Studies on the biology of marine Digenea : Meiogymnophallus minutus (Cobbold, 1859) Bowers & James, 1967

Al-Salman, Husam Ahmed M.

January 1985

No description available.

592

Digenea ; Meiogymnophallus minutes

Studies in the general ecology, physiology and bioenergetics of woodland Lumbricidae

Bolton, P. J.

January 1969

No description available.

592

Soil biotic community, Lumbricid

Reconstructing the phylogenetic relationships of nematodes using draft genomes and transcriptomes

Koutsovoulos, Georgios D.

January 2015

Nematoda is a very diverse animal phylum. Within Nematoda, species display a multitude of life styles, different reproductive strategies and parasitism has arisen independently several times. Furthermore, morphological conservation and a high rate of homoplasy have impeded the resolution of nematode systematics. To address these issues, single gene (usually the nuclear ribosomal small subunit gene) and mitochondrial gene phylogenies have been used, but the information contained within the sequence of these genes is not enough to resolve the topological relationships between clades that emerged during rapid cladogenesis. Next generation sequencing data have been shown to produce high quality genomic and transcriptomic assemblies at low cost, as a result more and more nematode species are being sequenced. Sequences were gathered or generated for 53 nematode species from ESTs, gene predictions from full genome assemblies and transcripts from RNA-Seq experiments. These sequences were screened for orthologous gene clusters, which were concatenated into a supermatrix with thousands of aminoacid sites. The analysis of the supermatrix with maximum likelihood and Bayesian inference methods sheds light into the early splitting clades of the phylogenetic tree of nematodes and the derived clades III, IV and V. Furthermore, the phylogenetic relationships within the parastitic family Onchocercidae were resolved, unveiling the evolutionary history of these important taxa. Finally, data produced in this work will be useful for subsequent evolutionary studies of the phylum Nematoda.

592

Development and growth of Schistocephalus solidus Müller in vivo and in vitro

Mason, Morag L. O.

January 1965

The life cycle of Schistocephalus solidus had been known for over thirty years but there was little information in the literature on the maintenance of the life cycle in the laboratory. It was thus decided to obtain each stage of the life cycle under laboratory conditions and study their development. The data obtained is recorded in Section I. The plerocercoid stage is the only stage in the cycle which can be obtained easily in nature. Hence numerous visits were made to two lochs to collect infected 3-spined sticklebacks. Records were kept of all the fish caught and the infection they harboured in order that information relating to the cycle under natural conditions could be obtained. This information is recorded in Section II. The regular sampling of two lochs produced many small plerocercoids which it was found could not become established in a warm-blooded host. The cultivation in vitro of these small plerocercoids was thus commenced as well as the cultivation of any larger plerocercoids not required for feeding to potential definitive hosts. The results of this work are recorded in Section III.

592

QH345 Biochemistry ; QL Zoology

Model order reduction techniques for circuit simulation

January 1995

Luis Miguel Silveira. / Includes bibliographical references (p. 156-160). / Supported in part by the Semiconductor Research Corporation. SRC 93-SJ-558 Supported in part by the National Science Foundation / Advanced Research Projects Agency. MIP 91-17724

TK7855.M41 R43 no.592

Ecological studies of symbiosis in Convoluta roscoffensis

Doonan, Shelagh A.

