@phdthesis{Tian2011, author = {Tian, Rui}, title = {Structural and functional organization of synaptic proteins in Drosophila melanogaster}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-57399}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2011}, abstract = {Structural and functional modifications of synaptic connections ("synaptic plasticity") are believed to mediate learning and memory processes. Thus, molecular mechanisms of how synapses assemble in both structural and functional terms are relevant for our understanding of neuronal development as well as the processes of learning and memory. Synapses form by an asymmetric association of highly specialized membrane domains: at the presynaptic active zone transmitter filled vesicles fuse, while transmitter receptors at the opposite postsynaptic density sense this signal. By genetic analysis, matrix proteins of active zones from various families have been shown to be important for fast vesicle fusion, and were suggested to contribute to synapse stability and assembly. The Sigrist lab in collaboration with the Buchner lab previously had shown that the large scaffold protein Bruchpilot (Brp) is essential for both the structural and functional integrity of active zones and for synaptic plasticity in Drosophila melanogaster. The work described in this thesis investigated several candidate proteins which appear to be involved in preand postsynaptic function, as summarized in the following: (1) DREP-2 (DEF45 related protein-2) had been found by co-immunoprecipitations with anti-Brp antibodies by Dr. Manuela Schmidt (unpublished data). Mutants and antibodies for the further study of DREP- 2 were generated in this thesis. Yeast two hybrid results suggest that DREP-2 might interact with dynein light chain 2, while in vivo imaging indicates that DREP-2 might be involved in bidirectional axonal transport. (2) Coimmunoprecipitation and pull down experiments suggested that the ARFGAP [ADP-ribosylation factor (ARF)-directed GTPase activating protein (GAP)] protein GIT (G-protein coupled receptor kinase interacting protein) could interact with the endocytosis associated molecule Stoned B (StnB). Mutants in the dgit gene showed an accumulation of large size vesicles, membrane intermediates and decreased vesicle density at the 3rd instar larval neuromuscular junction (NMJ) by electron microscopy (EM). The phenotypes accumulation of large size vesicles and membrane intermediates could be rescued partially by expression of Drosophila GIT (DGIT) or human GIT in dgit mutant background. Furthermore, by immunofluorescence the dgit mutant shows specifically decreased levels of StnB, which could be restored partially by the expression of DGIT. These results strongly support the suggestion that DGIT interacts with StnB, which is involved in the regulation of vesicle size, endocytosis or recycling of synaptic vesicles (SVs). Furthermore, the dgit mutants also showed signs of a mislocalization of the presynaptic protein Brp relative to the postsynaptic protein GluRIID, which could be rescued by expression of DGIT or human GIT in the dgit mutant background, but not by StnB. These results suggest that GIT on one hand executes roles in the regulation of synaptic vesicle endocytosis, but potentially also has structural roles for synapse assembly (3) Djm-1 is a candidate locus to mediate mental retardation in human patients when it is mutated. As a first step towards an understanding of the mechanistic role of DJM-1, Drosophila genetics were used to address DJM-1 function. So far, however, the djm-1 mutant generated in this thesis did not show a nervous system phenotype.}, subject = {Taufliege}, language = {en} } @phdthesis{Solanki2013, author = {Solanki, Narendra}, title = {Novelty choice in Drosophila melanogaster}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-103219}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2013}, abstract = {This study explores novelty choice, a behavioral paradigm for the investigation of visual pattern recognition and learning of the fly Drosophila melanogaster in the flight simulator. Pattern recognition in novelty choice differs significantly from pattern recognition studied by heat conditioning, although both paradigms use the same test. Out of the four pattern parameters that the flies can learn in heat conditioning, novelty choice can be shown for height (horizontal bars differing in height), size and vertical compactness but not for oblique bars oriented at +/- 45°. Upright and inverted Ts [differing in their centers of gravity (CsOG) by 13°] that have been extensively used for heat conditioning experiments, do not elicit novelty choice. In contrast, horizontal bars differing in their CsOG by 13° do elicit novelty choice; so do the Ts after increasing their CsOG difference from 13° to 23°. This indicates that in the Ts the heights of the CsOG are not the only pattern parameters that matter for the novelty choice behavior. The