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Chemical neurotransmission is a complex process of central importance for nervous system function. It is thought to be mediated by the orchestration of hundreds of proteins for its successful execution. Several synaptic proteins have been shown to be relevant for neurotransmission and many of them are highly conserved during evolution- suggesting a universal mechanism for neurotransmission. This process has checkpoints at various places like, neurotransmitter uptake into the vesicles, relocation of the vesicles to the vicinity of calcium channels in order to facilitate Ca2+ induced release thereby modulating the fusion probability, formation of a fusion pore to release the neurotransmitter and finally reuptake of the vesicles by endocytosis. Each of these checkpoints has now become a special area of study and maintains its own importance for the understanding of the overall process. Ca2+ induced release occurs at specialized membrane structures at the synapse known as the active zones. These are highly ordered electron dense grids and are composed of several proteins which assist the synaptic vesicles in relocating in the vicinity of Ca2+ channels thereby increasing their fusion probability and then bringing about the vesicular fusion itself. All the protein modules needed for these processes are thought to be held in tight arrays at the active zones, and the functions of a few have been characterized so far at the vertebrate active zones. Our group is primarily interested in characterizing the molecular architecture of the Drosophila synapse. Due to its powerful genetics and well-established behavioural assays Drosophila is an excellent system to investigate neuronal functioning. Monoclonal antibodies (MABs) from a hybridoma library against Drosophila brain are routinely used to detect novel proteins in the brain in a reverse genetic approach. Upon identification of the protein its encoding genetic locus is characterized and a detailed investigation of its function is initiated. This approach has been particularly useful to detect synaptic proteins, which may go undetected in a forward genetic approach due to lack of an observable phenotype. Proteins like CSP, Synapsin and Sap47 have been identified and characterized using this approach so far. MAB nc82 has been one of the shortlisted antibodies from the same library and is widely used as a general neuropil marker due to the relative transparency of immunohistochemical whole mount staining obtained with this antibody. A careful observation of double stainings at the larval neuromuscular junctions with MAB nc82 and other pre and post-synaptic markers strongly suggested an active zone localization of the nc82 antigen. Synaptic architecture is well characterized in Drosophila at the ultrastructural level. However, molecular details for many synaptic components and especially for the active zone are almost entirely unknown. A possible localization at the active zone for the nc82 antigen served as the motivation to initiate its biochemical characterization and the identification of the encoding gene. In the present thesis it is shown by 2-D gel analysis and mass spectrometry that the nc82 antigen is a novel active zone protein encoded by a complex genetic locus on chromosome 2R. By RT-PCR exons from three open reading frames previously annotated as separate genes are demonstrated to give rise to a transcript of at least 5.5 kb. Northern blots produce a prominent signal of 11 kb and a weak signal of 2 kb. The protein encoded by the 5.5 kb transcript is highly conserved amongst insects and has at its N-terminus significant homology to the previously described vertebrate active zone protein ELKS/ERC/CAST. Bioinformatic analysis predicts coiled-coil domains spread all over the sequence and strongly suggest a function involved in organizing or maintaining the structure of the active zone. The large C-terminal region is highly conserved amongst the insects but has no clear homologues in veretebrates. For a functional analysis of this protein transgenic flies expressing RNAi constructs under the control of the Gal4 regulated enhancer UAS were kindly provided by the collaborating group of S.Sigrist (Gِttingen). A strong pan-neuronal knockdown of the nc82 antigen by transgenic RNAi expression leads to embryonic lethality. A relatively weaker RNAi expression results in behavioural deficits in adult flies including unstable flight and impaired walking behavior. Due to this peculiar phenotype as observed in the first knockdown studies the gene was named “bruchpilot” (brp) encoding the protein “Bruchpilot (BRP)” (German for crash pilot). A pan-neuronal as well as retina specific downregulation of this protein results in loss of ON and OFF transients in ERG recordings indicating dysfunctional synapses. Retina specific downregulation also shows severely impaired optomotor behaviour. Finally, at an ultrastructural level BRP downregulation seems to impair the formation of the characteristic T-shaped synaptic ribbons at the active zones without significantly altering the overall synaptic architecture (in collaboration with E.Asan). Vertebrate active zone protein Bassoon is known to be involved in attaching the synaptic ribbons to the active zones as an adapter between active zone proteins RIBEYE and ERC/CAST. A mutation in Bassoon results in a floating synaptic ribbon phenotype. No protein homologous to Bassoon has been observed in Drosophila. BRP downregulation also results in absence of attached synaptic ribbons at the active zones. This invites the speculation of an adapter like function for BRP in Drosophila. However, while Bassoon mutant mice are viable, BRP deficit in addition to the structural phenotype also results in severe behavioural and physiological anomalies and even stronger downregulation causes embryonic lethality. This therefore suggests an additional and even more important role for BRP in development and normal functioning of synapses in Drosophila and also in other insects. However, how BRP regulates synaptic transmission and which other proteins are involved in this BRP dependant pathway remains to be investigated. Such studies certainly will attract prominent attention in the future.
The learned helplessness phenomenon is a specific animal behavior induced by prior exposure to uncontrollable aversive stimuli. It was first found by Seligman and Maier (1967) in dogs and then has been reported in many other species, e.g. in rats (Vollmayr and Henn, 2001), in goldfishes (Padilla, 1970), in cockroaches (Brown, 1988) and also in fruit flies (Brown, 1996; Bertolucci, 2008). However, the learned helplessness effect in fruit flies (Drosophila melanogaster) has not been studied in detail. Thus, in this doctoral study, we investigated systematically learned helplessness behavior of Drosophila for the first time.
Three groups of flies were tested in heatbox. Control group was in the chambers experiencing constant, mild temperature. Second group, master flies were punished in their chambers by being heated if they stopped walking for 0.9s. The heat pulses ended as soon as they resumed walking again. A third group, the yoked fly, was in their chambers at the same time. However, their behavior didn’t affect anything: yoked flies were heated whenever master flies did, with same timing and durations. After certain amount of heating events, yoked flies associated their own behavior with the uncontrollability of the environment. They suppressed their innate responses such as reducing their walking time and walking speed; making longer escape latencies and less turning around behavior under heat pulses. Even after the conditioning phase, yoked flies showed lower activity level than master and control flies. Interestingly, we have also observed sex dimorphisms in flies. Male flies expressed learned helplessness not like female flies. Differences between master and yoked flies were smaller in male than in female flies. Another interesting finding was that prolonged or even repetition of training phases didn’t enhance learned helplessness effect in flies.
Furthermore, we investigated serotonergic and dopaminergic nervous systems in learned helplessness. Using genetic and pharmacological manipulations, we altered the levels of serotonin and dopamine in flies’ central nervous system. Female flies with reduced serotonin concentration didn’t show helpless behavior, while the learned helplessness effect in male flies seems not to be affected by a reduction of serotonin. Flies with lower dopamine level do not display the learned helplessness effect in the test phase, suggesting that with low dopamine the motivational change in learned helplessness in Drosophila may decline faster than with a normal dopamine level.
Most natural learning situations are of a complex nature and consist of a tight conjunction of the animal's behavior (B) with the perceived stimuli. According to the behavior of the animal in response to these stimuli, they are classified as being either biologically neutral (conditioned stimuli, CS) or important (unconditioned stimuli, US or reinforcer). A typical learning situation is thus identified by a three term contingency of B, CS and US. A functional characterization of the single associations during conditioning in such a three term contingency has so far hardly been possible. Therefore, the operational distinction between classical conditioning as a behavior-independent learning process (CS-US associations) and operant conditioning as essentially behavior-dependent learning (B-US associations) has proven very valuable. However, most learning experiments described so far have not been successful in fully separating operant from classical conditioning into single-association tasks. The Drosophila flight simulator in which the relevant behavior is a single motor variable (yaw torque), allows for the first time to completely separate the operant (B-US, B-CS) and the classical (CS-US) components of a complex learning situation and to examine their interactions. In this thesis the contributions of the single associations (CS-US, B-US and B-CS) to memory formation are studied. Moreover, for the first time a particularly prominent single association (CS-US) is characterized extensively in a three term contingency. A yoked control shows that classical (CS-US) pattern learning requires more training than operant pattern learning. Additionally, it can be demonstrated that an operantly trained stimulus can be successfully transferred from the behavior used during training to a new behavior in a subsequent test phase. This result shows unambiguously that during operant conditioning classical (CS-US) associations can be formed. In an extension to this insight, it emerges that such a classical association blocks the formation of an operant association, which would have been formed without the operant control of the learned stimuli. Instead the operant component seems to develop less markedly and is probably merged into a complex three-way association. This three-way association could either be implemented as a sequential B-CS-US or as a hierarchical (B-CS)-US association. The comparison of a simple classical (CS-US) with a composite operant (B, CS and US) learning situation and of a simple operant (B-US) with another composite operant (B, CS and US) learning situation, suggests a hierarchy of predictors of reinforcement. Operant behavior occurring during composite operant conditioning is hardly conditioned at all. The associability of classical stimuli that bear no relation to the behavior of the animal is of an intermediate value, as is operant behavior alone. Stimuli that are controlled by operant behavior accrue associative strength most easily. If several stimuli are available as potential predictors, again the question arises which CS-US associations are formed? A number of different studies in vertebrates yielded amazingly congruent results. These results inspired to examine and compare the properties of the CS-US association in a complex learning situation at the flight simulator with these vertebrate results. It is shown for the first time that Drosophila can learn compound stimuli and recall the individual components independently and in similar proportions. The attempt to obtain second-order conditioning with these stimuli, yielded a relatively small effect. In comparison with vertebrate data, blocking and sensory preconditioning experiments produced conforming as well as dissenting results. While no blocking could be found, a sound sensory preconditioning effect was obtained. Possible reasons for the failure to find blocking are discussed and further experiments are suggested. The sensory preconditioning effect found in this study is revealed using simultaneous stimulus presentation and depends on the amount of preconditioning. It is argued that this effect is a case of 'incidental learning', where two stimuli are associated without the need of reinforcement. Finally, the implications of the results obtained in this study for the general understanding of memory formation in complex learning situations are discussed.
In order to select the appropriate behavior, it is important to choose the right behavior at the right time out of many options. It still remains unclear nowadays how exactly this is managed. To address this question, I expose flies (Drosophila melanogaster) to uncontrollable stress to study their behavior under restrictive circumstances by using the so-called shock box. Exposing animals to uncontrollable stress may have an impact on subsequent behavior and can last for some time. The animal learns that whatever it does, it cannot change the situation and therefore can develop something called learned helplessness. The term was first conceptualized by two American psychologists Maier and Seligman (1967), who discovered this phenomenon while doing experiments with dogs. They found out that dogs which are exposed to inescapable stress, later fail in a learning task (‘shuttle box’).
In this work the walking patterns of three different types of experimental flies, walking in a small dark chamber, were evaluated. Using the triadic design (Seligman and Maier, 1967), flies were either exposed to electric shock randomly (yoked), could turn it off by being active (master) or did not receive punishment at all (control). Master flies were shocked whenever they sat for more than 0.9 seconds. At the same time yoked flies received a shock as well independent of what they were doing, to ensure the same amount of shocks received and to create random punishment pattern for the yoked group. With this so-called no-idleness paradigm flies were conditioned either 10 minutes, which resulted in a short (3 minutes) after-effect, or 20 minutes that turned out to be more stable (10 minutes).
In a second part, the behavior during the 20 minute conditioning and a 10 minutes post-test was described in detail. Female flies of the yoked group developed lower activity levels, longer pauses and walked more slowly than master and control flies during conditioning. In the time after the shocks while still in the box, the yoked flies also reduced the frequency and duration of walking bouts as well as their walking speed. Additionally, they took more time to resume walking after the onset of an electric shock than master flies (escape latency) and turned out to make less pauses lasting between 1-1.5 seconds which supports the finding concerning the escape latency.
Male flies, tested under the same conditions, showed a slightly weaker after-effect regarding the difference between master and yoked during conditioning and post-test when compared to female flies.
When comparing the 20 minutes conditioning with subsequent 10 minutes test in the heat and the shock box in parallel, one finds the same effect: Flies which do not have control over the shocks, lower their activity, make less but longer pauses and walk more slowly than their respective master flies. Despite the similar effect of heat and shock on the flies, some differences between the devices occurred, which can partly be explained by different humidity conditions as well as by different surfaces within the chambers.
When the control over the shocks is given back to the yoked flies, it takes them about seven minutes to realize it. One could also show that dopamine levels in the brain were reduced in comparison to flies which did not receive shocks. Yoked flies also were impaired in a place learning task (place learning) and their reaction to light (exit from the box towards the light) directly after conditioning.
After characterizing the walking behavior in the chambers, the study deals with the question whether the effects observed in the chambers transfer to different environments.
