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The present work investigates the influence of environmental stimuli on the building behavior of workers of the leaf-cutting ant Atta vollenweideri. It focuses on cues related to the airflow-driven ventilation of their giant underground nests, i.e., air movements and their direction, carbon dioxide concentrations and humidity levels of the nest air. First, it is shown that workers are able to use airflow and its direction as learned orientation cue by performing learning experiments with individual foragers using a classical conditioning paradigm. This ability is expected to allow workers to also navigate inside the nest tunnels using the prevailing airflow directions for orientation, for example during tasks related to nest construction and climate control.
Furthermore, the influence of carbon dioxide on the digging behavior of workers is investigated. While elevated CO2 levels hardly affect the digging rate of the ants, workers prefer to excavate at locations with lower concentrations and avoid higher CO2 levels when given a choice. Under natural conditions, shifting their digging activity to soil layers containing lower carbon dioxide levels might help colonies to excavate new or to broaden existing nest openings, if the CO2 concentration in the underground rises.
It is also shown that workers preferably transport excavated soil along tunnels containing high CO2 concentrations, when carbon dioxide levels in the underground are elevated as well. In addition, workers prefer to carry soil pellets along outflow tunnels instead of inflow tunnels, at least for high humidity levels of the air. The material transported along tunnels providing outflow of CO2-rich air might be used by workers for the construction of ventilation turrets on top of the nest mound, which is expected to promote the wind-induced ventilation and the removal of carbon dioxide from the underground.
The climatic conditions inside the nest tunnels also influence the structural features of the turrets constructed by workers on top the nest. While airflow and humidity have no effect on turret structure, outflow of CO2-rich air from the nest causes workers to construct turrets with additional openings and increased aperture, potentially enhancing the airflow-driven gas exchanges within the nest.
Finally, the effect of airflow and ventilation turrets on the gas exchanges in Atta vollenweideri nests is tested experimentally on a physical model of a small nest consisting of a single chamber and two nest tunnels. The carbon dioxide clearance rate from the underground was measured depending on both the presence of airflow in the nest and the structural features of the built turrets. Carbon dioxide is removed faster from the physical nest model when air moves through the nest, confirming the contribution of wind-induced flow inside the nest tunnels to the ventilation of Atta vollenweideri nests. In addition, turrets placed on top of one of the tunnel openings of the nest further enhance the CO2 clearance rate and the effect is positively correlated with turret aperture.
Taken together, climatic variables like airflow, carbon dioxide and humidity levels strongly affect the building responses of Atta vollenweideri leaf-cutting ants. Workers use these environmental stimuli as orientation cue in the nest during tasks related to excavation, soil transport and turret construction. Although the effects of these building responses on the microclimatic conditions inside the nest remain elusive so far, the described behaviors are expected to allow ant colonies to restore and maintain a proper nest climate in the underground.
Background: Successful cooperation depends on reliable identification of friends and foes. Social insects discriminate colony members (nestmates/friends) from foreign workers (non-nestmates/foes) by colony-specific, multi-component colony odors. Traditionally, complex processing in the brain has been regarded as crucial for colony recognition. Odor information is represented as spatial patterns of activity and processed in the primary olfactory neuropile, the antennal lobe (AL) of insects, which is analogous to the vertebrate olfactory bulb. Correlative evidence indicates that the spatial activity patterns reflect odor-quality, i.e., how an odor is perceived. For colony odors, alternatively, a sensory filter in the peripheral nervous system was suggested, causing specific anosmia to nestmate colony odors. Here, we investigate neuronal correlates of colony odors in the brain of a social insect to directly test whether they are anosmic to nestmate colony odors and whether spatial activity patterns in the AL can predict how odor qualities like ‘‘friend’’ and ‘‘foe’’ are attributed to colony odors. Methodology/Principal Findings: Using ant dummies that mimic natural conditions, we presented colony odors and investigated their neuronal representation in the ant Camponotus floridanus. Nestmate and non-nestmate colony odors elicited neuronal activity: In the periphery, we recorded sensory responses of olfactory receptor neurons (electroantennography), and in the brain, we measured colony odor specific spatial activity patterns in the AL (calcium imaging). Surprisingly, upon repeated stimulation with the same colony odor, spatial activity patterns were variable, and as variable as activity patterns elicited by different colony odors. Conclusions: Ants are not anosmic to nestmate colony odors. However, spatial activity patterns in the AL alone do not provide sufficient information for colony odor discrimination and this finding challenges the current notion of how odor quality is coded. Our result illustrates the enormous challenge for the nervous system to classify multi-component odors and indicates that other neuronal parameters, e.g., precise timing of neuronal activity, are likely necessary for attribution of odor quality to multi-component odors.
