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Unstable environments and habitats changing due to climate change force individuals to either respond by genetic adaptation, phenotypic plasticity or by dispersal to suitable environments. Theodoxus fluviatilis (Linneaus, 1758) is a good study organisms when researching phenotypic plasticity and genetic adaptation as it naturally appears in freshwater (FW) as well as brackish water (BW) and thus inhabits a wide range of environmental salinities (0-18‰). It is a euryhaline snail that can be found in shallow waters with stony ground or on Fucus spp. and has formed regional subgroups. The brackish water and the freshwater subgroups are spatially separated and the species cannot be found in areas inbetween, e.g. estuaries.
The species shows great variability in shell patterning and shell size and there is still debate whether the subgroups are distinguishable by these traits or not. The mitochdrial RNA marker cytochrome c subunit I did not show differences between the subgroups indicating that they must be closely related, but salinity tolerance has been observed to be higher in BW snails. This might be caused by the different protein expression patterns and osmolyte accumulation (measured as ninhydrin-positive substances) observed in this species in previous studies. The exact mechanisms regulating protein expression and osmolyte accumulation, however, are not fully understood yet.
Data collected for this thesis shows differences in shell size and suggests a less strict grouping of FW and BW individuals as shell sizes of one FW site are more similar to BW individuals than the other FW ones. A better salinity tolerance towards high salinities and a higher physiological salinity limit of BW snails was confirmed and extended by demonstrating an expanded tolerance range through slow acclimation to challenging salinities in snails from both subgroups. This was achieved by a shift in the slope of their reaction norms that was much more pronounced in BW snails than FW ones. S3 individuals showed a shift similar to that of BW individuals. The data for the salinity tolerance indicates that the underlying mechanism for these tolerances are a combination of phenotypic plasticity and genetic adaptation. Despite an acclimation and shift in the slope of the reaction norms and therefore an increased tolerance towards high salinities (plasticity) FW individuals from two collection sites were not able to cope with salinities as high as BW individuals (local adaptation). The general ability to mobilise free amino acids (FAA) as organic osmolytes was not the reason for this tolerance difference. Individuals from BW and FW sites were capable of accumulating quantities of FAAs equally well. Proline, alanine and urea were the most important components of the accumulated cocktail of organic osmolytes. Even though the total amount of FAAs accumulated under hyperosmotic conditions was the same in both subgroups, there were differences in the metabolic pathways involved in osmolyte accumulation in the foot muscle. The data indicates that the hydrolysis of storage proteins and the synthesis of proline and alanine are the main processes to avoid detrimental body volume shrinkage in T. fluviatilis. While FW individuals seemed to rely on the degradation of proteins and synthesis of alanine, BW individuals depended on newly synthesising proline and alanine and accumulating urea as a side product of transamination. The accumulation of urea is a new finding in aquatic living snails and has not been reported as a mechanism to avoid cell volume shrinkage in these animals.
Differing protein expression patterns were observed under control conditions across all collection sites. 9 spots showed volume changes in BW snails opposite to those of FW snails from collection sites S1 and S2. For 6 of those spots, S3 individuals showed patterns similar to those of BW individuals and for the remaining 3 they showed patterns similar to those of FW animals. The patterns observed when exposing snails to hypo- or hyperosmotic stress were not conclusive in relation to pinpointing individual spots that show the same pattern in all collection sites, but revealed the heterogeneity of protein expression in snails from the different collection sites and in the process of osmoregulation. It also showed the general tendency of protein reduction when snails where under osmotic stress of either kind (hypo- or hyperosmotic), which supports the hypothesis of storage protein degradation.
The investigation of an ANP-receptor showed two variations of the encoding sequence expressed in T. fluviatilis. S3 individuals as well as BW individuals were found to express one type, while FW individuals, with the exception of one sample expressed the other type. This showed that the FW subgroup of T. fluviatilis seems to be more heterogeneous than the BW subgroup, but also raises the question of the dispersal history of this species. The collected data indicates that T. fluviatilis individuals are firstly capable of surviving the acidity of a duck's gizzard and secondly can tolerate acute salinity changes to 16‰ when introduced into a new environment. Hence, if snails from the FW were to be transported to waters with a salinity of up to 16‰ by man, bird, drifting plants or some other means of transport, they would most likely survive and possibly be able to thrive and spread.
