1.Research progress in control strategies of biological clock disorder.
Jing PENG ; Bao-Yin REN ; He ZHANG ; Li-Hong CHEN ; Guang-Rui YANG
Acta Physiologica Sinica 2023;75(2):279-290
Circadian clock is an internal mechanism evolved to adapt to cyclic environmental changes, especially diurnal changes. Keeping the internal clock in synchronization with the external clock is essential for health. Mismatch of the clocks due to phase shift or disruption of molecular clocks may lead to circadian disorders, including abnormal sleep-wake cycles, as well as disrupted rhythms in hormone secretion, blood pressure, heart rate, body temperature, etc. Long-term circadian disorders are risk factors for various common critical diseases such as metabolic diseases, cardiovascular diseases, and tumor. To prevent or treat the circadian disorders, scientists have conducted extensive research on the function of circadian clocks and their roles in the development of diseases, and screened hundreds of thousands of compounds to find candidates to regulate circadian rhythms. In addition, melatonin, light therapy, exercise therapy, timing and composition of food also play a certain role in relieving associated symptoms. Here, we summarized the progress of both drug- and non-drug-based approaches to prevent and treat circadian clock disorders.
Circadian Rhythm
;
Circadian Clocks
;
Melatonin/physiology*
2.Circadian rhythm in prostate cancer: time to take notice of the clock.
Wei-Zhen ZHU ; Qi-Ying HE ; De-Chao FENG ; Qiang WEI ; Lu YANG
Asian Journal of Andrology 2023;25(2):184-191
The circadian clock is an evolutionary molecular product that is associated with better adaptation to changes in the external environment. Disruption of the circadian rhythm plays a critical role in tumorigenesis of many kinds of cancers, including prostate cancer (PCa). Integrating circadian rhythm into PCa research not only brings a closer understanding of the mechanisms of PCa but also provides new and effective options for the precise treatment of patients with PCa. This review begins with patterns of the circadian clock, highlights the role of the disruption of circadian rhythms in PCa at the epidemiological and molecular levels, and discusses possible new approaches to PCa therapy that target the circadian clock.
Humans
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Male
;
Carcinogenesis
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Circadian Clocks/physiology*
;
Circadian Rhythm/physiology*
;
Prostatic Neoplasms/physiopathology*
3.Gut microbial methionine impacts circadian clock gene expression and reactive oxygen species level in host gastrointestinal tract.
Xiaolin LIU ; Yue MA ; Ying YU ; Wenhui ZHANG ; Jingjing SHI ; Xuan ZHANG ; Min DAI ; Yuhan WANG ; Hao ZHANG ; Jiahe ZHANG ; Jianghua SHEN ; Faming ZHANG ; Moshi SONG ; Jun WANG
Protein & Cell 2023;14(4):309-313
5.Co-regulation of circadian clock genes and microRNAs in bone metabolism.
Tingting LI ; Shihua ZHANG ; Yuxuan YANG ; Lingli ZHANG ; Yu YUAN ; Jun ZOU
Journal of Zhejiang University. Science. B 2022;23(7):529-546
Mammalian bone is constantly metabolized from the embryonic stage, and the maintenance of bone health depends on the dynamic balance between bone resorption and bone formation, mediated by osteoclasts and osteoblasts. It is widely recognized that circadian clock genes can regulate bone metabolism. In recent years, the regulation of bone metabolism by non-coding RNAs has become a hotspot of research. MicroRNAs can participate in bone catabolism and anabolism by targeting key factors related to bone metabolism, including circadian clock genes. However, research in this field has been conducted only in recent years and the mechanisms involved are not yet well established. Recent studies have focused on how to target circadian clock genes to treat some diseases, such as autoimmune diseases, but few have focused on the co-regulation of circadian clock genes and microRNAs in bone metabolic diseases. Therefore, in this paper we review the progress of research on the co-regulation of bone metabolism by circadian clock genes and microRNAs, aiming to provide new ideas for the prevention and treatment of bone metabolic diseases such as osteoporosis.
Animals
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Circadian Clocks/genetics*
;
Circadian Rhythm/genetics*
;
Mammals/genetics*
;
MicroRNAs/genetics*
;
Osteogenesis/genetics*
;
Osteoporosis/genetics*
6.Sleep deprivation affects sex hormones secretion by regulating the expression of the circadian clock gene in the hypothalamus and pituitary via the PI3K/Akt signaling pathway in pregnant rats.