novelty choice and heat conditioning paradigms are further differentiated using the gene rutabaga (rut) coding for a type 1 adenylyl cyclase. This protein had been shown to be involved in memory formation in the heat conditioning paradigm. Novelty choice is not affected by mutations in the rut gene. This is in line with the finding that dopamine, which in olfactory learning is known to regulate Rutabaga via the dopamine receptor Dumb in the mushroom bodies, is dispensable for novelty choice. It is concluded that in novelty choice the Rut cAMP pathway is not involved. Novelty choice requires short term working memory, as has been described in spatial orientation during locomotion. The protein S6KII that has been shown to be involved in visual orientation memory in walking flies is found here to be also required for novelty choice. As in heat conditioning the central complex plays a major role in novelty choice. The S6KII mutant phenotype for height can be rescued in some subsets of the ring neurons of the ellipsoid body. In addition the finding that the ellipsoid body mutants ebo678 and eboKS263 also show a mutant phenotype for height confirm the importance of ellipsoid body for height novelty choice. Interestingly some neurons in the F1 layer of the fan-shaped body are necessary for height novelty choice. Furthermore, different novelty choice phenotypes for different pattern parameters are found with and without mushroom bodies. Mushroom bodies are required in novelty choice for size but they are dispensable for height and vertical compactness. This special circuit requirement for the size parameter in novelty choice is found using various means of interference with mushroom body function during development or adulthood.}, subject = {Taufliege}, language = {en} } @phdthesis{Solanki2013, author = {Solanki, Narendra}, title = {Novelty choice in Drosophila melanogaster}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-78377}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2013}, abstract = {This study explores novelty choice, a behavioral paradigm for the investigation of visual pattern recognition and learning of the fly Drosophila melanogaster in the flight simulator. Pattern recognition in novelty choice differs significantly from pattern recognition studied by heat conditioning, although both paradigms use the same test. Out of the four pattern parameters that the flies can learn in heat conditioning, novelty choice can be shown for height (horizontal bars differing in height), size and vertical compactness but not for oblique bars oriented at +/- 45°. Upright and inverted Ts [differing in their centers of gravity (CsOG) by 13°] that have been extensively used for heat conditioning experiments, do not elicit novelty choice. In contrast, horizontal bars differing in their CsOG by 13° do elicit novelty choice; so do the Ts after increasing their CsOG difference from 13° to 23°. This indicates that in the Ts the heights of the CsOG are not the only pattern parameters that matter for the novelty choice behavior. The novelty choice and heat conditioning paradigms are further differentiated using the gene rutabaga (rut) coding for a type 1 adenylyl cyclase. This protein had been shown to be involved in memory formation in the heat conditioning paradigm. Novelty choice is not affected by mutations in the rut gene. This is in line with the finding that dopamine, which in olfactory learning is known to regulate Rutabaga via the dopamine receptor Dumb in the mushroom bodies, is dispensable for novelty choice. It is concluded that in novelty choice the Rut cAMP pathway is not involved. Novelty choice requires short term working memory, as has been described in spatial orientation during locomotion. The protein S6KII that has been shown to be involved in visual orientation memory in walking flies is found here to be also required for novelty choice. As in heat conditioning the central complex plays a major role in novelty choice. The S6KII mutant phenotype for height can be rescued in some subsets of the ring neurons of the ellipsoid body. In addition the finding that the ellipsoid body mutants ebo678 and eboKS263 also show a mutant phenotype for height confirm the importance of ellipsoid body for height novelty choice. Interestingly some neurons in the F1 layer of the fan-shaped body are necessary for height novelty choice. Furthermore, different novelty choice phenotypes for different pattern parameters are found with and without mushroom bodies. Mushroom bodies are required in novelty choice for size but they are dispensable for height and vertical compactness. This special circuit requirement for the size parameter in novelty choice is found using various means of interference with mushroom body function during development or adulthood.