@phdthesis{Amini2024, author = {Amini, Emad}, title = {How central and peripheral clocks and the neuroendocrine system interact to time eclosion behavior in \(Drosophila\) \(melanogaster\)}, doi = {10.25972/OPUS-36130}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-361309}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2024}, abstract = {To grow larger, insects must shed their old rigid exoskeleton and replace it with a new one. This process is called molting and the motor behavior that sheds the old cuticle is called ecdysis. Holometabolic insects have pupal stages in between their larval and adult forms, during which they perform metamorphosis. The pupal stage ends with eclosion, i.e., the emergence of the adult from the pupal shell. Insects typically eclose at a specific time during the day, likely when abiotic conditions are at their optimum. A newly eclosed insect is fragile and needs time to harden its exoskeleton. Hence, eclosion is regulated by sophisticated developmental and circadian timing mechanisms. In Drosophila melanogaster, eclosion is limited to a daily time window in the morning, regarded as the "eclosion gate". In a population of laboratory flies entrained by light/dark cycles, most of the flies eclose around lights on. This rhythmic eclosion pattern is controlled by the circadian clock and persists even under constant conditions. Developmental timing is under the control of complex hormonal signaling, including the steroid ecdysone, insulin-like peptides, and prothoracicotropic hormone (PTTH). The interactions of the central circadian clock in the brain and a peripheral clock in the prothoracic gland (PG) that produces ecdysone are important for the circadian timing of eclosion. These two clocks are connected by a bilateral pair of peptidergic PTTH neurons (PTTHn) that project to the PG. Before each molt, the ecdysone level rises and then falls shortly before ecdysis. The falling ecdysone level must fall below a certain threshold value for the eclosion gate to open. The activity of PTTHn is inhibited by short neuropeptide F (sNPF) from the small ventrolateral neurons (sLNvs) and inhibition is thought to lead to a decrease in ecdysone production. The general aim of this thesis is to further the understanding of how the circadian clock and neuroendocrinal pathways are coordinated to drive eclosion rhythmicity and to identify when these endocrinal signaling pathways are active. In Chapter I, a series of conditional PTTHn silencing-based behavioral assays, combined with neuronal activity imaging techniques such as non-invasive ARG-Luc show that PTTH signaling is active and required shortly before eclosion and may serve to phase-adjust the activity of the PG at the end of pupal development. Trans-synaptic anatomical stainings identified the sLNvs, dorsal neurons 1 (DN1), dorsal neurons 2 (DN2), and lateral posterior neurons (LPNs) clock neurons as directly upstream of the PTTHn. Eclosion motor behavior is initiated by Ecdysis triggering hormone (ETH) which activates a pair of ventromedial (Vm) neurons to release eclosion hormone (EH) which positively feeds back to the source of ETH, the endocrine Inka cells. In Chapter II trans-synaptic tracing showed that most clock neurons provide input to the Vm and non-canonical EH neurons. Hence, clock can potentially influence the ETH/EH feedback loop. The activity profile of the Inka cells and Vm neurons before eclosion is described. Vm and Inka cells are active around seven hours before eclosion. Interestingly, all EH neurons appear to be exclusively peptidergic. In Chapter III, using chemoconnectomics, PTTHns were found to express receptors for sNPF, allatostatin A (AstA), allatostatin C (AstC), and myosuppressin (Ms), while EH neurons expressed only Ms and AstA receptors. Eclosion assays of flies with impaired AstA, AstC, or Ms signaling do not show arrhythmicity under constant conditions. However, optogenetic activation of the AstA neurons strongly suppresses eclosion. Chapter IV focuses on peripheral ventral' Tracheal dendrite (v'Td) and class IV dendritic arborization (C4da) neurons. The C4da neurons mediate larval light avoidance through endocrine PTTH signaling. The v'Td neurons mainly receive O2/CO2 input from the trachea and are upstream of Vm neurons but are not required for eclosion rhythmicity. Conditional ablation of the C4da neurons or torso (receptor of PTTH) knock-out in the C4da neurons impaired eclosion rhythmicity. Six to seven hours before eclosion, PTTHn, C4da, and Vm neurons are active based on ARG-Luc imaging. Thus, C4da neurons may indirectly connect the PTTHn to the Vm neurons. In summary, this thesis advances our knowledge of the temporal activity and role of PTTH signaling during pupal development and rhythmic eclosion. It further provides a comprehensive characterization of the synaptic and peptidergic inputs from clock neurons to PTTHn and EH neurons. AstA, AstC, and Ms are identified as potential modulators of eclosion circuits and suggest an indirect effect of PTTH signaling on EH signaling via the peripheral sensory C4da neurons.