scholarly journals Roles of circadian clocks in cancer pathogenesis and treatment

2021 ◽  
Author(s):  
Yool Lee
Keyword(s):  
Circadian Rhythms ◽  
Cancer Treatment ◽  
Internal Clock ◽  
Circadian Clocks ◽  
Cancer Pathways ◽  
Cancer Pathogenesis ◽  
Timing Mechanisms ◽  
Living Species ◽  
Living Organisms ◽  
Daily Changes

AbstractCircadian clocks are ubiquitous timing mechanisms that generate approximately 24-h rhythms in cellular and bodily functions across nearly all living species. These internal clock systems enable living organisms to anticipate and respond to daily changes in their environment in a timely manner, optimizing temporal physiology and behaviors. Dysregulation of circadian rhythms by genetic and environmental risk factors increases susceptibility to multiple diseases, particularly cancers. A growing number of studies have revealed dynamic crosstalk between circadian clocks and cancer pathways, providing mechanistic insights into the therapeutic utility of circadian rhythms in cancer treatment. This review will discuss the roles of circadian rhythms in cancer pathogenesis, highlighting the recent advances in chronotherapeutic approaches for improved cancer treatment.

Circadian Rhythms, Disease and Chronotherapy

2021 ◽  
pp. 074873042110443
Author(s):  
Yool Lee ◽  
Jeffrey M. Field ◽  
Amita Sehgal
Keyword(s):  
Circadian Rhythms ◽  
Circadian Clocks ◽  
Cellular Mechanisms ◽  
Medical Interventions ◽  
Timing Mechanisms ◽  
Parasite Infections ◽  
Circadian Physiology ◽  
And Behavior ◽  
Internal Body

Circadian clocks are biological timing mechanisms that generate 24-h rhythms of physiology and behavior, exemplified by cycles of sleep/wake, hormone release, and metabolism. The adaptive value of clocks is evident when internal body clocks and daily environmental cycles are mismatched, such as in the case of shift work and jet lag or even mistimed eating, all of which are associated with physiological disruption and disease. Studies with animal and human models have also unraveled an important role of functional circadian clocks in modulating cellular and organismal responses to physiological cues (ex., food intake, exercise), pathological insults (e.g. virus and parasite infections), and medical interventions (e.g. medication). With growing knowledge of the molecular and cellular mechanisms underlying circadian physiology and pathophysiology, it is becoming possible to target circadian rhythms for disease prevention and treatment. In this review, we discuss recent advances in circadian research and the potential for therapeutic applications that take patient circadian rhythms into account in treating disease.

Circadian rhythms in a nutshell

2000 ◽  
Vol 3 (2) ◽  
pp. 59-74 ◽  
Author(s):  
ISAAC EDERY
Keyword(s):  
Circadian Rhythms ◽  
Molecular Mechanisms ◽  
The Elderly ◽  
Life Forms ◽  
Circadian Clocks ◽  
Model Systems ◽  
Circadian Timing System ◽  
Environmental Transitions ◽  
Rotation Of The Earth ◽  
Living Organisms

Edery, Isaac. Circadian rhythms in a nutshell. Physiol Genomics 3: 59–74, 2000.—Living organisms on this planet have adapted to the daily rotation of the earth on its axis. By means of endogenous circadian clocks that can be synchronized to the daily and seasonal changes in external time cues, most notably light and temperature, life forms anticipate environmental transitions, perform activities at biologically advantageous times during the day, and undergo characteristic seasonal responses. The effects of transmeridian flight and shift work are stark reminders that although modern technologies can create “cities that never sleep” we cannot escape the recalcitrance of endogenous clocks that regulate much of our physiology and behavior. Moreover, malfunctions in the human circadian timing system are implicated in several disorders, including chronic sleep disorders in the elderly, manic-depression, and seasonal affective disorders (SAD or winter depression). Recent progress in understanding the molecular mechanisms underlying circadian rhythms has been remarkable. In its most basic form, circadian clocks are comprised of a set of proteins that, by virtue of the design principles involved, generate a self-sustaining transcriptional-translational feedback loop with a free-running period of about 24 h. One or more of the clock components is acutely sensitive to light, resulting in an oscillator that can be synchronized to local time. This review provides an overview of the roles circadian clocks play in nature, how they might have arisen, human health concerns related to clock dysfunction, and mainly focuses on the clockworks found in Drosophila and mice, the two best studied animal model systems for understanding the biochemical and cellular bases of circadian rhythms.

scholarly journals Survival is reduced when endogenous period deviates from 24 h in a non-human primate, supporting the circadian resonance theory