January 1979

1. Convoluta roscoffensis is an intertidel flatworm symbiotic with the green alga, Platymonas convolutae. Field studies of a population of Convoluta on Shell Beach, Herm, Channel Islands, involved the measurement of seasonal changes in numbers of Convoluta and in environmental conditions. Features of the habitat were measured, including the nutrient levels in the beach run-off water flowing over Convoluta colonies and the light energy available. 2. The position of the colonies on the beach meant that they received about 60% of available PAR (photosynthetically active radiation) i.e. 4883 E m-2 in 1977. The spacing of worms in the colonies (mean density 9.3 x 10 to the power 5 worms m-2) was such that they did not haye to shade each other. 3. Nutrient analyses revealed that the beach run-off water is rich in nutrients, and dominated by nitrate (mean concentration 6-16υg atoms N03-N 1to the power -1). Uptake of nutrients from the run-off water by Convoluta was not apparent. 4. The Convoluta population was most abundant in September and numbers were lowest in May and June. This pattern of fluctuation in numbers showed some relation to seasonal changes in light intensity but not to changes in nutrient levels. 5. Primary productivity measurements (using the 14C technique) of symbiotic and free-living Platymonas showed that both types of algae achieved assimilation numbers (mg carbon fixed (mg chlorophyll 'a')-1 h-1) which were in the range 1-3. Photosynthetic rate was higher in worms incubated in Herm run-off water than in offshore seawater. Comparisons between symbiotic and free-living Platymonas were made with respect to photoinhibiting light levels and the amounts of dark carbon fixation. 6. Extrapolation of primary productivity values to Convoluta in the field gave an estimated annual production of 872.9 g carbon m to the power -2 of colony for 1977. This is comparable with values for rich ocean waters and coral reefs. 7. Primary production measurements were also made on a tropical algal-invertebrate system, Zoanthus sociatus, at Discovery Bay, Jamaica. The oxygen technique was used, so the values of assimilation number were not directly comparable with those obtained for Convoluta, but the symbionts of Zoanthus (Gymnodinium microadriaticum) achieved assimilation numbers similar to those published for other free-living species of Gymnodinium. The symbionts isolated from Zoanthus were of similar size to and contained similar amounts of chlorophyll 'a' to the Platymonas symbionts of Convoluta. 8. Structural studies of the development of symbiosis in Convoluta showed that the host and symbiont are in very intimate contact. There was evidence for the controlled and integrated growth of host and symbiont in the distribution and orientation of the 20,000-70,000 algae inside Convoluta. The ratios of algal to host protein and cell volume were measured and compared with values for other algal-invertebrate systems to discover whether any general statements may be made regarding the proportions of algal to host tissue in established symbioses.

592

Environmental and genetic influences on dauer larvae development in growing populations of Caenorhabditis species

Green, J.

January 2014

Phenotypic variation manifests from either simple (monogenic) or complex (multigenic) traits. Variation due to genetic and environmental influences is important because the ability to produce a range of phenotypes is essential for adaptive evolution. Complex traits are important not only for evolution, but because many diseases are complex traits. The genetic architecture of complex traits can be very multifaceted, with a large number of causal genes each having a small effect on the overall heritability of the trait, and as such our understanding of the genetic architecture and control of complex traits is limited. Complex traits are studied through quantitative trait loci mapping and genome-wide association studies. Since there are a great range of resources available for the nematode Caenorhabditis elegans, this is an appropriate system in which to study the genetic architecture of complex traits. Dauer larvae development represents a suitable complex trait as many of the genes involved and their genetic pathways have been identified. This trait is also important for the clear links between the dauer larvae of free-living species and the infective stages of many parasitic nematodes, and is therefore important as a model complex trait. Dauer larvae are routinely studied under unnatural conditions, with a cohort of aged-matched worms exposed to concentrated pheromone from many worms, conditions that are not obviously ecologically or evolutionally relevant. It is therefore important to understand the dynamics of growing populations in the laboratory both specifically to understand C. elegans, and generally to understand the genetics of complex traits. Methods have been established for the analysis of population growth assays, and experiments to validate this style of assay have been carried out for the analysis of dauer larvae development in a growing population. In this, extensive variation in dauer larvae development between natural wild isolates and the canonical isolate N2 has been shown, variation which has previously not been demonstrated in standard dauer larvae assays. The genetic basis of this variation was also investigated using two Recombinant Inbred Line (RILs) panels made from two distinct parental genotypes of C. elegans, Isogenic Lines (ILs) of C. elegans and also a C. briggsae RIL panel. These analyses revealed that the genetic architecture of dauer larvae development in growing populations is highly complex, with a large number of QTLs affecting this trait. Also, comparison of the results from the different mapping approaches (RILs vs. ILs) revealed variation in their power to detect QTLs, as the ILs were capable of identifying far more QTLs than the RILs. Three candidate genes which have an effect on dauer larvae development in growing populations were identified and analysed. These candidates are npr-1, srg-36 and srg-37, each showing a negative effect on dauer larvae development in a growing population and an allelic effect of variation at npr-1. Together, these results demonstrate that extensive variation in dauer larvae development can be analysed in growing populations, that the underlying genetics can be mapped and that candidate genes can be identified for the underlying regions.