}, subject = {Neuroendokrines System}, language = {en} } @phdthesis{Andlauer2013, author = {Andlauer, Till Felix Malte}, title = {Structural and Functional Diversity of Synapses in the Drosophila CNS}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-85018}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2013}, abstract = {Large-scale anatomical and functional analyses of the connectivity in both invertebrate and mammalian brains have gained intense attention in recent years. At the same time, the understanding of synapses on a molecular level still lacks behind. We have only begun to unravel the basic mechanisms of how the most important synaptic proteins regulate release and reception of neurotransmitter molecules, as well as changes of synaptic strength. Furthermore, little is known regarding the stoichiometry of presynaptic proteins at different synapses within an organism. An assessment of these characteristics would certainly promote our comprehension of the properties of different synapse types. Presynaptic proteins directly influence, for example, the probability of neurotransmitter release as well as mechanisms for short-term plasticity. We have examined the strength of expression of several presynaptic proteins at different synapse types in the central nervous system of Drosophila melanogaster using immunohistochemistry. Clear differences in the relative abundances of the proteins were obvious on different levels: variations in staining intensities appeared from the neuropil to the synaptic level. In order to quantify these differences, we have developed a ratiometric analysis of antibody stainings. By application of this ratiometric method, we could assign average ratios of presynaptic proteins to different synapse populations in two central relays of the olfactory pathway. In this manner, synapse types could be characterized by distinct fingerprints of presynaptic protein ratios. Subsequently, we used the method for the analysis of aberrant situations: we reduced levels of Bruchpilot, a major presynaptic protein, and ablated different synapse or cell types. Evoked changes of ratio fingerprints were proportional to the modifications we had induced in the system. Thus, such ratio signatures are well suited for the characterization of synapses. In order to contribute to our understanding of both the molecular composition and the function of synapses, we also characterized a novel synaptic protein. This protein, Drep-2, is a member of the Dff family of regulators of apoptosis. We generated drep-2 mutants, which did not show an obvious misregulation of apoptosis. By contrast, Drep-2 was found to be a neuronal protein, highly enriched for example at postsynaptic receptor fields of the input synapses of the major learning centre of insects, the mushroom bodies. Flies mutant for drep-2 were viable but lived shorter than wildtypes. Basic synaptic transmission at both peripheral and central synapses was in normal ranges. However, drep-2 mutants showed a number of deficiencies in adaptive behaviours: adult flies were locomotor hyperactive and hypersensitive towards ethanol-induced sedation. Moreover, the mutant animals were heavily impaired in associative learning. In aversive olfactory conditioning, drep-2 mutants formed neither short-term nor anaesthesia-sensitive memories. We could demonstrate that Drep-2 is required in mushroom body intrinsic neurons for normal olfactory learning. Furthermore, odour-evoked calcium transients in these neurons, a prerequisite for learning, were reduced in drep-2 mutants. The impairment of the mutants in olfactory learning could be fully rescued by pharmacological application of an agonist to metabotropic glutamate receptors (mGluRs). Quantitative mass spectrometry of Drep-2 complexes revealed that the protein is associated with a large number of translational repressors, among them the fragile X mental retardation protein FMRP. FMRP inhibits mGluR-mediated protein synthesis. Lack of this protein causes the fragile X syndrome, which constitutes the most frequent monogenic cause of autism. Examination of the performance of drep-2 mutants in courtship conditioning showed that the animals were deficient in both short- and long-term memory. Drep-2 mutants share these phenotypes with fmrp and mGluR mutants. Interestingly, drep-2; fmrp double mutants exhibited normal memory. Thus, we propose a model in which Drep-2 antagonizes FMRP in the regulation of mGluR-dependent protein synthesis. Our hypothesis is supported by the observation that impairments in synaptic plasticity can arise if mGluR signalling is imbalanced in either direction. We suggest that Drep-2 helps in establishing this balance.