Intestinal clock system regulates skeletal homeostasis
Masanobu Kawai, … , Keiichi Ozono, Toshimi Michigami
Masanobu Kawai, … , Keiichi Ozono, Toshimi Michigami
Published February 7, 2019
Citation Information: JCI Insight. 2019;4(5):e121798. https://doi.org/10.1172/jci.insight.121798.
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Research Article Bone biology Gastroenterology

Intestinal clock system regulates skeletal homeostasis

Abstract

The circadian clock network is an evolutionarily conserved system involved in the regulation of metabolic homeostasis; however, its impacts on skeletal metabolism remain largely unknown. We herein demonstrated that the circadian clock network in the intestines plays pivotal roles in skeletal metabolism such that the lack of the Bmal1 gene in the intestines (Bmal1Int–/– mice) caused bone loss, with bone resorption being activated and bone formation suppressed. Mechanistically, Clock protein interaction with the vitamin D receptor (VDR) accelerated its binding to the VDR response element by enhancing histone acetylation in a circadian-dependent manner, and this was lost in Bmal1Int–/– mice because nuclear translocation of Clock required the presence of Bmal1. Accordingly, the rhythmic expression of VDR target genes involved in transcellular calcium (Ca) absorption was created, and this was not observed in Bmal1Int–/– mice. As a result, transcellular Ca absorption was impaired and bone resorption was activated in Bmal1Int–/– mice. Additionally, sympathetic tone, the activation of which suppresses bone formation, was elevated through afferent vagal nerves in Bmal1Int–/– mice, the blockade of which partially recovered bone loss by increasing bone formation and suppressing bone resorption in Bmal1Int–/– mice. These results demonstrate that the intestinal circadian system regulates skeletal bone homeostasis.

Authors

Masanobu Kawai, Saori Kinoshita, Miwa Yamazaki, Keiko Yamamoto, Clifford J. Rosen, Shigeki Shimba, Keiichi Ozono, Toshimi Michigami

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Figure 6

Transcellular Ca absorption is decreased in Bmal1Int–/–mice.

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Transcellular Ca absorption is decreased in Bmal1Int–/–mice. (A) Transce...
(A) Transcellular Ca absorption was evaluated by everted gut sac assay at 8 weeks of age (n = 5–8). (a) P < 0.05, ZT8 vs. ZT20; P < 0.01, ZT8 vs. ZT14; in Bmal1Intfl/fl mice, by 1-way ANOVA. (b) P < 0.01, ZT14 vs. ZT8; P < 0.001, ZT14 vs. ZT2 and ZT20; in Bmal1Int–/– mice, by 1-way ANOVA. *P < 0.001, **P < 0.05; Bmal1Intfl/fl vs. Bmal1Int–/– at indicated time points by Student’s t test. (B) Serum Ca levels were determined every 4 hours at 8 weeks of age (n = 9). (a) P < 0.05, ZT16 vs. ZT4, ZT8, and ZT20; P < 0.01, ZT16 vs. ZT0; in Bmal1Intfl/fl mice, by 1-way ANOVA. (C) Urine volume and Ca excretion in the urine was measured at 8 weeks of age (n = 11 or 12). *P < 0.01 by Student’s t test. FECa, fractional excretion of Ca. (D) Serum intact PTH (n = 8–12) levels were determined at 8 weeks of age. *P < 0.05; Bmal1Intfl/fl vs. Bmal1Int–/– mice at indicated time points by Student’s t test. (E and F) Serum 1,25-(OH)2D3 (n = 5) (E), and CTX (n = 10) (F) levels were determined at 8 weeks of age. *P < 0.05 by Student’s t test.