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Es sollten neuronale Netzwerke in Drosophila melanogaster identifiziert werden, die in die Entwicklung von ethanolinduziertem Verhalten involviert sind. Mittels der Tyramin-beta-Hydroxylase (TbH) wird der letzte Schritt der Biosynthese von Oktopamin aus Tyramin gewährleistet. TbHM18 Mutanten entwickeln eine reduzierte Ethanoltoleranz und haben keine nachweisbaren Oktopamin Konzentrationen (MONASTIRIOTI et al. 1996; SCHOLZ et al. 2000). Die molekulargenetische Ursache dieser Mutante wurde näher untersucht. Wahrscheinlich ist die Deletion von einem Teil des Intron 1, des Exon 2 und einem Teil des Intron 2 des TbH-Gens verantwortlich für den Verlust der Tyramin-beta-Hydroxylase. Die Deletion der kodierenden Sequenz führt jedoch nicht zu einem Leserasterschub in der Aminosäuresequenz. Demzufolge könnte ein verkürztes Protein hergestellt werden. Ferner gibt es zwei Transkripte des TbH-Gens, woraus eventuell zwei Proteine exprimiert werden könnten. Ein Protein wäre die Tyramin-beta-Hydroxylase und das andere könnte eine Dopamin-beta-Hydroxylase sein. Um möglicherweise spezifische putative Subsets von TH-positiven Neuronen zu markieren, wurden verschiedene GAL4-Treiberlinien mit Hilfe unterschiedlicher Fragmente der Promoterregion des TbH-Gens hergestellt. Mittels des GAL4/UAS Systems konnte die Neurotransmitterausschüttung in putativen TbH-positiven Neuronen der TbH-GAL4-Linien inhibiert werden. Auf diese Weise sollte die Funktion der putativen TbH-positiven Neurone während der Entwicklung von Ethanolsensitivität und Toleranz untersucht werden. Das Transgen Tetanustoxin wurde mit der 1.3TbH-GAL4 Treiberlinie in einem bestimmten Set von Neuronen exprimiert. Die Inhibition der Synaptobrevin-abhängigen Neurotransmission in den 1.3TH-GAL4-positiven Neuronen beeinflusst nicht das ethanolinduzierte Verhalten. Hingegen das Ausschalten der Erregbarkeit der Zellen mit Hilfe eines UAS-Kir2.1 Transgens resultiert in erhöhter Resistenz gegenüber Ethanol. Das heißt, dass Synaptobrevin-unabhängige zelluläre Mechanismen der Zellen notwendig sind, um ethanolinduziertes Verhalten zu regulieren. Die 1.3TbH-GAL4-Linie exprimiert in einem sehr spezifischen Subset von Neuronen GAL4, bzw. Effektoren. Insgesamt werden ≈ 10 Zellen detektiert. Davon liegen die Somata zweier Neurone caudal und projizieren in die Region der ersten und vierten Bande des Fächerförmigen Körpers. Weitere kleine Ansammlungen von acht Zellen können um den Ösophagus und im Bereich des Subösophagialganglion verzeichnet werden. Die mit GFP markierten Neurone exprimieren wahrscheinlich kein Oktopamin. Ferner resultierte die Inhibition der synaptischen Transmission von 6.2TbH-GAL4-positiven Neuronen, mit Hilfe von Tetanustoxin, in einer erhöhten Ethanolsensitivität. Ebenfalls zu einer ethanolinduzierten Verhaltensänderung führt die Inaktivierung der 6.2TbH-GAL4 Zellen mittels eines UAS-Kir2.1 Transgens. Dabei entwickeln die Fliegen eine erhöhte Ethanolresistenz. Somit wäre möglich, dass die Entwicklung von Ethanolsensitivität und Resistenz über verschiedene zelluläre Mechanismen reguliert werden. Die 6.2TbH-GAL4-Linie ermöglicht die Transgen-Expression in 65-70 Neuronen. Diese innerverieren u.a. das Subösophagialganglion, den Ösophagus, den Ellipsoid Körper, das laterale und das dorso-laterale Protocerebrum. Fünf der Neurone, die sich durch die 6.2TbH-GAL4 Treiberlinie markieren lassen, exprimieren Oktopamin. Dazu gehört ein VUM-Neuron und vier große caudale Zellen. Eine weitere putativ oktopaminerge GAL4-Linie Tdc2-GAL4 wurde mit der UAS-Kir2.1 Effektorlinie gekreuzt und die Nachkommen im Inebriometer gemessen. Bei Inaktivierung der Erregbarkeit der Tdc2-positiven Neurone resultiert dies in einer erhöhten Ethanolsensitivität, hingegen in keiner Veränderung der Toleranz. Die reduzierten Levels an Oktopamin spielen dabei wahrscheinlich eine Rolle. Hingegen regulieren eventuelle neurosekretorische Zellen über andere Mechanismen die Ethanolresistenz, wie die 6.2TbH-GAL4, UAS-Kir2.1 Fliegen zeigen. Es konnte gezeigt werden, dass unterschiedliche Neuronencluster für verschiedene ethanolinduzierte Verhaltensantworten verantwortlich sind. Da wahrscheinlich neurosekretorische Zellen des PI die Ethanolresistenz beeinflussen (RODAN et al. 2002), hingegen den Zentralkomplex-innervierende Zellen eher für die Entwicklung von Ethanolsensitivität und Toleranz notwendig sind (URIZAR et al. 2007).
Development of the central nervous system in Drosophila melanogaster relies on neural stem cells called neuroblasts. Neuroblasts divide asymmetrically to give rise to a new neuroblast as well as a small daughter cell which eventually generates neurons or glia cells. Between each division, neuroblasts have to re-grow to be able to divide again. In previous studies, it was shown that neuroblast proliferation, cell size and the number of progeny cells is negatively affected in larvae carrying a P-element induced disruption of the gene mushroom body miniature (mbm). This mbm null mutation called mbmSH1819 is homozygously lethal during pupation. It was furthermore shown that the nucleolar protein Mbm plays a role in the processing of ribosomal RNA (rRNA) as well as the translocation of ribosomal protein S6 (RpS6) in neuroblasts and that it is a transcriptional target of Myc. Therefore, it was suggested that Mbm might regulate neuroblast proliferation through a role in ribosome biogenesis.
In the present study, it was attempted to further elucidate these proposed roles of Mbm and to identify the protein domains that are important for those functions. Mbm contains an arginine/glycine rich region in which a di-RG as well as a di-RGG motif could be found. Together, these two motifs were defined as Mbm’s RGG-box. RGG-boxes can be found in many proteins of different families and they can either promote or inhibit protein-RNA as well as protein-protein interactions. Therefore, Mbm’s RGG-box is a likely candidate for a domain involved in rRNA binding and RpS6 translocation. It could be shown by deletion of the RGG-box, that MbmdRGG is unable to fully rescue survivability and neuroblast cell size defects of the null mutation mbmSH1819. Furthermore, Mbm does indeed rely on its RGG-box for the binding of rRNA in vitro and in mbmdRGG as well as mbmSH1819 mutants RpS6 is partially delocalized. Mbm itself also seems to depend on the RGG-box for correct localization since MbmdRGG is partially delocalized to the nucleus. Interestingly, protein synthesis rates are increased in mbmdRGG mutants, possibly induced by an increase in TOR expression. Therefore, Mbm might possess a promoting function in TOR signaling in certain conditions, which is regulated by its RGG-box. Moreover, RGG-boxes often rely on methylation by protein arginine methyltransferases (in Drosophila: Darts – Drosophila arginine methyltransferases) to fulfill their functions. Mbm might be symmetrically dimethylated within its RGG-box, but the results are very equivocal. In any case, Dart1 and Dart5 do not seem to be capable of Mbm methylation.