592

QH0426 Genetics ; QL0360 Invertebrates

The biometeorology of high-altitude insect layers

Wood, Curtis Ron

January 2007

Flight at high altitude is part of a migration strategy that maximises insect population displacement. This thesis represents the first substantial analysis of insect migration and layering in Europe. Vertical-looking entomological radar has revealed specific characteristics of high-altitude flight: in particular layering (where a large proportion of the migrating insects are concentrated in a narrow altitude band). The meteorological mechanisms underpinning the formation of these layers are the focus of this thesis. Aerial netting samples and radar data revealed four distinct periods of high-altitude insect migration: dawn, daytime, dusk, and night-time. The most frequently observed nocturnal profiles during the summertime were layers. It is hypothesised that nocturnal layers initiate at a critical altitude (200–500 m above ground level) and time (20:00–22:00 hours UTC). Case study analysis, statistical analysis, and a Lagrangian trajectory model showed that nocturnal insect layers probably result from the insects’ response to meteorological conditions. Temperature was the variable most correlated with nocturnal insect layer presence and intensity because insects are poikilothermic, and temperatures experienced during high-altitude migration in temperate climates are expected to be marginal for many insects’ flight. Hierarchical effects were detected such that other variables—specifically wind speed—were only correlated with insect layer presence and intensity once temperatures were warm. The trajectory model developed comprised: (i) insect flight characteristics; (ii) turbulent winds (which cause vertical spread of the layer); and (iii) mean wind speed, which normally leads to horizontal displacements of hundreds of kilometres in a single migratory flight. This thesis has revealed that there is considerable migratory activity over the UK in the summer months, and a range of fascinating phenomena can be observed (including layers). The UK has moved from one of the least studied to perhaps the best studied environments of aerial insect migration and layering in the world.

595.70525

Aspects of neuronal plasticity in the mushroom body calyx during adult maturation in the honeybee Apis mellifera / Aspekte neuronaler Plastizität im Pilzkörper kalyx während der Adultreifung der Honigbiene Apis mellifera