Ants of the species Camponotus floridanus live in huge colonies composed of genetically identical or closely related animals, which should predispose them to an increased vulnerability towards infection by pathogens (Cremer et al. 2007). Therefore the question is how ants (or social insects in general) can nevertheless efficiently combat infections. In order to investigate the immune response of the ant C. floridanus, the present study initially focused on the identification of possible immune factors, encoded by the ant´s genome. By using the method “suppression subtractive hybridization” as well as by Illumnia sequencing technology, several immune-related genes could be identified. Among these were genes encoding proteins involved in pathogen recognition, signal transduction, antimicrobial activity, or general stress response. In accordance with the ant´s genome sequence (Bonasio et al. 2010), only three antimicrobial peptide (AMP) genes could be identified in C. floridanus. The gene and cDNA sequences of these AMPs were established and their expression was shown to be induced by microbial challenge. Two different defensin genes (type 1 and 2) were characterized. A detailed characterization of the mRNA and gene sequence of the other AMP, a hymenoptaecin, revealed a special repeat structure. The C. floridanus hymenoptaecin has a signal and a pro-sequence followed by a hymenoptaecin-like domain and six directly repeated hymenoptaecin domains (HDs). Since each HD is flanked by two known processing sites, proteolytic processing of the precursor protein may generate several mature AMPs. Bioinformatical analyses revealed the presence of hymenoptaecin genes with similar multipeptide precursor structure in genomes of other ant species suggesting an evolutionary conserved important role of this gene in ant immunity. C. floridanus ants harbor the obligate intracellular bacterium, Blochmannia floridanus, in specialized cells (so-called bacteriocytes), which are intercalated between midgut cells as well as in ovaries of females (Blochmann 1882; Sauer et al. 2002; Schröder et al. 1996). Ant hosts face the problem that on the one hand they have to maintain the beneficial symbiotic bacteria and on the other hand they need to raise an immune response against harmful pathogenic bacteria during an infection. It was investigated, if endosymbionts are actually detected by the host immune system. Injection of B. floridanus induced an immune response of its host C. floridanus, which was comparable to the one towards pathogens. This means that, despite the evolutionary established cooperation of the endosymbionts and their hosts, these bacteria are still recognized as „non-self“ by the host immune system. This finding led to the question, if the ant immune system might be involved in regulation of the endosymbiont number in the midgut tissue in order to avoid their uncontrolled replication. During the holometabolous life cycle of the ant hosts the distribution of bacteriocytes and of Blochmannia endosymbionts is remarkably dynamic and peaks in late pupal stages, in which the entire midgut is transformed into a symbiotic organ (Stoll et al. 2010). It was hypothesized that hosts could regulate the number of endosymbionts present in their tissues via the innate immune system. A quantitative gene expression analysis of assumed symbiosis-relevant candidate genes revealed distinct expression patterns of some genes according to developmental stage and tissue. Moreover, the immune gene expression in response to bacterial challenge was investigated in the pupal stage. By an artificial immune-challenge of pupae it was confirmed that in fact the immune response of the endosymbiont-bearing midgut tissue differs from that of other body parts. The data support a key role for amidase peptidoglycan recognition proteins (PGRPs), especially PGRP-LB, in endosymbiont tolerance and suggest an involvement of the lysosomal system in control of Blochmannia endosymbionts. In sum, this thesis provides a first description of the immune response of the ant C. floridanus. A comprehensive set of immune-relevant genes was determined. Especially, the identification and molecular characterization of the hymenoptaecin gene delivered new insights into the immune competence of ants in general. Moreover, first indications could be gathered for the involvement of the immune system in controlling the endosymbiont B. floridanus.
