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Scents as Floral Defence : Impact on Species and Communities, Mechanisms and Ecological Consequences
(2010)
Floral scents are compositions of diverse volatile substances. Despite the chemical complexity, the interpretation of their ecological relevance was mostly confined to the attractive function facilitating interactions with pollinators. However, the negative impact on plants’ reproduction by non-pollinating flower visitors is pronounced and demands floral adaptations that exclude antagonists. The aim of this dissertation was to explore the defensive properties of floral odours and to imbed them into ecological contexts. The thesis covered four scopes: the scents’ impact on individual species and on flower-visitor communities, the mechanisms that explain the dual function of floral volatiles (attraction and defence), and the ecological consequences of missing defences for plants and pollinators. The most important floral antagonists that are known to reduce the reproductive fitness of plants were identified and their responses towards floral scents were examined. We found that representatives of non‐pollinating florivores (bush crickets), predators that lure for pollinators (spiders), and microorganisms that potentially colonize petals were repelled, deterred or inhibited in their growth by floral secondary metabolites. An earlier study revealed the same effect on nectar thieving ants. These experimental studies clearly demonstrate that scents universally serve as floral defences that have the potential to reduce or even prevent the visitation and exploitation of flowers by these antagonists. Within diverse communities, we tested whether species‐specific responses to odours reflect the structure of naturally occurring flower-visitor interactions in order to examine the ecological importance of defensive floral scents. On three Hawaiian Islands, ant-flower interactions involving co-occurring native and introduced plants were observed. Ants were historically absent from the geographically isolated Hawaiian archipelago. Thus, we hypothesized that native Hawaiian plants lack floral features that exclude ants and therefore would be heavily exploited by introduced, invasive ants. We quantified the residual interaction strength of each pair of ant/plant species as the deviation of the observed interaction frequency from a null-model prediction based on available nectar sugar in a local plant community and local ant activity at sugar baits. As predicted, flowers of plants that are endemic or indigenous to Hawaii were stronger exploited by ants than flowers of co- occurring introduced plants, which share an evolutionary history with ants. We showed experimentally that the absence of ants on flowers of most introduced and few native plants species was due to morphological barriers and/or repellent floral scents, examined in a mobile olfactometer. Analysis of floral volatiles, however, revealed no consistent ant- repellent “syndrome”, probably due to the high chemical variability within the floral scent bouquets. On a fallow land in Germany, we linked the responses of receivers (flower visitors) towards signals (flower scent) with the structure of a highly diverse natural flower-insect network. For each interaction, we defined link temperature – a newly developed metric – as the deviation of the observed interaction strength from neutrality, assuming that animals randomly interact with flowers. Link temperature was positively correlated to the specific visitors' responses to floral scents. Thus, communication between plants and consumers via phytochemical signals reflects a significant part of the microstructure in a complex network. Negative as well as positive responses towards floral scents contributed to these results, where individual experience was important, apart from innate behaviour. The demonstration of the contrasting functions of floral scents that control the visitor spectrum of flowers represents the first evidence that floral scents act as filters allowing access to some flower visitors but simultaneously exclude others. These findings raise the central question of this thesis: what evolutionary mechanism explains the dual function of floral scents? The view of flower visitors as mutualistic and antagonistic agents considers primarily the interest of plants. A classification emphasizing the consumer’s point of view, however, may be more useful when considering adaptations of animals to flower visits. Therefore, we introduced a novel classification that acknowledges the consumers’ interest in the interaction: some animals evolved an obligate dependence on floral resources, others use nectar and pollen as supplement to their diet and are thus regarded as facultative flower visitors. In a meta-analysis covering 18 studies on the responses of animals to floral scents, we assigned the animals to the categories of obligate or facultative flower visitors. Their responses to floral scents were compared. On average, obligate flower visitors, often corresponding to pollinators, were attracted to floral scent compounds. In contrast, facultative and mainly antagonistic visitors were strongly repelled by flower odours. The findings confirm that floral scents have a dual function both as attractive and defensive cues. Whether an animal depends on floral resources determines its response to these signals, suggesting that obligate flower visitors evolved a tolerance against primarily defensive compounds. These findings were confirmed in an experimental study. We conclude that floral scents protect flowers against visitors that would otherwise reduce the reproductive success of plants. In Hawaii, where flowers do not have defensive means against ants, we studied the impact of ants on the pollination effectiveness of endemic and introduced bees and on the fruit set of an endemic tree Metrosideros polymorpha (Myrtaceae). Ants were dominant nectar-consumers that mostly depleted the nectar of visited inflorescences. Accordingly, the visitation frequency, duration, and consequently the pollinator effectiveness of nectar-foraging bees strongly decreased on ant-visited flowers, whereas pollen-collecting bees remained largely unaffected by ants. Overall, endemic bees (Hylaeus spp.) were much poorer pollinators than introduced honeybees (Apis mellifera). The average net effect of ants on pollination of M. polymorpha was neutral, corresponding to a similar fruit set of ant-visited and ant-free inflorescences. A second Hawaiian plant species, Vaccinium reticulatum (Ericaceae), was visited by the caterpillars of an introduced plume moth (Stenoptilodes littoralis) that destroyed buds and flowers of this species. The ants’ presence on flowers strongly reduced flower parasitism by the caterpillars and consequently decreased the loss of flowers and buds. This is, to our knowledge, the first documented mutualism between invasive ants and an endemic plant species in Hawaii. Thus, ants that have been shown to be detrimental flower visitors elsewhere, had neutral (M. polymorpha) or even positive (V. reticulatum) effects on endemic Hawaiian plants. However, their overall negative effect on the Hawaiian flora and fauna should not be disregarded.
