BACKGROUND: 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. RESULTS: 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. CONCLUSIONS: 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.
BACKGROUND: 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. RESULTS: 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. CONCLUSIONS: 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.
Authors: Edgar Buhl; Adam Bradlaugh; Maite Ogueta; Ko-Fan Chen; Ralf Stanewsky; James J L Hodge Journal: Proc Natl Acad Sci U S A Date: 2016-11-07 Impact factor: 11.205
Authors: Erica E Rosenbaum; Kimberley S Brehm; Eva Vasiljevic; Allen Gajeski; Nansi Jo Colley Journal: Vis Neurosci Date: 2012-05-10 Impact factor: 3.241
Authors: Renata Van De Maas de Azevedo; Celia Hansen; Ko-Fan Chen; Ezio Rosato; Charalambos P Kyriacou Journal: Front Physiol Date: 2020-03-06 Impact factor: 4.566