Summary
In a forward genetic screen in Drosophila, we have isolated insomniac, a mutant that severely reduces the duration and consolidation of sleep. Anatomically-restricted genetic manipulations indicate that insomniac functions within neurons to regulate sleep. insomniac expression does not oscillate in a circadian manner, and conversely, the circadian clock is intact in insomniac mutants, suggesting that insomniac regulates sleep by pathways distinct from the circadian clock. The protein encoded by insomniac is a member of the BTB/POZ superfamily, which includes many proteins that function as adaptors for the Cullin-3 (Cul3) ubiquitin ligase complex. We show that Insomniac can physically associate with Cul3, and that reduction of Cul3 activity in neurons recapitulates the insomniac phenotype. The extensive evolutionary conservation of insomniac and Cul3 suggests that protein degradation pathways may have a general role in governing the sleep and wakefulness of animals.
Odor attraction in walking Drosophila melanogaster is commonly used to relate neural function to behavior, but the algorithms underlying attraction are unclear. Here, we develop a high-throughput assay to measure olfactory behavior in response to well-controlled sensory stimuli. We show that odor evokes two behaviors: an upwind run during odor (ON response), and a local search at odor offset (OFF response). Wind orientation requires antennal mechanoreceptors, but search is driven solely by odor. Using dynamic odor stimuli, we measure the dependence of these two behaviors on odor intensity and history. Based on these data, we develop a navigation model that recapitulates the behavior of flies in our apparatus, and generates realistic trajectories when run in a turbulent boundary layer plume. The ability to parse olfactory navigation into quantifiable elementary sensori-motor transformations provides a foundation for dissecting neural circuits that govern olfactory behavior.
In female mammals, up-regulation of Xist triggers X-chromosome inactivation in cis. Up-regulation is inhibited by sequences 3 to Xist contained within the antisense locus, Tsix. Inhibition could depend on transcription of Tsix and͞or on DNA elements therein. Here we test the role of Tsix transcription by augmenting the duration and strength of Tsix expression. We find that Tsix hypertranscription is sufficient to block Xist RNA accumulation in a cis-limited manner. We propose that Tsix transcription is necessary to restrict Xist activity on the future active X and, conversely, that Tsix repression is required for Xist RNA accumulation on the future inactive X. We also find that Tsix hypertranscription does not affect X-chromosome choice. Thus, choice is mediated by elements within Tsix that are independent of promoter activity.
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