Disruption of the circadian clock within the cardiomyocyte influences myocardial contractile function, metabolism, and gene expression

Bray, Molly S.; Shaw, Chad A.; Moore, Michael W.; Garcia, Rodrigo Antonio Peliciari; Zanquetta, Melissa Moreira; Durgan, David J.; Jeong, William; Tsai, Ju Yun; Bugger, Heiko; Zhang, Dongfang; Rohrwasser, Andreas; Rennison, Julie H.; Dyck, Jason R.B.; Litwin, Sheldon E.; Hardin, Paul E.; Chow, Chi Wing; Chandler, Margaret P.; Abel, E. Dale; Young, Martin E.

doi:10.1152/ajpheart.01291.2007

Cited by 312 publications

(407 citation statements)

References 47 publications

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“…Mining this database can help to understand or explain tissue‐specific circadian physiology. For instance, CCGs in the murine heart are involved in cardiac glucose and fatty acid metabolism (e.g., Dgat2 , Adpn , Ppp1cc 32), but also electrophysiology which results in oscillatory contractile properties 33 (e.g., Tcap 34 , Kv4.2, and KChIP2 35). Surprisingly, the cardiac‐specific clock not only drives rhythmic output under normal physiological conditions, but also under pathophysiological conditions as noted by its oscillating responsiveness to myocardial infarction mediated by oscillating phosphorylated Akt and GSK‐3 levels 36.…”

Section: Tissue‐specific Circadian Clocks Influence Organ Physiologymentioning

confidence: 99%

Circadian clocks: from stem cells to tissue homeostasis and regeneration

2017

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The circadian clock is an evolutionarily conserved timekeeper that adapts body physiology to diurnal cycles of around 24 h by influencing a wide variety of processes such as sleep‐to‐wake transitions, feeding and fasting patterns, body temperature, and hormone regulation. The molecular clock machinery comprises a pathway that is driven by rhythmic docking of the transcription factors BMAL1 and CLOCK on clock‐controlled output genes, which results in tissue‐specific oscillatory gene expression programs. Genetic as well as environmental perturbation of the circadian clock has been implicated in various diseases ranging from sleep to metabolic disorders and cancer development. Here, we review the origination of circadian rhythms in stem cells and their function in differentiated cells and organs. We describe how clocks influence stem cell maintenance and organ physiology, as well as how rhythmicity affects lineage commitment, tissue regeneration, and aging.

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Section: Tissue‐specific Circadian Clocks Influence Organ Physiologymentioning

confidence: 99%

Circadian clocks: from stem cells to tissue homeostasis and regeneration

2017

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“…A possible risk factor for cardiovascular disease is a circadian dysfunction of the heart, where CLOCK regulates myocardial oleate oxidation and oxygen consumption by activation of fatty acid transport protein 1 (päÅOT~N) as well as of the a3 and b3 subunits of NADH hydrogenase (kÇìÑ~PLÄP) (Bray=et alK, 2008). Furthermore, metabolic processes unrelated to energy balance have been reported to be regulated by the circadian clock.…”

Section: Circadian Control Of Metabolismmentioning

confidence: 99%

A Time to Fast, a Time to Feast: The Crosstalk between Metabolism and the Circadian Clock

Kovac

Husse

Oster

2009

Molecules and Cells

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The cyclic environmental conditions brought about by the 24 h rotation of the earth have allowed the evolution of endogenous circadian clocks that control the temporal alignment of behaviour and physiology, including the uptake and processing of nutrients. Both metabolic and circadian regulatory systems are built upon a complex feedback network connecting centres of the central nervous system and different peripheral tissues. Emerging evidence suggests that circadian clock function is closely linked to metabolic homeostasis and that rhythm disruption can contribute to the development of metabolic disease. At the same time, metabolic processes feed back into the circadian clock, affecting clock gene expression and timing of behaviour. In this review, we summarize the experimental evidence for this bimodal interaction, with a focus on the molecular mechanisms mediating this exchange, and outline the implications for clock-based and metabolic diseases.

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“…Cardiomyocytespecific circadian clock mutant (CCM) mice, in which the circadian clock has been selectively disrupted, have provided important information on the function of these genes. 6 In 1985, in an analysis of the Multicenter Analysis of the Limitations of Infarct Size, Muller et al 7 observed a marked circadian periodicity in the time of onset of the clinical manifestations of acute myocardial infarction, with a peak incidence between 6 AM and noon. This increased morning incidence has been confirmed repeatedly in individual populations and in a meta-analysis of more than 60 000 patients.…”

mentioning

confidence: 99%

On Circadian Variation of Myocardial Reperfusion Injury

Braunwald

2012

Circulation Research

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Disruption of the circadian clock within the cardiomyocyte influences myocardial contractile function, metabolism, and gene expression

Cited by 312 publications

References 47 publications

Circadian clocks: from stem cells to tissue homeostasis and regeneration

Circadian clocks: from stem cells to tissue homeostasis and regeneration

A Time to Fast, a Time to Feast: The Crosstalk between Metabolism and the Circadian Clock

On Circadian Variation of Myocardial Reperfusion Injury

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