In synch but not in step: Circadian clock circuits regulating plasticity in daily rhythms

AbstractLife on earth adapted to the daily reoccurring changes in environment by evolving an endogenous circadian clock. Although the circadian clock has a crucial impact on survival and behavior of solitary bees, many aspects of solitary bee clock mechanisms remain unknown. Our study is the first to show that the circadian clock governs emergence in Osmia bicornis, a bee species which overwinters as adult inside its cocoon. Therefore, its eclosion from the pupal case is separated by an interjacent diapause from its emergence in spring. We show that this bee species synchronizes its emergence to the morning. The daily rhythms of emergence are triggered by temperature cycles but not by light cycles. In contrast to this, the bee’s daily rhythms in locomotion are synchronized by light cycles. Thus, we show that the circadian clock of O. bicornis is set by either temperature or light, depending on what activity is timed. Light is a valuable cue for setting the circadian clock when bees have left the nest. However, for pre-emerged bees, temperature is the most important cue, which may represent an evolutionary adaptation of the circadian system to the cavity-nesting life style of O. bicornis.

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Daily rhythms in gene expression of the human parasite Schistosoma mansoni

BMC Biology ◽

10.1186/s12915-021-01189-9 ◽

2021 ◽

Vol 19 (1) ◽

Author(s):

Kate A. Rawlinson ◽

Adam J. Reid ◽

Zhigang Lu ◽

Patrick Driguez ◽

Anna Wawer ◽

...

Keyword(s):

Gene Expression ◽

Schistosoma Mansoni ◽

Circadian Clock ◽

Drug Targets ◽

Clock Genes ◽

Biological Rhythms ◽

Active Phase ◽

Egg Laying ◽

Daily Rhythms ◽

Metazoan Parasites

Abstract Background The consequences of the earth’s daily rotation have led to 24-h biological rhythms in most organisms. Even some parasites are known to have daily rhythms, which, when in synchrony with host rhythms, can optimise their fitness. Understanding these rhythms may enable the development of control strategies that take advantage of rhythmic vulnerabilities. Recent work on protozoan parasites has revealed 24-h rhythms in gene expression, drug sensitivity and the presence of an intrinsic circadian clock; however, similar studies on metazoan parasites are lacking. To address this, we investigated if a metazoan parasite has daily molecular oscillations, whether they reveal how these longer-lived organisms can survive host daily cycles over a lifespan of many years and if animal circadian clock genes are present and rhythmic. We addressed these questions using the human blood fluke Schistosoma mansoni that lives in the vasculature for decades and causes the tropical disease schistosomiasis. Results Using round-the-clock transcriptomics of male and female adult worms collected from experimentally infected mice, we discovered that ~ 2% of its genes followed a daily pattern of expression. Rhythmic processes included a stress response during the host’s active phase and a ‘peak in metabolic activity’ during the host’s resting phase. Transcriptional profiles in the female reproductive system were mirrored by daily patterns in egg laying (eggs are the main drivers of the host pathology). Genes cycling with the highest amplitudes include predicted drug targets and a vaccine candidate. These 24-h rhythms may be driven by host rhythms and/or generated by a circadian clock; however, orthologs of core clock genes are missing and secondary clock genes show no 24-h rhythmicity. Conclusions There are daily rhythms in the transcriptomes of adult S. mansoni, but they appear less pronounced than in other organisms. The rhythms reveal temporally compartmentalised internal processes and host interactions relevant to within-host survival and between-host transmission. Our findings suggest that if these daily rhythms are generated by an intrinsic circadian clock then the oscillatory mechanism must be distinct from that in other animals. We have shown which transcripts oscillate at this temporal scale and this will benefit the development and delivery of treatments against schistosomiasis.

