Circadian Regulation of Bone Remodeling

• Published in: International journal of molecular sciences Vol. 25; no. 9; p. 4717
• Main Author: Kikyo, Nobuaki
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 01.05.2024
• Subjects: Animals; Bone and Bones - metabolism; Bone Remodeling - genetics; Bones; Cell differentiation; Circadian rhythm; Circadian Rhythm - genetics; Circadian Rhythm - physiology; Collagen; Cytokines; Dietary minerals; DNA binding proteins; Extracellular matrix; Gene Expression Regulation; Genetic aspects; Genetic transcription; Homeostasis; Hormones; Humans; Hydroxyapatite; Mineralization; Osteoblasts - metabolism; Osteoclasts - metabolism; Osteogenesis - genetics; Osteoporosis; Phosphatases; Phosphates; Proteins; Transcription factors; Vertebrae; Netherlands; RANKL; M-CSF; bone turnover marker; bone remodeling; bone; osteoblast; osteocyte; circadian rhythms; osteoclast; Bmal1
• ISSN: 1422-0067; 1661-6596; 1422-0067
• DOI: 10.3390/ijms25094717

Adult bones are continuously remodeled by the balance between bone resorption by osteoclasts and subsequent bone formation by osteoblasts. Many studies have provided molecular evidence that bone remodeling is under the control of circadian rhythms. Circadian fluctuations have been reported in the serum and urine levels of bone turnover markers, such as digested collagen fragments and bone alkaline phosphatase. Additionally, the expressions of over a quarter of all transcripts in bones show circadian rhythmicity, including the genes encoding master transcription factors for osteoblastogenesis and osteoclastogenesis, osteogenic cytokines, and signaling pathway proteins. Serum levels of calcium, phosphate, parathyroid hormone, and calcitonin also display circadian rhythmicity. Finally, osteoblast- and osteoclast-specific knockout mice targeting the core circadian regulator gene Bmal1 show disrupted bone remodeling, although the results have not always been consistent. Despite these studies, however, establishing a direct link between circadian rhythms and bone remodeling in vivo remains a major challenge. It is nearly impossible to repeatedly collect bone materials from human subjects while following circadian changes. In addition, the differences in circadian gene regulation between diurnal humans and nocturnal mice, the main model organism, remain unclear. Filling the knowledge gap in the circadian regulation of bone remodeling could reveal novel regulatory mechanisms underlying many bone disorders including osteoporosis, genetic diseases, and fracture healing. This is also an important question for the basic understanding of how cell differentiation progresses under the influence of cyclically fluctuating environments.