Alternative reproductive tactics, sexual selection and the effects of inbreeding in the ant Hypoponera opacior

Inbreeding can lead to a fitness reduction due to the unmasking of deleterious recessive alleles and the loss of heterosis. Therefore, most sexually reproducing organisms avoid inbreeding, often by disperal. Besides the avoidance of inbreeding, dispersal lowers intraspecific competition on a local scale and leads to a spreading of genotypes into new habitats. In social insects, winged reproductives disperse and mate during nuptial flights. Therafter, queens independently found a new colony. However, some species also produce wingless sexuals as an alternative reproductive tactic. Wingless sexuals mate within or close to their colony and queens either stay in the nest or they found a new colony by budding. During this dependent colony foundation, wingless queens are accompanied by a fraction of nestmate workers. The production of wingless reproductives therefore circumvents the risks associated with dispersal and independent colony foundation. However, the absence of dispersal can lead to inbreeding and local competition.rnIn my PhD-project, I investigated the mating biology of Hypoponera opacior, an ant that produces winged and wingless reproductives in a population in Arizona. Besides the investigation of the annual reproductive cycle, I particularly focused on the consequences of wingless reproduction. An analysis of sex ratios in wingless sexuals should reveal the relative importance of local resource competition among queens (that mainly compete for the help of workers) and local mate competition among males. Further, sexual selection was expected to act on wingless males that were previously found to mate with and mate-guard pupal queens in response to local mate competition. We studied whether males are able to adapt their mating behaviour to the current competitive situation in the nest and which traits are under selection in this mating situation. Last, we investigated the extent and effects of inbreeding. As the species appeared to produce non-dispersive males and queens quite frequently, we assumed to find no or only weak negative effects of inbreeding and potentially mechanisms that moderate inbreeding levels despite frequent nest-matings.rnWe found that winged and wingless males and queens are produced during two separate seasons of the year. Winged sexuals emerge in early summer and conduct nuptial flights in July, when climate conditions due to frequent rainfalls lower the risks of dispersal and independent colony foundation. In fall, wingless sexuals are produced that reproduce within the colonies leading to an expansion on the local scale. The absence of dispersal during this second reproductive season resulted in a local genetic population viscosity and high levels of inbreeding within the colonies. Male-biased sex ratios in fall indicated a greater importance of local resource competition among queens than local mate competition among males. Males were observed to adjust mate-guarding durations to the competitive situation (i.e. the number of competing males and pupae) in the nest, an adaptation that helps maximising their reproductive success. Further, sexual selection was found to act on the timing of emergence as well as on body size in these males, i.e. earlier emerging and larger males show a higher mating success. Genetic analyses revealed that wingless males do not actively avoid inbreeding by choosing less related queens as mating partners. Further, we detected diploid males, a male type that is produced instead of diploid females if close relatives mate. In contrast to many other Hymenopteran species, diploid males were here viable and able to sire sterile triploid offspring. They did not differ in lifespan, body size and mating success from “normal” haploid males. Hence, diploid male production in H. opacior is less costly than in other social Hymenopteran species. No evidence of inbreeding depression was found on the colony level but more inbred colonies invested more resources into the production of sexuals. This effect was more pronounced in the dispersive summer generation. The increased investment in outbreeding sexuals can be regarded as an active strategy to moderate the extent and effects of inbreeding. rnIn summary, my thesis describes an ant species that has evolved alternative reproductive tactics as an adaptation to seasonal environmental variations. Hereby, the species is able to maintain its adaptive mating system without suffering from negative effects due to the absence of dispersal flights in fall.rn

The physiological role of APP in the activation of neuroprotective signaling mechanisms

Accumulating evidence indicates that loss of physiological amyloid precursor protein (APP) function leads to enhanced susceptibility of neurons to cellular stress during brain aging. This study investigated the neuroprotective function of the soluble APP ectodomain sAPPα. Recombinant sAPPα protected primary hippocampal neurons and neuroblastoma cells from cell death induced by trophic factor deprivation. This protective effect was abrogated in APP-depleted neurons, but not in APLP1-, APLP2- or IGF1-R-deficient cells, indicating that expression of holo-APP is required for sAPPα-dependent neuroprotection. Strikingly, recombinant sAPPα, APP-E1 domain and the copper-binding growth factor-like domain (GFLD) of APP were able to stimulate PI3K/Akt survival signaling in different wildtype cell models, but failed in APP-deficient cells. An ADAM10 inhibitor blocking endogenous sAPPα secretion exacerbated neuron death in organotypic hippocampal slices subjected to metabolic stress, which could be rescued by exogenous sAPPα. Interestingly, sAPPα-dependent neuroprotection was unaffected in neurons of APP-ΔCT15 mice which lack the intracellular C-terminal YENPTY motif of APP. In contrast, sAPPα-dependent Akt signaling was completely abolished in APP mutant cells lacking the C-terminal G-protein interaction motif and by specifically blocking Gi/o-dependent signaling with pertussis toxin. Collectively, the present thesis provides new mechanistic insights into the physiological role of APP: the data suggest that cell surface APP mediates sAPPα-induced neuroprotection via Go-protein-coupled activation of the Akt pathway.