Your search keyword '"Yoshii, Taishi"' showing total 30 results

1. A Detailed Re-Examination of the Period Gene Rescue Experiments Shows That Four to Six Cryptochrome-Positive Posterior Dorsal Clock Neurons (DN 1p ) of Drosophila melanogaster Can Control Morning and Evening Activity.

Author

Sekiguchi M, Reinhard N, Fukuda A, Katoh S, Rieger D, Helfrich-Förster C, and Yoshii T

Subjects

Animals, Circadian Clocks genetics, Circadian Clocks physiology, Motor Activity, Photoperiod, Eye Proteins, Drosophila melanogaster physiology, Drosophila melanogaster genetics, Cryptochromes genetics, Cryptochromes metabolism, Drosophila Proteins genetics, Drosophila Proteins metabolism, Circadian Rhythm, Neurons physiology, Neurons metabolism, Period Circadian Proteins genetics, Period Circadian Proteins metabolism

Abstract

Animal circadian clocks play a crucial role in regulating behavioral adaptations to daily environmental changes. The fruit fly Drosophila melanogaster exhibits 2 prominent peaks of activity in the morning and evening, known as morning (M) and evening (E) peaks. These peaks are controlled by 2 distinct circadian oscillators located in separate groups of clock neurons in the brain. To investigate the clock neurons responsible for the M and E peaks, a cell-specific gene expression system, the GAL4-UAS system, has been commonly employed. In this study, we re-examined the two-oscillator model for the M and E peaks of Drosophila by utilizing more than 50 Gal4 lines in conjunction with the UAS-period 16 line, which enables the restoration of the clock function in specific cells in the period ( per ) null mutant background. Previous studies have indicated that the group of small ventrolateral neurons (s-LN v ) is responsible for controlling the M peak, while the other group, consisting of the 5 th ventrolateral neuron (5 th LN v ) and the three cryptochrome (CRY)-positive dorsolateral neurons (LN d ), is responsible for the E peak. Furthermore, the group of posterior dorsal neurons 1 (DN 1p ) is thought to also contain M and E oscillators. In this study, we found that Gal4 lines directed at the same clock neuron groups can lead to different results, underscoring the fact that activity patterns are influenced by many factors. Nevertheless, we were able to confirm previous findings that the entire network of circadian clock neurons controls M and E peaks, with the lateral neurons playing a dominant role. In addition, we demonstrate that 4 to 6 CRY-positive DN 1p cells are sufficient to generate M and E peaks in light-dark cycles and complex free-running rhythms in constant darkness. Ultimately, our detailed screening could serve as a catalog to choose the best Gal4 lines that can be used to rescue per in specific clock neurons., Competing Interests: Conflict of interest statementThe authors have no potential conflicts of interest with respect to the research, authorship, and/or publication of this article.

Published

2024

2. A four-oscillator model of seasonally adapted morning and evening activities in Drosophila melanogaster.

Author

Yoshii T, Saito A, and Yokosako T

Subjects

Animals, Circadian Clocks physiology, Neurons physiology, Adaptation, Physiological physiology, Sleep physiology, Drosophila melanogaster physiology, Seasons, Photoperiod, Circadian Rhythm physiology

Abstract

The fruit fly Drosophila melanogaster exhibits two activity peaks, one in the morning and another in the evening. Because the two peaks change phase depending on the photoperiod they are exposed to, they are convenient for studying responses of the circadian clock to seasonal changes. To explain the phase determination of the two peaks, Drosophila researchers have employed the two-oscillator model, in which two oscillators control the two peaks. The two oscillators reside in different subsets of neurons in the brain, which express clock genes, the so-called clock neurons. However, the mechanism underlying the activity of the two peaks is complex and requires a new model for mechanistic exploration. Here, we hypothesize a four-oscillator model that controls the bimodal rhythms. The four oscillators that reside in different clock neurons regulate activity in the morning and evening and sleep during the midday and at night. In this way, bimodal rhythms are formed by interactions among the four oscillators (two activity and two sleep oscillators), which may judiciously explain the flexible waveform of activity rhythms under different photoperiod conditions. Although still hypothetical, this model would provide a new perspective on the seasonal adaptation of the two activity peaks., (© 2023. The Author(s).)

Published

2024

3. Decapentaplegic Acutely Defines the Connectivity of Central Pacemaker Neurons in Drosophila .

Author

Polcowñuk S, Yoshii T, and Ceriani MF

Subjects

Animals, Animals, Genetically Modified, Drosophila Proteins genetics, Drosophila melanogaster, Male, Central Pattern Generators physiology, Circadian Rhythm physiology, Drosophila Proteins biosynthesis, Nerve Net physiology

Abstract

Rhythmic rest-activity cycles are controlled by an endogenous clock. In Drosophila , this clock resides in ∼150 neurons organized in clusters whose hierarchy changes in response to environmental conditions. The concerted activity of the circadian network is necessary for the adaptive responses to synchronizing environmental stimuli. Thus far, work was devoted to unravel the logic of the coordination of different clusters focusing on neurotransmitters and neuropeptides. We further explored communication in the adult male brain through ligands belonging to the bone morphogenetic protein (BMP) pathway. Herein we show that the lateral ventral neurons (LNvs) express the small morphogen decapentaplegic (DPP). DPP expression in the large LNvs triggered a period lengthening phenotype, the downregulation of which caused reduced rhythmicity and affected anticipation at dawn and dusk, underscoring DPP per se conveys time-of-day relevant information. Surprisingly, DPP expression in the large LNvs impaired circadian remodeling of the small LNv axonal terminals, likely through local modulation of the guanine nucleotide exchange factor Trio. These findings open the provocative possibility that the BMP pathway is recruited to strengthen/reduce the connectivity among specific clusters along the day and thus modulate the contribution of the clusters to the circadian network. SIGNIFICANCE STATEMENT The circadian clock relies on the communication between groups of so-called clock neurons to coordinate physiology and behavior to the optimal times across the day, predicting and adapting to a changing environment. The circadian network relies on neurotransmitters and neuropeptides to fine-tune connectivity among clock neurons and thus give rise to a coherent output. Herein we show that decapentaplegic, a ligand belonging to the BMP retrograde signaling pathway required for coordinated growth during development, is recruited by a group of circadian neurons in the adult brain to trigger structural remodeling of terminals on a daily basis., (Copyright © 2021 the authors.)

Published

2021

4. Amplitude of circadian rhythms becomes weaken in the north, but there is no cline in the period of rhythm in a beetle.