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The Circadian Clock, the Brain, and COVID-19: The Cases of Olfaction and the Timing of Sleep

Journal of Biological Rhythms ◽

10.1177/07487304211031206 ◽

2021 ◽

pp. 074873042110312

Author(s):

Rachel S. Herz ◽

Erik D. Herzog ◽

Martha Merrow ◽

Sara B. Noya

Keyword(s):

Ischemic Stroke ◽

Cognitive Function ◽

Human Brain ◽

Circadian Clock ◽

Clinical Data ◽

Circadian Clocks ◽

Olfactory Sensitivity ◽

Daily Rhythms ◽

Sense Of Smell ◽

The Brain

Daily rhythms of behavior and neurophysiology are integral to the circadian clocks of all animals. Examples of circadian clock regulation in the human brain include daily rhythms in sleep-wake, cognitive function, olfactory sensitivity, and risk for ischemic stroke, all of which overlap with symptoms displayed by many COVID-19 patients. Motivated by the relatively unexplored, yet pervasive, overlap between circadian functions and COVID-19 neurological symptoms, this perspective piece uses daily variations in the sense of smell and the timing of sleep and wakefulness as illustrative examples. We propose that time-stamping clinical data and testing may expand and refine diagnosis and treatment of COVID-19.

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The Circadian Clock, Light, and Cryptochrome Regulate Feeding and Metabolism in Drosophila

Journal of Biological Rhythms ◽

10.1177/0748730411420080 ◽

2011 ◽

Vol 26 (6) ◽

pp. 497-506 ◽

Cited By ~ 30

Author(s):

Daniel J. Seay ◽

Carl S. Thummel

Keyword(s):

Circadian Clock ◽

Feeding Behavior ◽

Critical Role ◽

Fruit Fly ◽

Lipid Homeostasis ◽

Dependent Manner ◽

Daily Rhythms ◽

Circadian Control ◽

Carbohydrate Levels ◽

Feeding Bout

Recent studies in mammals have demonstrated a central role for the circadian clock in maintaining metabolic homeostasis. In spite of these advances, however, little is known about how these complex pathways are coordinated. Here, we show that fundamental aspects of the circadian control of metabolism are conserved in the fruit fly Drosophila. We assay feeding behavior and basic metabolite levels in individual flies and show that, like mammals, Drosophila display a rapid increase in circulating sugar following a meal, which is subsequently stored in the form of glycogen. These daily rhythms in carbohydrate levels are disrupted in clock mutants, demonstrating a critical role for the circadian clock in the postprandial response to feeding. We also show that basic metabolite levels are coordinated in a clock-dependent manner and that clock function is required to maintain lipid homeostasis. By examining feeding behavior, we show that flies feed primarily during the first 4 hours of the day and that light suppresses a late day feeding bout through the cryptochrome photoreceptor. These studies demonstrate that central aspects of feeding and metabolism are dependent on the circadian clock in Drosophila. Our work also uncovers novel roles for light and cryptochrome on both feeding behavior and metabolism.

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Resynchronization Dynamics Reveal that the Ventral Entrains the Dorsal Suprachiasmatic Nucleus

Journal of Biological Rhythms ◽

10.1177/0748730416680904 ◽

2016 ◽

Vol 32 (1) ◽

pp. 35-47 ◽

Cited By ~ 10

Author(s):

Stephanie R. Taylor ◽

Thomas J. Wang ◽

Daniel Granados-Fuentes ◽

Erik D. Herzog

Keyword(s):

Circadian Clock ◽

Computational Model ◽

Suprachiasmatic Nucleus ◽

Computational Methods ◽

Direct Evidence ◽

Cell Communication ◽

Experimental Results ◽

Daily Rhythms ◽

Phase Amplitude ◽

Cell Cell

Although the suprachiasmatic nucleus (SCN) has long been considered the master circadian clock in mammals, the topology of the connections that synchronize daily rhythms among SCN cells is not well understood. We combined experimental and computational methods to infer the directed interactions that mediate circadian synchrony between regions of the SCN. We analyzed PERIOD2 (PER2) expression from SCN slices during and after treatment with tetrodotoxin, allowing us to map connections as cells resynchronized their daily cycling following blockade and restoration of cell-cell communication. Using automated analyses, we found that cells in the dorsal SCN stabilized their periods slower than those in the ventral SCN. A phase-amplitude computational model of the SCN revealed that, to reproduce the experimental results: (1) the ventral SCN had to be more densely connected than the dorsal SCN and (2) the ventral SCN needed strong connections to the dorsal SCN. Taken together, these results provide direct evidence that the ventral SCN entrains the dorsal SCN in constant conditions.