Merkel cell carcinoma (MCC) is an aggressive neuroendocrine skin cancer that has been associated with the Merkel cell polyomavirus (MCPyV). Indeed, MCC is one of the cancers with the best-established viral carcinogenesis. Despite persistence of the virus in MCC cells and the subsequent expression of viral antigens, the majority of MCC tumors are able to escape the surveillance of the immune system. Therefore the aim of the here presented thesis was to scrutinize immune escape mechanisms operative in MCC. A better understanding of their underlying molecular processes should allow to improve immunotherapeutic treatment strategies for MCC patients. The manuscripts included in this thesis characterize three novel immune evasion strategies of MCC.
I) the epigenetic silencing of the NKG2D ligands MICA and MICB via histone H3 hypoacetylation
II) reduced HLA class I surface expression via epigenetic silencing of the antigen processing machinery (APM)
III) the activation of the PI3K-AKT pathway in a mutation independent manner as potential immune escape strategy
MCC tumors and MCC cell lines were analyzed for their expression of MICA/B, HLA and components of the antigen processing machinery as well as for the activation of the PI3K-AKT pathway in situ and in vitro. These analysis reviled MICA and MICB, as well as HLA class I were not expressed or at least markedly reduced in ~80% of MCCs in situ. The PI3K-AKT pathway, that had only recently been demonstrated to play a significant role in tumor immune escape, was activated in almost 90% of MCCs in situ. To determine the underlying molecular mechanisms of these aberrations well characterized MCC cell lines were further analyzed in vitro. The fact that the PI3K-AKT pathway activation was due to oncogenic mutations in the PIK3CA or AKT1 gene in only 10% of MCCs, suggested an epigenetic regulation of this pathway in MCC. In line with this MICA/B as well as components of the APM were indeed silenced epigenetically via histone hypoacetylation in their respective promoter region. Notably MICA/B and HLA class I expression on the cell surface of MCC cells could be restored after treatment with HDAC inhibitors in combination with the Sp1 inhibitor Mithramycin A in all analyzed MCC cell lines in vitro and in a xenotransplantation mouse model in vivo. Moreover inhibition of HDACs increased immune recognition of MCC cell lines in a MICA/B and HLA class I dependent manner.
Several studies have accumulated evidence that immunotherapy is a promising treatment option for MCC patients due to the exquisite immunogenicity of this malignancy. However, current immunotherapeutic interventions towards solid tumors like MCC have to account for the plentitude of tumor immune escape strategies, in order to increase response rates. The immune escape mechanisms of MCC described in this thesis can be reverted by HDAC inhibition, thus providing the rationale to combine ‘epigenetic priming’ with currently tested immunotherapeutic regimens.