Author

Abe MS, Matsumura K, Yoshii T, and Miyatake T

Subjects

Animals, Japan, Biological Clocks physiology, Circadian Rhythm physiology, Tribolium physiology

Abstract

Many species show rhythmicity in activity, from the timing of flowering in plants to that of foraging behavior in animals. The free-running periods and amplitude (sometimes called strength or power) of circadian rhythms are often used as indicators of biological clocks. Many reports have shown that these traits are highly geographically variable, and interestingly, they often show latitudinal or longitudinal clines. In many cases, the higher the latitude is, the longer the free-running circadian period (i.e., period of rhythm) in insects and plants. However, reports of positive correlations between latitude or longitude and circadian rhythm traits, including free-running periods, the power of the rhythm and locomotor activity, are limited to certain taxonomic groups. Therefore, we collected a cosmopolitan stored-product pest species, the red flour beetle Tribolium castaneum, in various parts of Japan and examined its rhythm traits, including the power and period of the rhythm, which were calculated from locomotor activity. The analysis revealed that the power was significantly lower for beetles collected in northern areas than southern areas in Japan. However, it is worth noting that the period of circadian rhythm did not show any clines; specifically, it did not vary among the sampling sites, despite the very large sample size (n = 1585). We discuss why these cline trends were observed in T. castaneum., Competing Interests: The authors have declared that no competing interests exist.

Published

2021

5. Dopamine Signaling in Wake-Promoting Clock Neurons Is Not Required for the Normal Regulation of Sleep in Drosophila .

Author

Fernandez-Chiappe F, Hermann-Luibl C, Peteranderl A, Reinhard N, Senthilan PR, Hieke M, Selcho M, Yoshii T, Shafer OT, Muraro NI, and Helfrich-Förster C

Subjects

Action Potentials physiology, Animals, Drosophila Proteins metabolism, Drosophila melanogaster, Female, Male, Patch-Clamp Techniques, Receptors, Dopamine metabolism, Receptors, Dopamine D1 metabolism, Circadian Rhythm physiology, Dopamine metabolism, Neurons metabolism, Signal Transduction physiology, Sleep physiology

Abstract

Dopamine is a wake-promoting neuromodulator in mammals and fruit flies. In Drosophila melanogaster , the network of clock neurons that drives sleep/activity cycles comprises both wake-promoting and sleep-promoting cell types. The large ventrolateral neurons (l-LN v s) and small ventrolateral neurons (s-LN v s) have been identified as wake-promoting neurons within the clock neuron network. The l-LN v s are innervated by dopaminergic neurons, and earlier work proposed that dopamine signaling raises cAMP levels in the l-LN v s and thus induces excitatory electrical activity (action potential firing), which results in wakefulness and inhibits sleep. Here, we test this hypothesis by combining cAMP imaging and patch-clamp recordings in isolated brains. We find that dopamine application indeed increases cAMP levels and depolarizes the l-LN v s, but, surprisingly, it does not result in increased firing rates. Downregulation of the excitatory D 1 -like dopamine receptor (Dop1R1) in the l-LN v s and s-LN v s, but not of Dop1R2, abolished the depolarization of l-LN v s in response to dopamine. This indicates that dopamine signals via Dop1R1 to the l-LN v s. Downregulation of Dop1R1 or Dop1R2 in the l-LN v s and s-LN v s does not affect sleep in males. Unexpectedly, we find a moderate decrease of daytime sleep with downregulation of Dop1R1 and of nighttime sleep with downregulation of Dop1R2. Since the l-LN v s do not use Dop1R2 receptors and the s-LN v s also respond to dopamine, we conclude that the s-LN v s are responsible for the observed decrease in nighttime sleep. In summary, dopamine signaling in the wake-promoting LN v s is not required for daytime arousal, but likely promotes nighttime sleep via the s-LN v s. SIGNIFICANCE STATEMENT In insect and mammalian brains, sleep-promoting networks are intimately linked to the circadian clock, and the mechanisms underlying sleep and circadian timekeeping are evolutionarily ancient and highly conserved. Here we show that dopamine, one important sleep modulator in flies and mammals, plays surprisingly complex roles in the regulation of sleep by clock-containing neurons. Dopamine inhibits neurons in a central brain sleep center to promote sleep and excites wake-promoting circadian clock neurons. It is therefore predicted to promote wakefulness through both of these networks. Nevertheless, our results reveal that dopamine acting on wake-promoting clock neurons promotes sleep, revealing a previously unappreciated complexity in the dopaminergic control of sleep., (Copyright © 2020 the authors.)

Published

2020

6. Hub-organized parallel circuits of central circadian pacemaker neurons for visual photoentrainment in Drosophila.

Author

Li MT, Cao LH, Xiao N, Tang M, Deng B, Yang T, Yoshii T, and Luo DG

Subjects

Animals, Biological Clocks physiology, Circadian Rhythm genetics, Drosophila metabolism, Drosophila physiology, Drosophila Proteins metabolism, Drosophila Proteins physiology, Neurons cytology, Neurons metabolism, Neurons physiology, Visual Pathways physiology, Circadian Rhythm physiology, Drosophila cytology

Abstract

Circadian rhythms are orchestrated by a master clock that emerges from a network of circadian pacemaker neurons. The master clock is synchronized to external light/dark cycles through photoentrainment, but the circuit mechanisms underlying visual photoentrainment remain largely unknown. Here, we report that Drosophila has eye-mediated photoentrainment via a parallel pacemaker neuron organization. Patch-clamp recordings of central circadian pacemaker neurons reveal that light excites most of them independently of one another. We also show that light-responding pacemaker neurons send their dendrites to a neuropil called accessary medulla (aMe), where they make monosynaptic connections with Hofbauer-Buchner eyelet photoreceptors and interneurons that transmit compound-eye signals. Laser ablation of aMe and eye removal both abolish light responses of circadian pacemaker neurons, revealing aMe as a hub to channel eye inputs to central circadian clock. Taken together, we demonstrate that the central clock receives eye inputs via hub-organized parallel circuits in Drosophila.

Published

2018

7. Cryptochrome-dependent and -independent circadian entrainment circuits in Drosophila.

Author

Yoshii T, Hermann-Luibl C, Kistenpfennig C, Schmid B, Tomioka K, and Helfrich-Förster C

Subjects

Animals, Basic-Leucine Zipper Transcription Factors metabolism, Cryptochromes genetics, Drosophila, Drosophila Proteins genetics, Drosophila Proteins metabolism, Eye metabolism, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Light, Male, Mice, Transgenic, Motor Activity genetics, Mutation genetics, Physical Stimulation, RNA, Messenger, Circadian Rhythm physiology, Cryptochromes metabolism, Gene Expression Regulation physiology, Visual Pathways physiology

Abstract

Entrainment to environmental light/dark (LD) cycles is a central function of circadian clocks. In Drosophila, entrainment is achieved by Cryptochrome (CRY) and input from the visual system. During activation by brief light pulses, CRY triggers the degradation of TIMELESS and subsequent shift in circadian phase. This is less important for LD entrainment, leading to questions regarding light input circuits and mechanisms from the visual system. Recent studies show that different subsets of brain pacemaker clock neurons, the morning (M) and evening (E) oscillators, have distinct functions in light entrainment. However, the role of CRY in M and E oscillators for entrainment to LD cycles is unknown. Here, we address this question by selectively expressing CRY in different subsets of clock neurons in a cry-null (cry(0)) mutant background. We were able to rescue the light entrainment deficits of cry(0) mutants by expressing CRY in E oscillators but not in any other clock neurons. Par domain protein 1 molecular oscillations in the E, but not M, cells of cry(0) mutants still responded to the LD phase delay. This residual light response was stemming from the visual system because it disappeared when all external photoreceptors were ablated genetically. We concluded that the E oscillators are the targets of light input via CRY and the visual system and are required for normal light entrainment., (Copyright © 2015 the authors 0270-6474/15/356131-11$15.00/0.)