}, subject = {Taufliege}, language = {en} } @phdthesis{Aso2010, author = {Aso, Yoshinori}, title = {Dissecting the neuronal circuit for olfactory learning in Drosophila}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-55483}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2010}, abstract = {This thesis consists of three major chapters, each of which has been separately published or under the process for publication. The first chapter is about anatomical characterization of the mushroom body of adult Drosophila melanogaster. The mushroom body is the center for olfactory learning and many other functions in the insect brains. The functions of the mushroom body have been studied by utilizing the GAL4/UAS gene expression system. The present study characterized the expression patterns of the commonly used GAL4 drivers for the mushroom body intrinsic neurons, Kenyon cells. Thereby, we revealed the numerical composition of the different types of Kenyon cells and found one subtype of the Kenyon cells that have not been described. The second and third chapters together demonstrate that the multiple types of dopaminergic neurons mediate the aversive reinforcement signals to the mushroom body. They induce the parallel memory traces that constitute the different temporal domains of the aversive odor memory. In prior to these chapters, "General introduction and discussion" section reviews and discuss about the current understanding of neuronal circuit for olfactory learning in Drosophila.}, subject = {Taufliege}, language = {en} } @phdthesis{Batsching2016, author = {Batsching, Sophie Johanna}, title = {Behavior under uncontrollable stress in \(Drosophila\) \(melanogaster\) - Learned Helplessness revisited}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-145416}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2016}, abstract = {In order to select the appropriate behavior, it is important to choose the right behavior at the right time out of many options. It still remains unclear nowadays how exactly this is managed. To address this question, I expose flies (Drosophila melanogaster) to uncontrollable stress to study their behavior under restrictive circumstances by using the so-called shock box. Exposing animals to uncontrollable stress may have an impact on subsequent behavior and can last for some time. The animal learns that whatever it does, it cannot change the situation and therefore can develop something called learned helplessness. The term was first conceptualized by two American psychologists Maier and Seligman (1967), who discovered this phenomenon while doing experiments with dogs. They found out that dogs which are exposed to inescapable stress, later fail in a learning task ('shuttle box'). In this work the walking patterns of three different types of experimental flies, walking in a small dark chamber, were evaluated. Using the triadic design (Seligman and Maier, 1967), flies were either exposed to electric shock randomly (yoked), could turn it off by being active (master) or did not receive punishment at all (control). Master flies were shocked whenever they sat for more than 0.9 seconds. At the same time yoked flies received a shock as well independent of what they were doing, to ensure the same amount of shocks received and to create random punishment pattern for the yoked group. With this so-called no-idleness paradigm flies were conditioned either 10 minutes, which resulted in a short (3 minutes) after-effect, or 20 minutes that turned out to be more stable (10 minutes). In a second part, the behavior during the 20 minute conditioning and a 10 minutes post-test was described in detail. Female flies of the yoked group developed lower activity levels, longer pauses and walked more slowly than master and control flies during conditioning. In the time after the shocks while still in the box, the yoked flies also reduced the frequency and duration of walking bouts as well as their walking speed. Additionally, they took more time to resume walking after the onset of an electric shock than master flies (escape latency) and turned out to make less pauses lasting between 1-1.5 seconds which supports the finding concerning the escape latency. Male flies, tested under the same conditions, showed a slightly weaker after-effect regarding the difference between master and yoked during conditioning and post-test when compared to female flies. When comparing the 20 minutes conditioning with subsequent 10 minutes test in the heat and the shock box in parallel, one finds the same effect: Flies which do not have control over the shocks, lower their activity, make less but longer pauses and walk more slowly than their respective master flies. Despite the similar effect of heat and shock on the flies, some differences between the devices occurred, which can partly be explained by different humidity conditions as well as by different surfaces within the chambers. When