In free walk they only differed from flies which did not receive electric shocks and no effect of uncontrollability was transferred to courtship behavior. Handling as the cause could be excluded. Since handling could be exclude to be the cause of losing the effect, I assumed that the behavior shown in the boxes are context depend.
Not only were the after-effects of inescapable shock subject of the current research also the impact of the rearing situation on the response to electric shock was investigated in the present study. Flies which grew up in a single-reared situation turned out to be less affected by inescapable stress in both sexes.
In the next part, the first steps to unravel the neuronal underpinning were taken. A mutant – fumin – which is defective in the dopamine re-uptake transporter showed less reaction to inescapable foot shocks, while a mutant for the gene which encodes an adenylate cyclase (rutabaga2080) resulted in a good score during conditioning, but showed no stable after-effect. Downregulating the expression of the adenylate cyclase gene (rutabaga) in different parts of the mushroom bodies showed, that rutabaga is necessary in the α’β’-lobes for expressing the differences between master and yoked flies in the no-idleness paradigm. The study further confirmed previous findings, that rutabaga is needed in operant but not in classical conditioning.
As a result, the study could show that not the stimulus itself causes the state of uncontrollability but the fact that the fly learned that it was not in control of the stimulus. This state turned out to be context and time dependent.
Since Channelrhodopsins has been described first and introduced successfully in freely moving animals (Nagel et al., 2003 and 2005), tremendous impact has been made in this interesting field of neuroscience. Subsequently, many different optogenetic tools have been described and used to address long-lasting scientific issues. Furthermore, beside the ‘classical’ Channelrhodopsin-2 (ChR2), basically a cation-selective ion channel, also altered ChR2 descendants, anion selective channels and light-sensitive metabotropic proteins have expanded the optogenetic toolbox. However, in spite of this variety of different tools most researches still pick Channelrhodopsin-2 for their optogenetic approaches due to its well-known kinetics. In this thesis, an improved Channelrhodopsin, Channelrhodopsin2-XXM (ChR2XXM), is described, which might become an useful tool to provide ambitious neuroscientific approaches by dint of its characteristics. Here, ChR2XXM was chosen to investigate the functional consequences of Drosophila larvae lacking latrophilin in their chordotonal organs. Finally, the functionality of GtACR, was checked at the Drosophila NMJ. For a in-depth characterisation, electrophysiology along with behavioural setups was employed. In detail, ChR2XXM was found to have a better cellular expression pattern, high spatiotemporal precision, substantial increased light sensitivity and improved affinity to its chromophore retinal, as compared to ChR2. Employing ChR2XXM, effects of latrophilin (dCIRL) on signal transmission in the chordotonal organ could be clarified with a minimum of side effects, e.g. possible heat response of the chordotonal organ, due to high light sensitivity. Moreover, optogenetic activation of the chordotonal organ, in vivo, led to behavioural changes. Additionally, GtACR1 was found to be effective to inhibit motoneuronal excitation but is accompanied by unexpected side effects. These results demonstrate that further improvement and research of optogenetic tools is highly valuable and required to enable researchers to choose the best fitting optogenetic tool to address their scientific questions.
The correct regulation of cell growth and proliferation is essential during normal animal development. Myc proteins function as transcription factors, being involved in the con-trol of many growth- and proliferation-associated genes and deregulation of Myc is one of the main driving factors of human malignancies.
The first part of this thesis focuses on the identification of directly regulated Myc target genes in Drosophila melanogaster, by combining ChIPseq and RNAseq approaches. The analysis results in a core set of Myc target genes of less than 300 genes which are mainly involved in ribosome biogenesis. Among these genes we identify a novel class of Myc targets, the non-coding small nucleolar RNAs (snoRNAs). In vivo studies show that loss of snoRNAs not only impairs growth during normal development, but that overexpression of several snoRNAs can also enhance tumor development in a neu-ronal tumor model. Together the data show that Myc acts as a master regulator of ribo-some biogenesis and that Myc’s transforming effects in tumor development are at least partially mediated by the snoRNAs.
In the second part of the thesis, the interaction of Myc and the Zf-protein Chinmo is described. Co-immunoprecipitations of the two proteins performed under endogenous and exogenous conditions show that they interact physically and that neither the two Zf-domains nor the BTB/POZ-domain of Chinmo are important for this interaction. Fur-thermore ChIP experiments and Myc dependent luciferase assays show that Chinmo and Myc share common target genes, and that Chinmo is presumably also involved in their regulation. While the exact way of how Myc and Chinmo genetically interact with each other still has to be investigated, we show that their interaction is important in a tumor model. Overexpression of the tumor-suppressors Ras and Chinmo leads to tu-mor formation in Drosophila larvae, which is drastically impaired upon loss of Myc.
Characterization of memories and ignorant (S6KII) mutants in operant conditioning in the heat-box
(2002)
Learning and memory processes of operant conditioning in the heat-box were analysed. Age, sex, and larval desity were not critical parameters influencing memory, while low or high activity levels of flies were negatively correlated with their performance. In a search for conditioning parameters leading to high retention scores, intermittent training was shown to give better results than continuous training. As the memory test is the immediate continuation of the conditioning phase just omitting reinforcement, we obtain a memory which consists of two components: a spatial preference for one side of the chamber and a stay-where-you-are effect in which the side preference is contaminated by the persistence of heat avoidance. Intermittent training strengthens the latter. In the next part, memory retention was investigated. Flies were trained in one chamber and tested in a second one after a brief reminder training. With this direct transfer, memory scores reflect an associative learning process in the first chamber. To investigate memory retention after extended time periods, indirect transfer experiments were performed. The fly was transferred to a different environment between training and test phases. With this procedure an after-effect of the training was still observed two hours later. Surprisingly, exposure to the chamber without conditioning also lead to a memory effect in the indirect transfer experiment. This exposure effect revealed a dispositional change that facilitates operant learning during the reminder training. The various memory effects are independent of the mushroom bodies. The transfer experiments and yoked controls proved that the heat-box records an associative memory. Even two hours after the operant conditioning procedure, the fly remembers that its position in the chamber controls temperature. The cAMP signaling cascade is involved in heat-box learning. Thus, amnesiac, rutabaga, and dunce mutants have an impaired learning / memory. Searching for, yet unknown, genes and signaling cascades involved in operant conditioning, a Drosophila melanogaster mutant screen with 1221 viable X-chromosome P-element lines was performed. 29 lines with consistently reduced heat avoidance/ learning or memory scores were isolated. Among those, three lines have the p[lacW] located in the amnesiac ORF, confirming that with the chosen candidate criteria the heat-box is a useful tool to screen for learning and /or memory mutants. The mutant line ignP1 (8522), which is defective in the gene encoding p90 ribosomal S6 kinase (S6KII), was investigated. The P-insertion of line ignP1 is the first Drosophila mutation in the ignorant (S6KII) gene. It has the transposon inserted in the first exon. Mutant males are characterized by low training performance, while females perform well in the standard experiment. Several deletion mutants of the ignorant gene have been generated. In precise jumpouts the phenotype was reverted. Imprecise jumpouts with a partial loss of the coding region were defective in operant conditioning. Surprisingly, null mutants showed wild-type behavior. This might indicate an indirect effect of the mutated ignorant gene on learning processes. In classical odor avoidance conditioning, ignorant null mutants showed a defect in the 3-min, 30-min, and 3-hr memory, while the precise jumpout of the transposon resulted in a reversion of the behavioral phenotype. Deviating results from operant and classical conditioning indicate different roles for S6KII in the two types of learning.