2020 ◽  
Vol 10 (1) ◽  
Author(s):  
Clara Hozer ◽  
Martine Perret ◽  
Samuel Pavard ◽  
Fabien Pifferi
Keyword(s):  
Circadian Rhythms ◽  
Circadian Clock ◽  
Microcebus Murinus ◽  
Circadian Period ◽  
Biological Functions ◽  
Resonance Theory ◽  
Aging Research ◽  
Mouse Lemurs ◽  
Living Organisms ◽  
Human Primate

Abstract Circadian rhythms are ubiquitous attributes across living organisms and allow the coordination of internal biological functions with optimal phases of the environment, suggesting a significant adaptive advantage. The endogenous period called tau lies close to 24 h and is thought to be implicated in individuals’ fitness: according to the circadian resonance theory, fitness is reduced when tau gets far from 24 h. In this study, we measured the endogenous period of 142 mouse lemurs (Microcebus murinus), and analyzed how it is related to their survival. We found different effects according to sex and season. No impact of tau on mortality was found in females. However, in males, the deviation of tau from 24 h substantially correlates with an increase in mortality, particularly during the inactive season (winter). These results, comparable to other observations in mice or drosophila, show that captive gray mouse lemurs enjoy better fitness when their circadian period closely matches the environmental periodicity. In addition to their deep implications in health and aging research, these results raise further ecological and evolutionary issues regarding the relationships between fitness and circadian clock.

scholarly journals Interaction between photoperiod and variation in circadian rhythms in tomato

2022 ◽  
Author(s):  
Yanli Xiang ◽  
Thomas Sapir ◽  
Pauline Rouillard ◽  
Marina Ferrand ◽  
Jose M Jimenez-Gomez
Keyword(s):  
Seasonal Variation ◽  
Circadian Rhythms ◽  
Phase Shift ◽  
Circadian Clock ◽  
Environmental Changes ◽  
Circadian Clocks ◽  
Biological Processes ◽  
Near Isogenic Lines ◽  
Transcriptomic Profiling ◽  
Isogenic Lines

Many biological processes follow circadian rhythmicity and are controlled by the circadian clock. Predictable environmental changes such as seasonal variation in photoperiod can modulate circadian rhythms, allowing organisms to adjust to the time of the year. Modification of circadian clocks is especially relevant in crops to enhance their cultivability in specific regions by changing their sensibility to photoperiod. In tomato, the appearance of mutations in EMPFINDLICHER IM DUNKELROTEN LICHT 1 (EID1, Solyc09g075080) and NIGHT LIGHT-INDUCIBLE AND CLOCK-REGULATED GENE 2 (LNK2, Solyc01g068560) during domestication delayed its circadian rhythms, and allowed its expansion outside its equatorial origin. Here we study how variation in circadian rhythms in tomato affects its perception of photoperiod. To do this, we create near isogenic lines carrying combinations of wild alleles of EID1 and LNK2 and perform transcriptomic profiling under two different photoperiods. We observe that EID1, but not LNK2, has a large effect on the tomato transcriptome and its response to photoperiod. This large effect of EID1 is likely a consequence of the global phase shift elicited by this gene in tomato's circadian rhythms.

scholarly journals Timing metabolism in cartilage and bone: links between circadian clocks and tissue homeostasis

2019 ◽  
Vol 243 (3) ◽  
pp. R29-R46 ◽  
Author(s):  
Cátia F Gonçalves ◽  
Qing-Jun Meng
Keyword(s):  
Rheumatoid Arthritis ◽  
Circadian Rhythms ◽  
Circadian System ◽  
Tissue Homeostasis ◽  
Circadian Clocks ◽  
Clock System ◽  
Metabolic Functions ◽  
Biochemical Mechanisms ◽  
Skeletal Disorders ◽  
Bone Physiology

The circadian system in mammals is responsible for the temporal coordination of multiple physiological and behavioural processes that are necessary for homeostasis. In the skeleton, it has long been known that metabolic functions of chondrocytes, osteoblasts and osteoclasts exhibit intrinsic circadian rhythms. In addition, results from animal models reveal a close connection between the disruption of circadian rhythms and skeletal disorders such as rheumatoid arthritis, osteoarthritis and osteoporosis. In this review, we summarise the latest insights into the genetic and biochemical mechanisms linking cartilage and bone physiology to the circadian clock system. We also discuss how this knowledge can be utilised to improve human health.

scholarly journals The Kidney Clock Contributes to Timekeeping by the Master Circadian Clock

2019 ◽  
Vol 20 (11) ◽  
pp. 2765 ◽  
Author(s):  
Jihwan Myung ◽  
Mei-Yi Wu ◽  
Chun-Ya Lee ◽  
Amalia Ridla Rahim ◽  
Vuong Hung Truong ◽  
...  
Keyword(s):  
Circadian Rhythms ◽  
Sleep Disturbances ◽  
The Body ◽  
Circadian Clocks ◽  
Whole Body ◽  
The Hierarchical Structure ◽  
Body Level ◽  
The Brain ◽  
Master Clock