Acta Physiologica Sinica 2022;74(4):534-540
Sleep deprivation (SD) has many deleterious health effects and occurs in more than 70% of pregnant women. However, the changes in sex hormones and relevant mechanisms after SD have not been well clarified. The aim of the present study was to explore the effects of SD on the secretion of sex hormones and the underlying mechanisms. Twelve pregnant Wistar rats were divided into control (CON, n = 6) and SD (n = 6) groups. Pregnant rats in the SD group were deprived of sleep for 18 h, and allowed free rest for 6 h, and then the above procedures were repeated until delivery. The CON group lived in a 12 h light/dark light cycle environment. Estradiol (E2) and progesterone (P4) levels were detected by enzyme-linked immunosorbent assay (ELISA), and the expression of circadian clock genes, Bmal1, Clock and Per2, in hypothalamus and pituitary gland tissues were evaluated by immunohistochemistry (IHC) and reverse transcription-quantitative polymerase chain reaction (RT-qPCR). The PI3K and Akt phosphorylation levels in the hypothalamic and pituitary tissues were determined by Western blot. The results showed that, compared with the CON group, the SD group exhibited significantly reduced serum E2 and P4 levels, down-regulated Bmal1, Clock and Per2 expression, as well as decreased phosphorylation levels of PI3K and Akt. But there was no significant difference of the total PI3K and Akt protein expression levels between the two groups. These results suggest that SD might affect the expression of the circadian clock genes in the hypothalamus and pituitary via PI3K/Akt pathway, and subsequently regulate the secretion of sex hormones in the pregnant rats, which hints the important roles of SD-induced changes of serum sex hormone levels in the pregnant rats.
ARNTL Transcription Factors/metabolism*
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Animals
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Circadian Clocks/physiology*
;
Circadian Rhythm/genetics*
;
Female
;
Gene Expression Regulation/genetics*
;
Gonadal Steroid Hormones/metabolism*
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Hypothalamus/metabolism*
;
Phosphatidylinositol 3-Kinases/metabolism*
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Pituitary Gland/metabolism*
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Pregnancy
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Progesterone
;
Proto-Oncogene Proteins c-akt/metabolism*
;
Rats
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Rats, Wistar
;
Signal Transduction
;
Sleep Deprivation/metabolism*
7.Feeding rhythm entrains circadian metabolism genes, but not the circadian clock, in brown adipose tissue.
Jiang-Hui CHEN ; Mei-Yu ZHOU ; Rong-Feng HUANG ; Hao-Ran XIN ; Shu-Ting CHENG ; Min-Dian LI ; Shi-Fei TONG
Acta Physiologica Sinica 2022;74(5):726-736
The central circadian clock and feeding rhythm coordinately reset peripheral circadian clocks. Emerging evidence suggests that feeding rhythm resets peripheral circadian clocks in a tissue-specific manner. This study aimed to determine whether and how feeding rhythm regulates circadian rhythms of the circadian clock and metabolic genes in brown adipose tissue (BAT). We applied different regimens of time-restricted feeding (TRF) in wildtype and Per1/2 deficient C57BL/6 mice, and quantified the effects of sex, treatment duration, constant light, and circadian clock on circadian rhythms of the BAT circadian clock and metabolic genes by RT-qPCR; Representative circadian clock genes are Bmal1, Nr1d1, Dbp, and Per2, and representative metabolic genes are uncoupling protein 1 (Ucp1), 6-phosphofructo-2-kinase/fructose-2,6-biphosphatase 3 (Pfkfb3) that controls the flux through glycolysis, pyruvate dehydrogenase kinase isozyme 4 (Pdk4) gating the tricarboxylic acid cycle, and carnitine palmitoyltransferase 1A (Cpt1a) that controls mitochondrial fatty acid oxidation. The results showed that, daytime-restricted feeding (DRF) moderately shifted the phase of the BAT circadian clock in female mice within 7 or 36 d, and resulted in the loss of circadian rhythm in Dbp and Per2 transcripts in males. DRF induced de novo oscillation of the Ucp1 transcript, and shifted the phase of representative metabolic genes, such as Pfkfb3, Pdk4, and Cpt1a, more than 7 h. Constant light is known to disrupt the synchrony of the central circadian clock. The results showed that constant light promoted phase entrainment of the circadian clock by DRF in BAT, but abolished the oscillation of the metabolic genes (except for Pdk4). Despite combined treatment with Per1/2 deficiency and constant darkness, DRF was sufficient to drive circadian rhythms of Bmal1 and Dbp, but not those of Nr1d1, Ucp1, Pfkfb3, and Cpt1a. Overall, the circadian clock of BAT has weak adaptation to altered feeding rhythms and sex differences. The central circadian clock antagonizes DRF in the entrainment of the BAT circadian clock, whereas DRF resets circadian rhythms of metabolic genes, such as Ucp1, Pfkfb3, and Cpt1a, in a circadian clock-dependent manner.
Female
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Male
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Animals
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Mice
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Mice, Inbred C57BL
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Circadian Clocks
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Adipose Tissue, Brown
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ARNTL Transcription Factors
;
Circadian Rhythm
8.Low intensity near-infrared light promotes bone regeneration via circadian clock protein cryptochrome 1.