Insects have evolved an astonishing array of defences to ward off enemies. Well-known and widespread is the regurgitation of oral secretions (OS), fluids that repel attacking predators. In herbivores, the effectiveness of OS has been ascribed so far to the presence of deterrent secondary metabolites sequestered from the host plant. This notion implies, however, that generalists experience less protection on plants with low amounts of secondary metabolites or with compounds ineffective against potential enemies. Resolving the dilemma, we describe a novel defence mechanism that is independent of deterrents as it relies on the OS’ intrinsic detergent properties. The OS of Spodoptera exigua (and other species) was found to be highly amphiphilic and well capable of wetting the hydrophobic cuticle of predatory ants. As a result, affected ants stopped attacking and engaged in extensive cleansing. The presence of surfactants was sufficient to explain the defensive character of herbivore OS. We hypothesize that detergency is a common but unrecognised mode of defence which provides a base level of protection that may or may not be further enhanced by plant-derived deterrents. Our study also proves that insects ‘invented’ the use of defensive surfactants long before modern agriculture had started applying them as insecticides.
Large parts of the tropical lowland rain forests of Sabah (Malaysia) were transformed into secondary forests due to heavy logging. Additionally the remaining forest remnants are isolated from each other by large scale oil palm plantations. Biodiversity patterns and responses of the community of leaf litter ants were studied in anthropogenically disturbed habitats and primary forests of different size. In logged over forests, only 70 per cent of the species of a primary forest were present even 25 years after timber extraction. The ant communities were thinned and could be described by a lower species density producing lower species numbers and a different community composition. The similarity in species number and community composition between logged over forests of different degrees of disturbance was explained by source-sink dynamics within a heterogeneous forest matrix. Rain forest fragments displayed even higher reductions in species density, numbers and diversity due to a more pronounced thinning effect. Even forest isolates exceeding 4 000 ha in size did not support more than 50 per cent of the species of the leaf litter ant community of a contiguous primary rain forest. Additionally, an increase in tramp species was recorded with decreasing size of the forest fragments, leading to a very different community composition. Regarding the leaf litter ant community, the remaining rain forest fragments of Sabah are effectively isolated by a barrier of oil palm plantation, now stretching all over the lowlands of the east coast. Only 13 species, which belonged to the forest ant community in highly disturbed areas were collected in these plantations. Some of the 10 other species of the highly reduced ground-dwelling ant community in the plantations are known as invasive tramp species, forming large exclusive territories. Correlative evidence and a field experiment implied, that leaf litter humidity, volume and temperature affect the distribution and community composition of forest leaf litter ant species. The smaller primary forests and the most disturbed logged over forests in this study revealed higher temperatures and lower humidity levels and a reduction in leaf litter volume compared to a large primary forest or forests affected by a lower impact of timber harvesting. If the pattern for leaf litter ants is confirmed for other taxa, the implications for any efficient management design aiming to preserve the majority of the biodiversity of the country are tremendous and current concepts need rethinking.
Mechanisms and adaptive significance of interspecific associations between tropical ant species
(2009)
Aggression between ants from different colonies or species is ubiquitous. Exceptions to this rule exist in the form of supercolonies (within a species) and interspecific associations (between species). Probably the most intimate interspecific association is the parabiosis, where two ant species live together in a common nest. They keep their brood separate but jointly use trails and often share food resources. Parabioses are restricted to few species pairings and occur in South American and Southeast Asian rainforests. While the South American parabioses have been studied, albeit poorly, almost nothing is known about their Southeast Asian counterparts. My PhD project focuses on Southeast Asian parabioses between the myrmicine Crematogaster modiglianii Emery 1900 and the considerably