@phdthesis{Cook2012, author = {Cook, Mandy}, title = {The neurodegenerative Drosophila melanogaster AMPK mutant loechrig}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-72027}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2012}, abstract = {In dieser Doktorarbeit wird die Drosophila Mutante loechrig (loe), die progressive Degeneration des Nervensystems aufweist, weiter beschrieben. In der loe Mutante fehlt eine neuronale Isoform der γ- Untereinheit der Proteinkinase AMPK (AMP-activated protein kinase). Die heterotrimere AMPK (auch als SNF4Aγ bekannt) kontrolliert das Energieniveau der Zelle, was st{\"a}ndiges Beobachten des ATP/AMP- Verh{\"a}ltnis erfordert. AMPK wird durch niedrige Energiekonzentrationen und Beeintr{\"a}chtigungen im Metabolismus, wie zum Beispiel Sauerstoffmangel, aktiviert und reguliert mehrere wichtige Signaltransduktionswege, die den Zellmetabolismus kontrollieren. Jedoch ist die Rolle von AMPK im neuronalen {\"U}berleben noch unklar. Eines der Proteine, dass von AMPK reguliert wird, ist HMGR (hydroxymethylglutaryl-CoA- reductase), ein Schl{\"u}sselenzym in der Cholesterin- und Isoprenoidsynthese. Es wurde gezeigt, dass wenn die Konzentration von HMGR manipuliert wird, auch der Schweregrad des neurodegenerativen Ph{\"a}notyps in loe beeinflusst wird. Obwohl die regulatorische Rolle von AMPK auf HMGR in Drosophila konserviert ist, k{\"o}nnen Insekten Cholesterin nicht de novo synthetisieren. Dennoch ist der Syntheseweg von Isoprenoiden zwischen Vertebraten und Insekten evolution{\"a}r konserviert. Isoprenylierung von Proteinen, wie zum Beispiel von kleinen G-Proteinen, stellt den Proteinen einen hydophobischen Anker bereit, mit denen sie sich an die Zellmembran binden k{\"o}nnen, was in anschließender Aktivierung resultieren kann. In dieser Doktorarbeit wird gezeigt, dass die loe Mutation die Prenylierung von Rho1 und den LIM-Kinasesignalweg beeinflusst, was eine wichtige Rolle im Umsatz von Aktin und axonalem Auswachsen spielt. Die Ergebnisse weisen darauf hin, dass die Mutation in LOE, Hyperaktivit{\"a}t des Isoprenoidsynthesewegs verursacht, was zur erh{\"o}hten Farnesylierung von Rho1 und einer dementsprechend h{\"o}heren Konzentration von Phospho- Cofilin f{\"u}hrt. Eine Mutation in Rho1 verbessert den neurodegenerativen Ph{\"a}notyp und die Lebenserwartung von loe. Der Anstieg vom inaktiven Cofilin in loe f{\"u}hrt zu einer Zunahme von filament{\"o}sen Aktin. Aktin ist am Auswachen von Neuronen beteiligt und Experimente in denen loe Neurone analysiert wurden, gaben wertvolle Einblicke in eine m{\"o}gliche Rolle die AMPK, und dementsprechend Aktin, im Neuronenwachstum spielt. Des Weiteren wurde demonstriert, dass Neurone, die von der loe Mutante stamen, einen verlangsamten axonalen Transport aufweisen, was darauf hinweist dass Ver{\"a}nderungen, die durch den Einfluss von loe auf den Rho1 Signalweg im Zytoskelettnetzwerk hervorgerufen wurden, zur St{\"o}rung des axonalen Transports und anschließenden neuronalen Tod f{\"u}hren. Es zeigte außerdem, dass Aktin nicht nur am neuronalen Auswachsen beteiligt ist, sondern auch wichtig f{\"u}r die Aufrechterhaltung von Neuronen ist. Das bedeutet, dass {\"A}nderungen der Aktindynamik zur progressiven Degeneration von Neuronen f{\"u}hren kann. Zusammenfassend unterstreichen diese Ergebnisse die wichtige Bedeutung von AMPK in den Funktionen und im {\"U}berleben von Neuronen und er{\"o}ffnen einen neuartigen funktionellen Mechanismus in dem {\"A}nderungen in AMPK neuronale Degeneration hervorrufen kann.}, subject = {Taufliege}, language = {en} } @phdthesis{Kistenpfennig2012, author = {Kistenpfennig, Christa}, title = {Rhodopsin 7 and Cryptochrome - circadian photoreception in Drosophila}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-72209}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2012}, abstract = {Many organisms evolved an endogenous clock to adapt to the daily environmental changes caused by the earth's rotation. Light is the primary time cue ("Zeitgeber") for entrainment of circadian clocks to the external 24-h day. In Drosophila, several visual pigments are known to mediate synchronization to light: The blue-light photopigment Cryptochrome (CRY) and six well-described rhodopsins (Rh1-Rh6). CRY is present in the majority of clock neurons as well as in the compound eyes, whereas the location of rhodopsins is restricted to the photoreceptive organs - the compound eyes, the ocelli and the HB-eyelets. CRY is thought to represent the key photoreceptor of Drosophila's circadian clock. Nevertheless, mutant flies lacking CRY (cry01) are able to synchronize their locomotor activity rhythms to light-dark (LD) cycles, but need significantly longer than wild-type flies. In this behavior, cry01 mutants strongly resemble mammalian species that do not possess any internal photoreceptors and perceive light information exclusively through their photoreceptive organs (eyes). Thus, a mammalian-like phase-shifting behavior would be expected in cry01 flies. We investigated this issue by monitoring a phase response curve (PRC) of cry01 and wild-type flies to 1-h light pulses of 1000 lux irradiance. Indeed, cry01 mutants produced a