In this thesis we have used Drosophila melanogaster as a model organism to investigate proteins and their putative interacting partners that are directly or indirectly involved in the release of neurotransmitters at the synapse. We have used molecular techniques to investigate conserved synaptic proteins, synapsin and synapse associated protein of 47 kD (SAP47), and a putative interaction partner of SAP47, tubulin binding chaperone E-like (TBCEL). SAP47 and synapsins are highly conserved synaptic vesicle associated proteins in Drosophila melanogaster. To further investigate the role and function of Sap47 and Syn genes, we had earlier generated the null mutants by P-element mutagenesis (Funk et al., 2004; Godenschwege et al., 2004). Western blots and ELISA of brain homogenates from Sap47156 null mutants showed the presence of up-regulated phospho-synapsin in comparison to wild-type (CS) and the presence of up-regulated phospho-synapsin was partially abolished when a pan-neuronal rescue of SAP47 was performed by the Gal4- UAS technique. Thus, the results suggest a qualitative and quantitative modulation of synapsin by SAP47. At the transcript level, we did not observe any difference in content of Syn transcript in Sap47156 and wild-type CS flies. The question of a direct molecular interaction between SAP47 and synapsin was investigated by co-immunoprecipitation (Co-IP) experiments and we did not find any stable interactions under the several IP conditions we tested. The possibility of Sap47 as a modifier of Syn at the genetic level was investigated by generating and testing homozygous double null mutants of Sap47 and Syn. The Syn97, Sap47156 double mutants are viable but have a reduced life span and decreased locomotion when compared to CS. In 2D-PAGE analysis of synapsins we identified trains of spots corresponding to synapsins, suggesting that synapsin has several isoforms and each one of them is posttranslationally modified. In an analysis by Blue native-SDS-PAGE (BN-SDS-2D- PAGE) and Western blot we observed synapsin and SAP47 signals to be present at 700-900 kDa and 200-250 kDa, respectively, suggesting that they are part of large but different complexes. We also report the possibility of Drosophila synapsin forming homo- and heteromultimers, which has also been reported for synapsins of vertebrates. In parallel to the above experiments, phosphorylation of synapsins in Drosophila was studied by IP techniques followed by 1D-SDS gel electrophoresis and mass spectrometry (in collaboration with S. Heo and G. Lubec). We identified and verified 5 unique phosphorylation sites in Drosophila synapsin from our MS analysis. Apart from phosphorylation modifications we identified several other PTMs which have not been verified. The significance of these phosphorylations and other identified PTMs needs to be investigated further and their implications for synapsin function and Drosophila behavior has to be elucidated by further experiments. In a collaborative project with S. Kneitz and N. Nuwal, we investigated the effects of Sap156 and Syn97 mutations by performing a whole Drosophila transcriptome microarray analysis of the individual null mutants and the double mutants (V2 and V3). We obtained several candidates which were significantly altered in the mutants. These genes need to be investigated further to elucidate their interactions with Sap47 and Syn. In another project, we investigated the role and function of Drosophila tubulin- binding chaperone E-like (Tbcel, CG12214). The TBCEL protein has high homology to vertebrate TBCE-like (or E-like) which has high sequence similarity to tubulin-binding chaperone E (TBCE) (hence the name TBCE-Like). We generated an anti-TBCEL polyclonal antiserum (in collaboration with G. Krohne). According to flybase, the Tbcel gene has only one exon and codes for two different transcripts by alternative transcription start sites. The longer transcript RB is present only in males whereas the shorter transcript RA is present only in females. In order to study the gene function we performed P- element jump-out mutagenesis to generate deletion mutants. We used the NP4786 (NP) stock which has a P(GawB) insertion in the 5’ UTR of the Tbcel gene. NP4786 flies are homozygous lethal due to a second-site lethality as the flies are viable over a deficiency (Df) chromosome (a deletion of genomic region spanning the Tbcel gene and other upstream and downstream genes). We performed the P-element mutagenesis twice. In the first trial we obtained only revertants and the second experiment is still in progress. In the second attempt, jump-out was performed over the deficiency chromosome to prevent homologous chromosome mediated double stranded DNA repair. During the second mutagenesis an insertion stock G18151 became available. These flies had a P-element insertion in the open reading frame (ORF) of the Tbcel gene but was homozygous viable. Western blots of fresh tissue homogenates of NP/Df and G18151 flies probed with anti-TBCEL antiserum showed no TBCEL signal, suggesting that these flies are Tbcel null mutants. We used these flies for further immunohistochemical analyses and found that TBCEL is specifically expressed in the cytoplasm of cyst cells of the testes and is associated with the tubulin of spermatid tails in wild-type CS, whereas in NP/Df and G18151 flies the TBCEL staining in the cyst cells was absent and there was a disruption of actin investment cones. We also found enrichment of TBCEL staining around the actin investment cone. These results are also supported by the observation that the enhancer trap expression of the NP4786 line is localised to the cyst cells, similar to TBCEL expression. Also, male fertility of NP/Df and G18151 flies was tested and they were found to be sterile with few escapers. Thus, these results suggest that TBCEL is involved in Drosophila spermatogenesis with a possible role in the spermatid elongation and individualisation process.