larger formicine Camponotus rufifemur Emery 1900. The two species frequently nest together in hollow trees in the tropical lowland rainforest of Borneo. The basic question of my PhD project is why these two species live together. I investigated both proximate and ultimate aspects of this question. For comparative purposes, I included studies on a trail-sharing association in the same habitat. On the proximate level, I investigated which mechanisms facilitate tolerance towards hetero-spe¬ci¬fic nestmates. Ants generally discriminate nestmates from non-nestmates via cuticular hydro¬carbons that function as colony recognition cues. I studied the specificity of nestmate recognition within and between the two parabiotic species. Using gas chromatography-mass spectrometry (GC-MS), I analyzed the cuticular substances in both ant species to find potential differences to non-parabiotic species, and to estimate the substance overlap among the two species. A high substance overlap would e.g. suggest that interspecific tolerance is caused by chemical mimicry. Finally, bioassays were conducted to evaluate the function of different cuticular compounds. Interspecific tolerance in the two parabiotic species was species-specific but not colony-specific. Ca. rufifemur tolerated all Cr. modiglianii individuals, even those from foreign colonies, but strongly attacked workers of other Crematogaster species. Cr. modiglianii, in turn, tolerated Ca. rufifemur workers of certain foreign colonies but attacked those of others. Chemical analyses revealed two sympatric, chemically distinct Ca. rufifemur varieties (‘red’ and ‘black’) with almost no hydrocarbon overlap. Cr. modiglianii only tolerated foreign Ca. rufifemur workers if they belonged to the same chemical variety as their own Ca. rufifemur partner. It also attacked other, non-parabiotic Camponotus species. Thus, reciprocal interspecific tolerance was restricted to the species Cr. modiglianii and Ca. rufifemur. Ca. rufifemur frequently tolerated conspecific non-nestmates of the same chemical variety. Minor workers were more often tolerated than majors, possibly because they possess two to three times lower hydrocarbon quantities per body surface than majors. In contrast, Cr. modiglianii nearly always attacked conspecific non-nestmates. Both species possessed hydrocarbons with considerably higher chain lengths than congeneric, non-parabiotic ant species. Long-chain hydrocarbons are less volatile than shorter ones and thus harder to perceive. They may thus considerably facilitate interspecific tolerance. Moreover, up to 98% of the cuticular hydrocarbons in Ca. rufifemur were methylbranched alkenes, which are highly unusual among insect cuticular hydrocarbons. Cr. modiglianii and Ca. rufifemur had almost no hydrocarbons in common, refuting chemical mimicry as a possible cause of interspecific tolerance. The only hydrocarbons common to both species were two methylbranched alkenes, which constituted 89% of the ‘red’ Ca. rufifemur hydrocarbon profile and also occurred in those Cr. modiglianii colonies that lived together with this Ca. rufifemur variety. Cr. modiglianii presumably acquired these two compounds from its red Ca. rufifemur partner. Cr. modiglianii was significantly less aggressive towards foreign Cr. modiglianii workers that were associated with the same Ca. rufifemur variety than to those associated with the respective other one. Hence, this species seemed to use recognition cues acquired from its parabiotic partner. Apart from hydrocarbons, both species possessed a set of hitherto unknown substances on their cuticle. The quantitative composition of the unknown compounds varied between parabiotic nests but was similar among the two species of a nest. They are probably produced in the Dufour glanf of Cr. modiglianii and transferred to their Ca. rufifemur partner. Possible transfer mechanisms include interspecific trophallaxis and ‘mounting behaviour’, where Cr. modiglianii climbed onto Ca. rufifemur workers without being displaced. Although the composition of the unknown compounds greatly varied between nests, they did not function as nestmate recognition cues since both species used hydrocarbons for nestmate recognition. However, the unknown compounds significantly reduced aggression in Ca. rufifemur. The ultimate, i.e. ecological and evolutionary aspects of my PhD research deal with potential costs and benefits that Cr. modiglianii and Ca. rufifemur may derive from the parabiotic association, their interactions with other species, and population genetic analyses. Additional studies on a trail-sharing association between three other ant species deal with two possible mechanisms that may cause or facilitate trail-sharing. Whether parabioses are