Circadian timing of satellite cell function and muscle regeneration.

Recent research has highlighted an important role for the molecular circadian machinery in the regulation of tissue-specific function and stress responses. Indeed, disruption of circadian function, which is pervasive in modern society, is linked to accelerated aging, obesity, and type 2 diabetes. Furthermore, evidence supporting the importance of the circadian clock within both the mature muscle tissue and satellite cells to regulate the maintenance of muscle mass and repair capacity in response injury has recently emerged. Here, we review the discovery of circadian clocks within the satellite cell (a.k.a. adult muscle stem cell) and how they act to regulate metabolism, epigenetics, and myogenesis during both healthy and diseased states.

BMAL1 drives muscle repair through control of hypoxic NAD+ regeneration in satellite cells.

The process of tissue regeneration occurs in a developmentally timed manner, yet the role of circadian timing is not understood. Here, we identify a role for the adult muscle stem cell (MuSC)-autonomous clock in the control of muscle regeneration following acute ischemic injury. We observed greater muscle repair capacity following injury during the active/wake period as compared with the inactive/rest period in mice, and loss of Bmal1 within MuSCs leads to impaired muscle regeneration. We demonstrate that Bmal1 loss in MuSCs leads to reduced activated MuSC number at day 3 postinjury, indicating a failure to properly expand the myogenic precursor pool. In cultured primary myoblasts, we observed that loss of Bmal1 impairs cell proliferation in hypoxia (a condition that occurs in the first 1-3 d following tissue injury in vivo), as well as subsequent myofiber differentiation. Loss of Bmal1 in both cultured myoblasts and in vivo activated MuSCs leads to reduced glycolysis and premature activation of prodifferentiation gene transcription and epigenetic remodeling. Finally, hypoxic cell proliferation and myofiber formation in Bmal1-deficient myoblasts are restored by increasing cytosolic NAD+ Together, we identify the MuSC clock as a pivotal regulator of oxygen-dependent myoblast cell fate and muscle repair through the control of the NAD+-driven response to injury.

Associations of Poly (ADP-Ribose) Polymerase1 abundance in calf skeletal muscle with walking performance in peripheral artery disease.

OBJECTIVE: This study investigated associations of markers of oxidative stress and mitochondrial function in calf muscle biopsies with walking performance in people with and without lower extremity peripheral artery disease (PAD). METHODS: Participants with PAD (ankle-brachial index (ABI) <0.90) and without PAD (ABI: 0.90-1.50) underwent calf muscle biopsy and measurement of 6-min walk and four-meter walking velocity. PARP1 (Poly (ADP-Ribose) Polymerase 1), peroxisome proliferator-activated receptor gamma coactivator 1-alpha (PGC-1α), silent information regulator 1 (SIRT1) and 4-hydroxynonenal (4HNE) expression were measured in calf muscle using western blot. RESULTS: Among 15 participants with PAD mean age: 66.8 years (standard deviation (SD): 6.4) and six without PAD (age: 64.4 years, SD: 5.9), mean PARP1-abundance in calf muscle was 1.16 ± 0.92 AU and 0.96 ± 0.38 AU, respectively (P = 0.61). Among participants with PAD after adjustment with ABI, a greater abundance of PARP1 was associated with poorer 6-min walking distance (r = -0.65, P = 0.01), usual-paced 4-m walking velocity (r = -0.73, P = 0.003) and slower fast-paced four-meter walking velocity (r = -0.51, P = 0.07). Among participants with PAD, ABI was not associated with PARP1 abundance in calf muscle (r = 0.02, P = 0.93). Among participants without PAD, skeletal muscle PARP1 abundance was not significantly associated with 6-min walk distance (r = -0.58; P = 0.22), usual-paced walking velocity (r = -0.26; P = 0.62), or fast-paced walking velocity (r = -0.21; P = 0.69), perhaps due to lack of statistical power. There were no associations of remaining calf muscle measures with walking performance. CONCLUSIONS: These findings are consistent with the hypothesis that calf skeletal muscle characteristics are related to walking performance, independently of severity of lower extremity arterial obstruction in people with PAD.