In this thesis I studied psychological aspects in the behaviour of Drosophila, and especially Drosophila larvae. After an introduction where I present the general scientific context and describe the mechanisms of olfactory perception as well as of classical and operant conditioning, I present the different experiments that I realised during my PhD. Perception The second chapter deals with the way adult Drosophila generalise between single odours and binary mixtures of odours. I found that flies perceive a mixture of two odours as equally similar to the two elements composing it; and that the intensity as well as the physico-chemical nature of the elements composing a mixture affect the degree of generalisation between this mixture and one of its elements. These findings now call for further investigation on the physiological level, using functional imaging. Memory The third chapter presents a series of experiments in Drosophila larvae in order to define some characteristics of a new protocol for classical aversive learning which involves associating odours with mechanical disturbance as a punishment. The protocol and the first results should open new doors for the study of classical conditioning in Drosophila larvae, by allowing the comparison between two types of aversive memory (gustatory vs. mechanical reinforcement), including a comparison of their neurogenetic bases. It will also allow enquiries into the question whether these respective memories are specific for the kind of reinforcer used. Agency The fourth chapter documents our attempts to establish operant memory in Drosophila larvae. By analysing the first moments of the test, I could reveal that the larvae modified their behaviour according to their previous operant training. However, this memory seems to be quickly extinguished during the course of the test. We now aim at repeating these results and improving the protocol, in order to be able to systematically study the mechanisms allowing and underlying operant learning in Drosophila larvae. In the fifth chapter, I use the methods developed in chapter four for an analysis of larval locomotion. I determine whether larval locomotion in terms of speed or angular speed is affected by a treatment with the “cognitive enhancer” Rhodiola rosea, or by mutations in the Synapsin or SAP47 genes which are involved in the formation of olfactory memory. I also characterize the modifications induced by the presence of gustatory stimuli in the substrate on which the larvae are crawling. This thesis thus brings new elements to the current knowledge of Drosophila
Neuroanatomical data in fly brain research are mostly available as spatial gene expression patterns of genetically distinct fly strains. The Drosophila standard brain, which was developed in the past to provide a reference coordinate system, can be used to integrate these data. Working with the standard brain requires advanced image processing methods, including visualisation, segmentation and registration. The previously published VIB Protocol addressed the problem of image registration. Unfortunately, its usage was severely limited by the necessity of manually labelling a predefined set of neuropils in the brain images at hand. In this work I present novel tools to facilitate the work with the Drosophila standard brain. These tools are integrated in a well-known open-source image processing framework which can potentially serve as a common platform for image analysis in the neuroanatomical research community: ImageJ. In particular, a hardware-accelerated 3D visualisation framework was developed for ImageJ which extends its limited 3D visualisation capabilities. It is used for the development of a novel semi-automatic segmentation method, which implements automatic surface growing based on user-provided seed points. Template surfaces, incorporated with a modified variant of an active surface model, complement the segmentation. An automatic nonrigid warping algorithm is applied, based on point correspondences established through the extracted surfaces. Finally, I show how the individual steps can be fully automated, and demonstrate its application for the successful registration of fly brain images. The new tools are freely available as ImageJ plugins. I compare the results obtained by the introduced methods with the output of the VIB Protocol and conclude that our methods reduce the required effort five to ten fold. Furthermore, reproducibility and accuracy are enhanced using the proposed tools.
This thesis consists of three major chapters, each of which has been separately published or under the process for publication. The first chapter is about anatomical characterization of the mushroom body of adult Drosophila melanogaster. The mushroom body is the center for olfactory learning and many other functions in the insect brains. The functions of the mushroom body have been studied by utilizing the GAL4/UAS gene expression system. The present study characterized the expression patterns of the commonly used GAL4 drivers for the mushroom body intrinsic neurons, Kenyon cells. Thereby, we revealed the numerical composition of the different types of Kenyon cells and found one subtype of the Kenyon cells that have not been described. The second and third chapters together demonstrate that the multiple types of dopaminergic neurons mediate the aversive reinforcement signals to the mushroom body. They induce the parallel memory traces that constitute the different temporal domains of the aversive odor memory. In prior to these chapters, “General introduction and discussion” section reviews and discuss about the current understanding of neuronal circuit for olfactory learning in Drosophila.
Animals need to evaluate their experiences in order to cope with new situations they encounter. This requires the ability of learning and memory. Drosophila melanogaster lends itself as an animal model for such research because elaborate genetic techniques are available. Drosphila larva even saves cellular redundancy in parts of its nervous system. My Thesis has two parts dealing with associative olfactory learning in larval Drosophila. Firstly, I tackle the question of odour processing in respect to odour quality and intensity. Secondly, by focusing on the evolutionarily conserved presynaptic protein Synapsin, olfactory learning on the cellular and molecular level is investigated. Part I.1. provides a behaviour-based estimate of odour similarity in larval Drosophila by using four recognition-type experiments to result in a combined, task-independent estimate of perceived difference between odour-pairs. A further comparison of these combined perceived differences to published calculations of physico-chemical difference reveals a weak correlation between perceptual and physico-chemical similarity. Part I.2. focuses on how odour intensity is interpreted in the process of olfactory learning in larval Drosophila. First, the dose-effect curves of learnability across odour intensities are described in order to choose odour intensities such that larvae are trained at intermediate odour intensity, but tested for retention either with that trained intermediate odour intensity, or with respectively HIGHer or LOWer intensities. A specificity of retention for the trained intensity is observed for all the odours used. Such intensity specificity of learning adds to appreciate the richness in 'content' of olfactory memory traces, and to define the demands on computational models of associative olfactory memory trace formation. In part II.1. of the thesis, the cellular site and molecular mode of Synapsin function is investigated- an evolutionarily conserved, presynaptic vesicular phosphoprotein. On the cellular level, the study shows a Synapsin-dependent memory trace in the mushroom bodies, a third-order “cortical” brain region of the insects; on the molecular level, Synapsin engages as a downstream element of the AC-cAMP-PKA signalling cascade.
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.
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.
Latrophilin, alternatively named calcium-independent receptor of α-latrotoxin (CIRL), resembles a prototype of the adhesion class G-protein coupled receptors (GPCRs). Initially identified as a high-affinity receptor for α-latrotoxin, a component of the black widow spider, latrophilins are now associated with various distinct functions, such as synaptic exocytosis, tissue polarity and fertility (Tobaben et al., 2002; Langenhan et al., 2009; Promel et al., 2012). Despite these exploratory efforts the precise subcellular localisation as well as the endogenous ligand of CIRL still remains elusive. In this work genetic experiments, imaging approaches and behavioural studies have been used to unravel the localisation and physiological function of the latrophilin homolog dCirl in Drosophila melanogaster. Containing only one latrophilin homolog together with its genetic accessibility and well-established transgenic approaches, Drosophila seemed an ideally suited model organism. The present study showed that dCirl is widely expressed in the larval central nervous system including moto- and sensory neurons. Further, this work revealed that removal of the latrophilin homolog does not greatly affect synaptic transmission but it seems that aspects of the postsynaptic structural layout are controlled by dCIRL in the fruit fly. Additionally, dCirl expression at the transcriptional level was confirmed in larval and adult chordotonal organs, specialised mechanosensors implicated in proprioception (Eberl, 1999). Expression of dCIRL at the protein level could not yet been confirmed in moto- and sensory neurons likely due to low endogenous expression. However, behavioural studies using dCirl knockout mutant larvae indicated a putative mechanosensory function of dCIRL regarding touch sensitivity and locomotion behaviour.