Microtubules are a fascinating component of the cellular scaffold protein network, the cytoskeleton. These hollow tubular structures are assembled of laterally associated proto-filaments containing ab-tubulin heterodimers in a head to tail arrangement. Accordingly microtubules have a defined polarity, which sets the base for the polarity of the cell. The microtubule lattice can be arranged in two conformations: In the more abundant B-lattice conformation, where the protofilaments interact laterally through a- to a- and b- to b-tubulin contacts and in the less stable A-lattice conformation, where a-tubulin interacts laterally with b-tubulin. In cells the microtubules generally contain 13 protofilaments of which usually one pair interacts in the A-lattice conformation, forming the so-called lattice seam. Microtubule dynamics and interactions are strongly regulated by micro-tubule associate proteins (MAPs). Structural investigations on MAPs and microtubule associated motor proteins in complex with microtubules have become possible in combination with modern electron microscopy (EM) and image processing. We have used biochemistry and different advanced EM techniques to study the interaction between microtubules and the MAP Mal3p in vitro. Mal3p is the sole member of the end-binding protein 1 (EB1) protein family in the fission yeast Schizosaccharomyces pombe. Previous in vivo studies have shown that Mal3p promotes microtubule growth. Our studies with high-resolution unidirectional shadowing EM revealed that Mal3p interacts with the microtubule lattice in a novel way, using binding sites on the microtubule that are different from those reported for other MAPs or motor proteins. Full-length Mal3p preferentially binds between two protofilaments on the microtubule lattice, leaving the rest of the lattice free. A case where Mal3p was found in two adjacent protofilament, revealed an A-lattice conformation on the microtubules, surprisingly indicating specific binding of Mal3p to the microtubule seam. With a lattice enhancer, in form of a b-tubulin binding kinesin motor domain, it was demonstrated that Mal3p stabilizes the seam which is thought to be the weakest part of a microtubule. Further, the presence of Mal3p during microtubule polymerization enhances the closure of protofilament sheets into a tubular organization. Cryo-EM and 3-D helical reconstruction on a monomeric microtubule binding domain of Mal3p, confirm the localization in between the protofilament and result in an accurate localization on the microtubule lattice. The results also indicate Mal3p’s capacity to influence the microtubule lattice conformation. Together, studies approached in vitro demonstrate that an EB1-family homolog not only interacts with the microtubule plus end, but also with the microtubule lattice. The structure of Mal3p interacting with microtubules reveals a new mechanism for microtubule stabilization and further insight on how plus end binding proteins are able promote microtubule growth. These findings further suggest that microtubules exhibit two distinct reaction platforms on their surface that can independently interact with selected MAPs or motors.
The obligate human pathogen Neisseria gonorrhoeae is responsible for the widespread sexually transmitted disease gonorrhoea, which in rare cases also leads to the development of disseminated gonococcal infection (DGI). DGI is mediated by PorBIA-expressing bacteria that invade host cells under low phosphate condition by interaction with the scavenger receptor-1 (SREC-I) expressed on the surface of endothelial cells. The interaction of PorBIA and SREC-I was analysed using different in vitro approaches, including surface plasmon resonance experiments that revealed a direct phosphate-independent high affinity interaction of SREC-I to PorBIA. However, the same binding affinity was also found for the other allele PorBIB, which indicates unspecific binding and suggests that the applied methods were unsuitable for this interaction analysis.
Since N. gonorrhoeae was recently classified as a “super-bug” due to a rising number of antibiotic-resistant strains, this study aimed to discover inhibitors against the PorBIA-mediated invasion of N. gonorrhoeae. Additionally, inhibitors were searched against the human pathogen Chlamydia trachomatis, which causes sexually transmitted infections as well as infections of the upper inner eyelid. 68 compounds, including plant-derived small molecules, extracts or pure compounds of marine sponges or sponge-associated bacteria and pipecolic acid derivatives, were screened using an automated microscopy based approach. No active substances against N. gonorrhoeae could be identified, while seven highly antichlamydial compounds were detected.
The pipecolic acid derivatives were synthesized as potential inhibitors of the virulence-associated “macrophage infectivity potentiator” (MIP), which exhibits a peptidyl prolyl cis-trans isomerase (PPIase) enzyme activity. This study investigated the role of C. trachomatis and N. gonorrhoeae MIP during infection. The two inhibitors PipN3 and PipN4 decreased the PPIase activity of recombinant chlamydial and neisserial MIP in a dose-dependent manner. Both compounds affected the chlamydial growth and development in epithelial cells. Furthermore, this work demonstrated the contribution of MIP to a prolonged survival of N. gonorrhoeae in the presence of neutrophils, which was significantly reduced in the presence of PipN3 and PipN4.