parasitic, commensalistic, or mutualistic, is largely unknown and depends on the costs and benefits each party derives from the association. I therefore investigated food competition (as one of the most probable costs), differentiation of foraging niches (which can reduce competition), and several potential benefits of the parabiotic way of life. Besides, I studied interactions between the ant species and the hemiepiphyte Poikilospermum cordifolium. The foraging niches of the two species differed regarding foraging range, daily activity pattern, and food preferences. None of the two species aggressively displaced its partner species from baits. Thus, interference competition for food seemed to be low or absent. For both ant species, a number of benefits from the parabiotic lifestyle seem possible. They include interspecific trail-following, joint nest defence, provision of nest space by the partner species, food exchange via trophallaxis, and mutual brood care. If an ant species follows another species’ pheromone trails, it can reach food resources found by the other species. As shown by artificial extract trails, Ca. rufifemur workers indeed followed trails of Cr. modiglianii but not vice versa. Thus, Ca. rufifemur benefited from Cr. modiglianii’s knowledge on food sources (informational parasitism). In turn, Cr. modiglianii seemed to profit from nest defence by Ca. rufifemur. Ca. rufifemur majors are substantially larger than Cr. modiglianii workers. Although Cr. modiglianii often effectively defended the nest as well, it seemed likely that this species derived a benefit from its partner’s defensive abilities. In neotropical parabioses (ant-gardens), mutualistic epiphytes play an important role in providing nest space. The neotropical Camponotus benefits its Crematogaster partner by planting epiphyte seeds, for which Crematogaster is too small. Similarly, the Bornean parabioses often were inhabited by the hemiepiphyte Poikilospermum cordifolium (Barg.-Petr.) Merr (Cecropiaceae). P. cordifolium seedlings, saplings and sometimes larger indivi¬duals abundantly grew at the entrances of parabiotic nests. However, P. cordifolium provides no additional nest space and, apart from nutritive elaiosomes, perianths, and extrafloral nectar probably plays a less important role for the ants than the neotropical epiphytes. In conclusion, the parabiosis is probably beneficial to both species. The main benefits seem to be nest defence (for Cr. modiglianii) and interspecific trail-following (for Ca. rufifemur). However, Ca. rufifemur seems to be more dependent on its partner than vice versa. For both parabiotic species, I analyzed mitochondrial DNA of ants from different regions in Borneo. My data suggest that there are four genetically and chemically distinct, but closely related varieties of Camponotus rufifemur. In contrast, Crematogaster modiglianii showed high genetic differentiation between distant populations but was not differentiated into genetic or chemical varieties. This argues against variety-specific cocladogenesis between Cr. modiglianii and Ca. rufifemur, although a less specific coevolution of the two species is highly likely. In Bornean rainforests, trail-sharing associations of Polyrhachis (Polyrhachis) ypsilon Emery 1887 and Camponotus (Colobopsis) saundersi Emery 1889 are common and often include further species such as Dolichoderus cuspidatus Smith 1857. I investigated a trail-sharing association between these three species and studied two mechanisms that may cause or facilitate these associations: interspecific trail-following, i.e. workers following another species’ pheromone trail, and differential inter¬specific aggression. In trail-following assays, D. cuspidatus regularly followed extract trails of the other two species, thus probably parasitizing on their information on food sources. In contrast, only few P. ypsilon and Ca. saundersi workers followed hetero¬speci¬fic extract trails. Hence, the association between P. ypsilon and Ca. saundersi cannot be ex¬plained by foragers following heterospecific trails. In this case, trail-sharing may originate from few scout ants that do follow heterospecific pheromone trails and then lay their own trails. Interspecific aggression among P. ypsilon, Ca. saundersi and D. cuspidatus was strongly asymmetric, Ca. saundersi being submissive to the other two species. All three species discriminated between heterospecific workers from the same and a distant trail-sharing site. Thus, it seems likely that the species of a given trail-sharing site habituate to one another. Differential tolerance by dominant ant species may be mediated by selective habituation towards submissive species, and thereby influence the assembly of trail-sharing associations.
