Analysis of the sleep homeostat of the nematode Caenorhabditis elegans
von Jan-Philipp Spies
Datum der mündl. Prüfung:2015-02-20
Erschienen:2015-12-21
Betreuer:Dr. Henrik Bringmann
Gutachter:Prof. Dr. Andreas Stumpner
Gutachter:Prof. Dr. Jens Frahm
Zum Verlinken/Zitieren:
http://dx.doi.org/10.53846/goediss-5437
Dateien
Name:JanSpiesPhDThesis.pdf
Size:6.54Mb
Format:PDF
Lizenzbestimmungen:
Zusammenfassung
Englisch
Sleep is essential for animal life and conserved in all animals that have a nervous system. The nematode Caenorhabditis elegans exhibits sleep that is regulated homeostatically during larval development. However its regulation is poorly understood. The aim of this thesis was to gain a better understanding of the neuronal and molecular mechanisms underlying sleep homeostasis. To investigate the sleep homeostat of C. elegans, I developed an automated sleep deprivation setup based on mechanical stimulation/optogenetics allowing simultaneous behavioral analysis and functional imaging of neurons. I have identified RIS as the neuron reflecting the sleep homeostat and several molecules underlying sleep using genetic approaches and in vivo neuronal imaging. I found that sleep deprivation significantly shortens the animals sleeping duration and yields persistent increased locomotion past the deprivation period. To look for homeostatic changes in sleep intensity, I investigated the effect of sleep deprivation on the mechanosensory neuron ALM using calcium imaging. Prolonged sleep deprivation induces a significant decrease in stimulus-evoked ALM calcium transients compared to a wake control. In addition to this homeostatic regulation of ALM responsiveness I found that quiescence is already induced while the deprivation stimulus still yields strong activation of ALM. I show that this quiescence is induced by the interneuron RIS. Hence, RIS reflects the homeostat actively driving quiescence as a response to sleep deprivation. Moreover I demonstrate that RIS has a more general function on the homeostatic regulation of locomotion. Both spontaneous locomotion and evoked locomotion are dampened by RIS activation. The fact that RIS controls both the balance between mobility and immobility and the sleep homeostat suggests a related evolutionary origin. By reverse genetic approaches I found that the transcription factor lim-6 which is known to regulate RIS differentiation, is required for wild-type sleep. However, RIS activity at sleep onset and in response to sleep deprivation is similar to wild-type. I demonstrate that the neurotransmitters serotonin, dopamine, GABA, glutamate, and octopamine are not individually essential for the sleep homeostat. Furthermore I found that GABA, glutamate, and octopamine knockout mutants do not show altered RIS activity. egl-3 knockout mutants which have defects in the synthesis of neuropeptides, show RIS overactivation in the mid and late sleep phase while barely immobilizing during sleep. This implies that neuropeptide signaling is required downstream of RIS for the induction of quiescence. Finally, ion channel modulation is widely associated with sleep and sleep homeostasis. I demonstrate that the inositol trisphosphate receptor itr-1(sa73) KO mutant, has a reduced RIS sleep onset peak. I show that the calcium channel α2/δ subunit unc-36 knockout mutant exhibits long lasting RIS overactivation during sleep.
Keywords: Sleep; Caenorhabditis elegans; In vivo calcium imaging; Sleep deprivation