Additionally, Mbm contains two C2HC type zinc-finger motifs, which could be involved in rRNA binding. In an earlier study, it was shown that the mutation of the zinc-fingers, mbmZnF, does not lead to changes in neuroblast cell size, but that MbmZnF is delocalized to the cytoplasm. In the present study, mbmZnF mutants were included in most experiments. The results, however, are puzzling since mbmZnF mutant larvae exhibit an even lower viability than the mbm null mutants and MbmZnF shows stronger binding to rRNA than wild-type Mbm. This suggests an unspecific interaction of MbmZnF with either another protein, DNA or RNA, possibly leading to a dominant negative effect by disturbing other interaction partners. Therefore, it is difficult to draw conclusions about the zinc-fingers’ functions.
In summary, this study provides further evidence that Mbm is involved in neuroblast proliferation as well as the regulation of ribosome biogenesis and that Mbm relies on its RGG-box to fulfill its functions.
Endogenous clocks regulate physiological as well as behavioral rhythms within all organisms. They are well investigated in D. melanogaster on a molecular as well as anatomical level. The neuronal clock network within the brain represents the center for rhythmic activity control. One neuronal clock subgroup, the pigment dispersing factor (PDF) neurons, stands out for its importance in regulating rhythmic behavior. These neurons express the neuropeptide PDF (pigment dispersing factor). A small neuropil at the medulla’s edge, the accessory medulla (AME), is of special interest, as it has been determined as the main center for clock control. It is not only highly innervated by the PDF neurons but also by terminals of all other clock neuron subgroups. Furthermore, terminals of the photoreceptors provide light information to the AME. Many different types of neurons converge within the AME and afterward spread to their next target. Thereby the AME is supplied with information from a variety of brain regions. Among these neurons are the aminergic ones whose receptors’ are expressed in the PDF neurons. The present study sheds light onto putative synaptic partners and anatomical arrangements within the neuronal clock network, especially within the AME, as such knowledge is a prerequisite to understand circadian behavior. The aminergic neurons’ conspicuous vicinity to the PDF neurons suggests synaptic communication among them. Thus, based on former anatomical studies regarding this issue detailed light microscopic studies have been performed. Double immunolabellings, analyses of the spatial relation of pre- and postsynaptic sites of the individual neuron populations with respect to each other and the identification of putative synaptic partners using GRASP reenforce the hypothesis of synaptic interactions within the AME between dopaminergic/ serotonergic neurons and the PDF neurons. To shed light on the synaptic partners I performed first steps in array tomography, as it allows terrific informative analyses of fluorescent signals on an ultrastructural level. Therefore, I tested different ways of sample preparation in order to achieve and optimize fluorescent signals on 100 nm thin tissue sections and I made overlays with electron microscopic images. Furthermore, I made assumptions about synaptic modulations within the neuronal clock network via glial cells. I detected their cell bodies in close vicinity to the AME and PDFcontaining clock neurons. It has already been shown that glial cells modulate the release of PDF from s-LNvs’ terminals within the dorsal brain. On an anatomical level this modulation appears to exist also within the AME, as synaptic contacts that involve PDF-positive dendritic terminals are embedded into glial fibers. Intriguingly, these postsynaptic PDF fibers are often VIIAbstract part of dyadic or even multiple-contact sites in opposite to prolonged presynaptic active zonesimplicating complex neuronal interactions within the AME. To unravel possible mechanisms of such synaptic arrangements, I tried to localize the ABC transporter White. Its presence within glial cells would indicate a recycling mechanism of transmitted amines which allows their fast re-provision. Taken together, synapses accompanied by glial cells appear to be a common arrangement within the AME to regulate circadian behavior. The complexity of mechanisms that contribute in modulation of circadian information is reflected by the complex diversity of synaptic arrangements that involves obviously several types of neuron populations
We are living in a system that underlies permanent environmental changes due to the rotation of our planet. These changes are rhythmic with the most prominent one having a period of about 24 hours, but also shorter and longer rhythms characterize our environment. To cope with the ever-changing environmental conditions, it is thought to be beneficial if an organism can track and anticipate these changes. The so called endogenous clocks enable this and might provide a fitness advantage. To investigate and unravel the mechanism of endogenous clocks Chronobiologists have used different model organisms. In this thesis Drosophila melanogaster was used as model organism with its about 150 clock neurons representing the main endogenous clock of the fly in the central brain.
