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Neurodegenerative Erkrankungen des Menschen sind eines der Hauptfelder molekularer neurobiologischer Grundlagenforschung. Um generell molekulare, komplizierte Vorgänge in vivo untersuchen zu können, nutzt man seit geraumer Zeit Modellorganismen wie Caenorhabditis elegans oder Drosophila melanogaster. In der vorliegenden Arbeit wird die Drosophila-Neurodegenerationsmutante loe (löchrig) beschrieben, die als Modell für die Rolle des Cholesterinhaushalts im Bezug auf Neurodegeneration herangezogen werden kann. Die Fliegen dieser Mutante zeigen stark progressive, altersabhängige Degeneration von Neuronen, dabei unterlaufen diese Nervenzellen einen nekrotischenZelltod. Verantwortlich für diese Mutation ist die Insertion eines P-Elementes in einem Intron des Drosophila-g-5'-AMP-aktivierten Proteinkinase- (AMPK)-Gens. Die verschiedenen Spleißprodukte des loe Gens kodieren für die regulatorische g-Untereinheit des AMPK-Komplexes, der , aktiviert durch 5'AMP, energieintensive Prozesse negativ reguliert. Die Spleißform loeI ist durch die P-Element-Insertion betroffen, Anteile des P-Elementes werden in das loeI-Transkript hineingespleißt. Eine neuronale Expression von loeI im loe-Hintergrund führt zur Revertierung des loe-Phänotypes. Mit der Expression anderer Spleißformen kann dieser Effekt nicht erzielt werden. Das LOE I-Protein birgt in seinem N-Terminus eine Reihe möglicher Interaktionstellen mit anderen Proteinen, die den AMPK-Komplex in einen Kontext mit den Proteinen der APP (Amyloid Precursor Proteins) ?Familie stellen oder z. B. Interaktionen mit dem Cytoskelett herstellen können. Eine molekulare Interaktion mit NiPSNAP, einem Protein, dass vermutlich eine Rolle im Vesikelverkehr spielt, konnte nachgewiesen werden. Ein direktes humanes Homolog von LOE I ist nicht bekannt, wohlgleich es im Menschen drei AMPK-g-Untereinheiten gibt, von denen zwei ähnliche Funktionen übernehmen könnten wie LOE I. Die loe-Mutante interagiert genetisch mit der Mutante clb ? columbus, die einen Defekt im Gen der HMG-CoA-Reduktase trägt. Dieses Emzym ist das Schlüsselenzym der Cholesterinbiosynthese. Die Art der Interaktion belegt eine negative Regulierung der HMG-CoA-Reduktase durch die AMPK. So schwächt die clb-Mutation den neurodegenerativen loe-Phänotyp ab, eine Überexpression von clb verstärkt diesen. Eine Verminderung der Neurodegeneration kann auch mit Medikamenten erreicht werden: Statine, potente Hemmer der HMG-COA-Reduktase, reprimieren deutlich den loe-Phänotyp. In loe ist der Cholesterinester-Spiegel auf 40% abgesenkt. Eine weitere genetische Interaktion von loe konnte nachgewiesen werden: Die Mutante für das Drosophila-Homolog von APP (Appl) verstärkt den neurodegenerativen Phänotyp in loe stark, wogegen die Appl-Mutante selbst keine neurodegenerativen Defekte aufweist. Darüberhinaus zeigt die Doppelmutante Defekte, die keine der Einzelmutanten aufweist: Sterilität oder eine extrem kurze Lebensdauer von nur 3-4 Tagen. Diese Interaktion ließ sich auf molekularer Ebene charakterisieren. Die proteolytische Prozessierung von APPL durch Sekretasen ist in loe alteriert. In der vorliegenden Arbeit konnte gezeigt werden, dass durch die loe-Mutation die b-Sekretase aus Vertebraten (BACE) und eine bisher noch nicht beschriebene endogene Sekretase aus Drosophila negativ beeiflusst werden. Ein AMPK-Komplex mit LOE I als g-Untereinheit scheint über den Cholesterinester-Spiegel die Aktivität einer speziellen Untergruppe der Sekretasen zu beeinflussen. Die Missfunktion dieser Sekretasen ist ein kritischer Punkt in der Pathogenese der Alzheimer-Krankheit. Die loe-Mutation wirft neues Licht auf die bekannten Verbindungen zwischen Cholesterin-Stoffwechsel, Vesikelverkehr und Prozessierung von APP(L). Mit den großen Möglichkeiten, die die Drosophila-Genetik bietet, stellt diese neue Mutante ein weiteres Werkzeug zur Charakterisierung von Therapie-Ansätzen für die Alzheimer-Kankheit dar. Die vorliegende Arbeit belegt um ein weiteres Mal, dass Drosophila ein potentes Modellsystem zur Untersuchung humaner, neurodegenerativer Erkrankungen wie Chorea Huntington, Parkinson oder der Alzheimer Krankheit ist.