}, subject = {Drosophila melanogaster}, language = {en} } @phdthesis{Schubert2019, author = {Schubert, Frank Klaus}, title = {The circadian clock network of \(Drosophila\) \(melanogaster\)}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-157136}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2019}, abstract = {All living organisms need timekeeping mechanisms to track and anticipate cyclic changes in their environment. The ability to prepare for and respond to daily and seasonal changes is endowed by circadian clocks. The systemic features and molecular mechanisms that drive circadian rhythmicity are highly conserved across kingdoms. Therefore, Drosophila melanogaster with its relatively small brain (ca. 135.000 neurons) and the outstanding genetic tools that are available, is a perfect model to investigate the properties and relevance of the circadian system in a complex, but yet comprehensible organism. The last 50 years of chronobiological research in the fruit fly resulted in a deep understanding of the molecular machinery that drives circadian rhythmicity, and various histological studies revealed the neural substrate of the circadian system. However, a detailed neuroanatomical and physiological description on the single-cell level has still to be acquired. Thus, I employed a multicolor labeling approach to characterize the clock network of Drosophila melanogaster with single-cell resolution and additionally investigated the putative in- and output sites of selected neurons. To further study the functional hierarchy within the clock network and to monitor the "ticking clock" over the course of several circadian cycles, I established a method, which allows us to follow the accumulation and degradation of the core clock genes in living brain explants by the means of bioluminescence imaging of single-cells.}, subject = {Taufliege}, language = {en} } @phdthesis{Sareen2011, author = {Sareen, Preeti}, title = {Visual attention in Drosophila melanogaster}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-69616}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2011}, abstract = {There is such vast amount of visual information in our surroundings at any time that filtering out the important information for further processing is a basic requirement for any visual system. This is accomplished by deploying attention to focus on one source of sensory inputs to the exclusion of others (Luck and Mangun 2009). Attention has been studied extensively in humans and non human primates (NHPs). In Drosophila, visual attention was first demonstrated in 1980 (Wolf and Heisenberg 1980) but this field remained largely unexplored until recently. Lately, however, studies have emerged that hypothesize the role of attention in several behaviors but do not specify the characteristic properties of attention. So, the aim of this research was to characterize the phenomenon of visual attention in wild-type Drosophila, including both externally cued and covert attention using tethered flight at a torque meter. Development of systematic quantifiable behavioral tests was a key aspect for this which was not only important for analyzing the behavior of a population of wild-type flies but also for comparing the wild-type flies with mutant flies. The latter would help understand the molecular, genetic, and neuronal bases of attention. Since Drosophila provides handy genetic tools, a model of attention in Drosophila will serve to the greater questions about the neuronal circuitry and mechanisms involved which might be analogous to those in primates. Such a model might later be used in research involving disorders of attention. Attention can be guided to a certain location in the visual field by the use of external cues. Here, using visual cues the attention of the fly was directed to one or the other of the two visual half-fields. A simple yet robust paradigm was designed with which the results were easily quantifiable. This paradigm helped discover several interesting properties of the cued attention, the most substantial one being that this kind of external guidance of attention is restricted to the lower part of the fly's visual field. The guiding cue had an after-effect, i.e. it could occur at least up to 2 seconds before the test and still bias it. The cue could also be spatially separated from the test by at least 20° and yet attract the attention although the extent of the focus of attention (FoA) was smaller than one lower visual half-field. These observations excluded the possibility of any kind of interference between the test and the cue stimuli. Another interesting observation was the essentiality of continuous visibility of the test stimulus but not the cue for effective cuing. When the contrast of the visual scene was inverted, differences in response frequencies and cuing effects were observed. Syndirectional yaw torque responses became more frequent than the antidirectional responses and cuing was no longer effective in the lower visual field with inverted contrast. Interestingly, the test stimulus with simultaneous displacement of two stripes not only effectuated a phasic yaw torque