Marion Kever scite author profile

According to the classic life history theory, selection for longevity depends on age-dependant extrinsic mortality and fecundity. In social insects, the common life history trade-off between fecundity and longevity appears to be reversed, as the most fecund individual, the queen, often exceeds workers in lifespan several fold. But does fecundity directly affect intrinsic mortality also in social insect workers? And what is the effect of task on worker mortality? Here, we studied how social environment and behavioral caste affect intrinsic mortality of ant workers. We compared worker survival between queenless and queenright Temnothorax longispinosus nests and demonstrate that workers survive longer under the queens' absence. Temnothorax ant workers fight over reproduction when the queen is absent and dominant workers lay eggs. Worker fertility might therefore increase lifespan, possibly due to a positive physiological link between fecundity and longevity, or better care for fertile workers. In social insects, division of labor among workers is age-dependant with young workers caring for the brood and old ones going out to forage. We therefore expected nurses to survive longer than foragers, which is what we found. Surprisingly, inactive inside workers showed a lower survival than nurses but comparable to that of foragers. The reduced longevity of inactive workers could be due to them being older than the nurses, or due to a positive effect of activity on lifespan. Overall, our study points to behavioral caste-dependent intrinsic mortality rates and a positive association between fertility and longevity not only in queens but also in ant workers.

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Social isolation causes downregulation of immune and stress response genes and behavioural changes in a social insect

Scharf

Stoldt

Libbrecht

et al. 2021

Molecular Ecology

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Humans and other social mammals experience isolation from their group as stressful, triggering behavioural and physiological anomalies that reduce fitness. While social isolation has been intensely studied in social mammals, it is less clear how social insects, which evolved sociality independently, respond to isolation. Here we examined whether the typical mammalian responses to social isolation, e.g., an impaired ability to interact socially and immune suppression are also found in social insects. We studied the consequences of social isolation on behaviour and brain gene expression in the ant Temnothorax nylanderi. Following isolation, workers interacted moderately less with adult nestmates, increased the duration of brood contact, and reduced the time spent self‐grooming, an important sanitary behaviour. Our brain transcriptome analysis revealed that only a few behaviour‐related genes had altered their expression with isolation time. Rather, many genes linked to immune system functioning and stress response had been downregulated. This probably sensitizes isolated individuals to various stressors, in particular because isolated workers exhibit reduced sanitary behaviour. We provide evidence of the diverse consequences of social isolation in social insects, some of which resemble those found in social mammals, suggesting a general link between social well‐being, stress tolerance, and immune competence in social animals.

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Long live the host! Proteomic analysis reveals possible strategies for parasitic manipulation of its social host

Hartke

Ceron-Noriega

Stoldt

et al. 2022

Preprint

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Parasites with complex lifecycles are known to manipulate the phenotype of their intermediate hosts to increase the probability of transmission to their definitive hosts. Anomotaenia brevis, a cestode that uses Temnothorax nylanderi ants as intermediate hosts, extends the lifespan of these hosts several fold and changes their behaviour, morphology, and colouration. The mechanisms behind these changes are unknown, as is whether the increased longevity is achieved through manipulation of the parasite. Here we show that the prolonged lifespan of infected ants is probably due to the secretion of antioxidants and possibly novel substances by the parasite. These parasitic proteins make up a substantial portion of the host haemolymph proteome, and thioredoxin peroxidase and superoxide dismutase, two antioxidants, exhibited the highest abundances among them. The largest part of the secreted proteins could not be annotated, indicating they are either novel or severely altered during recent coevolution to function in host manipulation. We found not only secreted proteins, but also shifts in the host proteome, in particular an overabundance of vitellogenin-like A in infected ants, a protein that regulates division of labour in Temnothorax ants, which fits the observed behavioural changes. Our results thus point at two different strategies that are likely employed by this parasite to manipulate its host - by secretion of proteins with immediate influence on the host's phenotype and by altering the host's translational activity. Our results reveal the intricate molecular interplay required to influence host phenotype and shed light on potential signalling pathways and genes.

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Age- and caste-independent piRNAs in the germline and miRNA profiles linked to caste and fecundity in the antTemnothorax rugatulus

Seistrup

Choppin

Govind

et al. 2023

Preprint

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Social insects are models for phenotypic plasticity: the generation of different phenotypes from the same genotype. Ant queens and workers differ not only in their morphology and behaviour, but also in their fecundity and lifespan, which is often several times higher in queens. However, the gene regulatory mechanisms underlying these differences are not yet well understood. Since ant queens can live and reproduce for more than two decades, they need to protect their germline from the activity of transposable elements (TEs). This protection may be redundant in short-lived, often sterile workers. We have analysed the expression of two protective classes of smallRNAs, microRNAs (miRNAs) and Piwi-interacting RNAs (piRNAs), in different tissues, castes, and age classes of the ant species Temnothorax rugatulus. We show that piRNAs are particularly active in the ovaries of queens. TEs are clear targets of the piRNAs in this ant species, and piRNA-specific sequence signatures in the ovaries of all queens regardless of age indicate that young and old queens have similarly active piRNA pathways. Interestingly, the reduced ovaries of the workers also showed the same level of piRNA activity. This was not only the case in young, fertile workers from queenless nests, but also in the presumably older foragers, which have almost completely regressed ovaries. These findings suggest that the germline in these ants is invariably protected by piRNA activity, irrespective of ovarian development. The brain and thorax of queens also contained piRNAs, but at lower levels, and the piRNA-specific ping-pong signatures were strongly reduced in these tissues. We also annotated and analysed miRNAs in different tissues. We confidently detected the expression of 304 miRNAs. Of these, 10 were enriched in the brain and three to the thorax, whereas 83 were specific to the ovaries. 105 miRNAs were found to be expressed in all three tissues. We also identified miRNAs whose expression potentially is related to ant caste, fecundity, and age, suggesting that caste-specific gene activity may be regulated in part by miRNAs. In contrast, our studies of piRNA activity indicate similar profiles across caste, fecundity and age groups, but strong tissue specificity with the highest piRNA mediated TE protection in the germline.

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Marion Kever

Intrinsic worker mortality depends on behavioral caste and the queens’ presence in a social insect

Social isolation causes downregulation of immune and stress response genes and behavioural changes in a social insect

Long live the host! Proteomic analysis reveals possible strategies for parasitic manipulation of its social host

Age- and caste-independent piRNAs in the germline and miRNA profiles linked to caste and fecundity in the antTemnothorax rugatulus

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