This study investigated patterns of arthropod community organisation and the processes structuring these communities on a range of different tree species in a natural West African savannah (Comoé National Park, Côte d'Ivoire). It described and analysed patterns of arthropod distribution on the level of whole communities, on the level of multiple-species interactions, and on the level of individual insect species. Community samples were obtained by applying (i) canopy fogging for mature individuals of three tree species (Anogeissus leiocarpa, Burkea africana, Crossopteryx febrifuga) and (ii) a modified beating technique allowing to sample the complete arthropod communities of the respective study plants for medium-sized (up to 3 m) individuals of two other species (Combretum fragrans, Pseudocedrela kotschyi). General information on ant-plant interactions was retrieved from ant community comparisons of the mature savannah trees. In addition, ant-ant, ant-plant and ant-herbivore interactions were studied in more detail considering the ant assemblages on the myrmecophilic tree Pseudocedrela kotschyi. Herbivore-plant interactions were investigated on a multiple-species level (interrelationships between herbivores and Pseudocedrela trees) and on a species level (detailed studies of interrelationships between herbivorous beetles and caterpillars and the host tree Combretum fragrans). The studies on individual herbivore species were complemented by a study on an abundant ant species, clarifying not only the relationship between host plant and associated animal but allowing also to look at interactive (competitive) aspects of community organisation. The study demonstrated for the first time that (i) the structure of beetle communities on tropical trees can be strongly dependent on the host tree species, (ii) individual trees can host specific arthropod communities whose characteristic structure is stable over years and is strongly determined by the individual tree's attributes, (iii) ants can express a pronounced fidelity to single leaves as foraging area and can thereby determine distribution patterns of other ants, (iv) intraspecifically variable palatability of plants for insect herbivores can be stable over years and can influence the distribution of herbivores that can distinguish between individual hosts according to palatability and (v) intraspecific host plant change can positively affect fitness of herbivores if host plant quality is variable. In general, the present study contributes to our knowledge of anthropogenically unaltered processes affecting community assembly in a natural environment. The fundamental understanding of these processes is crucial for the identification of anthropogenic alterations and the establishment of sustainable management measures. The study points out the important role local factors can play for the distribution of organisms and thereby for community organisation. It emphasises the relevance of small scale heterogeneity of the abiotic and biotic environment to biodiversity and the need to consider these factors for development of effective conservation and restoration strategies.
Many polymorphisms are linked to alternative reproductive strategies. In animals, this is particularly common in males. Ant queens are an important exception. The case of ant queen size dimorphisms has not been studied in sufficient detail, and thus this thesis aimed at elucidating causes and consequences of the different size of small (microgynous) and large (macrogynous)ant queens using the North American ant species Leptothorax rugatulus as a model system. Employing neutral genetic markers, no evidence for a taxonomically relevant separation of the gene pools of macrogynes and microgynes was found. Queens in polygynous colonies were highly related to each other, supporting the hypothesis that colonies with more than one queen commonly arise by secondary polygyny, i.e. by the adoption of daughter queens into their natal colonies. These results and conclusions are also true for the newly discovered queen size polymorphism in Leptothorax cf. andrei. Several lines of evidence favor the view that macrogynes predominantly found their colonies independently, while microgynes are specialized for dependent colony founding by readoption. Under natural conditions, mother and daughter size are highly correlated and this is also true for laboratory colonies. However, the size of developing queens is influenced by queens present in the colony. Comparing populations across the distribution range, it turns out that queen morphology (head width and ovariole number) is more differentiated among populations than worker morphology (coloration, multivariate size and shape), colony characteristics (queen and worker number per colony) or neutral genetic variation. Northern and southern populations differed consistently which indicates the possibility of two different species. The queen size dimorphism in L. rugatulus did neither influence the sex ratio produced by a colony, nor its ratio of workers to gynes. However, the sex ratio covaried strongly across populations with the average number of queens per colony in accordance with sex ratio theory. At the colony level, sex ratio could not be explained by current theory and a hypothesis at the colony-level was suggested. Furthermore, queen body size has no significant influence on the amount of reproductive skew among queens. Generally, the skew in L. rugatulus is low, and supports incomplete control models, rather than the classic skew models. In eight of fourteen mixed or microgynous colonies, the relative contributions of individual queens to workers, gynes and males were significantly different. This was mainly due to the fact that relative body size was negatively correlated with the ratio of gynes to workers produced. This supports the kin conflict over caste determination hypothesis which views microgyny as a selfish reproductive tactic.