mammalian-similar so called type 1 PRC of comparatively low amplitude (< 25\% of wild-type) with phase delays to light pulses during the early subjective night and phase advances to light pulses during the late subjective night (~1 h each). Despite the predominant role of CRY, the visual system contributes to the light sensitivity of the fly's circadian clock, mainly around dawn and dusk. Furthermore, this phase shifting allows for the slow re-entrainment which we observed in cry01 mutants to 8-h phase delays of the LD 12 h:12 h cycle. However, cry01 also showed surprising differences in their shifting ability: First of all, their PRC was characterized by a second dead zone in the middle of the subjective night (ZT17-ZT19) in addition to the usual unresponsiveness during the subjective day. Second, in contrast to wild-type flies, cry01 mutants did not increase their shift of activity rhythms neither in response to longer stimuli nor to light pulses of higher irradiance. In contrast, both 6-h light pulses of 1000 lux and 1-h light pulses of 10,000 lux light intensity during the early subjective night even resulted in phase advances instead of the expected delays. Thus, CRY seems to be not only responsible for the high light sensitivity of the wild-type circadian clock, but is apparently also involved in integrating and processing light information. Rhodopsin 7 (Rh7) is a yet uncharacterized protein, but became a good photoreceptor candidate due to sequence similarities to the six known Drosophila Rhs. The second part of this thesis investigated the expression pattern of Rh7 and its possible functions, especially in circadian photoreception. Furthermore, we were interested in a potential interaction with CRY and thus, tested cry01 and rh70 cry01 mutants as well. Rh1 is the main visual pigment of the Drosophila compound eye and expressed in six out of eight photoreceptors cells (R1-R6) in each of the ~800 ommatidia. Motion vision depends exclusively on Rh1 function but, moreover, Rh1 plays an important structural role and assures proper photoreceptor cell development and maintenance. In order to investigate its possible photoreceptive function, we expressed Rh7 in place of Rh1. Rh7 was indeed able to overtake the role of Rh1 in both aspects: It prevented retinal degeneration and mediated the optomotor response (OR), a motion vision-dependent behavior. At the transcriptional level, rh7 is expressed at approximately equal amounts in adult fly brains and retinas. Due to a reduced specificity of anti-Rh7 antibodies, we could not verify this result at the protein level. However, analysis of rh7 null mutants (rh70) suggested different Rh7 functions in vivo. Previous experiments strongly indicated an increased sensitivity of the compound eyes in the absence of Rh7 and suggested impaired light adaptation. We aimed to test this hypothesis at the levels of circadian photoreception. Locomotor activity rhythms are a reliable output of the circadian clock. Rh70 mutant flies generally displayed a wild-type similar bimodal activity pattern comprising morning (M) and evening (E) activity bouts. Activity monitoring supported the proposed "shielding" function, since rh70 mutants behaved like wild-type flies experiencing high irradiances. Under all investigated conditions, their activity peaks lay further apart resulting in a prolonged midday break. The behavior of cry01 mutants was mainly characterized by an unexpectedly high flexibility in the timing of M and E activity bouts which allowed tracking of lights-on and lights-off even under extreme photoperiods. Activity profiles of the corresponding rh70 cry01 double mutants reflected neither synergistic nor antagonistic effects of Rh7 and CRY and were dominated by a broad E activity peak. In the future, the different circadian phenotypes will be further investigated on the molecular level by analysis of clock protein cycling in the underlying pacemaker neurons. The work of this thesis confirmed that Rh7 is indeed able to work as a photoreceptor and to initiate the classical phototransduction cascade. On the other hand, it provided further evidence at the levels of circadian photoreception that Rh7 might serve as a shielding pigment for Rh1 in vivo, thereby mediating proper light adaptation.}, language = {en} } @phdthesis{Schleyer2012, author = {Schleyer, Michael}, title = {Integrating past, present and future: mechanisms of a simple decision in larval Drosophila}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-78923}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2012}, abstract = {Is behaviour response or action? In this Thesis I study this question regarding a rather simple organism, the larva of the fruit fly Drosophila melanogaster. Despite its numerically simple brain and limited behavioural repertoire, it is nevertheless capable to accomplish surprisingly complex tasks. After association of an odour and a rewarding or punishing reinforcement signal, the learnt odour is able to retrieve the formed memory trace. However, the activated memory trace is not automatically turned into learned behaviour: Appetitive memory traces are behaviourally expressed only in absence of the