The second part of this thesis presents a strategy to examine interactions between several presynaptic proteins in living cells. The attempt described in this work is based on the discovery that GFP when split into two non-fluorescent fragments can form a fluorescent complex. The association of the fragments can be facilitated by fusing them to two proteins that interact with each other. Therefore, the split GFP method enables direct visualization of synaptic protein interactions in living cells. In initial experiments I could show that full length reporter protein fusions with n-Synaptobrevin (n-Syb), Synaptotagmin (Syt) and Syntaxin (Syx) allow expression in Drosophila and confirmed that fusion to either end of each synaptic protein did not impair expression or influence the viability of transgenic flies. Further, transgenes containing protein fusions of Syx, Syt, and n-Syb with split GFP fragments were established in previous studies (Gehring, 2010). The present work characterises the interaction of these protein fusions during different stages of synaptic vesicle turnover at active zones such as synaptic vesicle docking at the presynaptic membrane and vesicle fusion. These results suggest that the spGFP assay seems only partly suitable for resolving fast and transient protein-protein interactions at larval Drosophila active zones in vivo.
In the last years it became evident that many cytokines do not only bind to their specific cell surface receptors but also interact with components of the extracellular matrix. Mainly in Drosophila, several enzymes were identified, that are involved in glycosaminoglycan synthesis. Mutations in these enzymes mostly result in disturbances of several signaling pathways like hedgehog, wingless, FGF or dpp. In most cases it was, due to these pleiotropic effects, not possible to examine the relevance of matrix interactions for single pathways. The aim of this work was to examine the relevance of matrix interactions for the TGF-ß superfamily member DPP. Based on the fact that DPP is highly homologous to human BMP-2, the basic N-terminus of mature DPP was mutated, which has been shown to contain a heparin-binding site in BMP-2. Thus, a wildtype variant (D-MYC), a deletion variant (D-DEL), which lacked the whole basic part of the N-terminus and a duplication variant (D-DUP), which contained a second copy of the basic core moitiv, were generated. In order to characterise the variants biochemically, they were expressed in E.coli and refolded in a bioactive form. In chicken limbbud assay, the deletion variant was much more active than the wildtype variant, comparable to data of BMP-2. By means of biacore mesurements with the immobilised ectodomain of the high affinity type I receptor thick veins, it could be demonstrated, that the variants differ only in matrix binding and not in their receptor affinity. Different matrix binding was shown by Heparin FPLC. The biological relevance of the matrix interaction of DPP was examined in transgenic flies. To allow expression of the different variants under the control of various Gal4 driver lines, they were cloned behind an UAS-promoter site. In early tracheal development, a strong dependence of DPP signaling on matrix binding was observed. While ectopic expression of the deletion variant caused only minor defects, the branching pattern was strongly disturbed by overexpression of wildtype and duplication variant. Ubiquitous expression of the variants in the wing imaginal disc caused overproliferation of the disc and expansion of the omb target gene expression. The extent of phenotypes correlated with the matrix binding ability of the variants. Corresponding disturbances of the wing vein pattern was observed in adult flies. By the crossing of different dpp allels, transheterozygous animals were created, that lack dpp only in imaginal discs. Expression of the variants under the control of a suitable dpp-Gal4 driver line revealed insights into the biological relevance of matrix binding on DPP gradient formation and specific target gene activation in wing imaginal discs. It was shown, that all variants were able to generate a functional DPP gradient with correct expression of the target genes omb and spalt. Again a correlation between extent of target gene domains and matrix binding ability of the corresponding variants was found. Thus by mutating the N-terminus of DPP, it could be shown that this is responsible for DPP`s matrix interaction. Also the relevance of matrix binding of DPP in different tissues was examined. It turned out, that the reorganisation of tracheal branching by DPP strongly depends on matrix interactions wheras the establishing of a gradient in wing imaginal discs depends only gradually on matrix interactions. Based on these data a model for the action of DPP/TGFßs as morphogens was established. While a deletion of matrix binding leads to a decrease in specific bioactivity of the cytokine, the latter is increased by additional matrix binding sites.
Functional and genetic dissection of mechanosensory organs of \(Drosophila\) \(melanogaster\)
(2016)
In Drosophila larvae and adults, chordotonal organs (chos) are highly versatile mechanosensors
that are essential for proprioception, touch sensation and hearing. Chos share molecular,
anatomical and functional properties with the inner ear hair cells of mammals. These multiple
similarities make chos powerful models for the molecular study of mechanosensation.
In the present study, I have developed a preparation to directly record from the sensory neurons
of larval chos (from the lateral chos or lch5) and managed to correlate defined mechanical inputs
with the corresponding electrical outputs. The findings of this setup are described in several case
studies.
(1) The basal functional lch5 parameters, including the time course of response during continuous
mechanical stimulation and the recovery time between successive bouts of stimulation, was
characterized.
(2) The calcium-independent receptor of α-latrotoxin (dCIRL/Latrophilin), an Adhesion class G
protein-coupled receptor (aGPCR), is identified as a modulator of the mechanical signals
perceived by lch5 neurons. The results indicate that dCIRL/Latrophilin is required for the
perception of external and internal mechanical stimuli and shapes the sensitivity of neuronal
mechanosensation.
(3) By combining this setup with optogenetics, I have confirmed that dCIRL modulates lch5
neuronal activity at the level of their receptor current (sensory encoding) rather than their ability
to generate action potentials.
(4) dCIRL´s structural properties (e.g. ectodomain length) are essential for the mechanosensitive
properties of chordotonal neurons.
(5) The versatility of chos also provides an opportunity to study multimodalities at multiple levels.
In this context, I performed an experiment to directly record neuronal activities at different
temperatures. The results show that both spontaneous and mechanically evoked activity increase
in proportion to temperature, suggesting that dCIRL is not required for thermosensation in chos.
These findings, from the development of an assay of sound/vibration sensation, to neuronal
signal processing, to molecular aspects of mechanosensory transduction, have provided the first
insights into the mechanosensitivity of dCIRL.