The kidney harbors one of the strongest circadian clocks in the body. Kidney failure has long been known to cause circadian sleep disturbances. Using an adenine-induced model of chronic kidney disease (CKD) in mice, we probe the possibility that such sleep disturbances originate from aberrant circadian rhythms in kidney. Under the CKD condition, mice developed unstable behavioral circadian rhythms. When observed in isolation in vitro, the pacing of the master clock, the suprachiasmatic nucleus (SCN), remained uncompromised, while the kidney clock became a less robust circadian oscillator with a longer period. We find this analogous to the silencing of a strong slave clock in the brain, the choroid plexus, which alters the pacing of the SCN. We propose that the kidney also contributes to overall circadian timekeeping at the whole-body level, through bottom-up feedback in the hierarchical structure of the mammalian circadian clocks.

PREMONition: An algorithm for predicting the circadian clock-regulated molecular network

2018 ◽  
Author(s):  
Jasper Bosman ◽  
Zheng Eelderink-Chen ◽  
Emma Laing ◽  
Martha Merrow
Keyword(s):  
Circadian Clock ◽  
Clock Gene ◽  
Clock Genes ◽  
Circadian Clocks ◽  
Model Systems ◽  
Functional Relationships ◽  
Growth Assay ◽  
Living Organisms ◽  
Clock Mechanism ◽  
Transcriptional Feedback

AbstractA transcriptional feedback loop is central to clock function in animals, plants and fungi. The clock genes involved in its regulation are specific to - and highly conserved within - the kingdoms of life. However, other shared clock mechanisms, such as phosphorylation, are mediated by proteins found broadly among living organisms, performing functions in many cellular sub-systems. Use of homology to directly infer involvement/association with the clock mechanism in new, developing model systems, is therefore of limited use. Here we describe the approach PREMONition,PREdictingMolecularNetworks, that uses functional relationships to predict molecular circadian clock associations. PREMONition is based on the incorporation of proteins encoded by known clock genes (when available), rhythmically expressed clock-controlled genes and non-rhythmically expressed but interacting genes into a cohesive network. After tuning PREMONition on the networks derived for human, fly and fungal circadian clocks, we deployed the approach to predict a molecular clock network forSaccharomyces cerevisiae, for which there are no readily-identifiable clock gene homologs. The predicted network was validated using gene expression data and a growth assay for sensitivity to light, a zeitgeber of circadian clocks of most organisms. PREMONition may be used to identify candidate clock-regulated processes and thus candidate clock genes in other organisms.

Central regulation of photosensitive membrane turnover in the lateral eye of Limulus. I. Octopamine primes the retina for daily transient rhabdom shedding

2002 ◽  
Vol 19 (3) ◽  
pp. 283-297 ◽  
Author(s):  
RASHMI V. KHADILKAR ◽  
JOHN R. MYTINGER ◽  
LAURA E. THOMASON ◽  
SCOTT L. RUNYON ◽  
KEVIN J. WASHICOSKY ◽  
...  
Keyword(s):  
Optic Nerve ◽  
Circadian Rhythms ◽  
Internal Control ◽  
Circadian Clocks ◽  
Central Regulation ◽  
Membrane Turnover ◽  
Complex Interactions ◽  
Lateral Eye ◽  
Central Clock

Limulus lateral eyes shed and renew a portion of their photosensitive membrane (rhabdom) daily. Shedding, in many species including Limulus, is regulated by complex interactions between circadian rhythms and light. Little is known about how circadian clocks and photoreceptors communicate to regulate shedding. Limulus photoreceptors do not contain an endogenous circadian oscillator, but rely upon efferent outflow from a central clock for circadian timing. To investigate whether the putative efferent neurotransmitter octopamine (OA) communicates circadian rhythms that prime the lateral eye for transient rhabdom shedding, we decoupled photoreceptors from the clock by transecting the lateral optic nerve (contains the retinal efferent fibers). Overnight (6 h) intraretinal injections of 40 μM OA restored transient shedding to lateral eyes with transected nerves to levels comparable to those of intact internal control eyes. To determine whether OA acts alone in communicating circadian rhythms that prime the lateral eye for transient shedding, we “primed” eyes with intact nerves for transient shedding with exogenous OA during subjective day. In nature, lateral eyes shed their rhabdoms only once a day at dawn following overnight efferent priming. Eyes in animals placed in darkness during subjective day, when the retinal efferents are quiescent, and injected for 6 h with 40 μM OA shed their rhabdoms in response to a second introduction to light. Untreated control eyes of the same animals did not. The same results were observed in vitro in lateral eyes treated similarly. Octopamine is the only efferent neurotransmitter/messenger required to make lateral eyes competent for transient shedding. Phentolamine, an OA receptor antagonist, reduced the number of photoreceptors primed for transient shedding and the amount of rhabdom shed in those photoreceptors suggesting that OA acts via a specific OA receptor.