There is an increasingly urgent need to understand and predict how organisms will cope with the environmental consequences of global climate change. Adaptation in any form can be mediated by genetic adaptation and/or by phenotypic plasticity. Disentangling these two adaptive processes is critical in understanding and predicting adaptive responses to environmental change. Usually, disentangling genetic adaptation from phenotypic plasticity requires common garden experiments conducted under controlled laboratory conditions. While these experiments are powerful, it is often difficult to translate the results into natural populations and extrapolate to naturally occurring phenotypic variation. One solution to this problem is provided by the many examples of invasive species that exhibit wide phenotypic variation and that reproduce asexually. Besides selecting the appropriate in situ model, one must carefully choose a relevant trait to investigate. Ecomorphology has been a central theme in evolutionary biology because it reflects how organisms can adapt to their environment through their morphology. Intraspecific ecomorphological studies are especially well suited to identify adaptive pressures and provide insights into the microevolutionary mechanisms leading to the phenotypic differentiation.
One excellent candidate for an intraspecific ecomorphological study aiming to understand adaptation through genetic adaptation and phenotypic plasticity is the invasive New Zealand mudsnail Potamopyrgus antipodarum Gray (1853). This ovoviviparous snail features high variability in shell morphology and has successfully invaded a wide range of fresh- and brackish water habitats around the world. The evolutionary and ecological situations in this species’ native and invasive ranges is drastically different. In New Zealand, P. antipodarum’s native range, sexual and asexual individuals coexist and experience selective pressure by sterilizing endoparasites. By contrast, only a few asexual lineages have been established in invaded regions around the globe, where parasite infection is extremely rare. Here, we took advantage of the low genetic diversity among asexually reproducing European individuals in an attempt to characterize the relative contribution of genetic variation and phenotypic plasticity to the wide variation in shell morphology of this snail.
Analysing the ecomorphology of 425 European P. antipodarum in a geometric-morphometric framework, using brood size as proxy for fecundity, and mtDNA and nuclear SNPs to account for relatedness and identify reproductive mode, we hypothesized that 1) shell variation in the invasive range should be adaptive with respect to colonization of novel habitats, and 2) at least some of the variation might be caused by phenotypic plasticity. We then expanded our ecomorphological scope by analysing 996 native specimens, expecting 1) genetic and morphological diversity to be higher in the native range compared to invaded regions; 2) morphological diversity to be higher in sexual compared to asexual individuals according to the frozen niche hypothesis; and 3) shell morphology to be habitat specific, hence adaptative. In a last part, we used computational fluid dynamics simulations to calculate relative drag and lift forces of three shell morphologies (globular, intermediate, and slender). Here, we tested the overall hypothesis that shell morphology in gastropods is an adaptation against dislodgement through lift rather than drag forces, which would explain the counterintuitive presence of wider shells with shorter spires in lotic environments. With a final flow tank experiment, we tested the specific hypothesis that the dislocation velocity of living snails is positively linked to foot size, and that the latter can be predicted by shell morphology, in particular the aperture area as assumed by several authors.
As expected, we found genetic and morphological diversity to be higher in native than in invasive snails, but surprisingly no higher morphological diversity in sexual versus asexual individuals. The relationships between shell morphology, habitat, and fecundity were complex. Shape variation was primarily linked to genetic relatedness, but specific environmental factors including flow rate induced similar shell shapes. By contrast, shell size was largely explained by environmental factors. Fecundity was correlated with size, but showed trade-offs with shape in increasingly extreme conditions. With increasing flow and in smaller habitats such as springs, the trend of shell shape becoming wider was reversed, i.e. snails with slender shells were brooding more embryos. This increase in fitness was explained by our CFD simulations: in lotic habitats, slender shells experience less drag and lift forces compared to globular shells. We found no correlation between foot size and shell shape or aperture area showing that the assumed aperture/foot area correlation should be used with caution and cannot be generalized for all aquatic gastropod species. Finally, shell morphology and foot size were not related to dislodgement speed in our flow tank experiment. We concluded that the relationship of shell morphology and flow velocity is more complex than assumed. Hence, other traits must play a major role in decreasing dislodgement risk in stream gastropods, e.g. specific behaviours or pedal mucus stickiness. Although we did not find that globular shells are adaptations decreasing dislodgement risk, we cannot rule out that they are still flow related adaptations. For instance, globular shells are more crush-resistant and might therefore represent a flow adaptation in terms of diminishing damage caused by tumbling after dislodgement or against lotic specific crush-type predators.
