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Anoctamin 1 controls bone resorption by coupling Cl− channel activation with RANKL-RANK signaling transduction

Author

Listed:
  • Weijia Sun

    (China Astronaut Research and Training Center)

  • Shuai Guo

    (Hebei University of Technology
    Hebei University)

  • Yuheng Li

    (China Astronaut Research and Training Center
    The Fourth Military Medical University)

  • JianWei Li

    (China Astronaut Research and Training Center)

  • Caizhi Liu

    (China Astronaut Research and Training Center)

  • Yafei Chen

    (Hebei University of Technology)

  • Xuzhao Wang

    (Hebei University of Technology)

  • Yingjun Tan

    (China Astronaut Research and Training Center)

  • Hua Tian

    (Peking University the Third Hospital)

  • Cheng Wang

    (Peking University the Third Hospital)

  • Ruikai Du

    (China Astronaut Research and Training Center)

  • Guohui Zhong

    (China Astronaut Research and Training Center)

  • Sai Shi

    (Hebei University of Technology)

  • Biao Ma

    (Hebei University of Technology)

  • Chang Qu

    (Hebei University of Technology)

  • Jingxuan Fu

    (Hebei University of Technology)

  • Xiaoyan Jin

    (China Astronaut Research and Training Center)

  • Dingsheng Zhao

    (China Astronaut Research and Training Center)

  • Yong Zhan

    (Hebei University of Technology)

  • Shukuan Ling

    (China Astronaut Research and Training Center)

  • Hailong An

    (Hebei University of Technology)

  • Yingxian Li

    (China Astronaut Research and Training Center)

Abstract

Osteoclast over-activation leads to bone loss and chloride homeostasis is fundamental importance for osteoclast function. The calcium-activated chloride channel Anoctamin 1 (also known as TMEM16A) is an important chloride channel involved in many physiological processes. However, its role in osteoclast remains unresolved. Here, we identified the existence of Anoctamin 1 in osteoclast and show that its expression positively correlates with osteoclast activity. Osteoclast-specific Anoctamin 1 knockout mice exhibit increased bone mass and decreased bone resorption. Mechanistically, Anoctamin 1 deletion increases intracellular Cl− concentration, decreases H+ secretion and reduces bone resorption. Notably, Anoctamin 1 physically interacts with RANK and this interaction is dependent upon Anoctamin 1 channel activity, jointly promoting RANKL-induced downstream signaling pathways. Anoctamin 1 protein levels are substantially increased in osteoporosis patients and this closely correlates with osteoclast activity. Finally, Anoctamin 1 deletion significantly alleviates ovariectomy induced osteoporosis. These results collectively establish Anoctamin 1 as an essential regulator in osteoclast function and suggest a potential therapeutic target for osteoporosis.

Suggested Citation

  • Weijia Sun & Shuai Guo & Yuheng Li & JianWei Li & Caizhi Liu & Yafei Chen & Xuzhao Wang & Yingjun Tan & Hua Tian & Cheng Wang & Ruikai Du & Guohui Zhong & Sai Shi & Biao Ma & Chang Qu & Jingxuan Fu & , 2022. "Anoctamin 1 controls bone resorption by coupling Cl− channel activation with RANKL-RANK signaling transduction," Nature Communications, Nature, vol. 13(1), pages 1-15, December.
  • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-30625-9
    DOI: 10.1038/s41467-022-30625-9
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    References listed on IDEAS

    as
    1. Cristina Paulino & Valeria Kalienkova & Andy K. M. Lam & Yvonne Neldner & Raimund Dutzler, 2017. "Activation mechanism of the calcium-activated chloride channel TMEM16A revealed by cryo-EM," Nature, Nature, vol. 552(7685), pages 421-425, December.
    2. Young Duk Yang & Hawon Cho & Jae Yeon Koo & Min Ho Tak & Yeongyo Cho & Won-Sik Shim & Seung Pyo Park & Jesun Lee & Byeongjun Lee & Byung-Moon Kim & Ramin Raouf & Young Ki Shin & Uhtaek Oh, 2008. "TMEM16A confers receptor-activated calcium-dependent chloride conductance," Nature, Nature, vol. 455(7217), pages 1210-1215, October.
    3. Shangyu Dang & Shengjie Feng & Jason Tien & Christian J. Peters & David Bulkley & Marco Lolicato & Jianhua Zhao & Kathrin Zuberbühler & Wenlei Ye & Lijun Qi & Tingxu Chen & Charles S. Craik & Yuh Nung, 2017. "Cryo-EM structures of the TMEM16A calcium-activated chloride channel," Nature, Nature, vol. 552(7685), pages 426-429, December.
    4. Cheng-Hai Zhang & Pei Wang & Dong-Hai Liu & Cai-Ping Chen & Wei Zhao & Xin Chen & Chen Chen & Wei-Qi He & Yan-Ning Qiao & Tao Tao & Jie Sun & Ya-Jing Peng & Ping Lu & Kaizhi Zheng & Siobhan M. Craige , 2016. "The molecular basis of the genesis of basal tone in internal anal sphincter," Nature Communications, Nature, vol. 7(1), pages 1-10, September.
    5. Jianwei Li & Caizhi Liu & Yuheng Li & Qiaoxia Zheng & Youjia Xu & Beibei Liu & Weijia Sun & Yuan Li & Shuhui Ji & Mingwei Liu & Jing Zhang & Dingsheng Zhao & Ruikai Du & Zizhong Liu & Guohui Zhong & C, 2019. "TMCO1-mediated Ca2+ leak underlies osteoblast functions via CaMKII signaling," Nature Communications, Nature, vol. 10(1), pages 1-14, December.
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