Münz, Thomas Sebastian

January 2015

Division of labor represents a major advantage of social insect communities that accounts for their enormous ecological success. In colonies of the honeybee, Apis mellifera, division of labor comprises different tasks of fertile queens and drones (males) and, in general, sterile female workers. Division of labor also occurs among workers in form of an age-related polyethism. This helps them to deal with the great variety of tasks within the colony. After adult eclosion, workers spend around three weeks with various duties inside the hive such as tending the brood or cleaning and building cells. After this period workers switch to outdoor tasks and become foragers collecting nectar, pollen and water. With this behavioral transition, workers face tremendous changes in their sensory environment. In particular, visual sensory stimuli become important, but also the olfactory world changes. Foragers have to perform a completely new behavioral repertoire ranging from long distance navigation based on landmark orientation and polarized-skylight information to learning and memory tasks associated with finding profitable food sources. However, behavioral maturation is not a purely age-related internal program associated with a change, for example, in juvenile hormone titers. External factors such as primer pheromones like the brood pheromone or queen mandibular pheromone can modulate the timing of this transition. In this way colonies are able to flexibly adjust their work force distribution between indoor and outdoor tasks depending on the actual needs of the colony. Besides certain physiological changes, mainly affecting glandular tissue, the transition from indoor to outdoor tasks requires significant adaptations in sensory and higher-order integration centers of the brain. The mushroom bodies integrate olfactory, visual, gustatory and mechanosensory information. Furthermore, they play important roles in learning and memory processes. It is therefore not surprising that the mushroom bodies, in particular their main input region, the calyx, undergo volumetric neuronal plasticity. Similar to behavioral maturation, plastic changes of the mushroom bodies are associated with age, but are also to be affected by modulating factors such as task and experience. In my thesis, I analyzed in detail the neuronal processes underlying volumetric plasticity in the mushroom body. Immunohistochemical labeling of synaptic proteins combined with quantitative 3D confocal imaging revealed that the volume increase of the mushroom body calyx is largely caused by the growth of the Kenyon cell dendritic network. This outgrowth is accompanied by changes in the synaptic architecture of the mushroom body calyx, which is organized in a distinct pattern of synaptic complexes, so called microglomeruli. During the first week of natural adult maturation microglomeruli remain constant in total number. With subsequent behavioral transition from indoor duties to foraging, microglomeruli are pruned while the Kenyon cell dendritic network is still growing. As a result of these processes, the mushroom body calyx neuropil volume enlarges while the total number of microgloumeruli becomes reduced in foragers compared to indoor workers. In the visual subcompartments (calyx collar) this process is induced by visual sensory stimuli as the beginning of pruning correlates with the time window when workers start their first orientation flights. The high level of analysis of cellular and subcellular process underlying structural plasticity of the mushroom body calyx during natural maturation will serve as a framework for future investigations of behavioral plasticity in the honeybee. The transition to foraging is not purely age-dependent, but gets modulated, for example, by the presence of foragers. Ethyl oleate, a primer pheromone that is present only in foragers, was shown to delay the onset of foraging in nurse bees. Using artificial application of additional ethyl oleate in triple cohort colonies, I tested whether it directly affects adult neuronal plasticity in the visual input region of the mushroom body calyx. As the pheromonal treatment failed to induce a clear behavioral phenotype (delayed onset of foraging) it was not possible to show a direct link between the exposure to additional ethyl oleate and neuronal plasticity in mushroom body calyx. However, the general results on synaptic maturation confirmed my data of natural maturation processes in the mushroom body calyx. Given the result that dendritic plasticity is a major contributor to neuronal plasticity in the mushroom body calyx associated with division of labor, the question arose which proteins could be involved in mediating these effects. Calcium/calmodulin-dependent protein kinase II (CaMKII) especially