response but also a landing response. A 50 landing response was produced in more than half of the cases whenever a yaw torque response was produced. Elucidation of the neuronal correlates of the cued attention was commenced. Pilot experiments with hydroxyurea (HU) treated flies showed that mushroom bodies were not required for the kind of guidance of attention tested in this study. Dopamine mutants were also tested for the guidance of attention in the lower visual field. Surprisingly, TH-Gal4/UAS-shits1 flies flew like wild-type flies and also showed normal optomotor response during the initial calibration phase of the experiment but did not show any phasic yaw torque or landing response at 18 °C, 25 °C or 30 °C. dumb2 flies that have almost no D1 dopamine receptor dDA1 expression in the mushroom bodies and the central complex (Kim et al. 2007) were also tested and like THGal4/ UAS-shits1 flies did not show any phasic yaw torque or landing response. Since the dopamine mutants did not show the basic yaw torque response for the test the role of dopamine in attention could not be deduced. A different paradigm would be needed to test these mutants. Not only can attention be guided through external cues, it can also be shifted endogenously (covert attention). Experiments with the windows having oscillating stripes nicely demonstrated the phenomenon of covert attention due to the production of a characteristic yaw torque pattern by the flies. However, the results were not easily quantifiable and reproducible thereby calling for a more systematic approach. Experiments with simultaneous opposing displacements of two stripes provide a promising avenue as the results from these experiments showed that the flies had a higher tendency to deliver one type of response than when the responses would be produced stochastically suggesting that attention increased this tendency. Further experiments and analysis of such experiments could shed more light on the mechanisms of covert attention in flies.}, subject = {Visuelle Aufmerksamkeit}, language = {en} } @phdthesis{Niewalda2010, author = {Niewalda, Thomas}, title = {Neurogenetic analyses of pain-relief learning in the fruit fly}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-65035}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2010}, abstract = {All animals learn in order to cope with challenges imposed on them by their environment. This is true also for both larval and adult fruit flies as exemplified in pavlovian conditioning. The focus of this Thesis is on various aspects of the fruit flies learning ability. My main project deals with two types of learning which we call punishment-learning and pain-relief learning. Punishment learning happens when fruit flies are exposed to an odour which is followed by electric shock. After such training, flies have learned that that odour signals pain and consequently will avoid it in the future. If the sequence of the two stimuli is reversed such that odour follows shock, flies learn the odour as a signal for relief and will later on approach it. I first report a series of experiments investigating qualitative and parametric features of relief-learning; I find that (i) relief learning does result from true associative conditioning, (ii) it requires a relatively high number of training trials, (iii) context-shock training is ineffective for subsequent shock-odour learning. A further question is whether punishment-learning and pain-relief learning share genetic determinants. In terms of genetics, I test a synapsin mutant strain, which lacks all Synapsin protein, in punishment and relief-learning. Punishment learning is significantly reduced, and relief-learning is abolished. Pan-neuronal RNAi-mediated knock-down of Synapsin results in mutant-like phenotypes, confirming the attribution of the phenotype to lack of Synapsin. Also, a rescue of Synapsin in the mushroom body of syn97 mutants restores both punishment- and relief-learning fully, suggesting the sufficiency of Synapsin in the mushroom body for both these kinds of learning. I also elucidate the relationship between perception and physiology in adult fruit flies. I use odour-shock conditioning experiments to identify degrees of similarity between odours; I find that those similarity measures are consistent across generalization and discrimination tasks of diverse difficulty. Then, as collaborator of T. V{\"o}ller and A. Fiala, I investigate how such behavioural similarity/dissimilarity is reflected at the physiological level. I combine the behaviour data with calcium imaging data obtained by measuring the activity patterns of those odours in either the sensory neurons or the projection neurons at the antennal lobe. Our interpretation of the results is that the odours perceptual similarity is organized by antennal lobe interneurons. In another project I investigate the effect of gustatory stimuli on reflexive behaviour as well as their role as reinforcer in larval