A hitherto unresolved problem is how workers are prevented from reproducing in large insect societies. The queen informs about her fertility and health which ensures sufficient indirect fitness benefits for workers. In the ant Camponotus floridanus, I found such a signal located on eggs of highly fertile queens. Groups of workers were regularly provided with different sets of brood. Only in groups with queen eggs workers refrain from reproducing. Thus, the eggs seem to inform the workers about queen presence. The signal on queen eggs is presumably the same that enables workers to distinguish between queen and worker-laid eggs, latter are destroyed by workers. Queen and worker-laid eggs differ in their surface hydrocarbons in a similar way as fertile queens differ from workers in the composition of their cuticular hydrocarbons. When I transferred hydrocarbons from the queen cuticle to worker eggs the eggs were no longer destroyed, indicating that they now carry the signal. These hydrocarbons thus represent a queen signal that regulates worker reproduction in this species. But the signal is not present in all fertile queens. Founding queens with low egg-laying rates differ in the composition of cuticular hydrocarbons from queens with high productivity. Similar differences in the composition of surface hydrocarbons were present on their eggs. The queen signal develops along with an increasing fertility and age of the queen, and this is perceived by the workers. Eggs from founding queens were destroyed like worker eggs. This result shows that founding queens lack the appropriate signal. In these little colony foundations chemical communication of queen status may not be necessary to prevent workers from reproducing, since workers may benefit more from investing in colony growth and increased productivity of large colonies rather than from producing male eggs in incipient colonies. If the queen is missing or the productivity of the queen decreases, workers start laying eggs. There is some evidence from correlative studies that, under queenless conditions, worker police each other because of differences in individual odors as a sign of social status. It can be expressed as either aggressive inhibition of ovarian activity, workers with developed ovaries are attacked by nest-mates, or destruction by worker-laid eggs. I found that in C. floridanus workers, in contrast to known studies, police only by egg eating since they are able to discriminate queen- and worker-laid eggs. Workers with developed ovaries will never attacked by nest-mates. This is further supported by qualitative and quantitative differences in the cuticular hydrocarbon profile of queens and workers, whereas profiles of workers with and without developed ovaries show a high similarity. I conclude that workers discriminate worker eggs on the basis of their hydrocarbon profile, but they are not able to recognize egg-laying nest-mates. Improving our knowledge of the proximate mechanisms of the reproductive division of labor in evolutionary derived species like C. floridanus will help to understand the evolution of extreme reproductive altruism involving sterility as a characteristic feature of advanced eusocial systems.
Bees are subject to permanent threat from predators such as ants. Their nests with large quantities of brood, pollen and honey represent lucrative targets for attacks whereas foragers have to face rivalry at food sources. This thesis focused on the role of stingless bees as third party interactor on ant-aphid-associations as well as on the predatory potential represented by ants and defense mechanisms against this threat. Regular observations of an aphid infested Podocarpus for approaching stingless bees yielded no results. Another aim of this thesis was the observation of foraging habits of four native and one introduced ant species for assessment of their predatory potential to stingless bees. All species turned out to be dietary balanced generalists with one mostly carnivorous species and four species predominantly collecting nectar roughly according to optimal foraging theory. Two of the species monitored, Rhytidoponera metallica and Iridomyrmex rufoniger were considered potential nest robbers. As the name implies, stingless bees lack the powerful weapon of their distant relatives; hence they specialized on other defense strategies. Resin is an important, multipurpose resource for stingless bees that is used as material for nest construction, antibiotic and for defensive means. For the latter purpose highly viscous resin is either directly used to stick down aggressors or its terpenic compounds are included in the bees cuticular surface. In a feeding choice experiment, three ant species were confronted with the choice between two native bee species - Tetragonula carbonaria and Austroplebeia australis - with different cuticular profiles and resin collection habits. Two of the ant species, especially the introduced Tetramorium bicarinatum did not show any preferences. The carnivorous R. metallica predominantly took the less resinous A. australis as prey. The reluctance towards T. carbonaria disappeared when the resinous compounds on its cuticle had been washed off with hexane. To test whether the repulsive reactions were related to the stickiness of the resinous surface or to chemical substances, hexane extracts of bees’ cuticles, propolis and three natural tree resins were prepared. In the following assay responses of ants towards extract treated surfaces were observed. Except for one of the resin extracts, all tested substances had repellent effects to the ants. Efficacy varied with the type of extract and species. Especially to the introduced T. bicarinatum the cuticular extract had no effect. GCMS-analyses showed that some of the resinous compounds were also found in the cuticular profile of T. carbonaria which featured reasonable analogies to the resin of Corymbia torelliana that is highly attractive for stingless bees. The results showed that repellent effects were only partially related to the sticky quality of resin but were rather caused by chemical substances, presumably sesqui- and diterpenes. Despite its efficacy this defense strategy only provides short time repellent effects sufficient for escape and warning of nest mates to initiate further preventive measures.