In addition to the functional screening of peripheral sensory neurons, another
electrophysiological approach was applied in the central nervous system: dCIRL may impact the
excitability of the motor neurons in the ventral nerve cord (VNC). In the second part of my work,
whole-cell patch clamp recordings of motor neuron somata demonstrated that action potential
firing in the dCirl\(^K\)\(^O\) did not differ from control samples, indicating comparable membrane
excitability.
Neuropeptides and peptide hormones carrying neural or physiological information are intercellular signalling substances. They control most if not all biological processes in vertebrates and invertebrates by acting on specific receptors on the target cell. In mammals, many different neuropeptides and peptide hormones are involved in the regulation of feeding and sleep. In \textit{Drosophila}, allatostatin A (AstA) and myoinhibitory peptides (MIPs) are brain-gut peptides. The AstA receptors are homologues of the mammalian galanin receptors and the amino acid sequences of MIPs are similar to a part of galanin, which has an orexigenic effect and is implicated in the control of sleep behaviour in mammals. I am interested in dissecting pleiotropic functions of AstA and MIPs in the regulation of food intake and sleep in \textit{Drosophila}. \par
In the first part of the dissertation the roles of brain-gut peptide allatostatin A are analysed. Due to the genetic and molecular tools available, the fruit fly \textit{Drosophila melanogaster} is chosen to investigate functions of AstA. The aims in this part are to identify pleiotropic functions of AstA and assign specific effects to the activity of certain subsets of AstA expressing cells in \textit{Drosophila} adults. A new and restricted \textit{AstA\textsuperscript{34}-Gal4} line was generated. The confocal imaging result showed that AstA neurons are located in the posterior lateral protocerebrum (PLP), the gnathal ganglia (GNG), the medullae, and thoracic-abdominal ganglion (TAG). AstA producing DLAa neurons in the TAG innervate hindgut and the poterior part of midgut. In addition, AstA are detected in the enteroendocrine cells (EECs).\par
Thermogenetic activation and neurogenetic silencing tools with the aid of the \textit{UAS/Gal4} system were employed to manipulate the activity of all or individual subsets of AstA cells and investigate the effects on food intake, locomotor activity and sleep. Our experimental results showed that thermogenetic activation of two pairs of PLP neurons and/or AstA expressing EECs reduced food intake, which can be traced to AstA signalling by using \textit{AstA} mutants. In the locomotor activity, thermogenetic activation of two pairs of PLP neurons and/or AstA expressing EECs resulted in strongly inhibited locomotor activity and promoted sleep without sexual difference, which was most apparent during the morning and evening activity peaks. The experimental and control flies were not impaired in climbing ability. In contrast, conditional silencing of the PLP neurons and/or AstA expressing EECs reduced sleep specifically in the siesta. The arousal experiment was employed to test for the sleep intensity. Thermogenetically activated flies walked significantly slower and a shorter distance than controls for all arousal stimulus intensities. Furthermore, PDF receptor was detected in the PLP neurons and the PLP neurons reacted with an intracellular increase of cAMP upon PDF, only when PDF receptor was present. Constitutive activation of AstA cells by tethered PDF increased sleep and thermogenetic activation of the PDF producing sLNvs promoted sleep specifically in the morning and evening. \par
The study shows that the PLP neurons and/or EECs vis AstA signalling subserve an anorexigenic and sleep-regulating function in \textit{Drosophila}. The PLP neurons arborise in the posterior superior protocerebrum, where the sleep relevant dopaminergic neurons are located, and EECs extend themselves to reach the gut lumen. Thus, the PLP neurons are well positioned to regulate sleep and EECs potentially modulate feeding and possibly locomotor activity and sleep during sending the nutritional information from the gut to the brain. The results of imaging, activation of the PDF signalling pathway by tethered PDF and thermoactivation of PDF expressing sLNvs suggest that the PLP neurons are modulated by PDF from sLNv clock neurons and AstA in PLP neurons is the downstream target of the central clock to modulate locomotor activity and sleep. AstA receptors are homologues of galanin receptors and both of them are involved in the regulation of feeding and sleep, which appears to be conserved in evolutionary aspect.\par
In the second part of the dissertation, I analysed the role of myoinhibitory peptides. MIPs are brain-gut peptides in insects and polychaeta. Also in \textit{Drosophila}, MIPs are expressed in the CNS and EECs in the gut. Previous studies have demonstrated the functions of MIPs in the regulation of food intake, gut motility and ecdysis in moths and crickets. Yet, the functions of MIPs in the fruit fly are little known. To dissect effects of MIPs regarding feeding, locomotor activity and sleep in \textit{Drosophila melanogater}, I manipulated the activity of MIP\textsuperscript{WÜ} cells by using newly generated \textit{Mip\textsuperscript{WÜ}-Gal4} lines. Thermogenetical activation or genetical silencing of MIP\textsuperscript{WÜ} celles did not affect feeding behaviour and resulted in changes in the sleep status. \par
My results are in contradiction to a recent research of Min Soohong and colleagues who demonstrated a role of MIPs in the regulation of food intake and body weight in \textit{Drosophila}. They showed that constitutive silencing of MIP\textsuperscript{KR} cells increased food intake and body weight, whereas thermogenetic activation of MIP\textsuperscript{KR} cells decreased food intake and body weight by using \textit{Mip\textsuperscript{KR}-Gal4} driver. Then I repeated the experiments with the \textit{Mip\textsuperscript{KR}-Gal4} driver, but could not reproduce the results. Interestingly, I just observed the opposite phenotype. When MIP\textsuperscript{KR} cells were silenced by expressing UAS-tetanus toxin (\textit{UAS-TNT}), the \textit{Mip\textsuperscript{KR}$>$TNT} flies showed reduced food intake. The thermogenetic activation of MIP\textsuperscript{KR} cells did not affect food intake. Furthermore, I observed that the thermogenetic activation of MIP\textsuperscript{KR} cells strongly reduced the sleep duration.\par
In the third part of the dissertation, I adapted and improved a method for metabolic labelling for \textit{Drosophila} peptides to quantify the relative amount of peptides and the released peptides by mass spectrometry under different physiological and behavioural conditions. qRT-PCR is a practical technique to measure the transcription and the corresponding mRNA level of a given peptide. However, this is not the only way to measure the translation and production of peptides. Although the amount of peptides can be quantified by mass spectrometry, it is not possible to distinguish between peptides stored in vesicles and released peptides in CNS extracts. I construct an approach to assess the released peptides, which can be calculated by comparing the relative amount of peptides between two timepoints in combination with the mRNA levels which can be used as semiquantitative proxy reflecting the production of peptides during this period. \par
After optimizing the protocol for metabolic labelling, I carried out a quantitative analysis of peptides before and after eclosion as a test. I was able to show that the EH- and SIFa-related peptides were strongly reduced after eclosion. This is in line with the known function and release of EH during eclosion. Since this test was positive, I next used the metabolic labelling in \textit{Drosophila} adult, which were either fed \textit{ad libitum} or starved for 24 hrs, and analysed the effects on the amount of AstA and MIPs. In the mRNA level, my results showed that in the brain \textit{AstA} mRNA level in the 24 hrs starved flies was increased compared to in the \textit{ad libitum} fed flies, whereas in the gut the \textit{AstA} mRNA level was decreased. Starvation induced the reduction of \textit{Mip} mRNA level in the brain and gut. Unfortunately, due to technical problems I was unable to analyse the metabolic labelled peptides during the course of this thesis.\par
To unravel the role of single genes underlying certain biological processes, scientists often use amorphic or hypomorphic alleles. In the past, such mutants were often created by chance. Enormous approaches with many animals and massive screening effort for striking phenotypes were necessary to find a needle in the haystack. Therefore at the beginning chemical mutagens or radiation were used to induce mutations in the genome. Later P-element insertions and inaccurate jump-outs enabled the advantage of potential larger deletions or inversions. The mutations were characterized and subsequently kept in smaller populations in the laboratories. Thus additional mutations with unknown background effects could accumulate.