the control over the shocks is given back to the yoked flies, it takes them about seven minutes to realize it. One could also show that dopamine levels in the brain were reduced in comparison to flies which did not receive shocks. Yoked flies also were impaired in a place learning task (place learning) and their reaction to light (exit from the box towards the light) directly after conditioning. After characterizing the walking behavior in the chambers, the study deals with the question whether the effects observed in the chambers transfer to different environments. In free walk they only differed from flies which did not receive electric shocks and no effect of uncontrollability was transferred to courtship behavior. Handling as the cause could be excluded. Since handling could be exclude to be the cause of losing the effect, I assumed that the behavior shown in the boxes are context depend. Not only were the after-effects of inescapable shock subject of the current research also the impact of the rearing situation on the response to electric shock was investigated in the present study. Flies which grew up in a single-reared situation turned out to be less affected by inescapable stress in both sexes. In the next part, the first steps to unravel the neuronal underpinning were taken. A mutant - fumin - which is defective in the dopamine re-uptake transporter showed less reaction to inescapable foot shocks, while a mutant for the gene which encodes an adenylate cyclase (rutabaga2080) resulted in a good score during conditioning, but showed no stable after-effect. Downregulating the expression of the adenylate cyclase gene (rutabaga) in different parts of the mushroom bodies showed, that rutabaga is necessary in the α'β'-lobes for expressing the differences between master and yoked flies in the no-idleness paradigm. The study further confirmed previous findings, that rutabaga is needed in operant but not in classical conditioning. As a result, the study could show that not the stimulus itself causes the state of uncontrollability but the fact that the fly learned that it was not in control of the stimulus. This state turned out to be context and time dependent.}, subject = {Taufliege}, language = {en} } @phdthesis{Beck2019, author = {Beck, Sebastian}, title = {Using optogenetics to influence the circadian clock of \(Drosophila\) \(melanogaster\)}, doi = {10.25972/OPUS-18495}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-184952}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2019}, abstract = {Almost all life forms on earth have adapted to the most impactful and most predictable recurring change in environmental condition, the cycle of day and night, caused by the axial rotation of the planet. As a result many animals have evolved intricate endogenous clocks, which adapt and synchronize the organisms' physiology, metabolism and behaviour to the daily change in environmental conditions. The scientific field researching these endogenous clocks is called chronobiology and has steadily grown in size, scope and relevance since the works of the earliest pioneers in the 1960s. The number one model organism for the research of circadian clocks is the fruit fly, Drosophila melanogaster, whose clock serves as the entry point to understanding the basic inner workings of such an intricately constructed endogenous timekeeping system. In this thesis it was attempted to combine the research on the circadian clock with the techniques of optogenetics, a fairly new scientific field, launched by the discovery of Channelrhodopsin 2 just over 15 years ago. Channelrhodopsin 2 is a light-gated ion channel found in the green alga Chlamydomonas reinhardtii. In optogenetics, researches use these light-gated ion channels like Channelrhodopsin 2 by heterologously expressing them in cells and tissues of other organisms, which can then be stimulated by the application of light. This is most useful when studying neurons, as these channels provide an almost non-invasive tool to depolarize the neuronal plasma membranes at will. The goal of this thesis was to develop an optogenetic tool, which would be able to influence and phase shift the circadian clock of Drosophila melanogaster upon illumination. A phase shift is the adaptive response of the circadian clock to an outside stimulus that signals a change in the environmental light cycle. An optogenetic tool, able to influence and phase shift the circadian clock predictably and reliably, would open up many new ways and methods of researching the neuronal network of the clock and which neurons communicate to what extent, ultimately synchronizing the network. The first optogenetic tool to be tested in the circadian clock of Drosophila melanogaster was ChR2-XXL, a channelrhodopsin variant with dramatically increased expression levels and photocurrents combined with a prolonged open state. The specific expression of ChR2-XXL