Old flies have a robust central oscillator but weaker behavioral rhythms that can be improved by genetic and environmental manipulations

Luo, Weimin; Chen, Wenfeng; Yue, Zhifeng; Chen, Dechun; Sowcik, Mallory; Sehgal, Amita; Zheng, X. Long

doi:10.1111/j.1474-9726.2012.00800.x

Cited by 94 publications

(132 citation statements)

References 47 publications

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“…These findings may suggest that a dampening of rhythmic output from the master clock with age may lead to a desynchronization between central and peripheral oscillators, and consequently misalign peripheral oscillators with external temporal cues (151). In support of this idea, manipulations intended to align peripheral oscillators with the master clock, such as imposing an environmental temperature rhythm that is synchronized with the light/dark cycle, have yielded improvements in sleep and activity rhythms in aged Drosophila (83). Similarly, in rodents lacking a functional master clock, restricted feeding schedules are sufficient to synchronize rhythmic clock gene expression across several peripheral oscillators (121,152).…”

Section: Sensitivity To Zeitgebersmentioning

confidence: 49%

“…Many metabolic rhythms exhibit progressive dampening with age (76,81,82). These changes are underscored by evidence of age-related decreases in the amplitude of clock gene expression rhythms in clocks outside of the master pacemaker (83,84). Dampening of these rhythms is suspected to contribute to the increased risk in older adults of metabolic diseases such as diabetes, dyslipidemia, and hypertension (12,85).…”

Section: The Aging Clock: Possible Mechanismsmentioning

confidence: 99%

“…In tissues such as the lungs, the rhythm of Per1 expression seen in young rats (2 months) was absent in old animals (24-26 months) (84). In Drosophila, the amplitude of clock gene expression and protein rhythms in head and body tissues decreased in aged flies (58 days old), despite the persistence of a robust PER2 rhythm in brain clock neurons (83). These declines in peripheral clocks may have important implications for the susceptibility of aged animals to various disease states, given evidence demonstrating links between loss of rhythmic clock gene expression and the development of metabolic disease states and cancers (94,95).…”

Section: Age-associated Changes In Circadian Rhythmsmentioning

confidence: 99%

“…Using the PER2::LUC mouse model, Sellix and colleagues (151) demonstrated that peripheral clocks in esophagus, lung, and thymus gland in older mice (22-28 months) were slower to entrain to a 6-hour phase advance of the light/dark schedule, in comparison with younger (3-6 months) mice. In Drosophila, downstream clock gene oscillation in peripheral tissues and behavioral rhythms decrease in amplitude and become fragmented with increasing age (58 days) (83), despite robust Per expression rhythms persisting in neurons. These findings may suggest that a dampening of rhythmic output from the master clock with age may lead to a desynchronization between central and peripheral oscillators, and consequently misalign peripheral oscillators with external temporal cues (151).…”

Section: Sensitivity To Zeitgebersmentioning

confidence: 99%

See 3 more Smart Citations

The aging clock: circadian rhythms and later life

Hood¹,

Amir²

2017

Journal of Clinical Investigation

398

322

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Section: Sensitivity To Zeitgebersmentioning

confidence: 49%

Section: The Aging Clock: Possible Mechanismsmentioning

confidence: 99%

Section: Age-associated Changes In Circadian Rhythmsmentioning

confidence: 99%

Section: Sensitivity To Zeitgebersmentioning

confidence: 99%

See 2 more Smart Citations

The aging clock: circadian rhythms and later life

Hood¹,

Amir²

2017

Journal of Clinical Investigation

398

322

View full text Add to dashboard Cite

“…Daily cycling of Clk and cry expression is abol- ished, with intermediate levels of both transcripts throughout the day. As in the case of the Western blot analysis described above, these RNA assays of adult heads largely report clock gene expression in the compound eye (37,38), which constitutes a peripheral oscillator. We infer that the peripheral clock in the eye is dampened in dbt EY02910 mutants.…”

Section: Resultsmentioning

confidence: 99%

Casein Kinase 1 Promotes Synchrony of the Circadian Clock Network

Zheng

Sowcik

Chen

et al. 2014

Molecular and Cellular Biology

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bCasein kinase 1, known as DOUBLETIME (DBT) in Drosophila melanogaster, is a critical component of the circadian clock that phosphorylates and promotes degradation of the PERIOD (PER) protein. However, other functions of DBT in circadian regulation are not clear, in part because severe reduction of dbt causes preadult lethality. Here we report the molecular and behavioral phenotype of a viable dbt EY02910 loss-of-function mutant. We found that DBT protein levels are dramatically reduced in adult dbt EY02910 flies, and the majority of mutant flies display arrhythmic behavior, with a few showing weak, long-period (ϳ32 h) rhythms. Peak phosphorylation of PER is delayed, and both hyper-and hypophosphorylated forms of the PER and CLOCK proteins are present throughout the day. In addition, molecular oscillations of the circadian clock are dampened. In the central brain, PER and TIM expression is heterogeneous and decoupled in the canonical clock neurons of the dbt EY02910 mutants. We also report an interaction between dbt and the signaling pathway involving pigment dispersing factor (PDF), a synchronizing peptide in the clock network. These data thus demonstrate that overall reduction of DBT causes long and arrhythmic behavior, and they reveal an unexpected role of DBT in promoting synchrony of the circadian clock network. In Drosophila melanogaster, daily rhythmic behavior is governed by a network of ϳ150 brain clock neurons (1, 2), each of which contains a molecular oscillator (3). Within this oscillator, the CLOCK (CLK) and CYCLE (CYC) proteins activate transcription of the repressor genes period (per) and timeless (tim) during the day, and accumulated PER and TIM proteins repress the transcriptional activity of CLK-CYC in the late night/early morning. Phosphorylation of clock proteins, which is mainly regulated by casein kinases (CK1 and CK2) (4-6), glycogen synthase kinase 3 beta (GSK3␤) (7), and specific protein phosphatases (8, 9), plays a pivotal role in circadian timing, at least in part by regulating the stability and nuclear localization of PER and TIM (3).Robust circadian behavior relies on the coupling of clock neurons within the network. The neuropeptide pigment dispersing factor (PDF) is required for synchrony of the circadian clock circuit and its output (10-12). A similar framework operates in the mammalian circadian pacemaker, the suprachiasmatic nucleus (SCN), where a peptide, vasoactive intestinal polypeptide (VIP), released by some clock cells, synchronizes individual oscillators to generate a coherent output (13,14). How PDF and VIP synchronize the circadian clock network and its output is unclear. Interestingly, in Ck1ε tau hamsters, there is a tissue-specific misalignment of some peripheral clocks with the SCN, suggesting that the tau mutation in CK1 causes a defect in synchronization (15). However, tau appears to be a gain-of-function mutation (16), and the redundancy of CK1 isoforms in mammals makes it difficult to address consequences of CK1 loss.In Drosophila, Ck1ε is known as double-time (...

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