).

Article ADS CAS PubMed PubMed Central Google Scholar

Sharrock, W. Yolk proteins of Caenorhabditis elegans. Dev. Biol. 96, 182–188 (1983).

Article CAS PubMed Google Scholar

Kang, D.-H., Gho, Y.-S., Suh, M.-K. & Kang, C.-H. Highly sensitive and fast protein detection with coomassie brilliant blue in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Bull. Korean Chem. Soc. 23, 1511–1512 (2002).

Article CAS Google Scholar

Depina, A. S. et al. Regulation of Caenorhabditis elegans vitellogenesis by DAF-2/IIS through separable transcriptional and posttranscriptional mechanisms. BMC Physiol. 11, 11 (2011).

Article CAS PubMed PubMed Central Google Scholar

Riesen, M. et al. MDL-1, a growth- and tumor-suppressor, slows aging and prevents germline hyperplasia and hypertrophy in C. elegans. Aging 6, 98–117 (2014).

Article PubMed PubMed Central Google Scholar

Wei, J.-Z. et al. Bacillus thuringiensis crystal proteins that target nematodes. Proc. Natl Acad. Sci. USA 100, 2760–2765 (2003).

Article ADS CAS PubMed PubMed Central Google Scholar

Christensen, R. H. B. Regression Models for Ordinal Data [R package ordinal version 2022.11–16] (2022).

Hothorn, T., Bretz, F. & Westfall, P. Simultaneous inference in general parametric models. Biometrical J. 50, 346–363 (2008).

Article MathSciNet MATH Google Scholar

Bargmann, C. I. & Avery, L. Laser killing of cells in Caenorhabditis elegans. Methods Cell Biol. 48, 225 (1995).

Article CAS PubMed PubMed Central Google Scholar

Stevens, L. et al. Comparative genomics of 10 new Caenorhabditis species. Evol. Lett. 3, 217–236 (2019).

Article PubMed PubMed Central Google Scholar

Cutter, A. D., Morran, L. T. & Phillips, P. C. Males, outcrossing, and sexual selection in Caenorhabditis nematodes. Genetics 213, 27–57 (2019).

Article PubMed PubMed Central Google Scholar

Tesch F.-W. The Eel. Chapman and Hall (1977).

Bansal, A. et al. Transcriptional regulation of Caenorhabditis elegans FOXO/DAF-16 modulates lifespan. Longev. Healthspan 3, 5 (2014).

Article PubMed PubMed Central Google Scholar

Download references

We are grateful to L. Cao, B. Evans, D. Mills, S. Mirpuri, L. Montemayor, E. Morisot, C. Nguyen Hong, S. Theivendran, Y. Wang and X. Wei for technical assistance and minor contributions, M. Turmaine for help with electron microscopy, A. Barrios and R.J. Poole for access to laser ablation facilities, R.E. Ellis (Rowan University) for providing C. briggsae she-1 mutants, N. Kanzaki and T. Kikuchi (F.F.P.R.I. Tsukuba) for providing C. inopinata, 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, T. Niccoli, Y. de la Guardia and other scientists at the Institute of Healthy Ageing for advice and useful discussion and/or comments on the manuscript. Some strains were provided by the Caenorhabditis Genetics Center (CGC), which is funded by NIH Office of Research Infrastructure Programs (P40 OD010440). This work was supported by a Wellcome Trust Investigator Award (215574/Z/19/Z) to D.G. and a Boehringer Ingelheim Funds Ph.D. Fellowship to S.T. This paper is dedicated to the memory of our dear co-author StJohn Townsend, who recently passed away.

Deceased: StJohn Townsend.

Institute of Healthy Ageing, and Research Department of Genetics, Evolution and Environment, University College London, London, WC1E 6BT, UK

Carina C. Kern, Shivangi Srivastava, Marina Ezcurra, Kuei Ching Hsiung, Nancy Hui, StJohn Townsend, Dominik Maczik, Bruce Zhang, Victoria Tse, Viktoras Konstantellos, Jürg Bähler & David Gems

School of Biosciences, Stacey Building, University of Kent, Canterbury, Kent, CT2 7NJ, UK

Marina Ezcurra

Molecular Biology of Metabolism Laboratory, The Francis Crick Institute, London, NW1 1AT, UK

StJohn Townsend

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D.G. supervised the project. D.G. and C.C.K. conceived the project, designed the experiments and data analysis, and wrote the manuscript. C.C.K., M.E., N.H., S.S., V.T. and B.Z. performed experiments. M.E., N.H., D.M. and V.T. performed the pathology data capture and analysis. K.C.H. performed studies of RNAi by injection. N.H. assisted with the collection and measurement of internal and vented proteins. V.K. performed gel electrophoresis and analysed protein gels. S.S. performed and 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.

Correspondence to David Gems.

The authors declare no competing interests.

Nature Communications thanks the anonymous reviewers for their contribution to the peer review of this work.

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Kern, C.C., Srivastava, S., Ezcurra, M. et al. C. elegans ageing is accelerated by a self-destructive reproductive programme. Nat Commun 14, 4381 (2023). https://doi.org/10.1038/s41467-023-40088-1

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Received: 15 January 2021

Accepted: 12 July 2023

Published: 20 July 2023

DOI: https://doi.org/10.1038/s41467-023-40088-1

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