The molecular mechanisms and the interlocked feedback loops with the main circadian key players like period, timeless, clock or cycle are under investigation since the 1970s and are characterized quite well so far. But the impact of a functional endogenous clock in combination with diverse factors and the resulting fitness advantages were analysed in only a few studies and remains for the most part unknown. Therefore the aim of this thesis was to unravel the impact of Drosophila melanogaster`s endogenous clock on the fitness of the fly. To achieve this goal different factors – like day length, humidity and food composition – were analyzed in wild type CS and three different period mutants, namely perL, perS and per01, that carry a point mutation altering or abolishing the free-running period of the fruit fly as well as a second arrhythmic strain, clkAR.
In competition assay experiments wild type and clock mutant flies competed for up to 63 generations under a normal 24 hour rhythm with 12 hours light/day and 12 hours darkness/night (LD12:12) or T-cycles with 19 or 29 hours, according to the mutants free-running period, or constant light (LL) in case of the arrhythmic mutant as well as under natural-like outdoor conditions in two consecutive years. Overall the wild type CS strain was outcompeting the clock mutant strains independent of the environmental conditions. As the perL fly strain elongated their free-running period, the competition experiments were repeated with naturally cantonized new fly strains. With these experiments it could be shown that the genetic background of the fly strains – which are kept for decades in the lab, with backcrosses every few years – is very important and influences the fitness of flies. But also the day length impacts the fitness of the flies, enabling them to persist in higher percentage in a population under competition. Further factors that might influence the survival in a competing population were investigated, like e.g. mating preferences and locomotor activity of homo- and heterozygous females or sperm number of males transferred per mating. But these factors can still not explain the results in total and play no or only minor roles and show the complexity of the whole system with still unknown characteristics.
Furthermore populations of flies were recorded to see if the flies exhibit a common locomotor activity pattern or not and indeed a population activity pattern could be recorded for the first time and social contact as a Zeitgeber could be verified for Drosophila melanogaster.
In addition humidity and its impact on the flies´ fitness as well as a potential Zeitgeber was examined in this thesis. The flies experienced different relative humidities for eclosion and wing expansion and humidity cycle phase shifting experiments were performed to address these two different questions of fitness impact and potential Zeitgeber. The fruit fly usually ecloses in the morning hours when the relative humidity is quite high and the general assumption was that they do so to prevent desiccation. The results of this thesis were quite clear and demonstrate that the relative humidity has no great effect on the fitness of the flies according to successful eclosion or wing expansion and that temperature might be the more important factor. In the humidity cycle phase shifting experiments it could be revealed that relative humidity cannot act as a Zeitgeber for Drosophila melanogaster, but it influences and therefore masks the activity of flies by allowing or surpressing activity at specific relative humidity values.
As final experiments the lifespan of wild type and clock mutant flies was investigated under different day length and with different food qualities to unravel the impact of these factors on the fitness and therefore survival of the flies on the long run. As expected the flies with nutrient-poor minimum medium died earlier than on the nutrient-rich maximum medium, but a small effect of day length could also be seen with flies living slightly longer when they experience environmental day length conditions resembling their free-running period. The experiments also showed a fitness advantage of the wild type fly strain against the clock mutant strains for long term, but not short term (about the first 2-3 weeks).
As a conclusion it can be said that genetic variation is important to be able to adapt to changing environmental conditions and to optimize fitness and therefore survival. Having a functional endogenous clock with a free-running period of about 24 hours provides fitness advantages for the fruit fly, at least under competition. The whole system is very complex and many factors – known and unknown ones – play a role in this system by interacting on different levels, e.g. physiology, metabolism and/or behavior.
Cell growth and cell division are two interconnected yet distinct processes. Initiation of proliferation of central brain progenitor cells (neuroblasts) after the late embryonic quiescence stage requires cell growth, and maintenance of proper cell size is an important prerequisite for continuous larval neuroblast proliferation. Beside extrinsic nutrition signals, cell growth requires constant supply with functional ribosomes to maintain protein synthesis.