learning. Drosophila larvae greatly alter their behaviour in presence of sodium chloride. Increasing salt concentration modulates choice behaviour from weakly appetitive to strongly aversive. A similar concentration-behaviour function is also found for feeding: larval feeding is slightly enhanced in presence of low salt concentrations, and strongly decreased in the presence of high salt concentrations. Regarding learning, relatively weak salt concentrations function as appetitive reinforcer, whereas high salt concentrations function as aversive reinforcer. Interestingly, the behaviour-concentration curves are shifted towards higher concentrations from reflexive behaviour (choice behaviour, feeding) as compared to associative learning. This dissociation may reflect a different sensitivity in the respective sensory-motor circuitry.}, subject = {Taufliege}, language = {en} } @phdthesis{Mishra2011, author = {Mishra, Dushyant}, title = {The content of olfactory memory in larval Drosophila}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-66316}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2011}, abstract = {An animal depends heavily on its sense of smell and its ability to form olfactory associations as this is crucial for its survival. This thesis studies in two parts about such associative olfactory learning in larval Drosophila. The first part deals with different aspects of odour processing while the second part is concerned with aspects related to memory and learning. Chapter I.1 highlights how odour intensities could be integrated into the olfactory percept of larval Drosophila. I first describe the dose-effect curves of learnability across odour intensities for different odours and then choose odour intensities from these curves such that larvae are trained at intermediate odour intensity, but are tested for retention with either that trained intermediate odour intensity, or with respectively HIGHer or LOWer intensities. I observe a specificity of retention for the trained intensity for all the odours used. Further I compare these findings with the case of adult Drosophila and propose a circuit level model of how such intensity coding comes about. 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 olfaction and olfactory learning. Chapter I.2 provides a behaviour-based estimate of odour similarity using four different types of experiments to yield a combined, task-independent estimate of perceived difference between odour-pairs. Further comparison of these perceived differences to published measures of physico- chemical difference reveals a weak correlation. Notable exceptions to this correlation are 3-octanol and benzaldehyde. Chapter I.3 shows for two odours (3-octanol and 1-octene-3-ol) that perceptual differences between these odours can either be ignored after non-discriminative training (generalization), or accentuated by odour-specific reinforcement (discrimination). Anosmic Or83b1 mutants have lost these faculties, indicating that this adaptive adjustment is taking place downstream of Or83b expressing sensory neurons. Chapter II.1 of this thesis deals with food supplementation with dried roots of Rhodiola rosea. This dose-dependently improves odour- reward associative function in larval Drosophila. Supplementing fly food with commercially available tablets or extracts, however, does not have a 'cognitive enhancing' effect, potentially enabling us to differentiate between the effective substances in the root versus these preparations. Thus Drosophila as a genetically tractable study case should now allow accelerated analyses of the molecular mechanism(s) that underlie this 'cognitive enhancement' conveyed by Rhodiola rosea. Chapter II.2 describes the role of Synapsin, an evolutionarily conserved presynaptic phosphoprotein using a combined behavioural and genetic approach and asks where and how, this protein affects functions in associative plasticity of larval Drosophila. This study shows that a Synapsin-dependent memory trace can be pinpointed to the mushroom bodies, a 'cortical' brain region of the insects. On the molecular level, data in this study assign Synapsin as a behaviourally- relevant effector of the AC-cAMP-PKA cascade.}, subject = {Drosophila}, language = {en} } @phdthesis{Knapek2010, author = {Knapek, Stephan}, title = {Synapsin and Bruchpilot, two synaptic proteins underlying specific phases of olfactory aversive memory in Drosophila melanogaster}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-49726}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2010}, abstract = {Memory is dynamic: shortly after acquisition it is susceptible to amnesic treatments, gets gradually consolidated, and becomes resistant to retrograde amnesia (McGaugh, 2000). Associative olfactory memory of the fruit fly Drosophila melanogaster also shows these features. After a single associative training where an odor is paired with electric shock (Quinn et al., 1974; Tully and Quinn, 1985), flies