In this thesis two genes involved in causing neurodegenerative phenotypes in Drosophila are described. olk (omb-like), a futsch allele, is a micotubule associated protein (MAP) which is homologous to MAP1B and sws (swiss cheese) a serine esterase of yet unknown function within the nervous system. The lack of either one of these genes causes progressive neurodegeneration in two different ways. The sws mutant is characterized by general degeneration of the adult nervous system, glial hyperwrapping and neuronal apoptosis. Deletion of NTE (neuropathy target esterase), the SWS homolog in vertebrates, has been shown to cause a similar pattern of progressive neural degeneration in mice. NTE reacts with organophosphates causing axonal degeneration in humans. Inhibition of vertebrate NTE is insufficient to induce paralyzing axonal degeneration, a reaction called "aging reaction" is necessary for the disease to set in. It is hypothesized that a second "non-esterase" function of NTE is responsible for this phenomenon. The biological function of SWS within the nervous system is still unknown. To characterize the function of this protein several transgenic fly lines expressing different mutated forms of SWS were established. The controlled expression of altered SWS protein with the GAL4/UAS system allowed the analysis of isolated parts of the protein that were altered in the respective constructs. The characterization of a possible non-esterase function was of particular interest in these experiments. One previously described aberrant SWS construct lacking the first 80 amino acids (SWSΔ1-80) showed a deleterious, dominant effect when overexpressed and was used as a model for organophosphate (OP) intoxication. This construct retains part of its detrimental effect even without catalytically active serine esterase function. This strongly suggests that there is another characteristic to SWS that is not defined solely by its serine esterase activity. Experiments analyzing the lipid contents of sws mutant, wildtype (wt) and SWS overexpressing flies gave valuable insights into a possible biological function of SWS. Phosphatidylcholine, a major component of cell membranes, accumulates in sws mutants whereas it is depleted in SWS overexpressing flies. This suggests that SWS is involved in phosphatidylcholine regulation. The produced α-SWS antibody made it possible to study the intracellular localization of SWS. Images of double stainings with ER (endoplasmic reticulum) markers show that SWS is in great part localized to the ER. This is consistent with findings of SWS/ NTE localization in yeast and mouse cells. The olk mutant also shows progressive neurodegeneration but it is more localized to the olfactory system and mushroom bodies. Regarding specific cell types it seemed that specifically the projection neurons (PNs) are affected. A behavioral phenotype consisting of poor olfactory memory compared to wt is also observed even before histologically visible neurodegeneration sets in. Considering that the projection neurons connect the antennal lobes to the mushroom bodies, widely regarded as the "learning center", this impairment was expected. Three mutants where identified (olk1-3) by complementation analysis with the previously known futschN94 allele and sequencing of the coding sequence of olk1 revealed a nonsense mutation early in the protein. Consistent with the predicted function of Futsch as a microtubule associated protein (MAP), abnormalities are most likely due to a defective microtubule network and defects in axonal transport. In histological sections a modified cytoskeletal network is observed and western blots confirm a difference in the amount of tubulin present in the olk1 mutant versus the wt. The elaboration of neuronal axons and dendrites is dependent on a functional cytoskeleton. Observation of transport processes in primary neural cultures derived from olk1 mutant flies also showed a reduction of mitochondrial transport. Interaction with the fragile X mental retardation gene (dfmr1) was observed with the olk mutant. A dfmr1/ olk1 double mutant shows an ameliorated phenotype compared to the olk1 single mutant. tau, another MAP gene, was also shown to be able to partially rescue the olk1 mutant.