Mutations in the mushroom body miniature (mbm) gene were previously identified in a screen for structural brain mutants. This study focused on the function of the Mbm protein as a new nucleolar protein, which is the site of ribosome biogenesis. The comparison of the relative expression levels of Mbm and other nucleolar proteins in different cell types showed a pronounced expression of Mbm in neuroblasts, particularly in the fibrillar component of the nucleolus, suggesting that in addition to nucleolar components generally required for ribosome biogenesis, more neuroblast specific nucleolar factors exist. Mutations in mbm cause neuroblast proliferation defects but do not interfere with cell polarity, spindle orientation or asymmetry of cell division of neuroblasts. Instead a reduction in cell size was observed, which correlates with an impairment of ribosome biogenesis. In particular, loss of Mbm leads to the retention of the small ribosomal subunit in the nucleolus resulting in decreased protein synthesis. Interestingly, the defect in ribosome biogenesis was only observed in neuroblasts. Moreover, Mbm is apparently not required for cell size and proliferation control in wing imaginal disc and S2 cells supporting the idea of a neuroblast-specific function of Mbm.
Furthermore, the transcriptional regulation of the mbm gene and the functional relevance of posttranslational modifications were analyzed. Mbm is a transcriptional target of dMyc. A common feature of dMyc target genes is the presence of a conserved E-box sequence in their promoter regions. Two E-box motifs are found in the vicinity of the transcriptional start site of mbm. Gene reporter assays verified that only one of them mediates dMyc-dependent transcription. Complementary studies in flies showed that removal of dMyc function in neuroblasts resulted in reduced Mbm expression levels.
At the posttranslational level, Mbm becomes phosphorylated by protein kinase CK2. Six serine and threonine residues located in two acidic amino acid rich clusters in the C-terminal half of the Mbm protein were identified as CK2 phosphorylation sites.
Mutational analysis of these sites verified their importance for Mbm function in vivo and indicated that Mbm localization is controlled by CK2-mediated phosphorylation.
Although the molecular function of Mbm in ribosome biogenesis remains to be determined, the results of this study emphasize the specific role of Mbm in neuroblast ribosome biogenesis to control cell growth and proliferation.
Synapsen als Stellen der Kommunikation zwischen Neuronen besitzen spezialisierte Bereiche – Aktive Zonen (AZs) genannt –, die aus einem hoch komplexen Netzwerk von Proteinen aufgebaut sind und die Maschinerie für den Prozess der Neurotransmitter-Ausschüttung und das Vesikel-Recycling beinhalten. In Drosophila ist das Protein Bruchpilot (BRP) ein wichtiger Baustein für die T-förmigen Bänder („T-Bars“) der präsynaptischen Aktiven Zonen. BRP ist notwendig für eine intakte Struktur der Aktiven Zone und eine normale Exocytose von Neurotransmitter-Vesikeln. Auf der Suche nach Mutationen, welche die Verteilung von Bruchpilot im Gewebe beeinträchtigen, wurde eine P-Element-Insertion im Gen CG11489 an der Position 79D identifiziert, welches eine Kinase kodiert, die einen hohen Grad an Homologie zur Familie der SR Proteinkinasen (SRPKs) von Säugern aufweist. Die Mitglieder dieser Familie zeichnen sich durch eine evolutionär hoch konservierte zweigeteilte Kinasedomäne aus, die durch eine nicht konservierte Spacer-Sequenz unterbrochen ist. SRPKs phosphorylieren SR-Proteine, die zu einer evolutionär hoch konservierten Familie Serin/Arginin-reicher Spleißfaktoren gehören und konstitutive sowie alternative Spleißprozesse steuern und damit auf post-transkriptioneller