in mammals, but also in insects (Drosophila, Cockroach), was shown to be involved in facilitating learning and memory processes like long-term synaptic potentiation. In addition to presynaptic effects, the protein was also revealed to directly interact with cytoskeleton elements in the postsynapse. It therefore is a likely candidate to mediate structural synaptic plasticity. As part of my thesis, the presence and distribution of CaMKII was analyzed, and the results showed that the protein is highly concentrated in a distinct subpopulation of the mushroom body intrinsic neurons, the noncompact Kenyon cells. The dendritic network of this population arborizes in two calyx subregions: one receiving mainly olfactory input – the lip – and the collar receiving visual input. This distribution pattern did not change with age or task. The high concentration of CaMKII in dendritic spines and its overlap with f-actin indicates that CaMKII could be a key player inducing structural neuronal plasticity associated with learning and memory formation and/or behavioral transitions related to division of labor. Interestingly CaMKII immunoreactivity was absent in the basal ring, another subregion of the mushroom body calyx formed almost exclusively by the inner compact Kenyon cells and known to receive combined visual and olfactory input. This indicates differences of this mushroom body subregion regarding the molecular mechanisms controlling plastic changes in corresponding Kenyon cells. How is timing of behavioral and neuronal plasticity regulated? The primer pheromone ethyl oleate was found in high concentrations on foragers and was shown to influence behavioral maturation by delaying the onset of foraging when artificially applied in elevated concentrations. But how is ethyl oleate transferred and how does it shift the work force distribution between indoor and outdoor tasks? Previous work showed that ethyl oleate concentrations are highest in the honeycrop of foragers and suggested that it is transferred and communicated inside the colony via trophallaxis. The results of this thesis however clearly show, that ethyl oleate was not present inside the honey crop or the regurgitate, but rather in the surrounding tissue of the honey crop. As additionally the second highest concentration of ethyl oleate was measured on the surface of the cuticle of forgers, trophallaxis was ruled out as a mode of transmission. Neurophysiological measurements at the level of the antennae (electroantennogram recordings) and the first olfactory neuropil (calcium imaging of activity in the antennal lobe) revealed that the primer pheromone ethyl oleate is received and processed as an olfactory stimulus. Appetitive olfactory conditioning using the proboscis extension response as a behavioral paradigm showed that ethyl oleate can be associated with a sugar reward. This indicates that workers are able to perceive, learn and memorize the presence of this pheromone. As ethyl oleate had to be presented by a heated stimulation device at close range, it can be concluded that this primer pheromone acts via close range/contact chemoreception through the olfactory system. This is also supported by previous behavioral observations. Taken together, the findings presented in this thesis revealed structural changes in the synaptic architecture of the mushroom body calyx associated with division of labor. For the primer pheromone ethyl oleate, which modulates the transition from nursing to foraging, the results clearly showed that it is received via the olfactory system and presumably acts via this pathway. However, manipulation experiments did not indicate a direct effect of ethyl oleate on synaptic plasticity. At the molecular level, CaMKII is a prime candidate to mediate structural synaptic plasticity in the mushroom body calyx. Future combined structural and functional experiments are needed to finally link the activity of primer pheromones like ethyl oleate to the molecular pathways mediating behavioral and synaptic plasticity associated with division of labor in Apis mellifera. The here identified underlying processes will serve as excellent models for a general understanding of fundamental mechanisms promoting behavioral plasticity. / Arbeitsteilung stellt einen der wesentlichen Faktoren dar, der für den ökologischen Erfolg von sozialen Insektengemeinschaften verantwortlich ist. In Staaten der Honigbiene, Apis mellifera, umfasst die Arbeitsteilung verschiedene Aufgaben für die fertilen Königinnen und Drohnen (Männchen) beziehungsweise die gewöhnlicherweise sterilen Arbeiterinnen. Arbeitsteilung findet aber auch in Form eines altersabhängigen Polyethismus zwischen den Arbeiterinnen selber statt. Dies hilft ihnen die Vielzahl verschiedener Aufgaben im Stock zu bewältigen. Nach dem Schlupf