Published

2015

8. The ion transport peptide is a new functional clock neuropeptide in the fruit fly Drosophila melanogaster.

Author

Hermann-Luibl C, Yoshii T, Senthilan PR, Dircksen H, and Helfrich-Förster C

Subjects

Analysis of Variance, Animals, Animals, Genetically Modified, Brain cytology, Drosophila Proteins genetics, Drosophila melanogaster, Gene Expression Regulation physiology, Locomotion genetics, Motor Activity genetics, Neurons metabolism, Neuropeptides genetics, Periodicity, RNA Interference physiology, Sleep genetics, Biological Clocks genetics, Brain physiology, Circadian Rhythm genetics, Drosophila Proteins metabolism, Neuropeptides metabolism

Abstract

The clock network of Drosophila melanogaster expresses various neuropeptides, but a function in clock-mediated behavioral control was so far only found for the neuropeptide pigment dispersing factor (PDF). Here, we propose a role in the control of behavioral rhythms for the ion transport peptide (ITP), which is expressed in the fifth small ventral lateral neuron, one dorsal lateral neuron, and in only a few nonclock cells in the brain. Immunocytochemical analyses revealed that ITP, like PDF, is most probably released in a rhythmic manner at projection terminals in the dorsal protocerebrum. This rhythm continues under constant dark conditions, indicating that ITP release is clock controlled. ITP expression is reduced in the hypomorph mutant Clk(AR), suggesting that ITP expression is regulated by CLOCK. Using a genetically encoded RNAi construct, we knocked down ITP in the two clock cells and found that these flies show reduced evening activity and increased nocturnal activity. Overexpression of ITP with two independent timeless-GAL4 lines completely disrupted behavioral rhythms, but only slightly dampened PER cycling in important pacemaker neurons, suggesting a role for ITP in clock output pathways rather than in the communication within the clock network. Simultaneous knockdown (KD) of ITP and PDF made the flies hyperactive and almost completely arrhythmic under constant conditions. Under light-dark conditions, the double-KD combined the behavioral characteristics of the single-KD flies. In addition, it reduced the flies' sleep. We conclude that ITP and PDF are the clock's main output signals that cooperate in controlling the flies' activity rhythms., (Copyright © 2014 the authors 0270-6474/14/349522-15$15.00/0.)

Published

2014

9. Chronic electromyographic analysis of circadian locomotor activity in crayfish.

Author

Tomina Y, Kibayashi A, Yoshii T, and Takahata M

Subjects

Animals, Female, Male, Muscle, Skeletal physiology, Astacoidea physiology, Behavior, Animal physiology, Circadian Rhythm physiology, Electromyography methods, Motor Activity physiology

Abstract

Animals generally exhibit circadian rhythms of locomotor activity. They initiate locomotor behavior not only reflexively in response to external stimuli but also spontaneously in the absence of any specific stimulus. The neuronal mechanisms underlying circadian locomotor activity can, therefore, be based on the rhythmic changes in either reflexive efficacy or endogenous activity. In crayfish Procambarus clarkii, it can be determined by analyzing electromyographic (EMG) patterns of walking legs whether the walking behavior is initiated reflexively or spontaneously. In this study, we examined quantitatively the leg muscle activity that underlies the locomotor behavior showing circadian rhythms in crayfish. We newly developed a chronic EMG recording system that allowed the animal to freely behave under a tethered condition for more than 10 days. In the LD condition in which the animals exhibited LD entrainment, the rhythmic burst activity of leg muscles for stepping behavior was preceded by non-rhythmic tonic activation that lasted for 1323±488ms when the animal initiated walking. In DD and LL free-running conditions, the pre-burst activation lasted for 1779±31 and 1517±39ms respectively. In the mechanical stimulus-evoked walking, the pre-burst activation ended within 79±6ms. These data suggest that periodic changes in the crayfish locomotor activity under the condition of LD entrainment or free-running are based on activity changes in the spontaneous initiation mechanism of walking behavior rather than those in the sensori-motor pathway connecting mechanoreceptors with leg movements., (Copyright © 2013 Elsevier B.V. All rights reserved.)

Published

2013

10. Drosophila clock neurons under natural conditions.

Author

Menegazzi P, Vanin S, Yoshii T, Rieger D, Hermann C, Dusik V, Kyriacou CP, Helfrich-Förster C, and Costa R

Subjects

Animals, Drosophila metabolism, Drosophila Proteins metabolism, Motor Activity physiology, Neurons metabolism, Nuclear Proteins metabolism, Period Circadian Proteins metabolism, Photoperiod, Seasons, Circadian Clocks physiology, Circadian Rhythm physiology, Drosophila physiology, Drosophila Proteins physiology, Neurons physiology, Period Circadian Proteins physiology

Abstract

The circadian clock modulates the adaptive daily patterns of physiology and behavior and adjusts these rhythms to seasonal changes. Recent studies of seasonal locomotor activity patterns of wild-type and clock mutant fruit flies in quasi-natural conditions have revealed that these behavioral patterns differ considerably from those observed under standard laboratory conditions. To unravel the molecular features accompanying seasonal adaptation of the clock, we investigated Drosophila's neuronal expression of the canonical clock proteins PERIOD (PER) and TIMELESS (TIM) in nature. We find that the profile of PER dramatically changes in different seasons, whereas that of TIM remains more constant. Unexpectedly, we find that PER and TIM oscillations are decoupled in summer conditions. Moreover, irrespective of season, PER and TIM always peak earlier in the dorsal neurons than in the lateral neurons, suggesting a more rapid molecular oscillation in these cells. We successfully reproduced most of our results under simulated natural conditions in the laboratory and show that although photoperiod is the most important zeitgeber for the molecular clock, the flies' activity pattern is more strongly affected by temperature. Our results are among the first to systematically compare laboratory and natural studies of Drosophila rhythms.

Published

2013

11. Exquisite light sensitivity of Drosophila melanogaster cryptochrome.

Author

Vinayak P, Coupar J, Hughes SE, Fozdar P, Kilby J, Garren E, Yoshii T, and Hirsh J

Subjects

Animals, Circadian Clocks genetics, Circadian Rhythm physiology, Drosophila melanogaster physiology, Mutation, Neurons metabolism, Photons, Photoperiod, Photoreceptor Cells, Invertebrate physiology, Circadian Rhythm genetics, Cryptochromes genetics, Drosophila Proteins genetics, Drosophila melanogaster genetics, Eye Proteins genetics, Photophobia genetics

Abstract

Drosophila melanogaster shows exquisite light sensitivity for modulation of circadian functions in vivo, yet the activities of the Drosophila circadian photopigment cryptochrome (CRY) have only been observed at high light levels. We studied intensity/duration parameters for light pulse induced circadian phase shifts under dim light conditions in vivo. Flies show far greater light sensitivity than previously appreciated, and show a surprising sensitivity increase with pulse duration, implying a process of photic integration active up to at least 6 hours. The CRY target timeless (TIM) shows dim light dependent degradation in circadian pacemaker neurons that parallels phase shift amplitude, indicating that integration occurs at this step, with the strongest effect in a single identified pacemaker neuron. Our findings indicate that CRY compensates for limited light sensitivity in vivo by photon integration over extraordinarily long times, and point to select circadian pacemaker neurons as having important roles., Competing Interests: The authors have declared that no competing interests exist.