Ebene die Genexpression regulieren. Mutation des Srpk79D-Gens durch die P-Element-Insertion (Srpk79DP1) oder eine Deletion im Gen (Srpk79DVN Nullmutante) führt zu auffälligen BRP-Akkumulationen in larvalen und adulten Nerven. In der vorliegenden Arbeit wird gezeigt, dass diese BRP-Akkumulationen auf Ultrastruktur-Ebene ausgedehnten axonalen Agglomeraten elektronendichter Bänder entsprechen und von klaren Vesikeln umgeben sind. Charakterisierung durch Immuno-Elektronenmikroskopie ergab, dass diese Strukturen BRP-immunoreaktiv sind. Um die Bildung BRP-enthaltender Agglomerate in Axonen zu verhindern und damit eine intakte Gehirnfunktion zu gewährleisten, scheint die SRPK79D nur auf niedrigem Niveau exprimiert zu werden, da die endogene Kinase mit verschiedenen Antikörpern nicht nachweisbar war. Wie in anderen Arbeiten gezeigt werden konnte, ist die Expression der PB-, PC- oder PF-Isoform der vier möglichen SRPK79D-Varianten, die durch alternativen Transkriptionsstart in Exon eins beziehungsweise drei und alternatives Spleißen von Exon sieben zustande kommen, zur Rettung des Phänotyps der BRP-Akkumulation im Srpk79DVN Nullmutanten-Hintergrund ausreichend. Zur Charakterisierung der Rescue-Eigenschaften der SRPK79D-PE-Isoform wurde mit der Klonierung der cDNA in einen UAS-Vektor begonnen. Offenbar beruht die Bildung der axonalen BRP-Agglomerate nicht auf einer Überexpression von BRP in den betroffenen Neuronen, denn auch bei reduzierter Expression des BRP-Proteins im Srpk79DVN Nullmutanten-Hintergrund entstehen die BRP-Agglomerate. In Köpfen der Srpk79DVN Nullmutante ist die Gesamtmenge an Bruchpilot-Protein im Vergleich zum Wildtyp nicht deutlich verändert. Auch die auf Protein-Ebene untersuchte Expression der verschiedenen Isoformen der präsynaptischen Proteine Synapsin, Sap47 und CSP weicht in der Srpk79DVN Nullmutante nicht wesentlich von der Wildtyp-Situation ab, sodass sich keine Hinweise auf verändertes Spleißen der entsprechenden prä-mRNAs ergeben. Jedes der sieben bekannten SR-Proteine von Drosophila ist ein potentielles Zielprotein der SRPK79D. Knock-down-Experimente für die drei hier untersuchten SR-Proteine SC35, X16/9G8 und B52/SRp55 im gesamten Nervensystem durch RNA-Interferenz zeigten allerdings keinen Effekt auf die Verteilung von BRP im Gewebe. Hinsichtlich der Flugfähigkeit der Tiere hat die Srpk79DVN Nullmutation keinen additiven Effekt zum Knock-down des BRP-Proteins, denn die Doppelmutanten zeigten bei der Bestimmung des Anteils an flugunfähigen Tieren vergleichbare Werte wie die Einzelmutanten, die entweder die Nullmutation im Srpk79D-Gen trugen, oder BRP reduziert exprimierten. Vermutlich sind Bruchpilot und die SR Proteinkinase 79D somit Teil desselben Signalwegs. Durch Doppelfärbungen mit Antikörpern gegen BRP und CAPA-Peptide wurde abschließend entdeckt, dass Bruchpilot auch im Median- und Transvers-Nervensystem (MeN/TVN) von Drosophila zu finden ist, welche die Neurohämal-Organe beherbergen. Aufgabe dieser Organe ist die Speicherung und Ausschüttung von Neuropeptid-Hormonen. Daher ist zu vermuten, dass das BRP-Protein neben Funktionen bei der Neurotransmitter-Exocytose möglicherweise eine Rolle bei der Ausschüttung von Neuropeptiden spielt. Anders als in den Axonen der larvalen Segmental- und Intersegmentalnerven der Srpk79DVN Nullmutante, die charakteristische BRP-Agglomerate aufweisen, hat die Mutation des Srpk79D-Gens in den Axonen der Va-Neurone, die das MeN/TVN-System bilden, keinen sichtbaren Effekt auf die Verteilung von Brp, denn das Muster bei Färbung gegen BRP weist keine deutlichen Veränderungen zum Wildtyp auf.
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.
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.
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.