The precision of the knockout through homologous recombination and the additional advantage of being able to generate many useful rescue constructs that can be easily reintegrated into the target locus made us trying an ends-out targeting procedure of the two core clock genes period and timeless in Drosophila melanogaster. Instead of the endogenous region, a small fragment of approximately 100 base pairs remains including an attP-site that can be used as integration site for in vitro created rescue constructs. After a successful ends-out targeting procedure, the locus will be restored with e.g. flies expressing the endogenous gene under the native promoter at the original locus coupled to a fluorescence tag or expressing luciferase.
We also linked this project to other research interests of our work group, like the epigenetic related ADAR-editing project of the Timeless protein, a promising newly discovered feature of time point specific timeless mRNA modification after transcription with yet unexplored consequences. The editing position within the Timeless protein is likewise interesting and not only noticed for the first time. This will render new insights into the otherwise not-satisfying investigation and quest for functional important sequences of the Timeless protein, which anyway shows less homology to other yet characterized proteins.
Last but not least, we bothered with the question of the role of Shaggy on the circadian clock. The impact of an overexpression or downregulation of Shaggy on the pace of the clock is obvious and often described. The influence of Shaggy on Period and Timeless was also shown, but for the latter it is still controversially discussed. Some are talking of a Cryptochrome stabilization effect and rhythmic animals in constant light due to Shaggy overexpression, others show a decrease of Cryptochrome levels under these conditions. Also the constant light rhythmicity of the flies, as it was published, could not be repeated so far. We were able to expose the conditions behind the Cryptochrome stabilization and discuss possibilities for the phenomenon of rhythmicity under constant light due to Shaggy overexpression.
Vertebrate and invertebrate visual systems exhibit similarities in early stages of visual processing. For instance, in the human brain, the modalities of color, form and motion are separately processed in parallel neuronal pathways. This basic property is also found in the fly Drosophila melanogaster which has a similar division in color- sensitive and (color blind) motion-sensitive pathways that are determined by two distinct subsets of photoreceptors (the R1-6 and the R7/8 system, respectively). Flies have a highly organized visual system that is characterized by its repetitive, retinotopic organization of four neuropils: the lamina, the medulla, the lobula and the lobula plate. Each of these consists of columns which contain the same set of neurons. In the lamina, axon bundles of six photoreceptors R1-6 that are directed towards the same point in space form columnar structures called cartridges. These are the visual sampling units and are associated with four types of first-order interneuron that receive common input from R1-6: L1, L2, L3 and the amacrine cells (amc, together with their postsynaptic partner T1). They constitute parallel pathways that have been studied in detail at the anatomical level. Little is known, however, about their functional role in processing behaviorally relevant information, e.g. for gaze stabilization, visual course control or the fixation of objects. The availability of a variety of neurogenetic tools for structure-function analysis in Drosophila allowed first steps into the genetic dissection of the neuronal circuitry mediating motion and position detection. In this respect, the choice of the effector turned out to be crucial. Surprisingly, it was found that the clostridial tetanus neurotoxin failed to block mature Drosophila photoreceptor synapses, but caused irreversible damage when expressed during their development. Therefore, the dominant-negative shibire allele shits1 which turned out to be better suited was used for blocking lamina interneurons and thereby analyzing the necessity of the respective pathways. To determine whether the latter were also sufficient for the same behavioral task, the inverse strategy was developed, based on the fact that lamina interneurons express histamine receptors encoded by the ort gene. The specific rescue of ort function in defined channels in an otherwise mutant background allowed studying their sufficiency in a given task. Combining these neurogenetic methods with the optomotor response and object induced orientation behavior as behavioral measures, the aim of the present thesis was to answer the following questions: (a) Which pathways feed into elementary motion detectors and which ones are necessary and/or sufficient for the detection of directional motion? (b) Do pathways exist which specifically mediate responses to unidirectional motion? (c) Which pathways are necessary and/or sufficient for object induced orientation behavior? Some basic properties of the visual circuitry were revealed: The two central cartridge pathways, represented by the large monopolar cells L1 and L2, are key players in motion detection. Under a broad range of stimulatory conditions, the two subsystems are redundant and are able to process motion independently of each other. To detect an impairment when only one of the pathways is intact, one has to drive the system to its operational limits. At low signal to noise ratios, i.e. at low pattern contrast or low background illumination, the L2 pathway has a higher sensitivity. At intermediate pattern contrast, both pathways are specialized in mediating responses to unidirectional motion of opposite stimulus direction. In contrast, neither the L3, nor the amc/T1 pathway is necessary or sufficient for motion detection. While the former may provide position information for orientation, the latter has a modulatory role at intermediate pattern contrast. Orientation behavior turned out to be even more robust than motion vision and may utilize a less sophisticated mechanism, as it does not require a nonlinear comparison of signals from neighboring visual sampling units. The position of objects is processed in several redundant pathways, involving both receptor subsystems. The fixation of objects does not generally require motion vision. However, motion detection improves the fixation of landmarks, especially when these are narrow or have a reduced contrast.