Published

2013

12. Peripheral circadian rhythms and their regulatory mechanism in insects and some other arthropods: a review.

Author

Tomioka K, Uryu O, Kamae Y, Umezaki Y, and Yoshii T

Subjects

Animals, Biological Clocks physiology, CLOCK Proteins physiology, Drosophila melanogaster, Female, Male, Malpighian Tubules physiology, Periodicity, Photoperiod, Sexual Behavior, Animal physiology, Circadian Rhythm physiology, Insecta physiology

Abstract

Many physiological functions of insects show a rhythmic change to adapt to daily environmental cycles. These rhythms are controlled by a multi-clock system. A principal clock located in the brain usually organizes the overall behavioral rhythms, so that it is called the "central clock". However, the rhythms observed in a variety of peripheral tissues are often driven by clocks that reside in those tissues. Such autonomous rhythms can be found in sensory organs, digestive and reproductive systems. Using Drosophila melanogaster as a model organism, researchers have revealed that the peripheral clocks are self-sustained oscillators with a molecular machinery slightly different from that of the central clock. However, individual clocks normally run in harmony with each other to keep a coordinated temporal structure within an animal. How can this be achieved? What is the molecular mechanism underlying the oscillation? Also how are the peripheral clocks entrained by light-dark cycles? There are still many questions remaining in this research field. In the last several years, molecular techniques have become available in non-model insects so that the molecular oscillatory mechanisms are comparatively investigated among different insects, which give us more hints to understand the essential regulatory mechanism of the multi-oscillatory system across insects and other arthropods. Here we review current knowledge on arthropod's peripheral clocks and discuss their physiological roles and molecular mechanisms.

Published

2012

13. The dual-oscillator system of Drosophila melanogaster under natural-like temperature cycles.

Author

Bywalez W, Menegazzi P, Rieger D, Schmid B, Helfrich-Förster C, and Yoshii T

Subjects

ARNTL Transcription Factors genetics, ARNTL Transcription Factors metabolism, Adaptation, Physiological, Animals, CLOCK Proteins genetics, CLOCK Proteins metabolism, Drosophila Proteins genetics, Drosophila Proteins metabolism, Drosophila melanogaster genetics, Drosophila melanogaster metabolism, Genotype, Male, Mutation, Period Circadian Proteins genetics, Period Circadian Proteins metabolism, Phenotype, Thermosensing, Time Factors, Behavior, Animal, Biological Clocks genetics, Circadian Rhythm genetics, Drosophila melanogaster physiology, Motor Activity, Photoperiod, Temperature

Abstract

Dual-oscillator systems that control morning and evening activities can be found in a wide range of animals. The two coupled oscillators track dawn and dusk and flexibly adapt their phase relationship to seasonal changes. This is also true for the fruit fly Drosophila melanogaster that serves as model organism to understand the molecular and anatomical bases of the dual-oscillator system. In the present study, the authors investigated which temperature parameters are crucial for timing morning and evening activity peaks by applying natural-like temperature cycles with different daylengths. The authors found that the morning peak synchronizes to the temperature increase in the morning and the evening peak to the temperature decrease in the afternoon. The two peaks did not occur at fixed absolute temperatures, but responded flexibly to daylength and overall temperature level. Especially, the phase of the evening peak clearly depended on the absolute temperature level: it was delayed at high temperatures, whereas the phase of the M peak was less influenced. This suggests that the two oscillators have different temperature sensitivities. The bimodal activity rhythm was absent in the circadian clock mutants Clk(Jrk) and cyc(01) and reduced in per(01) and tim(01) mutants. Whereas the activity of Clk(Jrk) mutants just followed the temperature cycles, that of per(01) and tim(01) mutants did not, suggesting that these mutants are not completely clockless. This study revealed new characteristics of the dual-oscillator system in Drosophila that were not detected under different photoperiods.

Published

2012

14. Neuropeptide F immunoreactive clock neurons modify evening locomotor activity and free-running period in Drosophila melanogaster.

Author

Hermann C, Yoshii T, Dusik V, and Helfrich-Förster C

Subjects

Animals, Drosophila melanogaster, Male, Mice, Mice, Inbred BALB C, Circadian Clocks physiology, Circadian Rhythm physiology, Drosophila Proteins physiology, Motor Activity physiology, Neurons physiology, Neuropeptides physiology, Running physiology

Abstract

Different subsets of Drosophila melanogaster's clock neurons are characterized by their specific functions in daily locomotor rhythms and the differences in their neurotransmitter composition. We investigated the function of the neuropeptide F (NPF) immunoreactive clock neurons in the rhythmic locomotor behavior of adult flies. We newly identified the fifth s-LN(v) and a subset of the l-LN(v)s as NPF-positive in addition to the three LN(d)s that have been described previously. We then selectively ablated different subsets of NPF-expressing neurons using npfGal4-targeted expression of the cell death gene head involution defective (hid) in combination with cryGal80 and pdfGal80. By analyzing daily locomotor rhythms in these flies, we show that the NPF-positive clock neurons--especially the fifth s-LN(v) and the LN(d)s--are involved in both the control of the free-running period in constant darkness (DD) and the phasing and amplitude of the evening activity in light-dark (LD) cycles. Furthermore, we show that the simultaneous ablation of NPF and pigment dispersing factor (PDF)-immunoreactive neurons has additive effects in LD, resulting in an evening peak phase that is even more advanced in comparison to PDF-ablated flies. We also found that this more advanced evening peak is additionally reduced in amplitude. To putatively assign the observed phenotypes to the action of NPF, we knocked it down in conjunction with PDF using RNA-interference (RNAi) and further suggest a possible role for NPF in the control of the flies' evening activity., (Copyright © 2011 Wiley-Liss, Inc.)

Published

2012

15. Human cryptochrome-1 confers light independent biological activity in transgenic Drosophila correlated with flavin radical stability.