At this point, we can conclude that shell morphology in P. antipodarum varies at least in part as an adaptation to specific environmental factors. This study shows how essential it is to reveal how plastic, genetically as well as phenotypically, adaptive traits in species can be and to identify the causal factors and how these adaptations affect the fitness in order to better predict how organisms will cope with changing environmental conditions.
In the current era of anthropogenic climate change is the long-term survival of all organisms dependent on their ability to respond to changing environmental conditions either by (1) phenotypic plasticity, which allows species to tolerate novel conditions, (2) genetic adaptation, or (3) dispersal to more suitable habitats. The third option, dispersal, allows individuals to escape unfavorable conditions, the colonization of new areas (resulting in range shifts), and affects patterns of local adaptation. It is a complex process serving different functions and involving a variety of underlying mechanisms, but its multi-causality though has been fully appreciated in recent years only. Thus, the aim of this doctoral thesis was to disentangle the relative importance of the multiple factors relevant to dispersal in the copper butterfly Lycaena tityrus, including the individual condition (e.g. morphology, physiology, behavior) and the environmental context (e.g. habitat quality, weather). L. tityrus is a currently northward expanding species, which makes it particularly interesting to investigate traits underlying dispersal. In the first experiment, the influence of weather and sex on movement patterns under natural conditions was investigated. Using the Metatron, a unique experimental platform consisting of interconnected habitat patches, the second experiment aimed to examine the influence of environmental factors (resources, sun) on emigration propensity in experimental metapopulations. Human-induced global change (e.g. climate change, agricultural intensification) poses a substantial challenge to many herbivores due to a reduced availability or quality of feeding resources. Therefore, in the third experiment, the impact of larval and adult food stress on traits related to dispersal ability was investigated. Additionally, the effect of different ambient temperatures was tested. In the fourth experiment, core (Germany) and recently established edge (Estonia) populations were compared in order to explore variation in dispersal ability and life history traits indicative of local adaptation. Dispersal is often related to flight performance, and morphological and physiological traits, which was investigated in experiments 2-4. Butterflies were additionally subjected to behavioral experiments testing for the individual’s exploratory behavior (experiments 3 and 4).
Males and females differed substantially in morphology, with males showing traits typically associated with a better flight performance, which most likely result from selection on males for an increased flight ability to succeed in aerial combats with rivalling males and competition for females. This pattern could be verified by mobility measures under natural conditions and flight performance tests. Interestingly, although females showed traits associated with diminished flight performance, they had a higher emigration propensity than males (though in a context dependent manner). Reasons might be the capability of single mated females to found new populations, to spread their eggs over a wide range or to escape male harassment. Conditions indicative of poor habitat quality such as shade and a lack of resources promoted emigration propensity. The environmental context also affected condition and flight performance. The presence of resources increased the butterflies’ condition and flight performance. Larval and adult food stress in turn diminished flight performance, despite some reallocation of somatic resources in favor of dispersal-related traits. These detrimental effects seem to be mainly caused by reductions in body mass and storage reserves. A similar pattern was found for exploratory behavior. Furthermore, higher temperatures increased flight performance and mobility in the field, demonstrating the strong dependence of flight, and thus likely dispersal, on environmental conditions. Flight performance and exploratory behavior were positively correlated, probably indicating the existence of a dispersal syndrome. The population comparison revealed several differences between edge and core populations indicative of local adaptation and an enhanced dispersal ability in edge populations. For instance, edge populations were characterized by shorter development times, smaller size, and a higher sensitivity to high temperatures, which seem to reflect adaptations to the cooler Estonian climate and a shorter vegetation period. Moreover, Estonian individuals had an enhanced exploratory behavior, which can be advantageous in all steps of the dispersal process and may have facilitated the current range expansion.
In summary, these findings may have important implications for dispersal in natural environments, which should be considered when trying to forecast future species distributions. First, dispersal in this butterfly seems to be a highly plastic, context-dependent trait triggered largely by habitat quality rather than by individual condition. This suggests that dispersal in L. tityrus is not random, but an active process. Second, fast development and an enhanced exploratory behavior seem to facilitate the current range expansion. But third, while deteriorating habitat conditions are expected to promote dispersal, they may at the same time impair flight ability (as well as exploratory
behavior) and thereby likely dispersal rates. For a complete understanding of a complex process such as dispersal, further research is required.
