Kyunghee Koh scite author profile

Sleep is an essential process conserved from flies to humans. The importance of sleep is underscored by its tight homeostatic control. Here, through a forward-genetic screen, we identify a novel gene, sleepless, required for sleep in Drosophila. sleepless encodes a brain-enriched, glycosylphosphatidylinositol-anchored protein. Loss of SLEEPLESS protein causes an extreme (>80%) reduction in sleep. Furthermore, a moderate reduction in SLEEPLESS protein has minimal effects on baseline sleep, but markedly reduces recovery sleep following sleep deprivation. Genetic and molecular analyses reveal that quiver, a mutation that impairs Shaker-dependent K + current, is an allele of sleepless. Consistent with this finding, Shaker protein level is reduced in sleepless mutants. We propose that SLEEPLESS is a signaling molecule that connects sleep drive to lowered membrane excitability.Insufficient and poor quality sleep is an increasing problem in industrialized nations. Chronic sleep problems diminish quality of life, reduce workplace productivity, and contribute to fatal accidents (1). Although the biological needs fulfilled by sleep are unclear (2), they are likely to be important because sleep is conserved from flies to humans (3-7), and prolonged sleep deprivation can lead to lethality (8-10). Identifying mechanisms that control sleep may lead to novel approaches for improving sleep quality.Sleep is regulated by two main processes: circadian and homeostatic (11,12). The circadian clock regulates the timing of sleep, whereas the homeostatic mechanism controls sleep need. Homeostatic pressure to sleep increases with time spent awake and decreases with time spent asleep. Homeostatic control is thought to influence sleep under normal (baseline) conditions as well as recovery (rebound) sleep following deprivation. However, the molecular mechanisms underlying homeostatic regulation of sleep remain unclear.A powerful approach to unraveling a poorly understood biological process is to conduct unbiased genetic screens to identify novel molecules required for that process. The Drosophila model for sleep is well-suited for such an approach, which proved invaluable for elucidation of the molecular basis of the circadian clock. Although several Drosophila genes have been implicated in sleep regulation (for example, 13-15), only one of these, the gene encoding the Shaker (Sh) K + channel, was isolated as a result of a genetic screen (16). A mutation in this gene causes one of the shortest-sleeping phenotypes known, validating the use of screens and suggesting that control of membrane excitability is a critical requirement for # This manuscript has been accepted for publication in Science. This version has not undergone final editing. Please refer to the complete version of record at http://www.sciencemag.org/. Their manuscript may not be reproduced or used in any manner that does not fall within the fair use provisions of the

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JETLAG Resets the Drosophila Circadian Clock by Promoting Light-Induced Degradation of TIMELESS

Koh

Zheng

Sehgal

2006

Science

262

313

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Organisms ranging from bacteria to humans synchronize their internal clocks to daily cycles of light and dark. Photic entrainment of the Drosophila clock is mediated by proteasomal degradation of the clock protein TIMELESS (TIM). We have identified mutations in jetlag-a gene coding for an Fbox protein with leucine-rich repeats-that result in reduced light sensitivity of the circadian clock. Mutant flies show rhythmic behavior in constant light, reduced phase shifts in response to light pulses, and reduced light-dependent degradation of TIM. Expression of JET along with the circadian photoreceptor cryptochrome (CRY) in cultured S2R+ cells confers light-dependent degradation onto TIM, thereby reconstituting the acute response of the circadian clock to light in a cell culture system. Our results suggest that JET is essential for resetting the clock by transmitting light signals from CRY to TIM.

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Kyunghee Koh

Surface and structural similarity in analogical transfer

Identification of SLEEPLESS, a Sleep-Promoting Factor

JETLAG Resets the Drosophila Circadian Clock by Promoting Light-Induced Degradation of TIMELESS

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