Author

Vieira J, Jones AR, Danon A, Sakuma M, Hoang N, Robles D, Tait S, Heyes DJ, Picot M, Yoshii T, Helfrich-Förster C, Soubigou G, Coppee JY, Klarsfeld A, Rouyer F, Scrutton NS, and Ahmad M

Subjects

Animals, Animals, Genetically Modified, Cryptochromes isolation & purification, DNA Primers genetics, Darkness, Drosophila, Gene Expression Profiling, Humans, Microarray Analysis, Reverse Transcriptase Polymerase Chain Reaction, Circadian Rhythm physiology, Cryptochromes metabolism, Flavins metabolism, Metamorphosis, Biological physiology, Signal Transduction physiology

Abstract

Cryptochromes are conserved flavoprotein receptors found throughout the biological kingdom with diversified roles in plant development and entrainment of the circadian clock in animals. Light perception is proposed to occur through flavin radical formation that correlates with biological activity in vivo in both plants and Drosophila. By contrast, mammalian (Type II) cryptochromes regulate the circadian clock independently of light, raising the fundamental question of whether mammalian cryptochromes have evolved entirely distinct signaling mechanisms. Here we show by developmental and transcriptome analysis that Homo sapiens cryptochrome--1 (HsCRY1) confers biological activity in transgenic expressing Drosophila in darkness, that can in some cases be further stimulated by light. In contrast to all other cryptochromes, purified recombinant HsCRY1 protein was stably isolated in the anionic radical flavin state, containing only a small proportion of oxidized flavin which could be reduced by illumination. We conclude that animal Type I and Type II cryptochromes may both have signaling mechanisms involving formation of a flavin radical signaling state, and that light independent activity of Type II cryptochromes is a consequence of dark accumulation of this redox form in vivo rather than of a fundamental difference in signaling mechanism.

Published

2012

16. Synergic entrainment of Drosophila's circadian clock by light and temperature.

Author

Yoshii T, Vanin S, Costa R, and Helfrich-Förster C

Subjects

Animals, Biological Clocks radiation effects, Circadian Rhythm radiation effects, Drosophila melanogaster genetics, Drosophila melanogaster physiology, Male, Motor Activity genetics, Neurons radiation effects, Seasons, Biological Clocks genetics, Circadian Rhythm genetics, Light, Neurons physiology, Temperature

Abstract

Daily light and temperature cycles are considered the most important zeitgebers for circadian clocks in many organisms. The influence of each single zeitgeber on the clock has been well studied, but little is known about any synergistic effects of both zeitgebers on the clock. In nature, light and temperature show characteristic daily oscillations with the temperature rising during the light phase and reaching its maximum in the late afternoon. Here, we studied behavioral and molecular rhythms in Drosophila melanogaster under simulated natural low light-dark (LD) and temperature (T) cycles that typically occur during the September equinox. Wild-type flies were either subjected to simulated LD or T cycles alone or to a combination of both. Behavioral rhythms and molecular rhythms in the different clock neurons were assessed under the 3 different conditions. Although behavioral rhythms entrained to all conditions, the rhythms were most robust under the combination of LD and T cycles. The clock neurons responded differently to LD and T cycles. Some were not entrained by T cycles alone; others were only slightly entrained by LD cycles alone. The amplitude of the molecular cycling was not different between LD alone and T cycles alone; but LD alone could set the pacemaker neurons to similar phases, whereas T cycles alone could not. The combination of the 2 zeitgebers entrained all clock neurons not only with similar phase but also enhanced the amplitude of Timeless cycling in the majority of cells. Our results show that the 2 zeitgebers synergistically entrain behavioral and molecular rhythms of Drosophila melanogaster.

Published

2009

17. Cryptochrome mediates light-dependent magnetosensitivity of Drosophila's circadian clock.

Author

Yoshii T, Ahmad M, and Helfrich-Förster C

Subjects

Animals, Biological Clocks physiology, Cryptochromes, Light, Locomotion, Circadian Rhythm physiology, Drosophila Proteins physiology, Drosophila melanogaster physiology, Flavoproteins physiology, Magnetics, Photoreceptor Cells, Invertebrate physiology

Abstract

Since 1960, magnetic fields have been discussed as Zeitgebers for circadian clocks, but the mechanism by which clocks perceive and process magnetic information has remained unknown. Recently, the radical-pair model involving light-activated photoreceptors as magnetic field sensors has gained considerable support, and the blue-light photoreceptor cryptochrome (CRY) has been proposed as a suitable molecule to mediate such magnetosensitivity. Since CRY is expressed in the circadian clock neurons and acts as a critical photoreceptor of Drosophila's clock, we aimed to test the role of CRY in magnetosensitivity of the circadian clock. In response to light, CRY causes slowing of the clock, ultimately leading to arrhythmic behavior. We expected that in the presence of applied magnetic fields, the impact of CRY on clock rhythmicity should be altered. Furthermore, according to the radical-pair hypothesis this response should be dependent on wavelength and on the field strength applied. We tested the effect of applied static magnetic fields on the circadian clock and found that flies exposed to these fields indeed showed enhanced slowing of clock rhythms. This effect was maximal at 300 muT, and reduced at both higher and lower field strengths. Clock response to magnetic fields was present in blue light, but absent under red-light illumination, which does not activate CRY. Furthermore, cry(b) and cry(OUT) mutants did not show any response, and flies overexpressing CRY in the clock neurons exhibited an enhanced response to the field. We conclude that Drosophila's circadian clock is sensitive to magnetic fields and that this sensitivity depends on light activation of CRY and on the applied field strength, consistent with the radical pair mechanism. CRY is widespread throughout biological systems and has been suggested as receptor for magnetic compass orientation in migratory birds. The present data establish the circadian clock of Drosophila as a model system for CRY-dependent magnetic sensitivity. Furthermore, given that CRY occurs in multiple tissues of Drosophila, including those potentially implicated in fly orientation, future studies may yield insights that could be applicable to the magnetic compass of migratory birds and even to potential magnetic field effects in humans., Competing Interests: Competing interests. The authors have declared that no competing interests exist.

Published

2009

18. The neuropeptide pigment-dispersing factor adjusts period and phase of Drosophila's clock.

Author

Yoshii T, Wülbeck C, Sehadova H, Veleri S, Bichler D, Stanewsky R, and Helfrich-Förster C

Subjects

Adaptation, Physiological genetics, Analysis of Variance, Animals, Animals, Genetically Modified, Brain cytology, Drosophila, Drosophila Proteins genetics, Gene Expression Regulation genetics, Insect Proteins metabolism, Luciferases metabolism, Models, Biological, Neurons metabolism, Nuclear Proteins genetics, Period Circadian Proteins, Time Factors, Circadian Rhythm genetics, Drosophila Proteins metabolism, Gene Expression Regulation physiology, Neuropeptides metabolism, Nuclear Proteins metabolism

Abstract

The neuropeptide pigment-dispersing factor (PDF) is a key transmitter in the circadian clock of Drosophila melanogaster. PDF is necessary for robust activity rhythms and is thought to couple the circadian oscillations of the clock neurons. However, little is known about the action of PDF on individual clock neurons. Here, we combined the period-luciferase reporter system with immunolabeling of clock proteins in wild-type and Pdf(01) mutants to dissect the effects of PDF on specific subgroups of clock neurons. Additionally, PDF levels were elevated to higher than normal levels using specific neural mutants, and a correlation analysis of locomotor activity and clock protein staining served to determine the periods of specific clock cells. We found that PDF has multiple effects on the clock neurons: In some groups of clock neurons, PDF was required for maintaining the oscillations of individual cells, and in others, PDF was required for synchronous cycling of the individual members. Other clock neurons cycled with high amplitude in absence of PDF, but PDF affected their intrinsic clock speed. Sometimes PDF shortened and sometimes PDF lengthened period. Our observations indicate that PDF is crucial for adjusting cycling amplitude, period, and phase of the different players in the circadian clock. Under natural conditions PDF may be required for adapting Drosophila's clock to varying photoperiods. Indeed, we show here that Pdf(01) mutants are not able to adapt their activity to long photoperiods in a wild-type manner.