verbringen die Arbeiterinnen etwa drei Wochen mit verschiedenen Aufgaben im Stock, wie beispielsweise Brutpflege oder Reinigen und Bauen neuer Wabenzellen. Nach dieser Zeit wechseln die Arbeiterinnen zu Aufgaben außerhalb des Stocks und werden Nektar-, Pollen- oder Wassersammlerinnen. Durch diesen Verhaltensübergang sind die Arbeiterinnen mit einem massiven Wandel ihrer sensorischen Umwelt konfrontiert. Im speziellen werden nun visuelle Reize wichtig, aber auch die olfaktorische Welt der Arbeiterinnen ändert sich. Sammlerinnen zeigen ein komplett neues Verhaltensrepertoire das von Langstreckennavigation, basierend Landmarken und dem Polarisationsmuster des Himmels, bishin zu Lern- und Gedächtnisaufgaben im Zusammenhang mit dem Auffinden profitabler Futterquellen reicht. Allerdings ist Verhaltensreifung kein rein altersbedingtes internes Programm beispielsweise basierend auf einer Veränderung des Juvenilhormon-Titers. Externe Faktoren wie beispielsweise die Primer Pheromone Brutpheromone oder Königinnenpheromon können den Zeitpunkt des Übergangs modulieren. Hierdurch sind Staaten in der Lage ihre Arbeiterkräfte flexibel zwischen Innen- und Außendienst Aufgaben zu verschieben. Neben bestimmten physiologischen Veränderungen, die vor allem Drüsengewebe betreffen, benötigt der Übergang vom Innendienst zum Außendienst deutliche Anpassungen sensorischer und höherer Integrationszentren im Gehirn. Die Pilzkörper integrieren olfaktorische, visuelle und mechanosensorische Informationen. Sie spielen weiterhin eine wichtige Rolle für Lern- und Gedächtnisvorgänge. Es ist daher nicht überraschend, dass die Pilzkörper, im Speziellen deren Haupteingangsregion, der Kalyx, eine neuronale Volumensplastizität durchlaufen. Ähnlich wie die Verhaltensreifung, sind plastische Veränderungen im Pilzkörper mit dem Alter verbunden, werden aber auch durch modulierende Faktoren wie Aufgabe und Erfahrungen beeinflusst. In meiner Dissertation habe ich detailliert die neuronalen Prozesse analysiert, die der Volumensplastizität des Pilzkörpers zugrunde liegen. Immunhistologische Färbungen synaptischer Proteine kombiniert mit quantitativer 3D Konfokalmikroskopie zeigten, dass die Volumenszunahme des Pilzkörpers hauptsächlich durch dendritisches Wachstum des Kenyon-Zellen-Netzwerks bedingt ist. Dieses Auswachsen wurde begleitet durch Veränderungen der synaptischen Architektur des Kalyx des Pilzkörpers, welcher in Form synaptischer Komplexe, sogenannter Mikroglomeruli organisiert ist. Während der ersten Woche der Adultreifung blieb die Gesamtzahl der Mikroglomeruli konstant. Im folgenden Verhaltensübergang von Innendienstaufgaben zum Sammeln, wurden die Mikroglomeruli zurückgetrimmt, während das dendritische Kenyon-Zell-Netzwerk weiterhin wuchs. Als Ergebnis dieser Prozesse vergrößerte sich das Volumen des Kalyx des Pilzkörpers während die Gesamtzahl der Mikroglomeruli bei Sammlerinnen im Vergleich zu Inndienst Arbeiterinnen reduziert war. In der visuellen Unterregion (Kragen des Kalyx) wurde dieser Prozess induziert durch sensorische Stimuli, da der Beginn des Zurücktrimmens mit dem Zeitfenster zusammenfiel, in dem die Arbeiterinnen ihre ersten Orientierungsflüge starteten. Der hohe Analysegrad der zellulären und subzellulären Prozesse, die der strukturellen Plastizität des Kalyx des Pilzkörpers während der natürlichen Reifung zugrunde liegen, wird zukünftigen Untersuchungen der Verhaltensplastizität bei Honigbienen als Referenz dienen. Der Übergang zur Sammlerin ist nicht rein altersabhängig, sondern wird beispielsweise durch die Gegenwart von anderen Sammlerinnen moduliert. Ethyloleat, ein Primer Pheromone das nur auf Sammlerinnen auftritt, verzögert das Einsetzen des Sammelns von Ammenbienen. Durch das Einbringen zusätzlichen Ethyloleats in Dreifach Kohorten, testete ich, ob es einen direkten Einfluss auf die neuronale Plastizität der visuellen Eingangsregion des Pilzkörper Kalyx hat. Da durch die Pheromon Behandlung kein eindeutiger Verhaltensphänotyp (verzögerter Sammelbeginn) induziert werden konnte, war es nicht möglich einen direkten Zusammenhang zwischen der verstärkten Ethyloleat-Exposition und der neuronalen Plastizität des Kalyx des Pilzkörpers herzustellen. Dennoch bestätigten die Beobachtungen der synaptischen Reifung meine generellen Daten zu den natürlichen Reifungsprozessen im Kalyx des Pilzkörper. Basierend auf dem Ergebnis, dass dendritische Plastizität einen wesentlichen Anteil an der arbeitsteilungsbezogenen neuronalen Plastizität des Kalyx des Pilzkörper hat, stellte sich die Frage, welche Proteine daran beteiligt sein könnten diese Effekte zu vermitteln. Von der Calcium/Calmodulin abhängigen Kinase II (CaMKII) ist bekannt, dass sie speziell bei Säugetieren - aber bei Insekten (Drosophila, Schabe) - daran beteiligt ist, Lern- und Gedächtnisvorgänge, wie die