Peripheral circadian clock for the cuticle deposition rhythm in
            <i>Drosophila melanogaster</i>

Ito, Chihiro; Goto, Shin G.; Shiga, Sakiko; Tomioka, Kenji; Numata, Hideharu

doi:10.1073/pnas.0800145105

Cited by 58 publications

(72 citation statements)

References 45 publications

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“…Daily cuticle deposition in the inner apodemes has been noted in An. gambiae, forming discrete layers that are reliable indicators of mosquito age in days (93), and in many insect species this deposition is under circadian regulation (94,95). In fact, in Drosophila this rhythm is regulated locally by a peripheral oscillator in the epidermis (95).…”

mentioning

confidence: 99%

Genome-wide profiling of diel and circadian gene expression in the malaria vector Anopheles gambiae

Rund

Hou

Ward

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

168

269

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Anopheles gambiae, the primary African vector of malaria parasites, exhibits numerous rhythmic behaviors including flight activity, swarming, mating, host seeking, egg laying, and sugar feeding. However, little work has been performed to elucidate the molecular basis for these daily rhythms. To study how gene expression is regulated globally by diel and circadian mechanisms, we have undertaken a DNA microarray analysis of An. gambiae under light/ dark cycle (LD) and constant dark (DD) conditions. Adult mated, non-blood-fed female mosquitoes were collected every 4 h for 48 h, and samples were processed with DNA microarrays. Using a cosine wave-fitting algorithm, we identified 1,293 and 600 rhythmic genes with a period length of 20-28 h in the head and body, respectively, under LD conditions, representing 9.7 and 4.5% of the An. gambiae gene set. A majority of these genes was specific to heads or bodies. Examination of mosquitoes under DD conditions revealed that rhythmic programming of the transcriptome is dependent on an interaction between the endogenous clock and extrinsic regulation by the LD cycle. A subset of genes, including the canonical clock components, was expressed rhythmically under both environmental conditions. A majority of genes had peak expression clustered around the day/night transitions, anticipating dawn and dusk. Genes cover diverse biological processes such as transcription/translation, metabolism, detoxification, olfaction, vision, cuticle regulation, and immunity, and include rate-limiting steps in the pathways. This study highlights the fundamental roles that both the circadian clock and light play in the physiology of this important insect vector and suggests targets for intervention.

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mentioning

confidence: 99%

Genome-wide profiling of diel and circadian gene expression in the malaria vector Anopheles gambiae

Rund

Hou

Ward

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

168

269

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“…These results indicate that, instead of a photoreceptor in the central pacemaker, CRY1 functions as a core component in these peripheral oscillators [112]. Unlike these, however, another peripheral rhythm, which was recently found in the cuticle deposition, persisted in cry mutant flies [113]. Thus, there are at least two kinds of circadian molecular machinery in peripheral oscillators: one that requires CRY1 as an essential component, and the other that includes it just as a photoreceptor.…”

Section: Peripheral Oscillatorsmentioning

confidence: 83%

A comparative view of insect circadian clock systems

Tomioka

Matsumoto

2009

Cell. Mol. Life Sci.

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139

109

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Recent studies revealed that the neuronal network controlling overt rhythms shows striking similarity in various insect orders. The pigment-dispersing factor seems commonly involved in regulating locomotor activity. However, there are considerable variations in the molecular oscillatory mechanism, and input and output pathways among insects. In Drosophila, autoregulatory negative feedback loops that consist of clock genes, such as period and timeless are believed to create 24-h rhythmicity. Although similar clock genes have been found in some insects, the behavior of their product proteins shows considerable differences from that of Drosophila. In other insects, mammalian-type cryptochrome (cry2) seems to work as a transcriptional repressor in the feedback loop. For photic entrainment, Drosophila type cryptochrome (cry1) plays the major role in Drosophila while the compound eyes are the major photoreceptor in others. Further comparative study will be necessary to understand how this variety of clock mechanisms derived from an ancestral one.

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“…Even the rhythms of cultured body parts are synchronized by LD cycles , showing that the underlying peripheral oscillators are cell autonomous and photo responsive. Light entrains these oscillators directly, probably via CRY (Ivanchenko et al 2001;Ito et al 2008) (see Sect. 18.6.4).…”

Section: Locomotor Activity and Sleep Are Controlled By Several Circamentioning

confidence: 99%

How Light Resets Circadian Clocks

2014

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The daily revolutions of the earth around its axis are responsible for day and night and its annual orbit around the sun for the seasons with their fluctuations in day length. Most organisms have adapted to these diurnal and annual cycles. The strategies and mechanisms used are quite delicate and complicated.It came as a surprise that photosynthesis and many other processes are, however, additionally controlled by internal clocks. Thus, photosynthesis fluctuates not only during the daily light-dark cycle (=LD; see the List of Abbreviations and http://www.circadian.org/dictionary.html) but also when the plants are kept under LL and constant temperature (Hennessey and Field 1991). However, the period length (period for short) of this rhythmic event then deviates from exactly 24 h and is therefore called circadian (from Latin circa, about, and dies, day). If in the absence of LD and temperature cycles other 24 h time cues (also called zeitgeber, German for time giver) would control the rhythm, it should show an exact 24 h rhythm. This is not the case, demonstrating the endogenous nature of a clock that is locked to light signals (see Fig. 18.1). Spectrum of RhythmsEndogenous rhythms of organisms are not only tuned to the daily cycle of 24 h. The range of rhythms found in organisms covers ultradian (with periods of several hours to very short ones), circadian, and annual (with periods of about a year) rhythms. Other rhythms such as tidal, 14-day, and monthly ones cope with influences of the moon on the earth, mainly on the water movements of the oceans, and they are therefore found in organisms at the coasts and in the sea. Annual rhythms interact with the day-length changes during the year (see below). There are furthermore rhythms with periods covering several years. The following discussion of a "biological clock" is restricted to circadian rhythms. Even they are often not just composed of one clock type but form a "circadian system" consisting of two or more clocks with different prop- Function of Circadian ClocksThe term "clock" usually implies a time-measuring device or function. For instance, the day length (or night length) can be determined by an organism. Since day length is a function of the time of the year (long days in summer, short days in winter), it can be used to time certain events such as flowering or tuber formation of a plant or breeding of birds and mammals during the most appropriate season. These processes are denoted photoperiodism (see Chap. 19).However, a clock can also be used to set a certain temporal order. For instance, the circadian control of our sleepwake cycle ensures that we rise in the morning and fall asleep in the evening at a preferred time. Food intake and digestion are likewise controlled by this clock and gated to certain times of the day (Silver et al. 2011;Duguay and Cermakian 2009;Forsgren 1935). The circadian clock will time these events also under constant conditions. Furthermore, circadian clocks can serve as alarm clocks.

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Peripheral circadian clock for the cuticle deposition rhythm in Drosophila melanogaster

Cited by 58 publications

References 45 publications

Genome-wide profiling of diel and circadian gene expression in the malaria vector Anopheles gambiae

Genome-wide profiling of diel and circadian gene expression in the malaria vector Anopheles gambiae

A comparative view of insect circadian clock systems

How Light Resets Circadian Clocks

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