Published

2009

19. Cryptochrome is present in the compound eyes and a subset of Drosophila's clock neurons.

Author

Yoshii T, Todo T, Wülbeck C, Stanewsky R, and Helfrich-Förster C

Subjects

Analysis of Variance, Animals, Animals, Genetically Modified, Cryptochromes, Drosophila anatomy & histology, Drosophila Proteins genetics, Drosophila Proteins metabolism, Gene Expression Regulation physiology, Circadian Rhythm physiology, Flavoproteins metabolism, Neurons classification, Neurons metabolism, Photoreceptor Cells, Invertebrate cytology

Abstract

Cryptochrome (CRY) is intimately associated with the circadian clock of many organisms. In the fruit fly Drosophila melanogaster, CRY seems to be involved in photoreception as well as in the core clockwork. In spite of the critical role of CRY for the clock of Drosophila, it was not quite clear whether CRY is expressed in every clock cell. With the help of a new antibody and a mutant that lacks CRY, we show here that CRY is expressed in specific subsets of Drosophila's pacemaker neurons and in the photoreceptor cells of the compound eyes. In the pacemaker neurons, CRY levels and kinetics under light-dark cycles are quite different from each other. High-amplitude oscillations are observed in only three groups of clock neurons, suggesting that these three groups are strongly receptive to light. The different CRY kinetics may account for phase differences in oscillations of the clock proteins observed in these three groups in earlier studies. The molecular clock of the neurons that contain lower CRY levels or are completely CRY negative can still be synchronized by light, probably via intercellular communication with the CRY-positive neurons as well as via external photoreceptors., ((c) 2008 Wiley-Liss, Inc.)

Published

2008

20. Induction of Drosophila behavioral and molecular circadian rhythms by temperature steps in constant light.

Author

Yoshii T, Fujii K, and Tomioka K

Subjects

ARNTL Transcription Factors, Animals, Basic Helix-Loop-Helix Transcription Factors genetics, CLOCK Proteins, Drosophila Proteins genetics, Drosophila melanogaster genetics, Genes, Insect physiology, Motor Activity physiology, Nuclear Proteins genetics, Period Circadian Proteins, Polymerase Chain Reaction, RNA, Messenger metabolism, Transcription Factors genetics, Behavior, Animal physiology, Circadian Rhythm physiology, Drosophila melanogaster physiology, Temperature

Abstract

In constant light, where Drosophila rhythms are normally disrupted, temperature cycles induce circadian rhythms at both the molecular and behavioral level. The authors investigated the process by which the thermoperiod induces the rhythms using temperature steps. A 10 degrees C temperature step-up induced a single locomotor activity peak ca 9 h after the temperature transition, whereas a 10 degrees C step-down induced a strong activity peak ca 24 h after the transition, and the peak recurred for several cycles, suggesting that the underlying clock is reset. Arrhythmic per(01) , tim( 01) , dClk(Jrk) , and cyc(01) mutant flies failed to show the rhythm after the step-down, suggesting that per, tim, dClk, and cyc are necessary for the step-down-induced rhythm. After the step-up, per(01) flies exhibited an activity peak similar to that of wild-type flies, suggesting that the peak can be induced by the step-up in absence of PER. mRNA levels of per, tim , dClk, vri, and Pdp1epsilon were changed in response to the temperature steps, but the changes differed depending on the direction of temperature steps, suggesting that steps-up and steps-down have different roles in the initiation of the oscillation. Probably, alternating 12-h temperature steps-up and steps-down will induce opposite changes in mRNA levels of clock genes, eventually producing stable molecular oscillations. Although TIM shows responses to temperature consistent with the changes of its mRNA, this is not the case for PER, consistent with posttranscriptional regulation. Changes of the mRNA levels were significantly altered but still observed in per( 01) flies but not observed in dClk(Jrk) flies, except for per mRNA. This suggests that dCLK is involved in the temperature-induced changes in the levels of most clock gene mRNA but that per is regulated via a different mechanism.

Published

2007

21. Temperature cycles drive Drosophila circadian oscillation in constant light that otherwise induces behavioural arrhythmicity.

Author

Yoshii T, Heshiki Y, Ibuki-Ishibashi T, Matsumoto A, Tanimura T, and Tomioka K

Subjects

Animals, Animals, Genetically Modified, Behavior, Animal physiology, Blotting, Western methods, Drosophila, Drosophila Proteins genetics, Immunohistochemistry methods, Light, Nuclear Proteins genetics, Period Circadian Proteins, Time Factors, Circadian Rhythm physiology, Drosophila Proteins metabolism, Gene Expression Regulation physiology, Motor Activity physiology, Nuclear Proteins metabolism, Temperature

Abstract

The fruit fly, Drosophila melanogaster, shows a clear circadian locomotor rhythm in light cycles and constant darkness. Although the rhythm disappears in constant light, we found that temperature cycles drive the circadian rhythm both in locomotor activity and molecular abundance of PERIOD (PER) and TIMELESS (TIM). The thermoperiodically induced locomotor rhythm entailed an anticipatory activity at the late thermophase, which required several transient cycles to establish a steady-state entrainment, suggesting that the rhythm is endogenous and driven by a circadian clock. Western blot analysis revealed that PER and TIM increased during the cryophase, peaking at the middle to late cryophase. PER was also cyclically expressed under the temperature cycle in the known per-expressing neurons, i.e. so-called lateral (LNs) and dorsal neurons (DNs), and two pairs of cells (LPNs) that were located in the lateral posterior protocerebrum. It is thus suggested that the temperature cycle induces the cycling of PER and TIM either by blocking somewhere in the photic entrainment pathway during the cryophase or temporally activating their translation to sufficient protein levels to drive a circadian oscillation. In flies lacking pigment-dispersing factor (PDF) or PDF-expressing cells, the anticipatory activity was relatively dispersed. disco(2) mutant flies lacking the lateral neurons still showed an anticipatory activity, but with dispersed activity. These behavioural results suggest that not only LNs but also DNs and LPNs can, at least, partially participate in regulating the thermoperiodically induced rhythm.

Published

2005

22. Drosophila cryb mutation reveals two circadian clocks that drive locomotor rhythm and have different responsiveness to light.

