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4. 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

9. A Detailed Re-Examination of the Period Gene Rescue Experiments Shows That Four to Six Cryptochrome-Positive Posterior Dorsal Clock Neurons (DN1p) of Drosophila melanogaster Can Control Morning and Evening Activity.

Author

Sekiguchi, Manabu, Reinhard, Nils, Fukuda, Ayumi, Katoh, Shun, Rieger, Dirk, Helfrich-Förster, Charlotte, and Yoshii, Taishi

Subjects
DROSOPHILA melanogaster, FRUIT flies, CRYPTOCHROMES, GENE expression, CELL physiology
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-period16 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-LNv) is responsible for controlling the M peak, while the other group, consisting of the 5th ventrolateral neuron (5th LNv) and the three cryptochrome (CRY)-positive dorsolateral neurons (LNd), is responsible for the E peak. Furthermore, the group of posterior dorsal neurons 1 (DN1p) 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 DN1p 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. [ABSTRACT FROM AUTHOR]

Published
2024
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13. Pigment-dispersing factor and CCHamide1 in the Drosophila circadian clock network

Author

Kuwano, Riko, Katsura, Maki, Iwata, Mai, Yokosako, Tatsuya, and Yoshii, Taishi

Subjects
Neuropeptide, neural network, Physiology, Physiology (medical), clock protein, masking effect, activity rhythm
Abstract

Animals possess a circadian central clock in the brain, where circadian behavioural rhythms are generated. In the fruit fly (Drosophila melanogaster), the central clock comprises a network of approximately 150 clock neurons, which is important for the maintenance of a coherent and robust rhythm. Several neuropeptides involved in the network have been identified, including Pigment-dispersing factor (PDF) and CCHamide1 (CCHa1) neuropeptides. PDF signals bidirectionally to CCHa1-positive clock neurons; thus, the clock neuron groups expressing PDF and CCHa1 interact reciprocally. However, the role of these interactions in molecular and behavioural rhythms remains elusive. In this study, we generated Pdf (01) and CCHa1(SK8) double mutants and examined their locomotor activity-related rhythms. The single mutants of Pdf (01) or CCHa1(SK8) displayed free-running rhythms under constant dark conditions, whereas approximately 98% of the double mutants were arrhythmic. In light-dark conditions, the evening activity of the double mutants was phase-advanced compared with that of the single mutants. In contrast, both the single and double mutants had diminished morning activity. These results suggest that the effects of the double mutation varied in behavioural parameters. The double and triple mutants of per (01), Pdf (01), and CCHa1(SK8) further revealed that PDF signalling plays a role in the suppression of activity during the daytime under a clock-less background. Our results provide insights into the interactions between PDF and CCHa1 signalling and their roles in activity rhythms.

Published
2023
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15. Synaptic and peptidergic connectomes of the Drosophila circadian clock

Author

Reinhard, Nils, primary, Fukuda, Ayumi, additional, Manoli, Giulia, additional, Derksen, Emilia, additional, Saito, Aika, additional, Möller, Gabriel, additional, Sekiguchi, Manabu, additional, Rieger, Dirk, additional, Helfrich-Förster, Charlotte, additional, Yoshii, Taishi, additional, and Zandawala, Meet, additional

Published
2023
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19. Improved home BP profile with dapagliflozin is associated with amelioration of albuminuria in Japanese patients with diabetic nephropathy: the Yokohama add-on inhibitory efficacy of dapagliflozin on albuminuria in Japanese patients with type 2 diabetes study (Y-AIDA study)

Author

Kinguchi, Sho, Wakui, Hiromichi, Ito, Yuzuru, Kondo, Yoshinobu, Azushima, Kengo, Osada, Uru, Yamakawa, Tadashi, Iwamoto, Tamio, Yutoh, Jun, Misumi, Toshihiro, Aoki, Kazutaka, Yasuda, Gen, Yoshii, Taishi, Yamada, Takayuki, Ono, Syuji, Shibasaki-Kurita, Tomoko, Hosokawa, Saho, Orime, Kazuki, Hanaoka, Masaaki, Sasaki, Hiroto, Inazumi, Kohji, Yamada, Taku, Kobayashi, Ryu, Ohki, Kohji, Haruhara, Kotaro, Kobayashi, Yusuke, Yamanaka, Takeharu, Terauchi, Yasuo, and Tamura, Kouichi