SF2446A2 was one of the compounds that had a severe effect on the growth and development of C. trachomatis. The analysis of the mode of action of SF2446A2 revealed an inhibitory effect of the compound on the mitochondrial respiration and mitochondrial ATP
production of the host cell. However, the chlamydial development was independent of proper functional mitochondria, which excluded the connection of the antichlamydial properties of SF2446A2 with its inhibition of the respiratory chain. Only the depletion of cellular ATP by blocking glycolysis and mitochondrial respiratory chain inhibited the chlamydial growth. A direct effect of SF2446A2 on C. trachomatis was assumed, since the growth of the bacteria N. gonorrhoeae and Staphylococcus aureus was also affected by the compound.
In summary, this study identified the severe antichlamydial activity of plant-derived naphthoquinones and the compounds derived from marine sponges or sponge-associated bacteria SF2446A2, ageloline A and gelliusterol E. Furthermore, the work points out the importance of the MIP proteins during infection and presents pipecolic acid derivatives as novel antimicrobials against N. gonorrhoeae and C. trachomatis.
Insects living in temperate latitudes need to adjust their life-history to a seasonally variable environment. Reproduction, growth, and development have to be completed within the limited period where environmental conditions are favourable while climatically adverse conditions have to be spent in a state of diapause. Consequently, questions how individuals adapt their life-history to seasonality and which mechanisms underlie the responses to seasonal cues, like photoperiod, are important issues in the study of life-history strategies. This thesis focuses on the life-history adaptation to seasonality in the wing-dimorphic common pond skater Gerris lacustris L. (Heteroptera: Gerridae). Using a combination of field and laboratory studies as well as mathematical modelling, it is adressed how variation in the availability of thermal energy impacts on various aspects of larval development such as accumulated thermal energy (i.e. physiological development time), developmental pathway (direct reproduction vs. diapause) and wing dimorphism.
Biodiversity may be investigated and explored by the means of genetic sequence information and molecular phylogenetics. Yet, with ribosomal genes, information for phylogenetic studies may not only be retained from the primary sequence, but also from the secondary structure. Software that is able to cope with two dimensional data and designed to answer taxonomic questions has been recently developed and published as a new scientific pipeline. This thesis is concerned with expanding this pipeline by a tool that facialiates the annotation of a ribosomal region, namely the ITS2. We were also able to show that this states a crucial step for secondary structure phylogenetics and for data allocation of the ITS2-database. This resulting freely available tool determines high quality annotations. In a further study, the complete phylogenetic pipeline has been evaluated on a theoretical basis in a comprehensive simulation study. We were able to show that both, the accuracy and the robustness of phylogenetic trees are largely improved by the approach. The second major part of this thesis concentrates on case studies that applied this pipeline to resolve questions in taxonomy and ecology. We were able to determine several independent phylogenies within the green algae that further corroborate the idea that secondary structures improve the obtainable phylogenetic signal, but now from a biological perspective. This approach was applicable in studies on the species and genus level, but due to the conservation of the secondary structure also for investigations on the deeper level of taxonomy. An additional case study with blue butterflies indicates that this approach is not restricted to plants, but may also be used for metazoan phylogenies. The importance of high quality phylogenetic trees is indicated by two ecological studies that have been conducted. By integrating secondary structure phylogenetics, we were able to answer questions about the evolution of ant-plant interactions and of communities of bacteria residing on different plant tissues. Finally, we speculate how phylogenetic methods with RNA may be further enhanced by integration of the third dimension. This has been a speculative idea that was supplemented with a small phylogenetic example, however it shows that the great potential of structural phylogenetics has not been fully exploited yet. Altogether, this thesis comprises aspects of several different biological disciplines, which are evolutionary biology and biodiversity research, community and invasion ecology as well as molecular and structural biology. Further, it is complemented by statistical approaches and development of informatical software. All these different research areas are combined by the means of bioinformatics as the central connective link into one comprehensive thesis.