and of later constructs was facilitated by deploying the three different clock-specific GAL4-driver lines, clk856-gal4, pdf-gal4 and mai179-gal4. Although ChR2-XXL was shown to be highly effective at depolarizing neurons, these stimulations proved to be unable to significantly phase shift the circadian clock of Drosophila. The second series of experiments was conducted with the conceptually novel optogenetic tools Olf-bPAC and SthK-bPAC, which respectively combine a cyclic nucleotide-gated ion channel (Olf and SthK) with the light-activated adenylyl-cyclase bPAC. These tools proved to be quite useful when expressed in the motor neurons of instar-3 larvae of Drosophila, paralyzing the larvae upon illumination, as well as affecting body length. This way, these new tools could be precisely characterized, spawning a successfully published research paper, centered around their electrophysiological characterization and their applicability in model organisms like Drosophila. In the circadian clock however, these tools caused substantial damage, producing severe arrhythmicity and anomalies in neuronal development. Using a temperature-sensitive GAL80-line to delay the expression until after the flies had eclosed, yielded no positive results either. The last series of experiments saw the use of another new series of optogenetic tools, modelled after the Olf-bPAC, with bPAC swapped out for CyclOp, a membrane-bound guanylyl-cyclase, coupled with less potent versions of the Olf. This final attempt however also ended up being unsuccessful. While these tools could efficiently depolarize neuronal membranes upon illumination, they were ultimately unable to stimulate the circadian clock in way that would cause it to phase shift. Taken together, these mostly negative results indicate that an optogenetic manipulation of the circadian clock of Drosophila melanogaster is an extremely challenging subject. As light already constitutes the most impactful environmental factor on the circadian clock, the combination of chronobiology with optogenetics demands the parameters of the conducted experiments to be tuned with an extremely high degree of precision, if one hopes to receive positive results from these types of experiments at all.}, subject = {Chronobiologie}, language = {en} } @phdthesis{Bertolucci2008, author = {Bertolucci, Franco}, title = {Operant and classical learning in Drosophila melanogaster: the ignorant gene (ign)}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-33984}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2008}, abstract = {One of the major challenges in neuroscience is to understand the neuronal processes that underlie learning and memory. For example, what biochemical pathways underlie the coincidence detection between stimuli during classical conditioning, or between an action and its consequences during operant conditioning? In which neural substructures is this information stored? How similar are the pathways mediating these two types of associative learning and at which level do they diverge? The fly Drosophila melanogaster is an appropriate model organism to address these questions due to the availability of suitable learning paradigms and neurogenetic tools. It permits an extensive study of the functional role of the gene S6KII which in Drosophila had been found to be differentially involved in classical and operant conditioning (Bertolucci, 2002; Putz et al., 2004). Genomic rescue experiments showed that olfactory conditioning in the Tully machine, a paradigm for Pavlovian olfactory conditioning, depends on the presence of an intact S6KII gene. This rescue was successfully performed on both the null mutant and a partial deletion, suggesting that the removal of the phosphorylating unit of the kinase was the main cause of the functional defect. The GAL4/UAS system was used to achieve temporal and spatial control of S6KII expression. It was shown that expression of the kinase during the adult stage was essential for the rescue. This finding ruled out a developmental origin of the mutant learning phenotype. Furthermore, targeted spatial rescue of S6KII revealed a requirement in the mushroom bodies and excluded other brain structures like the median bundle, the antennal lobes and the central complex. This pattern is very similar to the one previously identified with the rutabaga mutant (Zars et al., 2000). Experiments with the double mutant rut, ign58-1 suggest that both rutabaga and S6KII operate in the same signalling pathway. Previous studies had already shown that deviating results from operant and classical conditioning point to different roles for S6KII in the two types of learning (Bertolucci, 2002; Putz, 2002). This conclusion was further strengthened by the defective performance of the transgenic lines in place learning and their normal behavior in olfactory conditioning. A novel type of learning experiment, called "idle experiment", was designed. It is based on the conditioning of the walking activity and represents a purely operant task, overcoming some of the limitations of the "standard" heat-box experiment, a place learning paradigm. The novel nature of the idle experiment allowed exploring "learned helplessness" in flies, unveiling astonishing similarities to more complex organisms such as rats, mice and humans. Learned helplessness in Drosophila is found only in females and is sensitive to antidepressants.