Author

Yoshii T, Funada Y, Ibuki-Ishibashi T, Matsumoto A, Tanimura T, and Tomioka K

Subjects

Animals, Animals, Genetically Modified, Biological Clocks physiology, Biological Clocks radiation effects, Circadian Rhythm physiology, Circadian Rhythm radiation effects, Cryptochromes, Drosophila Proteins metabolism, Drosophila melanogaster metabolism, Drosophila melanogaster radiation effects, Eye Proteins metabolism, Gene Expression Regulation, Immunohistochemistry, Light, Motor Activity genetics, Mutation, Neurons metabolism, Nuclear Proteins metabolism, Period Circadian Proteins, Photic Stimulation, Photoreceptor Cells, Invertebrate metabolism, Receptors, G-Protein-Coupled, Biological Clocks genetics, Circadian Rhythm genetics, Drosophila Proteins genetics, Drosophila melanogaster genetics, Eye Proteins genetics, Motor Activity physiology

Abstract

Cryptochrome (CRY) is a blue-light-absorbing protein involved in the photic entrainment of the circadian clock in Drosophila melanogaster. We have investigated the locomotor activity rhythms of flies carrying cryb mutant and revealed that they have two separate circadian oscillators with different responsiveness to light. When kept in constant light conditions, wild-type flies became arrhythmic, while cryb mutant flies exhibited free-running rhythms with two rhythmic components, one with a shorter and the other with a longer free-running period. The rhythm dissociation was dependent on the light intensities: the higher the light intensities, the greater the proportion of animals exhibiting the two oscillations. External photoreceptors including the compound eyes and the ocelli are the likely photoreceptors for the rhythm dissociation, since rhythm dissociation was prevented in so1;cryb and norpAP41;cryb double mutant flies. Immunohistochemical analysis demonstrated that the PERIOD expression rhythms in ventrally located lateral neurons (LNvs) occurred synchronously with the shorter period component, while those in the dorsally located per-expressing neurons showed PER expression most likely related to the longer period component, in addition to that synchronized to the LNvs. These results suggest that the Drosophila locomotor rhythms are driven by two separate per-dependent clocks, responding differentially to constant light.

Published

2004

23. A temperature-dependent timing mechanism is involved in the circadian system that drives locomotor rhythms in the fruit fly Drosophila melanogaster.

Author

Yoshii T, Sakamoto M, and Tomioka K

Subjects

ARNTL Transcription Factors, Animals, Basic Helix-Loop-Helix Transcription Factors, CLOCK Proteins, Darkness, Drosophila melanogaster genetics, Feedback, Physiological, Gene Expression Regulation, Insect Proteins genetics, Insect Proteins metabolism, Light, Male, Motor Activity, Nuclear Proteins genetics, Nuclear Proteins metabolism, Period Circadian Proteins, Time Factors, Trans-Activators genetics, Trans-Activators metabolism, Transcription Factors genetics, Transcription Factors metabolism, Circadian Rhythm, Drosophila Proteins, Drosophila melanogaster physiology, Temperature

Abstract

The circadian clock of Drosophila melanogaster is thought to include rhythmic expression of period gene. Recent studies suggested, however, that a per-less oscillation is also involved in the regulation of circadian locomotor rhythms. In the present study, we examined the existence and the property of the possible per-less oscillation using arrhythmic clock mutant flies carrying per (01), tim(01), dClk(Jrk) or cyc(01), which lack rhythmic per expression. When temperature cycles consisting of 25 degrees C and 30 degrees C with various periods (T=8-32 hr) were given, wild-type (Canton-S) flies showed locomotor rhythms entrained to temperature cycles over a wide range of period (T=8-32 hr) in constant light (LL) while only to T=24 hr in constant darkness (DD). The mutant flies showed rhythms synchronizing with the given cycle both under LL and DD. In per(01) and tim(01) flies, the phase of a major peak slightly changed dependent on Ts in DD, while it did not in dClk(Jrk) and cyc(01) flies. When they were transferred from a constant temperature to a temperature cycle under DD, several cycles were necessary to establish a clear temperature entrainment in per(01) and tim (01) flies. These results suggest that per(01) and tim(01) flies have a temperature-entrainable weak oscillatory mechanism and that the per-less oscillatory mechanism may require dClk and cyc. In addition, per (01) and tim(01) flies changed from thermoactive in DD to cryoactive in LL, while dClk(Jrk) and cyc(01) flies did not. It is thus suggested that dClk and cyc are also involved in determining the light-associated temperature preference in per(01) and tim(01) flies.

Published

2002

24. Dorsal clock networks drive temperature preference rhythms in Drosophila

Author

Chen, Shyh-Chi, Tang, Xin, Goda, Tadahiro, Umezaki, Yujiro, Riley, Abigail C, Sekiguchi, Manabu, Yoshii, Taishi, and Hamada, Fumika N

Subjects

Biological Sciences, Neurosciences, Generic health relevance, Animals, Circadian Rhythm, Drosophila, Drosophila Proteins, Drosophila melanogaster, Neurons, Temperature, CP: Neuroscience, anterior dorsal neurons 1, body temperature rhythms and Drosophila melanogaster, circadian clock, circadian rhythms, dorsal neurons 2, posterior dorsal neurons 1, temperature homeostasis, temperature preference rhythms, thermoregulation, Biochemistry and Cell Biology, Medical Physiology, Biological sciences

Abstract

Animals display a body temperature rhythm (BTR). Little is known about the mechanisms by which a rhythmic pattern of BTR is regulated and how body temperature is set at different times of the day. As small ectotherms, Drosophila exhibit a daily temperature preference rhythm (TPR), which generates BTR. Here, we demonstrate dorsal clock networks that play essential roles in TPR. Dorsal neurons 2 (DN2s) are the main clock for TPR. We find that DN2s and posterior DN1s (DN1ps) contact and the extent of contacts increases during the day and that the silencing of DN2s or DN1ps leads to a lower temperature preference. The data suggest that temporal control of the microcircuit from DN2s to DN1ps contributes to TPR regulation. We also identify anterior DN1s (DN1as) as another important clock for TPR. Thus, we show that the DN networks predominantly control TPR and determine both a rhythmic pattern and preferred temperatures.

Published

2022

25. Entrainment of Drosophila circadian rhythms by temperature cycles

Author

Tomioka, Kenji and Yoshii, Taishi

Published

2006

26. Genetic variation and phenotypic plasticity in circadian rhythms in an armed beetle, Gnatocerus cornutus (Tenebrionidae).