Leonia cymosa (Violaceae) is a small tree from the under story of the Amazonian rain forest. I investigated the seed dispersal ecology of L. cymosa in plots of old growth terra firme forest located within the Cuyabeno Faunistic Reserve in north-eastern Ecuador. This species offered good conditions to examine the variation of traits of individual trees and the way they are linked with fruit removal from each tree. With this study I aimed to address the question whether frugivores exert selection pressures on fruits and the fruiting regime of fleshy fruited plants. The mean height of a fruiting L. cymosa was 6.6 m (range: 2 - 12.6 m). The median tree density was 11.8 trees per hectare. Trees grew in clusters consisting of different numbers of trees of different heights. L. cymosa flowered two times a year, in late February to March and in October. The respective fruiting seasons occurred in August/September and between March and May. The fruit pulp of L. cymosa contained the sugars fructose, glucose, and sucrose, the total soluble sugar being the first important nutritional compound of the fruit pulp. The second important compound was proteins. No lipids were found in the fruit pulp. The variation of nutritional quality of the fruits was high within trees. Nonetheless, significant differences were found among trees in all nutrient constituents studied. The maximum of ripe fruits produced per season by a single tree was 427. Median productivity of the trees was 45 ripe fruits throughout the fruiting season in 1999 (n=57) and 36 ripe fruits in 2000 (n=92). The maximum standing crop of fruits in a tree was 324 fruits (counted in 2000). Black mantle tamarins, Saguinus nigricollis (Callitrichidae), and squirrel monkeys, Saimiri sciureus (Cebidae), and possibly an unknown nocturnal frugivore consumed the fruits of L. cymosa at my study site. Green-rumped acouchis (Myoprocta pratti, Dasyproctidae) consumed fallen fruits and seeds underneath the trees. Black mantle tamarins and squirrel monkeys differed widely in their effectiveness as seed dispersers. Black mantle tamarins swallowed the seeds together with the fruit pulp and defecated intact seeds far away from the mother tree. Squirrel monkeys opened the fruits to suck and gnaw on the fruit pulp, and then dropped seeds to the forest floor below the tree crowns. Each of my study plots fell into the core home range of one group each of S. nigricollis and S. sciureus. Thus, the frugivore assemblage is small and disperser availability is limited for the individual tree of L. cymosa. In a sample of 6 trees of comparable and high fruit crop size, the total of ripe fruits removed from a tree throughout the whole fruiting season by the reliable seed disperser S. nigricollis was neither significantly correlated with the content of any of the nutrients measured in the fruit pulp (fructose, glucose, sucrose, total protein; pulp does not contain lipids), nor with total metabolisable energy, seed to pulp weight ratio, or water content of the fruit pulp. Feeding preferences for single sugars determined by other laboratory studies were not confirmed by this field study. The reliable seed disperser S. nigricollis does not seem to exert selective pressure on the nutrient content of the fruits of L. cymosa. Seasonal fruit crop size was the main predictor of all aspects of fruit removal by the effective disperser of L. cymosa, Saguinus nigricollis, as well as by the non-disperser, Saimiri sciureus. Trees with larger seasonal fruit crop size had a higher probability to have fruits removed by the disperser than those with small seasonal fruit crop sizes. They also had a higher number of fruits removed by the seed disperser. However, the proportion of fruits removed by the disperser decreased with increasing seasonal fruit crop size. In contrast, probability of fruit removal, the number of fruits removed, and the proportion of fruits removed by the non-disperser increased with increasing seasonal fruit crop sizes. The observed differences between disperser and non-disperser are due to differences in feeding capacity, group size and foraging behavior. Tamarins were less likely to harvest Leonia trees that were not or less completely covered by surrounding vegetation. This probably reflects a behavior to avoid predation by forest raptors. At high con-specific fruit abundance in the neighborhood, the proportion of fruits removed by tamarins was reduced. This suggests competition of trees for the disperser. My study revealed selection of the disperser on seasonal fruit crop size of L. cymosa. My results are consistent with the “fruit crop size hypothesis”. FCSH appears to constitute a valid framework also in the monkey-dispersed L. cymosa. My findings also show that factors beyond the tree’s control influenced fruit removal from Leonia trees. Disperser-mediated selection may be constrained (yet not impeded) by neighborhood conditions.
Deregulated MYC expression contributes to cellular transformation as well as progression and
maintenance of human tumours. Interestingly, in the absence of additional genetic alterations,
potentially oncogenic levels of MYC sensitise cells to a variety of apoptotic stimuli. Hence, MYC-induced
apoptosis has long been recognised as a major barrier against cancer development.
However, it is largely unknown how cells discriminate physiological from supraphysiological levels
of MYC in order to execute an appropriate biological response.
The experiments described in this thesis demonstrate that induction of apoptosis in mammary
epithelial cells depends on the repressive actions of MYC/MIZ1 complexes. Analysis of gene
expression profiles and ChIP-sequencing experiments reveals that high levels of MYC are required
to invade low-affinity binding sites and repress target genes of the serum response factor SRF.