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Daily rhythms of food-anticipatory behavioral activity do not require the known circadian clock

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.0902063106 ◽

2009 ◽

Vol 106 (16) ◽

pp. 6808-6813 ◽

Cited By ~ 151

Author(s):

K.-F. Storch ◽

C. J. Weitz

Keyword(s):

Circadian Clock ◽

Behavioral Activity ◽

Daily Rhythms

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Circadian rhythm and neurodegenerative disorders

Brain Science Advances ◽

10.26599/bsa.2020.9050006 ◽

2020 ◽

Vol 6 (2) ◽

pp. 71-80

Author(s):

Michelle Werdann ◽

Yong Zhang

Keyword(s):

Circadian Rhythm ◽

Early Intervention ◽

Circadian Rhythms ◽

Neurodegenerative Diseases ◽

Circadian Clock ◽

Neurodegenerative Disorders ◽

Circadian Clocks ◽

Daily Rhythms ◽

Animal Physiology ◽

And Behavior

The circadian clock controls daily rhythms in animal physiology, metabolism, and behavior, such as the sleep‐wake cycle. Disruption of circadian rhythms has been revealed in many diseases including neurodegenerative disorders. Interestingly, patients with many neurodegenerative diseases often show problems with circadian clocks even years before other symptoms develop. Here we review the recent studies identifying the association between circadian rhythms and several major neurodegenerative disorders. Early intervention of circadian rhythms may benefit the treatment of neurodegeneration.

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Ticking over: Circadian systems across the kingdoms of life

The Biochemist ◽

10.1042/bio03301012 ◽

2011 ◽

Vol 33 (1) ◽

pp. 12-15

Author(s):

Neil Dalchau ◽

Alex A.R. Webb

Keyword(s):

Circadian Clock ◽

Model Organisms ◽

Molecular Architecture ◽

General Phenomenon ◽

Daily Rhythms ◽

Fitness Benefits ◽

Multidisciplinary Studies ◽

The Many

The ability to anticipate the day–night cycle and direct physiology accordingly has proven to be a general phenomenon across all kingdoms of life. Considerable fitness benefits are conferred by an internal 24hour clock, which is known as a circadian clock. Extensive multidisciplinary studies in a range of model organisms have elucidated many of the components involved in generating and sustaining daily rhythms. When comparing the circadian systems across the kingdoms, it is fascinating to observe the commonalities and differences in their molecular architecture, and the many adaptations which have evolved to deal with organismspecific requirements of biological timing.

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Insect circadian clock outputs

Essays in Biochemistry ◽

10.1042/bse0490087 ◽

2011 ◽

Vol 49 ◽

pp. 87-101 ◽

Cited By ~ 13

Author(s):

Charlotte Helfrich-Förster ◽

Michael N. Nitabach ◽

Todd C Holmes

Keyword(s):

Circadian Clock ◽

Local Environment ◽

Circadian Rhythmicity ◽

The Other ◽

Environmental Cues ◽

Daily Rhythms ◽

Sun Compass ◽

Small Areas ◽

Other Hand ◽

Navigational Systems

Insects display an impressive variety of daily rhythms, which are most evident in their behaviour. Circadian timekeeping systems that generate these daily rhythms of physiology and behaviour all involve three interacting elements: the timekeeper itself (i.e. the clock), inputs to the clock through which it entrains and otherwise responds to environmental cues such as light and temperature, and outputs from the clock through which it imposes daily rhythms on various physiological and behavioural parameters. In insects, as in other animals, cellular clocks are embodied in clock neurons capable of sustained autonomous circadian rhythmicity, and those clock neurons are organized into clock circuits. Drosophila flies spend their entire lives in small areas near the ground, and use their circadian brain clock to regulate daily rhythms of rest and activity, so as to organize their behaviour appropriately to the daily rhythms of their local environment. Migratory locusts and butterflies, on the other hand, spend substantial portions of their lives high up in the air migrating long distances (sometimes thousands of miles) and use their circadian brain clocks to provide time-compensation to their sun-compass navigational systems. Interestingly, however, there appear to be substantial similarities in the cellular and network mechanisms that underlie circadian outputs in all insects.

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