Published
2019
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25. Artificial selections for death-feigning behavior in beetles show correlated responses in amplitude of circadian rhythms, but the period of the rhythm does not

Author

Miyatake, Takahisa, S. Abe, Masato, Matsumura, Kentarou, Yoshii, Taishi, Miyatake, Takahisa, S. Abe, Masato, Matsumura, Kentarou, and Yoshii, Taishi

Abstract

One of the most important survival strategies of organisms is to avoid predators. Studying one of such strategies, namely, death-feigning behavior, has recently become more common. The success or failure of this antipredator strategy will be affected by the circadian rhythms of both prey and predator because death feigning sometimes has a diurnal rhythm. However, few studies have analyzed the effects of differences in circadian rhythms on predator-avoidance behavior at the genetic level. Recently, the relationship between genes relating to circadian rhythm and death-feigning behavior, an antipredator behavior, has been established at the molecular level. Therefore, in this study, we compared three circadian rhythm-related traits, the free-running period of rhythms, amplitude of circadian rhythms, and total activity of strains of three Tribolium species that were artificially selected for the death-feigning duration: short (S-strains) and long (L-strains) durations. As a result, the amplitude of circadian rhythms and total activity were significantly different between S- and L-strains, but there was no difference in the free-running periods of the rhythm between the strains in T. castaneum, T. confusum, and T. freemani. Although the relationship between death-feigning behavior and activity has been reported for all three species, a genetic relationship between the duration of death feigning and the amplitude of circadian rhythms has been newly found in the present study. It is important to investigate the relationship between antipredator strategies and circadian rhythms at the molecular level in the future.

Published
2022

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

Author

Abe, Masato S., Matsumura, Kentarou, Yoshii, Taishi, Miyatake, Takahisa, Abe, Masato S., Matsumura, Kentarou, Yoshii, Taishi, and Miyatake, Takahisa

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.

Published
2021

33. Antibodies against the clock proteins period and cryptochrome reveal the neuronal organization of the circadian clock in the pea aphid

Author

European Commission, European Research Council, Japan Society for the Promotion of Science, Universität Würzburg, Colizzi, Francesca Sara, Beer, Katharina, Cuti, Paolo, Deppisch, Peter, Martínez Torres, David, Yoshii, Taishi, Helfrich-Förster, Charlotte, European Commission, European Research Council, Japan Society for the Promotion of Science, Universität Würzburg, Colizzi, Francesca Sara, Beer, Katharina, Cuti, Paolo, Deppisch, Peter, Martínez Torres, David, Yoshii, Taishi, and Helfrich-Förster, Charlotte

Abstract

Circadian clocks prepare the organism to cyclic environmental changes in light, temperature, or food availability. Here, we characterized the master clock in the brain of a strongly photoperiodic insect, the aphid Acyrthosiphon pisum, immunohistochemically with antibodies against A. pisum Period (PER), Drosophila melanogaster Cryptochrome (CRY1), and crab Pigment-Dispersing Hormone (PDH). The latter antibody detects all so far known PDHs and PDFs (Pigment-Dispersing Factors), which play a dominant role in the circadian system of many arthropods. We found that, under long days, PER and CRY are expressed in a rhythmic manner in three regions of the brain: the dorsal and lateral protocerebrum and the lamina. No staining was detected with anti-PDH, suggesting that aphids lack PDF. All the CRY1-positive cells co-expressed PER and showed daily PER/CRY1 oscillations of high amplitude, while the PER oscillations of the CRY1-negative PER neurons were of considerable lower amplitude. The CRY1 oscillations were highly synchronous in all neurons, suggesting that aphid CRY1, similarly to Drosophila CRY1, is light sensitive and its oscillations are synchronized by light-dark cycles. Nevertheless, in contrast to Drosophila CRY1, aphid CRY1 was not degraded by light, but steadily increased during the day and decreased during the night. PER was always located in the nuclei of the clock neurons, while CRY was predominantly cytoplasmic and revealed the projections of the PER/CRY1-positive neurons. We traced the PER/CRY1-positive neurons through the aphid protocerebrum discovering striking similarities with the circadian clock of D. melanogaster: The CRY1 fibers innervate the dorsal and lateral protocerebrum and putatively connect the different PER-positive neurons with each other. They also run toward the pars intercerebralis, which controls hormone release via the neurohemal organ, the corpora cardiaca. In contrast to Drosophila, the CRY1-positive fibers additionally travel directly

Published
2021

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

Author

Yoshii, Taishi, Fujii, Kana, and Tomioka, Kenji

Subjects
Temperature -- Research -- Testing -- Analysis, Messenger RNA -- Research -- Analysis, Circadian rhythms -- Research -- Analysis, Drosophila -- Research -- Analysis, Biological sciences, Testing, Analysis, Research
Abstract

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 [...]