rewarding tastant whereas aversive memory traces are behaviourally expressed in the presence of the punishing tastant. The 'decision' whether to behaviourally express a memory trace or not relies on a quantitive comparison between memory trace and current situation: only if the memory trace (after odour-sugar training) predicts a stronger sugar reward than currently present, animals show appetitive conditioned behaviour. Learned appetitive behaviour is best seen as active search for food - being pointless in the presence of (enough) food. Learned aversive behaviour, in turn, can be seen as escape from a punishment - being pointless in absence of punishment. Importantly, appetitive and aversive memory traces can be formed and retrieved independent from each other but also can, under appriate circumstances, summate to jointly organise conditioned behaviour. In contrast to learned behaviour, innate olfactory behaviour is not influenced by gustatory processing and vice versa. Thus, innate olfactory and gustatory behaviour is rather rigid and reflexive in nature, being executed almost regardless of other environmental cues. I suggest a behavioural circuit-model of chemosensory behaviour and the 'decision' process whether to behaviourally express a memory trace or not. This model reflects known components of the larval chemobehavioural circuit and provides clear hypotheses about the kinds of architecture to look for in the currently unknown parts of this circuit. The second chapter deals with gustatory perception and processing (especially of bitter substances). Quinine, the bitter tastant in tonic water and bitter lemon, is aversive for larvae, suppresses feeding behaviour and can act as aversive reinforcer in learning experiments. However, all three examined behaviours differ in their dose-effect dynamics, suggesting different molecular and cellular processing streams at some level. Innate choice behaviour, thought to be relatively reflexive and hard-wired, nevertheless can be influenced by the gustatory context. That is, attraction toward sweet tastants is decreased in presence of bitter tastants. The extent of this inhibitory effect depends on the concentration of both sweet and bitter tastant. Importantly, sweet tastants differ in their sensitivity to bitter interference, indicating a stimulus-specific mechanism. The molecular and cellular processes underlying the inhibitory effect of bitter tastants are unknown, but the behavioural results presented here provide a framework to further investigate interactions of gustatory processing streams.}, subject = {Lernen}, language = {en} } @phdthesis{Chen2012, author = {Chen, Yi-chun}, title = {Experimental access to the content of an olfactory memory trace in larval Drosophila}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-83705}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2012}, abstract = {Animals need to evaluate their experiences in order to cope with new situations they encounter. This requires the ability of learning and memory. Drosophila melanogaster lends itself as an animal model for such research because elaborate genetic techniques are available. Drosphila larva even saves cellular redundancy in parts of its nervous system. My Thesis has two parts dealing with associative olfactory learning in larval Drosophila. Firstly, I tackle the question of odour processing in respect to odour quality and intensity. Secondly, by focusing on the evolutionarily conserved presynaptic protein Synapsin, olfactory learning on the cellular and molecular level is investigated. Part I.1. provides a behaviour-based estimate of odour similarity in larval Drosophila by using four recognition-type experiments to result in a combined, task-independent estimate of perceived difference between odour-pairs. A further comparison of these combined perceived differences to published calculations of physico-chemical difference reveals a weak correlation between perceptual and physico-chemical similarity. Part I.2. focuses on how odour intensity is interpreted in the process of olfactory learning in larval Drosophila. First, the dose-effect curves of learnability across odour intensities are described in order to choose odour intensities such that larvae are trained at intermediate odour intensity, but tested for retention either with that trained intermediate odour intensity, or with respectively HIGHer or LOWer intensities. A specificity of retention for the trained intensity is observed for all the odours used. Such intensity specificity of learning adds to appreciate the richness in 'content' of olfactory memory traces, and to define the demands on computational models of associative olfactory memory trace formation. In part II.1. of the thesis, the cellular site and molecular mode of Synapsin function is investigated- an evolutionarily conserved, presynaptic vesicular phosphoprotein. On the cellular level, the study shows a Synapsin-dependent memory trace in the mushroom bodies, a third-order "cortical" brain region of the insects; on the molecular level, Synapsin engages as a downstream element of the AC-cAMP-PKA signalling cascade.}, subject = {Taufliege}, language = {en} }