Metabolic Implications of Circadian-HIF Crosstalk.

Research over the past few decades has shed light on the mechanisms underlying the link between circadian disruption and the development of metabolic diseases such as obesity, type 2 diabetes, and cancer. However, how the clock network interacts with tissue-specificnutrient-sensing pathways during conditions of nutrient stress or pathological states remains incompletely understood. Recent work has demonstrated that the circadian clock can 'reprogram' the transcriptome to control distinct sets of genes during altered nutrient conditions, such as high fat diet, aging, and exercise. In this review, I discuss connections between circadian clock transcription factors and the oxygen- and nutrient-responsivehypoxia-inducible factor (HIF) pathway. I highlight recently uncovered mechanistic insights underlying these pathway interactions and address potential implications for the role of circadian disruption in metabolic diseases.

Cryptochromes-Mediated Inhibition of the CRL4Cop1-Complex Assembly Defines an Evolutionary Conserved Signaling Mechanism.

In plants, cryptochromes are photoreceptors that negatively regulate the ubiquitin ligase CRL4Cop1. In mammals, cryptochromes are core components of the circadian clock and repressors of the glucocorticoid receptor (GR). Moreover, mammalian cryptochromes lost their ability to interact with Cop1, suggesting that they are unable to inhibit CRL4Cop1. Contrary to this assumption, we found that mammalian cryptochromes are also negative regulators of CRL4Cop1, and through this mechanism, they repress the GR transcriptional network both in cultured cells and in the mouse liver. Mechanistically, cryptochromes inactivate Cop1 by interacting with Det1, a subunit of the mammalian CRL4Cop1 complex that is not present in other CRL4s. Through this interaction, the ability of Cop1 to join the CRL4 complex is inhibited; therefore, its substrates accumulate. Thus, the interaction between cryptochromes and Det1 in mammals mirrors the interaction between cryptochromes and Cop1 in planta, pointing to a common ancestor in which the cryptochromes-Cop1 axis originated.

Circadian measurements of sirtuin biology.

Many of our behavioral and physiological processes display daily oscillations that are under the control of the circadian clock. The core molecular clock network is present in both the brain and peripheral tissues and is composed of a complex series of interlocking transcriptional/translational feedback loops that oscillate with a periodicity of ~24 h. Recent evidence has implicated NAD(+) biosynthesis and the sirtuin family of NAD(+)-dependent protein deacetylases as part of a novel feedback loop within the core clock network, findings which underscore the importance of taking circadian timing into consideration when designing and interpreting metabolic studies, particularly in regard to sirtuin biology. Thus, this chapter introduces both in vivo and in vitro circadian methods to analyze various sirtuin-related endpoints across the light-dark cycle and discusses the transcriptional, biochemical, and physiological outputs of the clock.

Circadian clocks and metabolism.

Circadian clocks maintain periodicity in internal cycles of behavior, physiology, and metabolism, enabling organisms to anticipate the 24-h rotation of the Earth. In mammals, circadian integration of metabolic systems optimizes energy harvesting and utilization across the light/dark cycle. Disruption of clock genes has recently been linked to sleep disorders and to the development of cardiometabolic disease. Conversely, aberrant nutrient signaling affects circadian rhythms of behavior. This chapter reviews the emerging relationship between the molecular clock and metabolic systems and examines evidence that circadian disruption exerts deleterious consequences on human health.

Nutrient sensing and the circadian clock.

The circadian system synchronizes behavioral and physiologic processes with daily changes in the external light-dark cycle, optimizing energetic cycles with the rising and setting of the sun. Molecular clocks are organized hierarchically, with neural clocks orchestrating the daily switch between periods of feeding and fasting, and peripheral clocks generating 24h oscillations of energy storage and utilization. Recent studies indicate that clocks respond to nutrient signals and that a high-fat diet influences the period of locomotor activity under free-running conditions, a core property of the clock. A major goal is to identify the molecular basis for the reciprocal relation between metabolic and circadian pathways. Here the role of peptidergic hormones and macromolecules as nutrient signals integrating circadian and metabolic systems is highlighted.