Parkinson's disease (PD) provokes bradykinesia, resting tremor, rigidity and postural instability, and also non-motor symptoms such as depression, anxiety, sleep and cognitive impairments. Similar phenotypes can be induced in Drosophila melanogaster through modification of PD-relevant genes or the administration of PD inducing toxins. Recent studies correlated deregulation of human p21-activated kinase 4 (PAK4) with PD, leaving open the question of a causative relationship of mutations in this gene for manifestation of PD symptoms. To determine whether flies lacking the PAK4 homolog Mushroom bodies tiny (Mbt) show PD-like phenotypes, we tested for a variety of PD criteria. Here, we demonstrate that mbt mutant flies show PD-like phenotypes including age-dependent movement deficits, reduced life expectancy and fragmented sleep. They also react to a stressful situation with higher immobility, indicating an influence of Mbt on emotional behavior. Loss of Mbt function has a negative effect on the number of dopaminergic protocerebral anterior medial (PAM) neurons, most likely caused by a proliferation defect of neural progenitors. The age-dependent movement deficits are not accompanied by a corresponding further loss of PAM neurons. Previous studies highlighted the importance of a small PAM subgroup for age-dependent PD motor impairments. We show that impaired motor skills are caused by a lack of Mbt in this PAM subgroup. In addition, a broader re-expression of Mbt in PAM neurons improves life expectancy. Conversely, selective Mbt knockout in the same cells shortens lifespan. We conclude that mutations in Mbt/PAK4 can play a causative role in the development of PD phenotypes.
Im Rahmen dieser Arbeit wurden visuelle Einflüsse auf die Beinplatzierung beim Laufen und auf das Kletterverhalten der Fliege Drosophila melanogaster analysiert. Während sich die Beinplatzierung als vorwiegend taktil gesteuert herausstellte, ist das Klettern sowohl bezüglich der Entscheidung zur Durchführung (Motivationssteuerung) als auch bezüglich der Ausführung selbst unter präziser visueller Kontrolle. Für die Untersuchungen wurde ein Lücken-Überwindungsparadigma entwickelt und die Kinematik des Kletterns über verschieden breite Lücken mit einer eigens entwickelten 3D-Hochgeschwindigkeits-Videoanlage erstmals quantitativ beschrieben. Drei wesentliche Verhaltensanpassungen sorgen dafür, dass die Fliegen die maximal mögliche Spannbreite ihrer Beine voll ausnützen und Lücken von bis zu 170% der eigenen Körperlänge überqueren können. Das Kletterverhalten wird abhängig von der Lückenbreite initiiert und sinnlose Versuche an unüberwindbar breiten Lücken vermieden. Die visuelle Lückenbreitenmessung wurde analysiert; sie beruht auf der Auswertung von Bewegungsparallaxe beim Anlauf. Einige Erkenntnisse aus der Laufforschung an Fliegen wurden auf einem im Rahmen dieser Arbeit modifizierten hexapoden Laufroboter umgesetzt und die Verbesserungen quantifiziert.
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.
Understanding of complex interactions and events in a nervous system, leading from the molecular level up to certain behavioural patterns calls for interdisciplinary interactions of various research areas. The goal of the presented work is to achieve such an interdisciplinary approach to study and manipulate animal behaviour and its underlying mechanisms. Optical in vivo imaging is a new constantly evolving method, allowing one to study not only the local but also wide reaching activity in the nervous system. Due to ease of its genetic accessibility Drosophila melanogaster represents an extraordinary experimental organism to utilize not only imaging but also various optogenetic techniques to study the neuronal underpinnings of behaviour. In this study four genetically encoded sensors were used to investigate the temporal dynamics of cAMP concentration changes in the horizontal lobes of the mushroom body, a brain area important for learning and memory, in response to various physiological and pharmacological stimuli. Several transgenic lines with various genomic insertion sites for the sensor constructs Epac1, Epac2, Epac2K390E and HCN2 were screened for the best signal quality, one line was selected for further experiments. The in vivo functionality of the sensor was assessed via pharmacological application of 8-bromo-cAMP as well as Forskolin, a substance stimulating cAMP producing adenylyl cyclases. This was followed by recording of the cAMP dynamics in response to the application of dopamine and octopamine, as well as to the presentation of electric shock, odorants or a simulated olfactory signal, induced by acetylcholine application to the observed brain area. In addition the interaction between the shock and the simulated olfactory signal by simultaneous presentation of both stimuli was studied. Preliminary results are supporting a coincidence detection mechanism at the level of the adenylyl cyclase as postulated by the present model for classical olfactory conditioning. In a second series of experiments an effort was made to selecticvely activate a subset of neurons via the optogenetic tool Channelrhodopsin (ChR2). This was achieved by recording the behaviour of the fly in a walking ball paradigm. A new method was developed to analyse the walking behaviour of the animal whose brain was made optically accessible via a dissection technique, as used for imaging, thus allowing one to target selected brain areas. Using the Gal4-UAS system the protocerebral bridge, a substructure of the central complex, was highlighted by expressing the ChR2 tagged by fluorescent protein EYFP. First behavioural recordings of such specially prepared animals were made. Lastly a new experimental paradigm for single animal conditioning was developed (Shock Box). Its design is based on the established Heat Box paradigm, however in addition to spatial and operant conditioning available in the Heat Box, the design of the new paradigm allows one to set up experiments to study classical and semioperant olfactory conditioning, as well as semioperant place learning and operant no idleness experiments. First experiments involving place learning were successfully performed in the new apparatus.
