Clock-genes and mitochondrial respiratory activity: Evidence of a reciprocal interplay

Scrima, Rosella; Cela, Olga; Merla, Giuseppe; Augello, Bartolomeo; Rubino, Rosa; Quarato, Giovanni; Fugetto, Sabino; Menga, Marta; Fuhr, Luise; Relógio, Angela; Piccoli, Cláudia; Mazzoccoli, Gianluigi; Capitanio, Nazzareno

doi:10.1016/j.bbabio.2016.03.035

Cited by 45 publications

(45 citation statements)

References 26 publications

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“…In regards to mitochondrial oxidation, silencing Bmal1 expression in vivo and ex vivo silences mitochondrial oxidation [5, 34]. Arresting mitochrondrial oxidation can also downregulate Bmal1 expression [34].…”

Section: Discussionmentioning

confidence: 99%

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Homeostatic effects of exercise and sleep on metabolic processes in mice with an overexpressed skeletal muscle clock

et al. 2017

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Brain and muscle-ARNT-like factor (Bmal1/BMAL1) is an essential transcriptional/translational factor of circadian clocks. Loss of function of Bmal1/BMAL1 is highly disruptive to physiological and behavioral processes. In light of these previous findings, we examined if transgenic overexpression of Bmal1/BMAL1 in skeletal muscle could alter metabolic processes. First, we characterized in vivo and ex vivo metabolic phenotypes of muscle overexpressed mice (male and female) compared to wild-type littermates (WT). Second, we examined in vivo and ex vivo metabolic processes in the presence of positive and negative homeostatic challenges: high-intensity treadmill running (positive) and acute sleep deprivation (negative). In vivo measures of metabolic processes included body composition, respiratory exchange ratio (RER; VCO2/VO2), energy expenditure, total activity counts, and food intake collected from small animal indirect calorimetry. An ex vivo measure of insulin sensitivity in skeletal muscle was determined from radioassays. RER was lower for muscle overexpressed females compared to WT females. There were no genotype-dependent differences in metabolic phenotypes for males. With homeostatic challenges, muscle overexpressed mice had lower energy expenditure after high-intensity treadmill running. Acute sleep deprivation reduced insulin sensitivity in skeletal muscle in overexpressed males, but not WT males. The present study contributes to a body of evidence showing pleiotropic, non-circadian, and homeostatic effects of altered Bmal1/BMAL1 expression on metabolic processes, demonstrating a critical need to further investigate the broad and complex actions of Bmal1/BMAL1 on physiology and behavior.

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Section: Discussionmentioning

confidence: 99%

“…Arresting mitochrondrial oxidation can also downregulate Bmal1 expression [34]. In regards to insulin signaling, developmentally knocking-out or pharmacologically-arresting Bmal1 expression alters blood glucose levels, insulin sensitivity in skeletal muscle, and downregulates GLUT4 and glucose regulatory genes in skeletal muscle.…”

Section: Discussionmentioning

confidence: 99%

Homeostatic effects of exercise and sleep on metabolic processes in mice with an overexpressed skeletal muscle clock

et al. 2017

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“…Therefore, it is not surprising that important functions of cellular energy metabolism, such as mitochondrial respiration are under circadian control. Disrupting Bmal1 transcription by siRNA in a liver-derived cell line (HepG2) led to a decrease in mitochondrial respiration ( Scrima et al 2016 ). In mice, genetic ablation of Bmal1 at the whole-body level resulted in a decreased oxygen consumption rate (OCR) in isolated liver mitochondria ( Peek et al 2013 ).…”

