@article{LyutovaSelchoPfeufferetal.2019, author = {Lyutova, Radostina and Selcho, Mareike and Pfeuffer, Maximilian and Segebarth, Dennis and Habenstein, Jens and Rohwedder, Astrid and Frantzmann, Felix and Wegener, Christian and Thum, Andreas S. and Pauls, Dennis}, title = {Reward signaling in a recurrent circuit of dopaminergic neurons and peptidergic Kenyon cells}, series = {Nature Communications}, volume = {10}, journal = {Nature Communications}, doi = {10.1038/s41467-019-11092-1}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-202161}, pages = {3097}, year = {2019}, abstract = {Dopaminergic neurons in the brain of the Drosophila larva play a key role in mediating reward information to the mushroom bodies during appetitive olfactory learning and memory. Using optogenetic activation of Kenyon cells we provide evidence that recurrent signaling exists between Kenyon cells and dopaminergic neurons of the primary protocerebral anterior (pPAM) cluster. Optogenetic activation of Kenyon cells paired with odor stimulation is sufficient to induce appetitive memory. Simultaneous impairment of the dopaminergic pPAM neurons abolishes appetitive memory expression. Thus, we argue that dopaminergic pPAM neurons mediate reward information to the Kenyon cells, and in turn receive feedback from Kenyon cells. We further show that this feedback signaling is dependent on short neuropeptide F, but not on acetylcholine known to be important for odor-shock memories in adult flies. Our data suggest that recurrent signaling routes within the larval mushroom body circuitry may represent a mechanism subserving memory stabilization.}, language = {en} } @article{SelchoMillanPalaciosMunozetal.2017, author = {Selcho, Mareike and Mill{\´a}n, Carola and Palacios-Mu{\~n}oz, Angelina and Ruf, Franziska and Ubillo, Lilian and Chen, Jiangtian and Bergmann, Gregor and Ito, Chihiro and Silva, Valeria and Wegener, Christian and Ewer, John}, title = {Central and peripheral clocks are coupled by a neuropeptide pathway in Drosophila}, series = {Nature Communications}, volume = {8}, journal = {Nature Communications}, number = {15563}, doi = {10.1038/ncomms15563}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-170831}, year = {2017}, abstract = {Animal circadian clocks consist of central and peripheral pacemakers, which are coordinated to produce daily rhythms in physiology and behaviour. Despite its importance for optimal performance and health, the mechanism of clock coordination is poorly understood. Here we dissect the pathway through which the circadian clock of Drosophila imposes daily rhythmicity to the pattern of adult emergence. Rhythmicity depends on the coupling between the brain clock and a peripheral clock in the prothoracic gland (PG), which produces the steroid hormone, ecdysone. Time information from the central clock is transmitted via the neuropeptide, sNPF, to non-clock neurons that produce the neuropeptide, PTTH. These secretory neurons then forward time information to the PG clock. We also show that the central clock exerts a dominant role on the peripheral clock. This use of two coupled clocks could serve as a paradigm to understand how daily steroid hormone rhythms are generated in animals.}, language = {en} } @article{WidmannArtingerBiesingeretal.2016, author = {Widmann, Annekathrin and Artinger, Marc and Biesinger, Lukas and Boepple, Kathrin and Peters, Christina and Schlechter, Jana and Selcho, Mareike and Thum, Andreas S.}, title = {Genetic Dissection of Aversive Associative Olfactory Learning and Memory in Drosophila Larvae}, series = {PLoS Genetics}, volume = {12}, journal = {PLoS Genetics}, number = {10}, doi = {10.1371/journal.pgen.1006378}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-166672}, pages = {e1006378}, year = {2016}, abstract = {Memory formation is a highly complex and dynamic process. It consists of different phases, which depend on various neuronal and molecular mechanisms. In adult Drosophila it was shown that memory formation after aversive Pavlovian conditioning includes—besides other forms—a labile short-term component that consolidates within hours to a longer-lasting memory. Accordingly, memory formation requires the timely controlled action of different neuronal circuits, neurotransmitters, neuromodulators and molecules that were initially identified by classical forward genetic approaches. Compared to adult Drosophila, memory formation was only sporadically analyzed at its larval stage. Here we deconstruct the larval mnemonic organization after aversive olfactory conditioning. We show that after odor-high salt conditioning larvae form two parallel memory phases; a short lasting component that depends on cyclic adenosine 3'5'-monophosphate (cAMP) signaling and synapsin gene function. In addition, we show for the first time for Drosophila larvae an anesthesia resistant component, which relies on radish and bruchpilot gene function, protein kinase C activity, requires presynaptic output of mushroom body Kenyon cells and dopamine function. Given the numerical simplicity of the larval nervous system this work offers a unique prospect for studying memory formation of defined specifications, at full-brain scope with single-cell, and single-synapse resolution.