School of Biological and Chemical Sciences, Queen Mary, University of London, London E1 4NS, UK.
Curr Biol. 2011 May 10;21(9):719-29. doi: 10.1016/j.cub.2011.03.049. Epub 2011 Apr 28.
Circadian clocks are synchronized to the solar day via visual and specialized photoreceptors. In Drosophila, CRYPTOCHROME (CRY) is a major photoreceptor that mediates resetting of the circadian clock via light-dependent degradation of the clock protein TIMELESS (TIM). However, in the absence of CRY, this TIM-mediated resetting still occurs in some pacemaker neurons, resulting in synchronized behavioral rhythms when flies are exposed to light-dark cycles. Even in the additional absence of visual photoreception, partial molecular and behavioral light synchronization persists. Therefore, other important clock-related photoreceptive and synchronization mechanisms must exist.
We identified a novel clock-controlled gene (quasimodo) that encodes a light-responsive and membrane-anchored Zona Pellucida domain protein that supports light-dependent TIM degradation. Whereas wild-type flies become arrhythmic in constant light (LL), quasimodo mutants elicit rhythmic expression of clock proteins and behavior in LL. QUASIMODO (QSM) can function independently of CRY and is predominantly expressed within CRY-negative clock neurons. Interestingly, downregulation of qsm in the clock circuit restores LL clock protein rhythms in qsm-negative neurons, indicating that qsm-mediated light input is not entirely cell autonomous and can be accessed by the clock circuit.
Our findings indicate that QSM constitutes part of a novel and CRY-independent light input to the circadian clock. Like CRY, this pathway targets the clock protein TIM. QSM's light-responsive character in conjunction with the predicted localization at the outer neuronal membrane suggests that its function is linked to a yet unidentified membrane-bound photoreceptor.
生物钟通过视觉和专门的光感受器与太阳日同步。在果蝇中,隐花色素(CRY)是一种主要的光感受器,通过光依赖性降解生物钟蛋白 TIMLESS(TIM)来调节生物钟的重置。然而,在没有 CRY 的情况下,这种 TIM 介导的重置仍然会在一些起搏器神经元中发生,导致当苍蝇暴露在光-暗循环中时,行为节律同步。即使在缺乏视觉光感受器的情况下,部分分子和行为光同步仍然存在。因此,必须存在其他重要的与时钟相关的光感受和同步机制。
我们鉴定了一个新的生物钟控制基因(quasimodo),该基因编码一种对光反应的、膜锚定的 Zona Pellucida 结构域蛋白,支持光依赖性 TIM 降解。虽然野生型苍蝇在持续光照(LL)中变得无节奏,但 quasimodo 突变体在 LL 中引发时钟蛋白和行为的节律表达。QUASIMODO(QSM)可以独立于 CRY 发挥作用,主要在 CRY 阴性时钟神经元中表达。有趣的是,在时钟电路中下调 qsm 可以恢复 qsm 阴性神经元中 LL 时钟蛋白的节律,表明 qsm 介导的光输入不完全是细胞自主的,并且可以被时钟电路访问。
我们的研究结果表明,QSM 构成了一个新的、独立于 CRY 的光输入到生物钟的一部分。像 CRY 一样,这条途径针对时钟蛋白 TIM。QSM 的光反应特性以及在外层神经元膜上的预测定位表明,其功能与尚未鉴定的膜结合光感受器有关。
