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Distinct juvenile behaviour differences, changes in adult sizes and reproductive capacity and a long reproductive period triggered the working hypothesis of two alternative life-cycle strategies favouring aestivation or immediate reproduction. The hypothesis for the life-cycles of Hyperolius nitidulus that differed from the commonly assumed reproductive strategy for this species was confirmed by the results of this study. Aestivated juveniles start to mature at the beginning of the rainy season and reproduce subsequently. Their tadpoles grow until metamorphosis and either reproduce in this same season, in which case their offspring aestivates (one year - two generations), or they delay reproduction to the following year and aestivate themselves (one year - one generation). Juveniles trying to reproduce as fast as possible will invest in growth and differentiation and show no costly adaptations to aestivation, while juveniles delaying reproduction to the following rainy season will be well adapted to dry season conditions. Indirect evidence for the existence of a second generation was found in all three investigation years: adult size decreased abruptly towards the end of the rainy season, mainly due to the arrival of very small individuals, and clutch size decreased abruptly. Also at the end of the rainy season juveniles had two behavioural types: one hiding on the ground and clearly avoiding direct sunlight and another sitting freely above ground showing higher tolerance towards dry season conditions (high air temperatures and low humidity). Skin morphology differed between the types showing many more purine crystals in a higher order in the dry-season adapted juveniles. The final proof for the existence of a second generation came with the recapture of individuals marked as juveniles when they left the pond. The 45 recaptured frogs definitely came back to the pond to reproduce during the same season in 1999. Second generation frogs (males and females) were significantly smaller than the rest of all adults and egg diameter was reduced. Clutch size did not differ significantly. It was found that females did not discriminate against second generation males when coming to the ponds to reproduce. Second generation males had a similar chance to be found in amplexus as first generation males. Indirect and direct evidence for a second generation matched very well. The sudden size decrease in adults occurred just at the time when the first marked frogs returned. The observation that freshly metamorphosed froglets were able to sit in the sun directly after leaving the water led to the assumption that the decision whether to aestivate or to reproduce already happens during the frogs' larval period. Water chemistry and the influence of light was investigated to look for the factors triggering the decision, but only contaminated water increased the number of juveniles ready for aestivation. Whether the life history polymorphism observed in Hyperolius nitidulus is due to phenotypic plasticity or genetic polymorphism is still not known. Despite this uncertainty, there is no doubt that the optimal combination of different life histories is profitable and may be a reason for the wide range and high local abundance of Hyperolius nitidulus.
Olfaction plays an important role in a variety of behaviors throughout the life of the European honeybee. Caste specific, environmentally induced and aging/experiencedependent differences in olfactory behavior represent a promising model to investigate mechanisms and consequences of phenotypic neuronal plasticity within the olfactory pathway of bees. This study focuses on the two different female phenotypes within the honeybee society, queens and workers. In this study, for the first time, structural plasticity in the honeybee brain was investigated at the synaptic level. Queens develop from fertilized eggs that are genetically not different from those that develop into workers. Adult queens are larger than workers, live much longer, and display different behaviors. Developmental trajectory is mainly determined by nutritional factors during the larval period. Within the subsequent post-capping period, brood incubation is precisely controlled, and pupae are incubated close to 35°C via thermoregulatory activity of adult workers. Behavioral studies suggest that lower rearing temperatures cause deficits in olfactory learning in adult bees. To unravel possible neuronal correlates for thermoregulatory and caste dependent influences on olfactory behavior, I examined structural plasticity of developing as well as mature olfactory synaptic neuropils. Brood cells were reared in incubators and pupal as well as adult brains were dissected for immunofluorescent staining. To label synaptic neuropils, I used an antibody to synapsin and fluophore-conjugated phalloidin which binds to filamentous (F-) actin. During development, neuronal F-actin is expressed in growing neurons, and in the mature nervous system, F-actin is most abundant in presynaptic terminals and dendritic spines. In the adult brains, this double labeling technique enables the quantification of distinct synaptic complexes microglomeruli [MG]) within olfactory and visual input regions of the mushroom bodies (MBs) prominent higher sensory integration centers. Analyses during larval-adult metamorphosis revealed that the ontogenetic plasticity in the female castes is reflected in the development of the brain. Distinct differences among the timing of the formation of primary and secondary olfactory neuropils were also revealed. These differences at different levels of the olfactory pathway in queens and workers correlate with differences in tasks performed by both female castes. In addition to caste specific differences, thermoregulation of sealed brood cells has important consequences on the synaptic organization within the MB calyces of adult workers and queens. Even small differences in rearing temperatures affected the number of MG in the olfactory calyx lip regions. In queens, the highest number of MG in the olfactory lip developed at 1°C below the temperature where the maximum of MG is found in workers (33.5 vs. 34.5°C). Apart from this developmental neuronal plasticity, this study exhibits a striking age-related plasticity of MG throughout the extended life span of queens. Interestingly, MG numbers in the olfactory lip increased with age, but decreased within the adjacent visual collar of the MB calyx. To conclude, developmental and adult plasticity of the synaptic circuitry in the sensory input regions of the MB calyx may underlie caste- and age-specific adaptations and long-term plasticity in behavior.