Damaraland mole-rats do not rely on helpers for reproduction or survival

Establishment of primary and immortalized fibroblasts reveals resistance to cytotoxic agents and loss of necroptosis-inducing ability in long-lived Damaraland mole-rats

The Damaraland mole-rat (DMR; Fukomys damarensis) is a long-lived (~ 20 years) Bathyergid rodent that diverged 26 million years ago from its close relative, the naked mole-rat (NMR). While the properties of NMR cultured fibroblasts have been extensively studied and have revealed several unusual features of this cancer-resistant, long-lived species, comparative DMR studies are extremely limited. We optimized conditions for successfully culturing primary DMR skin fibroblasts and also established immortalized DMR cells using simian virus 40 early region expression. Like NMRs, DMR fibroblasts are more resistant than mice to various cytotoxins including heavy metals, DNA-damaging agents, oxidative stressors, and proteasome inhibitors. DMR genome sequencing analyses revealed the presence of premature stop codons in the master regulator genes of necroptosis, an inflammatory programmed cell death-receptor-interacting protein kinase 3 (RIPK3) and mixed lineage kinase domain-like (MLKL), although these mutations have different locations to those found in the NMR. DMR cells, like NMR cells, did not show significantly increased cell death in response to necroptosis induction. Our data suggest that both Bathyergid species require species-specific cell culture conditions for optimized growth, display similar resistance to cytotoxins, and show loss-of-function mutations abrogating the ability to employ necroptosis. These shared traits may contribute to their evolved adaptations to their subterranean lifestyle and prolonged longevity. These convergent insights and valuable resource may be pertinent to biomedical research.

A New Laboratory Research Model: The Damaraland Mole-rat and Its Managed Care

The Damaraland mole-rat (Fukomys damarensis) is a subterranean, hypoxia-tolerant, long-lived rodent endemic to southern and central Africa that is increasingly being used in laboratory research. Its husbandry needs and characteristics differ from traditional rodent research models. Here, we provide a brief overview of this species and discuss its captive housing and husbandry requirements for managed care and good health.

Evidence for inbreeding depression in captive Damaraland mole-rats

Mating between closely related individuals can result in a reduction in offspring fitness, known as inbreeding depression. Here, we investigate whether breeding with close relatives affects the reproductive output of parents and the development of their offspring in Damaraland mole-rats (Fukomys damarensis), a cooperatively breeding species where females avoid mating with familiar individuals. By cross-fostering litters of pups soon after birth, we were able to form breeding pairs from full siblings that were reared apart. We compared the reproductive output of these sibling pairs and the survival and growth of their pups with that of unrelated pairs over a period of 4 years. The litter sizes and interbirth intervals of sibling pairs did not differ from those of unrelated pairs, but the growth and survival of inbred offspring were lower, showing that breeding between close relatives is associated with substantial fitness costs. This study suggests that inbreeding depression is an important driver of the extreme reproductive skew observed in social mole-rats. Studies of the costs of inbred matings are now needed in similar species, such as naked mole-rats (Heterocephalus glaber), where captive females more commonly breed with close relatives, to determine whether these costs are lower than in Damaraland mole-rats.

Kin recognition for incest avoidance in Damaraland mole-rats, Fukomys damarensis

Across taxa, breeding among close relatives is usually avoided because it incurs fitness costs to offspring. Incest is often averted through the dispersal of either sex from the natal area to breed. In some philopatric species, association among relatives extends into adulthood, and an ability to discriminate kin may be required for individuals to reduce inbreeding risk. Here, we aim to determine the mechanism of kin recognition for incest avoidance in the Damaraland mole-rat Fukomys damarensis, a cooperative breeder characterized by extreme reproductive skew. Pairs of opposite-sex adults were formed in the laboratory and, within pairs, genetic relatedness and degree of familiarity were manipulated through cross-fostering experiments. We found that unfamiliar pairs were more likely to engage in sexual behaviours and bred more successfully than familiar pairs, regardless of their genetic similarity. Females paired with unfamiliar males were also more likely to exhibit reproductive activation, characterized by increased levels of oestradiol and progesterone. This study shows that in Damaraland mole-rats, inbreeding avoidance can be achieved through a discrimination mechanism that relies on association during rearing, and that ovulation is induced by mating. This study advances our understanding of incest avoidance in species with constrained dispersal.

Environmental effects rather than relatedness determine gut microbiome similarity in a social mammal

In social species, group members commonly show substantial similarity in gut microbiome composition. Such similarities have been hypothesized to arise either by shared environmental effects or by host relatedness. However, disentangling these factors is difficult, because group members are often related, and social groups typically share similar environmental conditions. In this study, we conducted a cross-foster experiment under controlled laboratory conditions in group-living Damaraland mole-rats (Fukomys damarensis) and used 16S amplicon sequencing to disentangle the effects of the environment and relatedness on gut microbiome similarity and diversity. Our results show that a shared environment is the main factor explaining gut microbiome similarity, overshadowing any effect of host relatedness. Together with studies in wild animal populations, our results suggest that among conspecifics environmental factors are more powerful drivers of gut microbiome composition similarity than host genetics.