}, subject = {Klassische Konditionierung}, language = {en} } @phdthesis{BlancoRedondo2014, author = {Blanco Redondo, Beatriz}, title = {Studies of synapsin phosphorylation and characterization of monoclonal antibodies from the W{\"u}rzburg Hybridoma Library in Drosophila melanogaster}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-93766}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2014}, abstract = {Synapsins are conserved synapse-associated hosphoproteins involved in the fine regulation of neurotransmitter release. The aim of the present project is to study the phosphorylation of synapsins and the distribution of phospho-synapsin in the brain of Drosophila melanogaster. Three antibodies served as important tools in this work, a monoclonal antibody (3C11/α-Syn) that recognizes all known synapsin isoforms and two antisera against phosphorylated synapsin peptides (antiserum PSyn(S6) against phospho-serine 6 and antiserum PSyn(S464) against phospho-serine 464). These antisera were recently generated in collaboration with Bertram Gerber and Eurogentec. ...}, subject = {Synapsine}, language = {en} } @phdthesis{Brembs2000, author = {Brembs, Bj{\"o}rn}, title = {An Analysis of Associative Learning in Drosophila at the Flight Simulator}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-1039}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2000}, abstract = {Most natural learning situations are of a complex nature and consist of a tight conjunction of the animal's behavior (B) with the perceived stimuli. According to the behavior of the animal in response to these stimuli, they are classified as being either biologically neutral (conditioned stimuli, CS) or important (unconditioned stimuli, US or reinforcer). A typical learning situation is thus identified by a three term contingency of B, CS and US. A functional characterization of the single associations during conditioning in such a three term contingency has so far hardly been possible. Therefore, the operational distinction between classical conditioning as a behavior-independent learning process (CS-US associations) and operant conditioning as essentially behavior-dependent learning (B-US associations) has proven very valuable. However, most learning experiments described so far have not been successful in fully separating operant from classical conditioning into single-association tasks. The Drosophila flight simulator in which the relevant behavior is a single motor variable (yaw torque), allows for the first time to completely separate the operant (B-US, B-CS) and the classical (CS-US) components of a complex learning situation and to examine their interactions. In this thesis the contributions of the single associations (CS-US, B-US and B-CS) to memory formation are studied. Moreover, for the first time a particularly prominent single association (CS-US) is characterized extensively in a three term contingency. A yoked control shows that classical (CS-US) pattern learning requires more training than operant pattern learning. Additionally, it can be demonstrated that an operantly trained stimulus can be successfully transferred from the behavior used during training to a new behavior in a subsequent test phase. This result shows unambiguously that during operant conditioning classical (CS-US) associations can be formed. In an extension to this insight, it emerges that such a classical association blocks the formation of an operant association, which would have been formed without the operant control of the learned stimuli. Instead the operant component seems to develop less markedly and is probably merged into a complex three-way association. This three-way association could either be implemented as a sequential B-CS-US or as a hierarchical (B-CS)-US association. The comparison of a simple classical (CS-US) with a composite operant (B, CS and US) learning situation and of a simple operant (B-US) with another composite operant (B, CS and US) learning situation, suggests a hierarchy of predictors of reinforcement. Operant behavior occurring during composite operant conditioning is hardly conditioned at all. The associability of classical stimuli that bear no relation to the behavior of the animal is of an intermediate value, as is operant behavior alone. Stimuli that are controlled by operant behavior accrue associative strength most easily. If several stimuli are available as