Circadianes und Stress-System sind zwei physiologische Systeme, die dem Organismus helfen sich an Veränderungen ihrer Umwelt anzupassen. Während letzteres spontane und schnelle Antworten auf akute, unvorhersehbare Umweltreize liefert, sagt das circadiane System täglich wiederkehrende Ereignisse vorher and bereitet den Organismus so vorzeitig auf diese nahende Umweltveränderung vor. Dennoch, trotz dieser unterschiedlichen Reaktionsmechanismen agieren beide Systeme nicht komplett autonom. Studien der vergangen Jahre belegen vielmehr eine Interaktion beider Systeme. So postulieren sie zum einem Unterschiede in der Stressantwort in Abhängigkeit von der Tageszeit zu der der Reiz auftritt und weisen zugleich auf eine Zunahme von gestörten biologischen Tagesrhythmen, wie zum Beispiel Schlafstörungen, in Folge von unkontrollierten oder exzessiven Stress hin. Ebenso liefern kürzlich durchgeführte Studien an Vertebraten und Pilzen Hinweise, dass mit p38, eine Stress-aktivierte Kinase, an der Signalweiterleitung zur inneren Uhr beteiligt ist (Hayashi et al., 2003), sogar durch dieses endogene Zeitmesssystem reguliert wird (Vitalini et al., 2007; Lamb et al., 2011) und deuten damit erstmals eine mögliche Verbindung zwischen Stress-induzierten und regulären rhythmischen Anpassungen des Organismus an Umweltveränderungen an. Molekulare und zelluläre Mechanismen dieser Verknüpfung sind bisher noch nicht bekannt.
Während die Rolle von p38 MAPK bei der Stress- und Immunantwort in Drosophila melanogaster gut charakterisiert ist, wurden Expression und Funktion von p38 in der inneren Uhr hingegen bislang nicht untersucht. Die hier vorliegende Arbeit hatte daher zum Ziel mittels immunhistochemischer, verhaltensphysiologischer und molekularer Methoden eine mögliche Rolle der Stress-aktivierten Kinase im circadianen System der Fliege aufzudecken. Antikörperfärbungen sowie Studien mit Reporterlinien zeigen deutliche Färbesignale in den s-LNv, l-LNv und DN1a und erbringen erstmals einen Nachweis für p38 Expression in den Uhrneuronen der Fliege. Ebenso scheint die Aktivität von p38 MAPK in den DN1a uhrgesteuert zu sein. So liegt p38 vermehrt in seiner aktiven Form in der Dunkelphase vor und zeigt, neben seiner circadian regulierten Aktivierung, zusätzlich auch eine Inaktivierung durch Licht. 15-Minuten-Lichtpulse in der subjektiven Nacht führen zu einer signifikanten Reduktion von aktivierter, phosphorylierter p38 MAPK in den DN1a von Canton S Wildtypfliegen im Vergleich zu Fliegen ohne Lichtpuls-Behandlung. Aufzeichnungen der Lokomotoraktivität offenbaren zusätzlich die Notwendigkeit von p38 MAPK für wildtypisches Timing der Abendaktivität sowie zum Erhalt von 24-Stunden-Verhaltensrhythmen unter konstanten Dauerdunkel-Bedindungen. So zeigen Fliegen mit reduzierten p38 Level in Uhrneuronen einen verzögerten Beginn der Abendaktivität und stark verlängerte Freilaufperioden. In Übereinstimmung mit Effekten auf das Laufverhalten scheint darüber hinaus die Expression einer dominant-negativen Form von p38b in Drosophila’s wichtigsten Uhrneuronen eine verspätete nukleäre Translokation von Period zur Folge zu haben. Westernblots legen zusätzlich einen Einfluss von p38 auf den Phosphorylierungsgrad von Period nahe und liefern damit einen mögliche Erklärung für den verspäteten Kerneintritt des Uhrproteins. Abschließende Stützung der Westernblotergebnisse bringen in vitro Kinasenassays und deuten auf p38 als eine potentielle „Uhrkinase“ hin, welche auch in vivo Period an Serin 661 sowie weiteren potentiellen Phosphorylierungsstellen phosphorylieren könnte.
Zusammengenommen deuten die Ergebnisse der hier vorliegenden Arbeit eindeutig auf eine bedeutende Rolle von p38, neben dessen Funkion im Stress-System, auch im circadianen System der Fliege hin und offenbaren damit die Möglichkeit, dass p38 als Schnittstelle zwischen beider Systeme fungiert.