Author

Matsumura, Kentarou, Abe, Masato S, Sharma, Manmohan D, Hosken, David J, Yoshii, Taishi, and Miyatake, Takahisa

Subjects

PHENOTYPIC plasticity, CIRCADIAN rhythms, TENEBRIONIDAE, BIOLOGICAL rhythms, TEMPERATURE effect, BIOINDICATORS

Abstract

Circadian rhythms, their free-running periods and the power of the rhythms are often used as indicators of biological clocks, and there is evidence that the free-running periods of circadian rhythms are not affected by environmental factors, such as temperature. However, there are few studies of environmental effects on the power of the rhythms, and it is not clear whether temperature compensation is universal. Additionally, genetic variation and phenotypic plasticity in biological clocks are important for understanding the evolution of biological rhythms, but genetic and plastic effects are rarely investigated. Here, we used 18 isofemale lines (genotypes) of Gnatocerus cornutus to assess rhythms of locomotor activity, while also testing for temperature effects. We found that total activity and the power of the circadian rhythm were affected by interactions between sex and genotype or between sex, genotype and temperature. The males tended to be more active and showed greater increases in activity, but this effect varied across both genotypes and temperatures. The period of activity varied only by genotype and was thus independent of temperature. The complicated genotype–sex–environment interactions we recorded stress the importance of investigating circadian activity in more integrated ways. [ABSTRACT FROM AUTHOR]

Published

2020

27. The CCHamide1 Neuropeptide Expressed in the Anterior Dorsal Neuron 1 Conveys a Circadian Signal to the Ventral Lateral Neurons in Drosophila melanogaster.

Author

Fujiwara, Yuri, Hermann-Luibl, Christiane, Katsura, Maki, Sekiguchi, Manabu, Ida, Takanori, Helfrich-Förster, Charlotte, and Yoshii, Taishi

Subjects

CELL communication, NEUROPEPTIDES, DROSOPHILA melanogaster, INSECT neurons, CIRCADIAN rhythms

Abstract

The fruit fly Drosophila melanogaster possesses approximately 150 brain clock neurons that control circadian behavioral rhythms. Even though individual clock neurons have self-sustaining oscillators, they interact and synchronize with each other through a network. However, little is known regarding the factors responsible for these network interactions. In this study, we investigated the role of CCHamide1 (CCHa1), a neuropeptide expressed in the anterior dorsal neuron 1 (DN1a), in intercellular communication of the clock neurons. We observed that CCHa1 connects the DN1a clock neurons to the ventral lateral clock neurons (LNv) via the CCHa1 receptor, which is a homolog of the gastrin-releasing peptide receptor playing a role in circadian intercellular communications in mammals. CCHa1 knockout or knockdown flies have a generally low activity level with a special reduction of morning activity. In addition, they exhibit advanced morning activity under light-dark cycles and delayed activity under constant dark conditions, which correlates with an advance/delay of PAR domain Protein 1 (PDP1) oscillations in the small-LNv (s-LNv) neurons that control morning activity. The terminals of the s-LNv neurons show rather high levels of Pigment-dispersing factor (PDF) in the evening, when PDF is low in control flies, suggesting that the knockdown of CCHa1 leads to increased PDF release; PDF signals the other clock neurons and evidently increases the amplitude of their PDP1 cycling. A previous study showed that high-amplitude PDP1 cycling increases the siesta of the flies, and indeed, CCHa1 knockout or knockdown flies exhibit a longer siesta than control flies. The DN1a neurons are known to be receptive to PDF signaling from the s-LNv neurons; thus, our results suggest that the DN1a and s-LNv clock neurons are reciprocally coupled via the neuropeptides CCHa1 and PDF, and this interaction fine-tunes the timing of activity and sleep. [ABSTRACT FROM AUTHOR]

Published

2018

28. Pigment-Dispersing Factor Is Involved in Age-Dependent Rhythm Changes in Drosophila melanogaster.

Author

Umezaki, Yujiro, Yoshii, Taishi, Kawaguchi, Tomoaki, Helfrich-Förster, Charlotte, and Tomioka, Kenji

Subjects

*CIRCADIAN rhythms, *DROSOPHILA melanogaster, *BIOLOGICAL rhythms, *GENE expression, *IMMUNOHISTOCHEMISTRY

Abstract

Most animals show rest/activity rhythms that are regulated by an endogenous timing mechanism, the so-called circadian system. The rhythm becomes weaker with age, but the mechanism underlying the age-associated rhythm change remains to be elucidated. Here we employed Drosophila melanogaster as a model organism to study the aging effects on the rhythm. We first investigated activity rhythms under light-dark (LD) cycles and constant darkness (DD) in young (1-day-old) and middle-aged (30-, 40-, and 50-day-old) wild-type male flies. The middle-aged flies showed a reduced activity level in comparison with young flies. Additionally, the free-running period significantly lengthened in DD, and the rhythm strength was diminished. Immunohistochemistry against pigment-dispersing factor (PDF), a principal neurotransmitter of the Drosophila clock, revealed that PDF levels declined with age. We also found an attenuation of TIMELESS (TIM) oscillation in the cerebral clock neurons in elder flies. Intriguingly, overexpression of PDF suppressed age-associated changes not only in the period and strength of free-running locomotor rhythms but also in the amplitude of TIM oscillations in many pacemaker neurons in the elder flies, suggesting that the age-dependent PDF decline is responsible for the rhythm attenuation. These results suggest that the age-associated reduction of PDF may cause attenuation of intercellular communication in the circadian neuronal network and of TIM cycling, which may result in the age-related rhythm decay. [ABSTRACT FROM PUBLISHER]

Published

2012

29. A New ImageJ Plug-in “ActogramJ” for Chronobiological Analyses.

Author

Schmid, Benjamin, Helfrich-Förster, Charlotte, and Yoshii, Taishi

Subjects

PERSONAL computers, CIRCADIAN rhythms, COMPUTER software, CHRONOBIOLOGY, COMPUTER engineering

Abstract

While the rapid development of personal computers and high-throughput recording systems for circadian rhythms allow chronobiologists to produce huge amounts of data, the software to analyze them often lags behind. Here, we announce newly developed chronobiology software that is easy to use, compatible with many different systems, and freely available. Our system can perform the most frequently used analyses: actogram drawing, periodogram analysis, and waveform analysis. The software is distributed as a pure Java plug-in for ImageJ and so works on the 3 main operating systems: Linux, Macintosh, and Windows. We believe that this free software raises the speed of data analyses and makes studying chronobiology accessible to newcomers. [ABSTRACT FROM PUBLISHER]

Published

2011

30. Circadian light-input pathways in Drosophila.

Author

Yoshii, Taishi, Hermann-Luibl, Christiane, and Helfrich-Förster, Charlotte

Subjects

*DROSOPHILA melanogaster, *CIRCADIAN rhythms, *EFFECT of light on insects, *INSECT photoreceptors, *NEURAL physiology, *PHYSIOLOGY, *INSECTS

Abstract

Light is the most important environmental cue to entrain the circadian clock in most animals. In the fruit flyDrosophila melanogaster, the light entrainment mechanisms of the clock have been well-studied. TheDrosophilabrain contains approximately 150 neurons that rhythmically express circadian clock genes. These neurons are called “clock neurons” and control behavioral activity rhythms. Many clock neurons express the Cryptochrome (CRY) protein, which is sensitive to UV and blue light, and thus enables clock neurons deep in the brain to directly perceive light. In addition to the CRY protein, external photoreceptors in theDrosophilaeyes play an important role in circadian light-input pathways. Recent studies have provided new insights into the mechanisms that integrate these light inputs into the circadian network of the brain. In this review, we will summarize the current knowledge on the light entrainment pathways in theDrosophilacircadian clock. [ABSTRACT FROM AUTHOR]

Published

2016