form an aversive odor memory that lasts for several hours, consisting of qualitatively different components. These components can be dissociated by mutations, their underlying neuronal circuitry and susceptibility to amnesic treatments (Dubnau and Tully, 1998; Isabel et al., 2004; Keene and Waddell, 2007; Masek and Heisenberg, 2008; Xia and Tully, 2007). A component that is susceptible to an amnesic treatment, i.e. anesthesia-sensitive memory (ASM), dominates early memory, but decays rapidly (Margulies et al., 2005; Quinn and Dudai, 1976). A consolidated anesthesia-resistant memory component (ARM) is built gradually within the following hours and lasts significantly longer (Margulies et al., 2005; Quinn and Dudai, 1976). I showed here that the establishment of ARM requires less intensity of shock reinforcement than ASM. ARM and ASM rely on different molecular and/or neuronal processes: ARM is selectively impaired in the radish mutant, whereas for example the amnesiac and rutabaga genes are specifically required for ASM (Dudai et al., 1988; Folkers et al., 1993; Isabel et al., 2004; Quinn and Dudai, 1976; Schwaerzel et al., 2007; Tully et al., 1994). The latter comprise the cAMP signaling pathway in the fly, with the PKA being its supposed major target (Levin et al., 1992). Here I showed that a synapsin null-mutant encoding the evolutionary conserved phosphoprotein Synapsin is selectively impaired in the labile ASM. Further experiments suggested Synapsin as a potential downstream effector of the cAMP/PKA cascade. Similar to my results, Synapsin plays a role for different learning tasks in vertebrates (Gitler et al., 2004; Silva et al., 1996). Also in Aplysia, PKA-dependent phosphorylation of Synapsin has been proposed to be involved in regulation of neurotransmitter release and short-term plasticity (Angers et al., 2002; Fiumara et al., 2004). Synapsin is associated with a reserve pool of vesicles at the presynapse and is required to maintain vesicle release specifically under sustained high frequency nerve stimulation (Akbergenova and Bykhovskaia, 2007; Li et al., 1995; Pieribone et al., 1995; Sun et al., 2006). In contrast, the requirement of Bruchpilot, which is homologous to the mammalian active zone proteins ELKS/CAST (Wagh et al., 2006), is most pronounced in immediate vesicle release (Kittel et al., 2006). Under repeated stimulation of a bruchpilot mutant motor neuron, immediate vesicle release is severely impaired whereas the following steady-state release is still possible (Kittel et al., 2006). In line with that, knockdown of the Bruchpilot protein causes impairment in clustering of Ca2+ channels to the active zones and a lack of electron-dense projections at presynaptic terminals (T-bars). Thus, less synaptic vesicles of the readily-releasable pool are accumulated to the release sites and their release probability is severely impaired (Kittel et al., 2006; Wagh et al., 2006). First, I showed that Bruchpilot is required for aversive olfactory memory and localized the requirement of Bruchpilot to the Kenyon cells of the mushroom body, the second-order olfactory interneurons in Drosophila. Furthermore, I demonstrated that Bruchpilot selectively functions for the consolidated anesthesia-resistant memory. Since Synapsin is specifically required for the labile anesthesia sensitive memory, different synaptic proteins can dissociate consolidated and labile components of olfactory memory and two different modes of neurotransmission (high- vs. low frequency dependent) might differentiate ASM and ARM.}, subject = {Taufliege}, language = {en} } @phdthesis{Jenett2007, author = {Jenett, Arnim}, title = {The Virtual Insect Brain Protocol : development and application of software for the standardization of neuroanatomy}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-22297}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2007}, abstract = {Since the fruit fly Drosophila melanogaster entered the laboratories as a model organism, new genetic, physiological, molecular and behavioral techniques for the functional analysis of the brain rapidly accumulated. Nowadays this concerted assault obtains its main thrust form Gal4 expression patterns that can be visualized and provide the means for manipulating -in unrestrained animals- groups of neurons of the brain. To take advantage of these patterns one needs to know their anatomy. This thesis describes the Virtual Insect Brain (VIB) protocol, a software package for the quantitative assessment, comparison, and presentation of neuroanatomical data. It is based on the 3D-reconstruction and visualization software Amira (Mercury Inc.). Its main part is a standardization procedure which aligns individual 3D images (series of virtual sections obtained by confocal microscopy) to a common coordinate system and computes average intensities for each voxel (volume pixel). The VIB protocol facilitates direct comparison of gene expression patterns and describes their interindividual