Jinfeng PENG ; Jiajia ZHAO ; Qingming TANG ; Jinyu WANG ; Wencheng SONG ; Xiaofeng LU ; Xiaofei HUANG ; Guangjin CHEN ; Wenhao ZHENG ; Luoying ZHANG ; Yunyun HAN ; Chunze YAN ; Qian WAN ; Lili CHEN
International Journal of Oral Science 2022;14(1):53-53
Bone regeneration remains a great clinical challenge. Low intensity near-infrared (NIR) light showed strong potential to promote tissue regeneration, offering a promising strategy for bone defect regeneration. However, the effect and underlying mechanism of NIR on bone regeneration remain unclear. We demonstrated that bone regeneration in the rat skull defect model was significantly accelerated with low-intensity NIR stimulation. In vitro studies showed that NIR stimulation could promote the osteoblast differentiation in bone mesenchymal stem cells (BMSCs) and MC3T3-E1 cells, which was associated with increased ubiquitination of the core circadian clock protein Cryptochrome 1 (CRY1) in the nucleus. We found that the reduction of CRY1 induced by NIR light activated the bone morphogenetic protein (BMP) signaling pathways, promoting SMAD1/5/9 phosphorylation and increasing the expression levels of Runx2 and Osterix. NIR light treatment may act through sodium voltage-gated channel Scn4a, which may be a potential responder of NIR light to accelerate bone regeneration. Together, these findings suggest that low-intensity NIR light may promote in situ bone regeneration in a CRY1-dependent manner, providing a novel, efficient and non-invasive strategy to promote bone regeneration for clinical bone defects.
Animals
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Rats
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Bone Morphogenetic Protein 2/metabolism*
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Bone Regeneration
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Cell Differentiation
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Circadian Clocks
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Cryptochromes/metabolism*
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Osteoblasts/metabolism*
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Osteogenesis
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Transcription Factors/metabolism*
9.Advances in circadian rhythms in oral maxillofacial tissues and oral-related diseases.
Chinese Journal of Stomatology 2022;57(5):481-489
Circadian rhythm is an internal autonomous timing mechanism formed by the body in response to changes of external environment. It participates in the regulations of various physiological activities, affecting the formation and outcome of various diseases in the human body. This paper summarizes the changes of local tissue rhythms in common disease states, such as oral and maxillofacial malformations, inflammation and malignant tumors. The importance of circadian clock system to the activities of oral and maxillofacial tissues are dialectically analyzed, mainly on the mechanisms of action in maintaining oral health and in affecting the processes of common oral diseases and oral-related systemic diseases. At the same time, chronological therapy and new strategies of prevention and treatment for oral-related diseases based on the changes in tissue rhythm are summarized and prospected to provide new ideas for maintaining oral and systemic health.
Circadian Clocks/physiology*
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Circadian Rhythm/physiology*
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Humans
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Inflammation
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Mouth Diseases
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Neoplasms
10.Research progress on the regulation of mammalian energy metabolism by the circadian clock system and gut microbiota.
Hai-Sen ZHANG ; Chao LI ; Ya-Ting LI ; Ya-Ping JIN ; Wei LIU ; Hua-Tao CHEN
Acta Physiologica Sinica 2022;74(3):443-460
The mammalian internal circadian clock system has been evolved to adapt to the diurnal changes in the internal and external environment of the organism to regulate diverse physiological functions, such as the sleep-wake cycle and feeding rhythm, thereby coordinating the rhythmic changes of energy demand and nutrition supply in each diurnal cycle. The circadian clock regulates glucose metabolism, lipid metabolism, and hormones secretion in diverse tissues and organs, including the liver, skeletal muscle, pancreas, heart, and vessels. As a special "organ" of the host, the gut microbiota, together with the intestinal microenvironment (tissues, cells, and metabolites) in a co-evolutionary process, constitutes a micro-ecosystem and plays an important role in the process of nutrient digestion and absorption in the intestine of the host. In recent years, accumulating evidence indicates that the compositions, quantities, colonization, and functional activities of the gut microbiota exhibit significant circadian variations, which are closely related to the changes of various physiological functions under the regulation of host circadian clock system. In addition, several studies have shown that the gut microbiota can produce many important metabolites such as the short-chain fatty acids through the degradation of indigestive dietary fibers. A portion of gut microbiota-derived metabolites can regulate the circadian clock system and metabolism of the host. This article mainly discusses the interaction between the host circadian clock system and the gut microbiota, and highlights its influence on energy metabolism of the host, providing a novel clues and thought for the prevention and treatment of metabolic diseases.
Animals
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Circadian Clocks/physiology*
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Circadian Rhythm/physiology*
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Ecosystem
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Energy Metabolism
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Gastrointestinal Microbiome/physiology*
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Lipid Metabolism/physiology*
;
Mammals

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