Published
2007

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

Author

Fernandez-Chiappe, Florencia, primary, Hermann-Luibl, Christiane, additional, Peteranderl, Alina, additional, Reinhard, Nils, additional, Senthilan, Pingkalai R., additional, Hieke, Marie, additional, Selcho, Mareike, additional, Yoshii, Taishi, additional, Shafer, Orie T., additional, Muraro, Nara I., additional, and Helfrich-Förster, Charlotte, additional

Published
2020
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44. The Circadian Clock Improves Fitness in the Fruit Fly, Drosophila melanogaster

Author

Horn, Melanie, Mitesser, Oliver, Hovestadt, Thomas, Yoshii, Taishi, Rieger, Dirk, and Helfrich-Förster, Charlotte

Subjects
fertility, lcsh:QP1-981, ddc:570, mating preference, fungi, resonance theory, competition, period mutants, lcsh:Physiology
Abstract

It is assumed that a properly timed circadian clock enhances fitness, but only few studies have truly demonstrated this in animals. We raised each of the three classical Drosophila period mutants for >50 generations in the laboratory in competition with wildtype flies. The populations were either kept under a conventional 24-h day or under cycles that matched the mutant’s natural cycle, i.e., a 19-h day in the case of pers mutants and a 29-h day for perl mutants. The arrhythmic per0 mutants were grown together with wildtype flies under constant light that renders wildtype flies similar arrhythmic as the mutants. In addition, the mutants had to compete with wildtype flies for two summers in two consecutive years under outdoor conditions. We found that wildtype flies quickly outcompeted the mutant flies under the 24-h laboratory day and under outdoor conditions, but perl mutants persisted and even outnumbered the wildtype flies under the 29-h day in the laboratory. In contrast, pers and per0 mutants did not win against wildtype flies under the 19-h day and constant light, respectively. Our results demonstrate that wildtype flies have a clear fitness advantage in terms of fertility and offspring survival over the period mutants and – as revealed for perl mutants – this advantage appears maximal when the endogenous period resonates with the period of the environment. However, the experiments indicate that perl and pers persist at low frequencies in the population even under the 24-h day. This may be a consequence of a certain mating preference of wildtype and heterozygous females for mutant males and time differences in activity patterns between wildtype and mutants.

Published
2019
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50. A Catalog of GAL4 Drivers for Labeling and Manipulating Circadian Clock Neurons in Drosophila melanogaster.

Author

Sekiguchi, Manabu, Inoue, Kotaro, Yang, Tian, Luo, Dong-Gen, and Yoshii, Taishi

Subjects
DROSOPHILA melanogaster, SUPRACHIASMATIC nucleus, NEURONS, CLOCKS & watches, DROSOPHILA, CATALOGS
Abstract

Daily rhythms of physiology, metabolism, and behavior are orchestrated by a central circadian clock. In mice, this clock is coordinated by the suprachiasmatic nucleus, which consists of 20,000 neurons, making it challenging to characterize individual neurons. In Drosophila, the clock is controlled by only 150 clock neurons that distribute across the fly's brain. Here, we describe a comprehensive set of genetic drivers to facilitate individual characterization of Drosophila clock neurons. We screened GAL4 lines that were obtained from Drosophila stock centers and identified 63 lines that exhibit expression in subsets of central clock neurons. Furthermore, we generated split-GAL4 lines that exhibit specific expression in subsets of clock neurons such as the 2 DN2 neurons and the 6 LPN neurons. Together with existing driver lines, these newly identified ones are versatile tools that will facilitate a better understanding of the Drosophila central circadian clock. [ABSTRACT FROM AUTHOR]

Published
2020
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