Langzeitpotenzierung, zu ermöglichen. Neben präsynaptischen Effekten, wurde gezeigt, dass dieses Protein direkt mit Elementen des postsynaptischen Cytoskeletts interagieren kann. Als Teil meiner Dissertation habe ich das Vorkommen und die Verteilung der CaMKII analysiert. Ich konnte es hochkonzentriert in einer definierten Subpopulation der intrinsischen Pilzkörper-Neurone, den „nicht kompakten“ Kenyon Zellen, nachweisen. Das dendritische Netzwerk dieser Population verzweigt sich in zwei Kalyx Subregionen: eine olfaktorisch innervierte – die Lippe – und den Kragen, welcher optischen Eingang erfährt. Dieses Verteilungsmuster ändert sich nicht mit dem Alter oder der Aufgabe der Biene. Die hohe Konzentration von CaMKII in den dendritsichen Dornenfortsätzen und die gleichzeitige räumliche Überlappung mit f-Aktin, weisen darauf hin, dass CaMKII eine Schüsselrolle bei der Induzierung struktureller neuronaler Plastizität im Zusammenhang mit Lernen und Gedächtnisbildung und/oder Arbeitsteilung bezogener Verhaltensübergänge, zukommen könnte. Interessanterweise wies der Basalring, eine weitere Subregion des Kalyx des Pilzkörpers die dafür bekannt ist kombinierten visuellen und olfaktorischen Eingang zu erhalten und fast ausschließlich durch die „inneren kompakten“ Kenyon Zellen gebildet wird, keine Immunreaktivität auf. Dies deutet auf Unterschiede in den molekularen Mechanismen die plastische Veränderungen in den entsprechenden Kenyon zellen kontrollieren. Wie wird die zeitliche Abstimmung der Verhaltensplastizität und neuronalen Plastizität reguliert? Für das in hohen Konzentration auf Sammlerinnen vorkommende Primer Pheromon Ethyloelat konnte durch dessen Anwendung in erhöhten Konzentrationen gezeigt werden, dass es die Verhaltensreifung durch Verzögerung des Sammelbeginns beeinflussen kann. Wie aber wird Ethyloleat transferiert und wie verschiebt es die Arbeitskräfteverteilung zwischen Innen- und Außendienst Aufgaben? Frühere Arbeiten zeigten die höchste Konzentration von Ethyloleat im Sozialmagen der Sammlerinnen und schlugen vor, dass es innerhalb der Kolonie über Trophollaxis transferiert und kommuniziert wird. Die Ergebnisse meiner Arbeit zeigten aber eindeutig, dass Ethyloleat nicht im Inhalt des Sozialmagen und auch nicht im Regurgitat, sondern nur im Gewebe des Sozialmagens vorhanden ist. Da zusätzlich die zweithöchste Konzentration von Ethyloleat auf der Oberfläche der Kutikula von Sammlerinnen gemessen wurde, wurde Trophollaxis als Übertragungsmodus ausgeschlossen. Neurophysiologische Messungen an der Antenne (Elektroantennografie), dem ersten olfaktorischen Neuropil (Calcium Imaging der Aktivität des Antennallobus), zeigten, dass Ethyloleat als olfaktorischer Reiz wahrgenommen und prozessiert wird. Appetitive olfaktorische Konditionierung mit Hilfe des Rüsselstreckreflexes wurde als Verhaltensparadigma verwendet um zu zeigen, dass Ethyloleat mit einer Zuckerbelohnung assoziiert werden kann. Dies deutet darauf hin, dass Arbeiterinnen in der Lage sind, die Anwesenheit dieses Pheromons zu perzipieren, zu erlernen und sich auch daran zu erinnern. Da Ethyloleat nur durch Erwärmung als Stimulus präsentiert werden konnte, lässt sich schlussfolgern, dass es über Nahbereichs/Kontakt-Chemorezeption durch das olfaktorische System wahrgenommen wird. Dies wird auch durch frühere Verhaltensbeobachtungen unterstützt. Zusammengenommen, zeigen die in dieser Dissertation präsentierten Ergebnisse strukturelle Veränderungen in der synaptischen Architektur des Kalyx des Pilzkörpers in Zusammenhang mit Arbeitsteilung. Für das Primer Pheromone Ethyloleat, welches den Übergang von Ammendiensten zum Sammeln moduliert, zeigten die Ergebnisse eindeutig, dass es über das olfaktorische System wahrgenommen wird und vermutlich auch über diesen Weg seine Wirkung vermittelt. Dennoch konnten Manipulationsexperimente keine direkte Verbindung zwischen Ethyloleat und der synaptischen Reifung herstellen. Auf molekularer Ebene stellt CaMKII einen Topkandidaten dar, der strukturelle synaptische Plastizität im Kalyx des Pilzkörpers vermitteln kann. Eine Kombination struktureller und funktioneller Experimente ist der nächste logische Schritt um schlussendlich die Verbindung zwischen der Aktivität von Primer Pheromonen (wie Ethyloleat) und molekularen Signalwegen, die Verhaltensplastizität und synaptische Plastizität im Zusammenhang mit der Arbeitsteilung von Apis mellifera vermitteln, herzustellen. Die hierbei identifizierten zugrundeliegenden Prozesse werden als exzellente Modelle für ein generelles Verständnis der fundamentalen Mechanismen welche Verhaltensplastizität vermitteln, dienen.

Biene

Neuronale Plastizität

Pheromon

ddc:592

Molecular genetic and phenotypic analysis of a new C. elegans MAB mutant, mab-29

Canas Simoes, Mariana

January 2007

No description available.

592