scholarly journals Clock proteins regulate spatiotemporal organization of clock genes to control circadian rhythms

2020 ◽  
Author(s):  
Yangbo Xiao ◽  
Ye Yuan ◽  
Mariana Jimenez ◽  
Neeraj Soni ◽  
Swathi Yadlapalli
Keyword(s):  
Gene Expression ◽  
Circadian Rhythms ◽  
Nuclear Envelope ◽  
Circadian Clock ◽  
Clock Genes ◽  
Circadian Clocks ◽  
Spatiotemporal Organization ◽  
Clock Proteins ◽  
Expression Behavior ◽  
Clock Protein

ABSTRACTCircadian clocks regulate ∼24 hour oscillations in gene expression, behavior, and physiology. While the molecular and neural mechanisms of circadian rhythms are well characterized, how cellular organization of clock components controls circadian clock regulation remains poorly understood. Here, we elucidate how clock proteins regulate circadian rhythms by controlling the spatiotemporal organization of clock genes. Using high-resolution live imaging techniques we demonstrate that Drosophila clock proteins are concentrated in a few discrete foci and are organized at the nuclear envelope; these results are in contrast to longstanding expectations that clock proteins are diffusely distributed in the nucleus. We also show that clock protein foci are highly dynamic and change in number, size, and localization over the circadian cycle. Further, we demonstrate that clock genes are positioned at the nuclear periphery by the clock proteins precisely during the circadian repression phase, suggesting that subnuclear localization of clock genes plays an important role in the control of rhythmic gene expression. Finally, we show that Lamin B receptor, a nuclear envelope protein, is required for peripheral localization of clock protein foci and clock genes and for normal circadian rhythms. These results reveal that clock proteins form dynamic nuclear foci and play a hitherto unexpected role in the subnuclear reorganization of clock genes to control circadian rhythms, identifying a novel mechanism of circadian regulation. Our results further suggest a new role for clock protein foci in the clustering of clock-regulated genes during the repression phase to control gene co-regulation and circadian rhythms.SIGNIFICANCEAlmost all living organisms have evolved circadian clocks to tell time. Circadian clocks regulate ∼24-hour oscillations in gene expression, behavior and physiology. Here, we reveal the surprisingly sophisticated spatiotemporal organization of clock proteins and clock genes and its critical role in circadian clock function. We show, in contrast to current expectations, that clock proteins are concentrated in a few discrete, dynamic nuclear foci at the nuclear envelope during the repression phase. Further, we uncovered several unexpected features of clock protein foci, including their role in positioning the clock genes at the nuclear envelope precisely during the repression phase to enable circadian rhythms. These studies provide fundamental new insights into the cellular mechanisms of circadian rhythms and establish direct links between nuclear organization and circadian clocks.

scholarly journals Social synchronization of circadian rhythms with a focus on honeybees

2021 ◽  
Vol 376 (1835) ◽  
pp. 20200342 ◽  
Author(s):  
Oliver Siehler ◽  
Shuo Wang ◽  
Guy Bloch
Keyword(s):  
Circadian Rhythms ◽  
Recent Literature ◽  
Good Evidence ◽  
Circadian Clocks ◽  
Self Organization ◽  
Behavioural Ecology ◽  
Theme Issue ◽  
Social Time ◽  
The Brain ◽  
Organization Models

Many animals benefit from synchronizing their daily activities with conspecifics. In this hybrid paper, we first review recent literature supporting and extending earlier evidence for a lack of clear relationship between the level of sociality and social entrainment of circadian rhythms. Social entrainment is specifically potent in social animals that live in constant environments in which some or all individuals do not experience the ambient day-night cycles. We next focus on highly social honeybees in which there is good evidence that social cues entrain the circadian clocks of nest bees and can override the influence of conflicting light-dark cycles. The current understanding of social synchronization in honeybees is consistent with self-organization models in which surrogates of forager activity, such as substrate-borne vibrations and colony volatiles, entrain the circadian clocks of bees dwelling in the dark cavity of the nest. Finally, we present original findings showing that social synchronization is effective even in an array of individually caged callow bees placed on the same substrate and is improved for bees in connected cages. These findings reveal remarkable sensitivity to social time-giving cues and show that bees with attenuated rhythms (weak oscillators) can nevertheless be socially synchronized to a common phase of activity. This article is part of the theme issue ‘Synchrony and rhythm interaction: from the brain to behavioural ecology’.

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