variability. It provides volumetry of brain regions and helps to characterize the phenotypes of brain structure mutants. Using the VIB protocol does not require any programming skills since all operations are carried out at a (near to) self-explanatory graphical user interface. Although the VIB protocol has been developed for the standardization of Drosophila neuroanatomy, the program structure can be used for the standardization of other 3D structures as well. Standardizing brains and gene expression patterns is a new approach to biological shape and its variability. Using the VIB protocol consequently may help to integrate knowledge on the correlation of form and function of the insect brain. The VIB protocol provides a first set of tools supporting this endeavor in Drosophila. The software is freely available at http://www.neurofly.de.}, subject = {Taufliege}, language = {en} } @phdthesis{Hovhanyan2014, author = {Hovhanyan, Anna}, title = {Functional analyses of Mushroom body miniature (Mbm) in growth and proliferation of neural progenitor cells in the central brain of Drosophila melanogaster}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-91303}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2014}, abstract = {Zellwachstum und Zellteilung stellen zwei miteinander verkn{\"u}pfte Prozesse dar, die dennoch grunds{\"a}tzlich voneinander zu unterscheiden sind. Die Wiederaufnahme der Proliferation von neuralen Vorl{\"a}uferzellen (Neuroblasten) im Zentralhirn von Drosophila nach der sp{\"a}t-embryonalen Ruhephase erfordert zun{\"a}chst Zellwachstum. Der Erhalt der regul{\"a}ren Zellgr{\"o}ße ist eine wichtige Voraussetzung f{\"u}r die kontinuierliche Proliferation der Neuroblasten {\"u}ber die gesamte larvale Entwicklungsphase. Neben extrinsischen Ern{\"a}hrungssignalen ist f{\"u}r das Zellwachstum eine kontinuierliche Versorgung mit funktionellen Ribosomen notwendig, damit die Proteinsynthese aufrechterhalten werden kann. Mutationen im mushroom body miniature (mbm) Gen wurden {\"u}ber einen genetischen Screen nach strukturellen Gehirnmutanten identifiziert. Der Schwerpunkt dieser Arbeit lag in der funktionellen Charakterisierung des Mbm Proteins als neues nukleol{\"a}res Protein und damit seiner m{\"o}glichen Beteiligung in der Ribosomenbiogenese. Der Vergleich der relativen Expressionslevel von Mbm und anderen nuklearen Proteinen in verschiedenen Zelltypen zeigte eine verst{\"a}rkte Expression von Mbm in der fibrill{\"a}ren Komponente des Nukleolus von Neuroblasten. Diese Beobachtung legte die Vermutung nahe, dass in Neuroblasten neben generell ben{\"o}tigten Faktoren der Ribosomenbiogenese auch Zelltyp-spezifische Faktoren existieren. Mutationen in mbm verursachen Proliferationsdefekte von Neuroblasten, wirken sich jedoch nicht auf deren Zellpolarit{\"a}t, die Orientierung der mitotischen Spindel oder die Asymmetrie der Zellteilung aus. Stattdessen wurde eine Reduktion der Zellgr{\"o}ße beobachtet, was im Einklang mit einer Beeintr{\"a}chtigung der Ribosomenbiogenese steht. Insbesondere f{\"u}hrt der Verlust der Mbm Funktion zu einer Retention der kleinen ribosomalen Untereinheit im Nukleolus, was eine verminderte Proteinsynthese zur Folge hat. Interessanterweise wurden St{\"o}rungen der Ribosomenbiogenese nur in den Neuroblasten beobachtet. Zudem ist Mbm offensichtlich nicht erforderlich, um Wachstum oder die Proliferation von Zellen der Fl{\"u}gelimginalscheibe und S2-Zellen zu steuern, was wiederum daf{\"u}r spricht, dass Mbm eine Neuroblasten-spezifische Funktion erf{\"u}llt. Dar{\"u}ber hinaus wurden die transkriptionelle Regulation des mbm-Gens und die funktionelle Bedeutung von posttranslationalen Modifikationen analysiert. Mbm Transkription wird von dMyc reguliert. Ein gemeinsames Merkmal von dMyc Zielgenen ist das Vorhandensein einer konservierten „E-Box"-Sequenz in deren Promotorregionen. In der Umgebung der mbm-Transkriptionsstartstelle befinden sich zwei „E-Box"-Motive. Mit Hilfe von Genreporteranalysen konnte nachgewiesen werden, dass nur eine von ihnen die dMyc-abh{\"a}ngige Transkription vermittelt. Die dMyc-abh{\"a}ngige Expression von Mbm konnte auch in Neuroblasten verifiziert werden. Auf posttranslationaler Ebene wird Mbm durch die Proteinkinase CK2 phosphoryliert. In der C-terminalen H{\"a}lfte des Mbm Proteins wurden in zwei Clustern mit einer Abfolge von sauren Aminos{\"a}uren sechs Serin- und Threoninreste als CK2- Phosphorylierungsstellen identifiziert. Eine Mutationsanalyse dieser Stellen best{\"a}tigte deren Bedeutung f{\"u}r die Mbm Funktion in vivo. Weiterhin ergaben sich Evidenzen, dass die Mbm-Lokalisierung durch die CK2-vermittelte Phosphorylierung gesteuert wird. Obwohl die genaue molekulare Funktion von Mbm in der Ribosomenbiogenese noch im Unklaren ist, unterstreichen die Ergebnisse dieser Studie die besondere Rolle von Mbm in der Ribosomenbiogenese von Neuroblasten um Zellwachstum und Proliferation zu regulieren.}, subject = {Taufliege}, language = {en} }