potential predictors, again the question arises which CS-US associations are formed? A number of different studies in vertebrates yielded amazingly congruent results. These results inspired to examine and compare the properties of the CS-US association in a complex learning situation at the flight simulator with these vertebrate results. It is shown for the first time that Drosophila can learn compound stimuli and recall the individual components independently and in similar proportions. The attempt to obtain second-order conditioning with these stimuli, yielded a relatively small effect. In comparison with vertebrate data, blocking and sensory preconditioning experiments produced conforming as well as dissenting results. While no blocking could be found, a sound sensory preconditioning effect was obtained. Possible reasons for the failure to find blocking are discussed and further experiments are suggested. The sensory preconditioning effect found in this study is revealed using simultaneous stimulus presentation and depends on the amount of preconditioning. It is argued that this effect is a case of 'incidental learning', where two stimuli are associated without the need of reinforcement. Finally, the implications of the results obtained in this study for the general understanding of memory formation in complex learning situations are discussed.}, subject = {Taufliege}, language = {en} } @phdthesis{Chen2018, author = {Chen, Jiangtian}, title = {Functions of allatostatin A (AstA) and myoinhibitory peptides (MIPs) in the regulation of food intake and sleep in Drosophila}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-156838}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2018}, abstract = {Neuropeptides and peptide hormones carrying neural or physiological information are intercellular signalling substances. They control most if not all biological processes in vertebrates and invertebrates by acting on specific receptors on the target cell. In mammals, many different neuropeptides and peptide hormones are involved in the regulation of feeding and sleep. In \textit{Drosophila}, allatostatin A (AstA) and myoinhibitory peptides (MIPs) are brain-gut peptides. The AstA receptors are homologues of the mammalian galanin receptors and the amino acid sequences of MIPs are similar to a part of galanin, which has an orexigenic effect and is implicated in the control of sleep behaviour in mammals. I am interested in dissecting pleiotropic functions of AstA and MIPs in the regulation of food intake and sleep in \textit{Drosophila}. \par In the first part of the dissertation the roles of brain-gut peptide allatostatin A are analysed. Due to the genetic and molecular tools available, the fruit fly \textit{Drosophila melanogaster} is chosen to investigate functions of AstA. The aims in this part are to identify pleiotropic functions of AstA and assign specific effects to the activity of certain subsets of AstA expressing cells in \textit{Drosophila} adults. A new and restricted \textit{AstA\textsuperscript{34}-Gal4} line was generated. The confocal imaging result showed that AstA neurons are located in the posterior lateral protocerebrum (PLP), the gnathal ganglia (GNG), the medullae, and thoracic-abdominal ganglion (TAG). AstA producing DLAa neurons in the TAG innervate hindgut and the poterior part of midgut. In addition, AstA are detected in the enteroendocrine cells (EECs).\par Thermogenetic activation and neurogenetic silencing tools with the aid of the \textit{UAS/Gal4} system were employed to manipulate the activity of all or individual subsets of AstA cells and investigate the effects on food intake, locomotor activity and sleep. Our experimental results showed that thermogenetic activation of two pairs of PLP neurons and/or AstA expressing EECs reduced food intake, which can be traced to AstA signalling by using \textit{AstA} mutants. In the locomotor activity, thermogenetic activation of two pairs of PLP neurons and/or AstA expressing EECs resulted in strongly inhibited locomotor activity and promoted sleep without sexual difference, which was most apparent during the morning and evening activity peaks. The experimental and control flies were not impaired in climbing ability. In contrast, conditional silencing of the PLP neurons and/or AstA expressing EECs reduced sleep specifically in the siesta. The arousal experiment was employed to test for the sleep intensity. Thermogenetically activated flies walked significantly slower and a shorter distance than controls for all arousal stimulus intensities. Furthermore, PDF receptor was detected in the PLP neurons and the PLP neurons reacted with an intracellular increase of cAMP upon PDF, only when PDF receptor was present. Constitutive activation of AstA cells by tethered PDF increased sleep and thermogenetic activation of the PDF producing sLNvs promoted sleep specifically in the morning and