These genes are involved in cytoskeletal dynamics as well as cell adhesion processes and are likely
needed to transmit survival signals to the AKT kinase. Restoration of SRF activity rescues MIZ1-
dependent gene repression and increases AKT phosphorylation and downstream function.
Collectively, these results indicate that association with MIZ1 leads to an expansion of MYC’s
transcriptional response that allows sensing of oncogenic levels, which points towards a tumour-suppressive
role for the MYC/MIZ1 complex in epithelial cells.
Leaf-cutting ants have a highly developed thermal sense which the insects use to regulate the own body temperature and also to optimize brood and fungus development. Apart from the already described temperature guided behaviors inside the nest it is unknown to what extent the ants may use their thermal sense outside the nest. As part of the present thesis, the question was addressed whether leaf-cutting ants (Atta vollenweideri) are able to learn the position of a warm object as landmark for orientation during foraging. Using absolute conditioning, it was shown that ten training trials are sufficient to elicit the association be-tween food reward and the temperature stimulus. In the test situation (without reward) a significantly higher amount of ants preferred the heated site compared to the unheated con-trol. Importantly, thermal radiation alone was sufficient to establish the learned association and served as orientation cue during the test situation (chapter IV). Based on the experi-mental design used in the previous chapter, the localization of thermosensitive neurons, which detect the underlying thermal stimuli, is restricted to the head or the antennae of the ants. The antennal sensillum coeloconicum is a potential candidate to detect the thermal stimuli during the orientation behavior. In chapter V the sensillum coeloconicum of Atta vollenweideri was investigated concerning its gross morphology, fine-structure and the phy-siology of the associated thermosensitive neuron. The sensillum is predominantly located on the apical antennal segment (antennal tip) where around 12 sensilla are clustered, and it has a peg-in-pit morphology with a double walled, multiporous peg. The sensory peg is deeply embedded in a cuticular pit, connected to the environment only by a tiny aperture. The sen-sillum houses three receptor neurons of which one is thermosensitive whereas the sensory modality of the other two neurons remains to be shown. Upon stimulation with a drop in temperature, the thermosensitve neuron responds with a phasic-tonic increase in neuronal activity (cold-sensitive neuron) and shows rapid adaptation to prolonged stimulation. In ad-dition, it is shown that thermal radiation is an effective stimulus for the thermosensitive neuron. This is the first evidence that sensilla coeloconica play an important role during the thermal orientation behavior described in chapter IV. During the test situation of the classic-al conditioning paradigm, the ants showed rapid antennal movements, indicating that they scan their environment in order to detect the heated object. Rapid antennal movements will result in rapid discontinuities of thermal radiation that re-quire thermosensitive neurons with outstanding sensitivity and high temporal resolution. In Chapter VI the question was addressed whether the thermosensitive neuron of the sensilla coeloconica fulfils these preconditions. Extracellular recordings revealed that the neuron is extremely sensitive to temperature transients and that, due to the response dynamics, an estimated stimulus frequency of up to 5 Hz can be resolved by the neuron. Already a tem-perature increase of only 0.005 °C leads to a pronounced response of the thermosensitive neuron. Through sensory adaptation, the sensitivity to temperature transients is maintained over a wide range of ambient temperatures. The discovered extreme sensitivity, the high temporal resolution and the pronounced adaptation abilities are further evidence support-ing the idea that sensilla coeloconica receive information of the thermal environment, which the ants may use for orientation. In order to understand how the ants use their thermal environment for orientation, it is ne-cessary to know where and how thermal information is processed in their central nervous system. In Chapter VII the question is addressed where in the brain the thermal information, specifically received by the thermosensitive neuron of sensilla coeloconica, is represented. By selectively staining single sensilla coeloconica, the axons of the receptor neurons could be tracked into the antennal lobe of Atta vollenweideri workers. Each of the three axons termi-nated in a single functional unit (glomerulus) of the antennal lobe. Two of the innervated glomeruli were adjacent to each other and are located lateral, while the third one was clear-ly separate and located medial in the antennal lobe. Using two-photon Ca2+ imaging of an-tennal lobe projection neurons, the general representation of thermal information in the antennal lobe was studied. In 11 investigated antennal lobes up to six different glomeruli responded to temperature stimulation in a single specimen. Both, warm- and cold-sensitive glomeruli could be identified. All thermosensitive glomeruli were located in the