Sexual selection favours traits that confer a competitive advantage in access to mates and to their gametes. This results in males evolving a wide array of adaptations that may be conflictual with female’s interests and even to collateral negative effects on female’s lifespan or reproductive success. Harmful male adaptations are diverse and can be extreme. For example, males of various species evolved adaptations that incur physical damage to the female during copulation, referred to as traumatic mating. Most of these adaptations provide males with a competitive fertilization advantage due to the injection of sperm or non-sperm compounds through the wound. In the spider taxonomical literature, alterations of external genital structures have been reported in females and may result from male inflicted damage during copulation. Contrarily to other cases of traumatic mating, the transfer of sperm or non-sperm compounds does not seem to be the target of selection for external female genital mutilation (EFGM) to evolve. Therefore, investigating EFGM may provide valuable information to extend our understanding of the evolution of harmful male adaptations. In this thesis, I explore this newly discovered phenomenon and combine empirical and theoretical approaches to investigate the causes and consequences of EFGM evolution from male and female perspectives. My findings suggest that EFGM is a natural phenomenon and is potentially widespread throughout spider taxa. I demonstrate the proximal mechanism by which the male copulatory organ mutilates the external female genitalia during genital coupling and show that the mutilation results in full monopolization of the female as mutilated females are unable to remate. Using a theoretical approach, I investigated the conditions for the evolution of EFGM. The model developed suggests that EFGM evolution is favoured for last male sperm precedence and for costs to females that can be relatively high as the male-male competition increases. I present the results of physiological measurements that suggest there is no physiological cost of genital mutilation resulting from healing and immune responses for the female. Finally, I report the results of a behavioural experiment that suggest that females have control over the mutilation and selectively allow or avoid mutilation. These findings suggest that EFGM benefits males by securing paternity, that males and females may have evolved to reduce the costs incurred by the female and that female choice may also play a role in EFGM evolution.
Most animals live solitarily, but for some species the benefits of group living outweigh the costs and social communities have evolved. Truly social societies are characterized by cooperation in tasks like foraging, predator defense and brood care. In the most extreme cases, non-reproducing individuals act as helpers and provision offspring of reproducing individuals at the cost of their own reproductive success. This alloparental care is attributed to kin selection that provides the helpers with inclusive fitness benefits. However, how reproductive role is determined and in which ways virgin helpers in a group benefit the community is not always well understood.
Spiders are known to be generalist hunters, which in many cases do not shy away from cannibalism. Thus, most spiders live solitarily. However, in a few species a permanently social lifestyle has evolved in which individuals live together throughout their life, providing an intriguing case of social evolution. These spider communities are characterized by lack of premating dispersal leading to extreme inbreeding, by reproductive skew, in which only a proportion of females reproduce and by cooperative breeding of the reproducing females. It has been assumed that the large proportion of virgin females act as helpers not only in foraging and web maintenance but also during brood care. In the social spider Stegodyphus dumicola brood care involves the intensive task of regurgitation feeding, at which mothers regurgitate their own liquefied body tissue. At the end of brood care, the offspring sucks the mothers dry during matriphagy, leading to the death of brood caring females and a semelparous lifestyle. In the closely related solitarily breeding Stegodyphus lineatus virgin females do not provide brood care. The ability of virgin females in S. dumicola to care for offspring would thus depict an adaptation to sociality and cooperative breeding. I therefore aimed to clarify the role and significance of virgin females in colonies of social spiders and furthermore investigated a possible mechanism of how reproductive role within a colony is determined.
I investigated whether there is differential task participation in a non-reproductive task and the task of brood care among reproducing mothers and virgin females (helpers) in Stegodyphus dumicola. The study provides explicit evidence that brood care – including egg sac care, regurgitation feeding and matriphagy – is performed by mothers as well as by virgin helpers. Virgin females in a colony can thus rightfully be termed allomothers. However, the task participation differed between the reproductive states. While mothers engaged more often in brood care, virgin females were more active in foraging. However, the active provisioning of offspring by the virgin females decreases the motherly workload as is suggested by the extended brood care period in comparison to solitary breeders. The observations on virgin allomaternal care are supported by histological studies on the midgut tissue of brood caring females, which revealed that mothers and virgin helpers undergo comparable morphological changes in preparation of regurgitation feeding. The changes in virgin females correlate to ovarian development that might depict an internal maturation process which sets virgin females in the right state to provide care. The morphological changes in mothers and virgin helpers of S. dumicola are less comprehensive than in the solitarily breeding S. lineatus mothers. This indicates that cooperatively caring females are able to save on their resources, provision offspring for longer and thus are probably able to increase survival of the brood by an extended care period. A surprising consequence of cooperative brood care is the ability of mothers to produce a second viable egg sac, even when the first brood is successful. Mothers of the cooperative breeding S. dumicola can thus depart from the strictly semelparous lifestyle and instead invest part of their resources in a second clutch. This finding identified a new way of how cooperative breeding enhances breeding success of reproducers and thus inclusive fitness for helpers as well, thus adding to the benefits of allomaternal care.
