@phdthesis{Ruf2016,
  author    = {Ruf, Franziska},
  title     = {The circadian regulation of eclosion in \(Drosophila\) \(melanogaster\)},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-146265},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2016},
  abstract  = {Eclosion is the emergence of an adult insect from the pupal case at the end of development. In the fruit fly Drosophila melanogaster, eclosion is a circadian clock-gated event and is regulated by various peptides. When studied on the population level, eclosion reveals a clear rhythmicity with a peak at the beginning of the light-phase that persists also under constant conditions. It is a long standing hypothesis that eclosion gating to the morning hours with more humid conditions is an adaption to reduce water loss and increase the survival. Eclosion behavior, including the motor pattern required for the fly to hatch out of the puparium, is orchestrated by a well-characterized cascade of peptides. The main components are ecdysis-triggering hormone (ETH), eclosion hormone (EH) and crustacean cardioactive peptide (CCAP). The molt is initiated by a peak level and pupal ecdysis by a subsequent decline of the ecdysteroid ecdysone. Ecdysteroids are produced by the prothoracic gland (PG), an endocrine tissue that contains a peripheral clock and degenerates shortly after eclosion. Production and release of ecdysteroids are regulated by the prothoracicotropic hormone (PTTH). Although many aspects of the circadian clock and the peptidergic control of the eclosion behavior are known, it still remains unclear how both systems are interconnected. The aim of this dissertation research was to dissect this connection and evaluate the importance of different Zeitgebers on eclosion rhythmicity under natural conditions. Potential interactions between the central clock and the peptides regulating ecdysis motor behavior were evaluated by analyzing the influence of CCAP on eclosion rhythmicity. Ablation and silencing of CCAP neurons, as well as CCAP null-mutation did not affect eclosion rhythmicity under either light or temperature entrainment nor under natural conditions. To dissect the connection between the central and the peripheral clock, PTTH neurons were ablated. Monitoring eclosion under light and temperature entrainment revealed that eclosion became arrhythmic under constant conditions. However, qPCR expression analysis revealed no evidence for cycling of Ptth mRNA in pharate flies. To test for a connection with pigment-dispersing factor (PDF)-expressing neurons, the PDF receptor (PDFR) and short neuropeptide F receptor (sNPFR) were knocked down in the PTTH neurons. Knockdown of sNPFR, but not PDFR, resulted in arrhythmic eclosion under constant darkness conditions. PCR analysis of the PTTH receptor, Torso, revealed its expression in the PG and the gonads, but not in the brain or eyes, of pharate flies. Knockdown of torso in the PG lead to arrhythmicity under constant conditions, which provides strong evidence for the specific effect of PTTH on the PG. These results suggest connections from the PDF positive lateral neurons to the PTTH neurons via sNPF signaling, and to the PG via PTTH and Torso. This interaction presumably couples the period of the peripheral clock in the PG to that of the central clock in the brain. To identify a starting signal for eclosion and possible further candidates in the regulation of eclosion behavior, chemically defined peptidergic and aminergic neurons were optogenetically activated in pharate pupae via ChR2-XXL. This screen approach revealed two candidates for the regulation of eclosion behavior: Dromyosuppressin (DMS) and myo-inhibitory peptides (MIP). However, ablation of DMS neurons did not affect eclosion rhythmicity or success and the exact function of MIP must be evaluated in future studies. To assess the importance of the clock and of possible Zeitgebers in nature, eclosion of the wildtype Canton S and the clock mutant per01 and the PDF signaling mutants pdf01 and han5304 was monitored under natural conditions. For this purpose, the W{\"u}rzburg eclosion monitor (WEclMon) was developed, which is a new open monitoring system that allows direct exposure of pupae to the environment. A general decline of rhythmicity under natural conditions compared to laboratory conditions was observed in all tested strains. While the wildtype and the pdf01 and han5304 mutants stayed weakly rhythmic, the per01 mutant flies eclosed mostly arrhythmic. PDF and its receptor (PDFR encoded by han) are required for the synchronization of the clock network and functional loss can obviously be compensated by a persisting synchronization to external Zeitgebers. The loss of the central clock protein PER, however, lead to a non-functional clock and revealed the absolute importance of the clock for eclosion rhythmicity. To quantitatively analyze the effect of the clock and abiotic factors on eclosion rhythmicity, a statistical model was developed in cooperation with Oliver Mitesser and Thomas Hovestadt. The modelling results confirmed the clock as the most important factor for eclosion rhythmicity. Moreover, temperature was found to have the strongest effect on the actual shape of the daily emergence pattern, while light has only minor effects. Relative humidity could be excluded as Zeitgeber for eclosion and therefore was not further analyzed. Taken together, the present dissertation identified the so far unknown connection between the central and peripheral clock regulating eclosion. Furthermore, a new method for the analysis of eclosion rhythms under natural conditions was established and the necessity of a functional clock for rhythmic eclosion even in the presence of multiple Zeitgebers was shown.},
  subject      = {Taufliege},
  language  = {en}
}
@article{RufFraunholzOechsneretal.2017,
  author    = {Ruf, Franziska and Fraunholz, Martin and {\"O}chsner, Konrad and Kaderschabeck, Johann and Wegener, Christian},
  title     = {WEclMon - A simple and robust camera-based system to monitor Drosophila eclosion under optogenetic manipulation and natural conditions},
  series = {PLoS ONE},
  volume    = {12},
  journal   = {PLoS ONE},
  number    = {6},
  doi       = {10.1371/journal.pone.0180238},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-170755},
  pages     = {e0180238},
  year      = {2017},
  abstract  = {Eclosion in flies and other insects is a circadian-gated behaviour under control of a central and a peripheral clock. It is not influenced by the motivational state of an animal, and thus presents an ideal paradigm to study the relation and signalling pathways between central and peripheral clocks, and downstream peptidergic regulatory systems. Little is known, however, about eclosion rhythmicity under natural conditions, and research into this direction is hampered by the physically closed design of current eclosion monitoring systems. We describe a novel open eclosion monitoring system (WEclMon) that allows the puparia to come into direct contact with light, temperature and humidity. We demonstrate that the system can be used both in the laboratory and outdoors, and shows a performance similar to commercial closed funnel-type monitors. Data analysis is semi-automated based on a macro toolset for the open imaging software Fiji. Due to its open design, the WEclMon is also well suited for optogenetic experiments. A small screen to identify putative neuroendocrine signals mediating time from the central clock to initiate eclosion showed that optogenetic activation of ETH-, EH and myosuppressin neurons can induce precocious eclosion. Genetic ablation of myosuppressin-expressing neurons did, however, not affect eclosion rhythmicity.},
  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}
}