Section: Circadian Control Of Mitochondrial Respirationmentioning

confidence: 99%

Circadian rhythms in mitochondrial respiration

Goede

Wefers

Brombacher

et al. 2018

Journal of Molecular Endocrinology

145

123

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Many physiological processes are regulated with a 24-h periodicity to anticipate the environmental changes of daytime to nighttime and vice versa. These 24-h regulations, commonly termed circadian rhythms, among others control the sleep–wake cycle, locomotor activity and preparation for food availability during the active phase (daytime for humans and nighttime for nocturnal animals). Disturbing circadian rhythms at the organ or whole-body level by social jetlag or shift work, increases the risk to develop chronic metabolic diseases such as type 2 diabetes mellitus. The molecular basis of this risk is a topic of increasing interest. Mitochondria are essential organelles that produce the majority of energy in eukaryotes by converting lipids and carbohydrates into ATP through oxidative phosphorylation. To adapt to the ever-changing environment, mitochondria are highly dynamic in form and function and a loss of this flexibility is linked to metabolic diseases. Interestingly, recent studies have indicated that changes in mitochondrial morphology (i.e., fusion and fission) as well as generation of new mitochondria are dependent on a viable circadian clock. In addition, fission and fusion processes display diurnal changes that are aligned to the light/darkness cycle. Besides morphological changes, mitochondrial respiration also displays diurnal changes. Disturbing the molecular clock in animal models leads to abrogated mitochondrial rhythmicity and altered respiration. Moreover, mitochondrial-dependent production of reactive oxygen species, which plays a role in cellular signaling, has also been linked to the circadian clock. In this review, we will summarize recent advances in the study of circadian rhythms of mitochondria and how this is linked to the molecular circadian clock.

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“…These TFs, via transcriptional and translational feedback loops, regulate their own transcription, which leads to ≈24‐hr oscillations in their gene and protein expression in all cells, tissues, and organs. In addition, the CCN elements coordinate the transcription of many other genes, clock‐controlled genes (CCGs), in a circadian‐ and organ‐specific manner, regulating a variety of biological processes, at both the cell and tissue levels, such as cell division, bioenergetics, autophagy, metabolism, redox balance, hormone regulation, and immune responses (El‐Athman et al, ; Fuhr et al, ; Relógio et al, ; Scrima et al, ; Zhang, Lahens, Ballance, Hughes, & Hogenesch, ; reviewed in Pilorz et al, ). These cellular peripheral clocks, distributed throughout the body, are further coordinated by a central pacemaker, located at the suprachiasmatic nuclei (SCNs) in the hypothalamus (Albrecht, ).…”

Section: Introductionmentioning

confidence: 99%

The importance of determining circadian parameters in pharmacological studies

Gaspar

Álvaro

Carmo‐Silva

et al. 2019

British J Pharmacology

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In mammals, most molecular and cellular processes show circadian changes, leading to daily variations in physiology and ultimately in behaviour. Such daily variations induce a temporal coordination of processes that is essential to ensure homeostasis and health. Thus, it is of no surprise that pharmacokinetics (PK) and pharmacodynamics (PD) of many drugs are also subject to circadian variations, profoundly affecting their efficacy and tolerability. Understanding how circadian rhythms influence drug PK, PD, and toxicity might significantly improve treatment efficacy and decrease related side effects. Therefore, it is essential to take circadian variations into account and to determine circadian parameters in pharmacological studies, especially when drugs have a short half‐life or target rhythmic processes. This review provides an overview of the current knowledge on circadian rhythms and their relevance to the field of pharmacology. Methodologies to evaluate circadian rhythms in vitro, in rodent models and in humans, from experimental to computational approaches, are described and discussed. Lastly, we aim at alerting the scientific, medical, and regulatory communities to the relevance of the physiological time, as a key parameter to be considered when designing pharmacological studies. This will eventually lead to more successful preclinical and clinical trials and pave the way to a more personalized treatment to the benefit of the patients.

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Clock-genes and mitochondrial respiratory activity: Evidence of a reciprocal interplay

Cited by 45 publications

References 26 publications

Homeostatic effects of exercise and sleep on metabolic processes in mice with an overexpressed skeletal muscle clock

Homeostatic effects of exercise and sleep on metabolic processes in mice with an overexpressed skeletal muscle clock

Circadian rhythms in mitochondrial respiration

The importance of determining circadian parameters in pharmacological studies

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