Virgin females did not store significantly lower amounts of lipids in their midgut tissue than mothers, raising the question of how much reproductive role of females is determined by competition for resources during growth, as often assumed. Another possible determinant of female reproductive skew is the characteristic male scarcity in spider colonies, with only about 12 percent of spiders being male. Males are assumed to mature early within a few days and die early, thus leaving late maturing females unmated due to lack of mating partners. However, my studies provided evidence that male maturation is more skewed than expected and males might survive several months. Subadult females did not accelerate molting when an adult male was present, which could further indicate, that male presence is not a limiting factor on reproduction in males. Furthermore, males are able copulate with up to 16 females and did not show e preference for large females during mating trials. Males are thus able to fertilize all females, provided all females mature in time. I therefore suggest, that male scarcity is not major determinant of reproductive skew in females, especially in small and middle-sized colonies in which female maturation might only be moderately skewed.
My studies were able to demonstrate the meaning of the large proportion of unmated females in a colony of the social spider S. dumicola. Virgin helpers support mothers during brood care and thus do not only enhance the brood care period but facilitate mothers to produce multiple clutches. Virgin females are able to care as they undergo similar morphological changes as mothers’ do. This seems to be facilitated by an internal maturation process, indicated by ovarian development and oviposition by virgin females, both of which has never been observed in virgins of the subsocial species. How reproductive role is determined remains unclear, but I was able to exclude male scarcity as a major factor influencing reproductive skew.
Analysis of partial migration strategies of Central European raptors based on ring re-encounter data
(2018)
The phenomenon of partial migration in birds in
which some individuals of a population are migratory while others stay in the breeding area is of increasing scientific interest. The strategies of partial migratory raptors from Central Europe are, however, unclear for most species. We analysed ring re-encounter data of Common Kestrels Falco tinnunculus, Eurasian Sparrowhawks Accipter nisus and Common Buzzards Buteo buteo ringed in Germany in terms of distances and directions between ringing and re-encounter sites. We investigated possible differences between sexes and age classes, as well as effects of ringing region, seasonal weather (in the form of North Atlantic Oscillation indices) and long-term temporal changes (including climate change) on migratory strategies by means of generalized linear models. We found that migration is mostly conducted by juveniles, although migratory adults were also found. In general, males tend to migrate less than females and juveniles less than adults.
Kestrels showed differences between age classes and sexes and they responded to weather in summer and autumn. The migration activities of Kestrels decreased over years. Sparrowhawks from different regions showed no differences in migration activity and no responses to long-term temporal changes. They did not respond to seasonal weather either. Buzzards showed strong responses to winter weather (‘winter escapes’) predominantly in highland regions, and a reduction of migratory intensity probably due to global warming.
The explanatory power of ringing data, however, is limited by low re-encounter rates and temporal and spatial heterogeneity in re-encounter probability. Spatial heterogeneity mainly depends on the distribution of observers as well as on their willingness to report a re-encountered ring to the corresponding ringing scheme. We analyzed a data set of ringing and re-encounter data of Kestrels, Buzzards and Sparrowhawks provided by the EURING Data Bank. We calculated monthly re-encounter rates across Europe and, for different time periods, we predicted re-encounters for individuals of these species ringed in Germany, on the assumption that re-encounter probabilities are evenly distributed at the highest value observed within the respective home ranges. Subsequently, we tested for correlation between re-encounter rates and human population density. The number of predicted re-encounters exceed the observed by 50-300 %. We found differences between monthly re-encounter rates and between different prediction periods. Distances (between ringing and re-encounter sites) differ significantly between observations and predicted re-encounters, with higher distances in predictions. Correlation between re-encounter rates and human population density is significant, but correlation coefficients are low (ρ = 0.291-0.511). Correcting for observer heterogeneity can help to analyze ring re-encounter data e.g. in terms of dispersal and migration. However, a comprehensive data collection and a digitalization of possible prior data records by the respective ringing schemes may allow advances in this method even further.