Synaptic plasticity determines the development of functional neural circuits. It is widely accepted as the mechanism behind learning and memory. Among different forms of synaptic plasticity, Hebbian plasticity describes an activity-induced change in synaptic strength, caused by correlated pre- and postsynaptic activity. Additionally, Hebbian plasticity is characterised by input specificity, which means it takes place only at synapses, which participate in activity. Because of its correlative nature, Hebbian plasticity suggests itself as a mechanism behind associative learning.
Although it is commonly assumed that synaptic plasticity is closely linked to synaptic activity during development, the mechanistic understanding of this coupling is far from complete.
In the present study channelrhodopsin-2 was used to evoke activity in vivo, at the glutamatergic Drosophila neuromuscular junction. Remarkably, correlated pre- and postsynaptic stimulation led to increased incorporation of GluR-IIA-type glutamate receptors into postsynaptic receptor fields, thus boosting postsynaptic sensitivity. This phenomenon is input-specific.
Conversely, GluR-IIA was rapidly removed from synapses at which neurotransmitter release failed to evoke substantial postsynaptic depolarisation. This mechanism might be responsible to tame uncontrolled receptor field growth. Combining these results with developmental GluR-IIA dynamics leads to a comprehensive physiological concept, where Hebbian plasticity guides growth of postsynaptic receptor fields and sparse transmitter release stabilises receptor fields by preventing overgrowth.
Additionally, a novel mechanism of retrograde signaling was discovered, where direct postsynaptic channelrhodopsin-2 based stimulation, without involvement of presynaptic neurotransmitter release, leads to presynaptic depression. This phenomenon is reminiscent of a known retrograde homeostatic mechanism, of inverted polarity, where neurotransmitter release is upregulated, upon reduction of postsynaptic sensitivity.
Different transgenes that can be expressed in neurons to kill or block them were compared. Tetanus neurotoxin blocked chemical synapses very efficiently. Synapses consisting of a chemical and an electrical component were blocked more reliably by expressing a human inwardly rectifying potassium channel. To gain temporal control over neuronal function, three genetic tools have been investigated. None of the systems is without drawbacks, however, the recombination induced tetanus neurotoxin expression is a promising approach. The knowledge gained from the comparative methodological study was used to investigate the role of neurons in sensory systems in processing different sensory informations. Receptor neurons sensitive for chemical or mechanical stimuli were correlated to specific olfactory behaviors or locomotor tasks. The main topic of this thesis is the much discussed question of which neurons are involved in motion processing in the visual system of flies. Neither L2 nor L4 neurons in the first visual neuropil are essential for motion-detection. The results indicate that maybe motion is detected by the network of amacrine cells (a). The vertical motion-sensitive VS cells in the lobula plate are not necessary for behavioral responses to vertical motion. This finding implies that the lack of VS cells in the structural mutant optomotor blind is not causally related to the altered responses to motion stimuli. Other abnormalities in optomotor blind are responsible for this behavioral phenotype. This work shows the potential of the described methods in studying information processing in the Drosophila brain. Groups of neurons were correlated to complex behavioral responses and theories about information processing were tested by behavioral experiments with transgenic flies. The refinement of the genetic tools to interfere with neuronal function will make the Drosophila brain an even better model to study information processing in nervous systems.
Genetic Dissection of Aversive Associative Olfactory Learning and Memory in Drosophila Larvae
(2016)
Memory formation is a highly complex and dynamic process. It consists of different phases, which depend on various neuronal and molecular mechanisms. In adult Drosophila it was shown that memory formation after aversive Pavlovian conditioning includes—besides other forms—a labile short-term component that consolidates within hours to a longer-lasting memory. Accordingly, memory formation requires the timely controlled action of different neuronal circuits, neurotransmitters, neuromodulators and molecules that were initially identified by classical forward genetic approaches. Compared to adult Drosophila, memory formation was only sporadically analyzed at its larval stage. Here we deconstruct the larval mnemonic organization after aversive olfactory conditioning. We show that after odor-high salt conditioning larvae form two parallel memory phases; a short lasting component that depends on cyclic adenosine 3’5’-monophosphate (cAMP) signaling and synapsin gene function. In addition, we show for the first time for Drosophila larvae an anesthesia resistant component, which relies on radish and bruchpilot gene function, protein kinase C activity, requires presynaptic output of mushroom body Kenyon cells and dopamine function. Given the numerical simplicity of the larval nervous system this work offers a unique prospect for studying memory formation of defined specifications, at full-brain scope with single-cell, and single-synapse resolution.