evening. \par The study shows that the PLP neurons and/or EECs vis AstA signalling subserve an anorexigenic and sleep-regulating function in \textit{Drosophila}. The PLP neurons arborise in the posterior superior protocerebrum, where the sleep relevant dopaminergic neurons are located, and EECs extend themselves to reach the gut lumen. Thus, the PLP neurons are well positioned to regulate sleep and EECs potentially modulate feeding and possibly locomotor activity and sleep during sending the nutritional information from the gut to the brain. The results of imaging, activation of the PDF signalling pathway by tethered PDF and thermoactivation of PDF expressing sLNvs suggest that the PLP neurons are modulated by PDF from sLNv clock neurons and AstA in PLP neurons is the downstream target of the central clock to modulate locomotor activity and sleep. AstA receptors are homologues of galanin receptors and both of them are involved in the regulation of feeding and sleep, which appears to be conserved in evolutionary aspect.\par In the second part of the dissertation, I analysed the role of myoinhibitory peptides. MIPs are brain-gut peptides in insects and polychaeta. Also in \textit{Drosophila}, MIPs are expressed in the CNS and EECs in the gut. Previous studies have demonstrated the functions of MIPs in the regulation of food intake, gut motility and ecdysis in moths and crickets. Yet, the functions of MIPs in the fruit fly are little known. To dissect effects of MIPs regarding feeding, locomotor activity and sleep in \textit{Drosophila melanogater}, I manipulated the activity of MIP\textsuperscript{W{\"U}} cells by using newly generated \textit{Mip\textsuperscript{W{\"U}}-Gal4} lines. Thermogenetical activation or genetical silencing of MIP\textsuperscript{W{\"U}} celles did not affect feeding behaviour and resulted in changes in the sleep status. \par My results are in contradiction to a recent research of Min Soohong and colleagues who demonstrated a role of MIPs in the regulation of food intake and body weight in \textit{Drosophila}. They showed that constitutive silencing of MIP\textsuperscript{KR} cells increased food intake and body weight, whereas thermogenetic activation of MIP\textsuperscript{KR} cells decreased food intake and body weight by using \textit{Mip\textsuperscript{KR}-Gal4} driver. Then I repeated the experiments with the \textit{Mip\textsuperscript{KR}-Gal4} driver, but could not reproduce the results. Interestingly, I just observed the opposite phenotype. When MIP\textsuperscript{KR} cells were silenced by expressing UAS-tetanus toxin (\textit{UAS-TNT}), the \textit{Mip\textsuperscript{KR}\$>\$TNT} flies showed reduced food intake. The thermogenetic activation of MIP\textsuperscript{KR} cells did not affect food intake. Furthermore, I observed that the thermogenetic activation of MIP\textsuperscript{KR} cells strongly reduced the sleep duration.\par In the third part of the dissertation, I adapted and improved a method for metabolic labelling for \textit{Drosophila} peptides to quantify the relative amount of peptides and the released peptides by mass spectrometry under different physiological and behavioural conditions. qRT-PCR is a practical technique to measure the transcription and the corresponding mRNA level of a given peptide. However, this is not the only way to measure the translation and production of peptides. Although the amount of peptides can be quantified by mass spectrometry, it is not possible to distinguish between peptides stored in vesicles and released peptides in CNS extracts. I construct an approach to assess the released peptides, which can be calculated by comparing the relative amount of peptides between two timepoints in combination with the mRNA levels which can be used as semiquantitative proxy reflecting the production of peptides during this period. \par After optimizing the protocol for metabolic labelling, I carried out a quantitative analysis of peptides before and after eclosion as a test. I was able to show that the EH- and SIFa-related peptides were strongly reduced after eclosion. This is in line with the known function and release of EH during eclosion. Since this test was positive, I next used the metabolic labelling in \textit{Drosophila} adult, which were either fed \textit{ad libitum} or starved for 24 hrs, and analysed the effects on the amount of AstA and MIPs. In the mRNA level, my results showed that in the brain \textit{AstA} mRNA level in the 24 hrs starved flies was increased compared to in the \textit{ad libitum} fed flies, whereas in the gut the \textit{AstA} mRNA level was decreased. Starvation induced the reduction of \textit{Mip} mRNA level in the brain and gut. Unfortunately, due to technical problems I was unable to analyse the metabolic labelled peptides during the course of this thesis.\par}, subject = {AstA}, 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} }