medial half of the antennal lobe. Based on the correlative evidence of the general representation of thermal information and the results from the single sensilla stainings, it is assumed that thermal information received by sensilla coeloconica is processed in the medial of the three target glomeruli. This part of the thesis shows the important role of the antennal lobe in temperature processing and links one specific thermosensitive neuron to its target region (a single glomerulus). In chapter V it was shown that the sensilla coeloconica are clustered at the antennal tip and have an extraordinary peg-in-pit morphology. In the last chapter of this thesis (Chapter VIII) the question is addressed whether the morphology of the sensilla coeloconica predicts the receptive field of the thermosensitive neuron during the detection of thermal radiation. The sensory pegs of all sensilla coeloconica in the apical cluster have a similar orientation, which was not constraint by the shape of the antennal tip where the cluster is located. This finding indicates that the sensilla coeloconica function as a single unit. Finally the hypothesis was tested whether a single sensillum could be direction sensitive to thermal radiation based on its eye-catching morphology. By stimulating the thermosensitive neuron from various angles around the sensillum this indeed could be shown. This is the last and most significant evi-dence that the sensilla coeloconica may be adapted to detect spatially distributed heated objects in the environment during the thermal landmark orientation of ants.
The study examines the sensory ecology of CO2 perception in leaf-cutting ants. It begins with the ecological role of CO2 for leaf-cutting ants. Inside the subterranean nests of Atta vollenweideri large amounts of CO2 are produced by the ants and their symbiotic fungus. Measurements in field nest at different depths revealed that CO2 concentrations do not exceed 2 per cent in mature nests. These findings indicate effective ventilation even at depths of 2 m. Small colonies often face the situation of reduced ventilation when they close their nest openings as a measure against flooding. A simulation of this situation in the field as well as in the laboratory revealed increasing CO2 concentrations causing reduced colony respiration which ultimately might limit colony success. Wind-induced ventilation is the predominant ventilation mechanism of the nests of Atta vollenweideri, shown by an analysis of external wind and airflow in the channels. The mound architecture promotes nest ventilation. Outflow channels have their openings in the upper, central region and inflow channels had their openings in the lower, peripheral region of the nest mound. Air is sucked out through the central channels, followed by a delayed inflow of air through the peripheral channels. The findings support the idea that the nest ventilation mechanism used by Atta vollenweideri resembles the use of Bernoulli’s principle in Venturi Tubes and Viscous Entrainment. CO2 is important in a second context besides microclimatic control. A laboratory experiment with Atta sexdens demonstrated that leaf-cutting ants are able to orientate in a CO2 gradient. Foragers chose places with higher CO2 concentration when returning to the nest. This effect was found in all homing foragers, but it was pronounced for workers carrying leaf fragments compared to workers without leaf fragments. The findings support the hypothesis that CO2 gradients are used as orientation cue inside the (dark) nest to find suited fungus chambers for unloading of the leaf fragments. After the importance of CO2 in the natural history of the ants has thus been demonstrated, the study identifies for the first time in Hymenoptera type and location of the sensory organ for CO2 perception. In Atta sexdens a single neuron associated with the sensilla ampullacea was found to respond to CO2. Since it is the only neuron of this sensillum, the sensillum characters can be assumed to be adapted for CO2 perception. A detailed description of the morphology and the ultrastructure allows a comparison with sensilla for CO2 perception found in other insects and provides more information about sensillum characters and their functional relevance. The CO2 receptor cells respond to increased CO2 with increased neural activity. The frequency of action potentials generated by the receptor cell shows a phasic-tonic time course during CO2 stimulation and a reduced activity after stimulation. Phasic response accomplished with a reduced activity after stimulation results in contrast enhancement and the ability to track fast fluctuations in CO2 concentration. The neurons have a working range of 0 to 10 per cent CO2 and thus are able to respond to the highest concentrations the ants might encounter in their natural environment. The most exciting finding concerning the receptor cells is that the CO2 neurons of the leaf-cutting ants do not adapt to continuous stimulation. This enables the ants to continuously monitor the actual CO2 concentration of their surroundings. Thus, the sensilla ampullacea provide the ants with the information necessary to orientate in a CO2 gradient (tracking of fluctuations) as well as with the necessary information for microclimatic control (measuring of absolute concentrations).