}, language = {en} } @article{PaulsBlechschmidtFrantzmannetal.2018, author = {Pauls, Dennis and Blechschmidt, Christine and Frantzmann, Felix and el Jundi, Basil and Selcho, Mareike}, title = {A comprehensive anatomical map of the peripheral octopaminergic/tyraminergic system of Drosophila melanogaster}, series = {Scientific Reports}, volume = {8}, journal = {Scientific Reports}, number = {15314}, doi = {10.1038/s41598-018-33686-3}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-177412}, year = {2018}, abstract = {The modulation of an animal's behavior through external sensory stimuli, previous experience and its internal state is crucial to survive in a constantly changing environment. In most insects, octopamine (OA) and its precursor tyramine (TA) modulate a variety of physiological processes and behaviors by shifting the organism from a relaxed or dormant condition to a responsive, excited and alerted state. Even though OA/TA neurons of the central brain are described on single cell level in Drosophila melanogaster, the periphery was largely omitted from anatomical studies. Given that OA/TA is involved in behaviors like feeding, flying and locomotion, which highly depend on a variety of peripheral organs, it is necessary to study the peripheral connections of these neurons to get a complete picture of the OA/TA circuitry. We here describe the anatomy of this aminergic system in relation to peripheral tissues of the entire fly. OA/TA neurons arborize onto skeletal muscles all over the body and innervate reproductive organs, the heart, the corpora allata, and sensory organs in the antennae, legs, wings and halteres underlining their relevance in modulating complex behaviors.}, language = {en} } @article{HuserRohwedderApostolopoulouetal.2012, author = {Huser, Annina and Rohwedder, Astrid and Apostolopoulou, Anthi A. and Widmann, Annekathrin and Pfitzenmaier, Johanna E. and Maiolo, Elena M. and Selcho, Mareike and Pauls, Dennis and von Essen, Alina and Gupta, Tript and Sprecher, Simon G. and Birman, Serge and Riemensperger, Thomas and Stocker, Reinhard F. and Thum, Andreas S.}, title = {The Serotonergic Central Nervous System of the Drosophila Larva: Anatomy and Behavioral Function}, series = {PLoS One}, volume = {7}, journal = {PLoS One}, number = {10}, doi = {10.1371/journal.pone.0047518}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-130437}, pages = {e47518}, year = {2012}, abstract = {The Drosophila larva has turned into a particularly simple model system for studying the neuronal basis of innate behaviors and higher brain functions. Neuronal networks involved in olfaction, gustation, vision and learning and memory have been described during the last decade, often up to the single-cell level. Thus, most of these sensory networks are substantially defined, from the sensory level up to third-order neurons. This is especially true for the olfactory system of the larva. Given the wealth of genetic tools in Drosophila it is now possible to address the question how modulatory systems interfere with sensory systems and affect learning and memory. Here we focus on the serotonergic system that was shown to be involved in mammalian and insect sensory perception as well as learning and memory. Larval studies suggested that the serotonergic system is involved in the modulation of olfaction, feeding, vision and heart rate regulation. In a dual anatomical and behavioral approach we describe the basic anatomy of the larval serotonergic system, down to the single-cell level. In parallel, by expressing apoptosis-inducing genes during embryonic and larval development, we ablate most of the serotonergic neurons within the larval central nervous system. When testing these animals for naive odor, sugar, salt and light perception, no profound phenotype was detectable; even appetitive and aversive learning was normal. Our results provide the first comprehensive description of the neuronal network of the larval serotonergic system. Moreover, they suggest that serotonin per se is not necessary for any of the behaviors tested. However, our data do not exclude that this system may modulate or fine-tune a wide set of behaviors, similar to its reported function in other insect species or in mammals. Based on our observations and the availability of a wide variety of genetic tools, this issue can now be addressed.}, language = {en} } @article{WegenerKarsaiPollaketal.2013, author = {Wegener, Christian and Karsai, Gergely and Poll{\´a}k, Edit and Wacker, Matthias and V{\"o}mel, Matthias and Selcho, Mareike and Berta, Gergely and Nachman, Ronald J. and Isaac, R. Elwyn and Moln{\´a}r, L{\´a}szl{\´o}}, title = {Diverse in- and output polarities and high complexity of local synaptic and non-synaptic signaling within a chemically defined class of peptidergic Drosophila neurons}, series = {Frontiers in Neural Circuits}, journal = {Frontiers in Neural Circuits}, doi = {10.3389/fncir.2013.00127}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-96914}, year = {2013}, abstract = {Peptidergic neurons are not easily integrated into current connectomics concepts, since their peptide messages can be distributed via non-synaptic paracrine signaling or volume transmission. Moreover, the polarity of peptidergic interneurons in terms of in- and out-put sites can be hard to predict and is very little explored. We describe in detail the morphology and the subcellular distribution of fluorescent vesicle/dendrite markers in CCAP neurons (NCCAP), a well defined set of peptidergic neurons in the Drosophila larva. NCCAP can be divided into five morphologically distinct subsets. In contrast to other subsets, serial homologous interneurons in the ventral ganglion show a mixed localization of in- and output markers along ventral neurites that defy a classification as dendritic or axonal compartments. Ultrastructurally, these neurites contain both pre- and postsynaptic sites preferably at varicosities. A significant portion of the synaptic events are due to reciprocal synapses. Peptides are mostly non-synaptically or parasynaptically released, and dense-core vesicles and synaptic vesicle pools are typically well separated. The responsiveness of the NCCAP to ecdysis-triggering hormone may be at least partly dependent on a tonic synaptic inhibition, and is independent of ecdysteroids. Our results reveal a remarkable variety and complexity of local synaptic circuitry within a chemically defined set of peptidergic neurons. Synaptic transmitter signaling as well as peptidergic paracrine signaling and volume transmission from varicosities can be main signaling modes of peptidergic interneurons depending on the subcellular region. The possibility of region-specific variable signaling modes should be taken into account in connectomic studies that aim to dissect the circuitry underlying insect behavior and physiology, in which peptidergic neurons act as important regulators.}, language = {en} }