Proton-activated chloride channel increases endplate porosity and pain in a mouse spine degeneration model
Peng Xue, Weixin Zhang, Mengxi Shen, Junhua Yang, Jiachen Chu, Shenyu Wang, Mei Wan, Junying Zheng, Zhaozhu Qiu, Xu Cao
Peng Xue, Weixin Zhang, Mengxi Shen, Junhua Yang, Jiachen Chu, Shenyu Wang, Mei Wan, Junying Zheng, Zhaozhu Qiu, Xu Cao
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Research Article Bone biology Cell biology

Proton-activated chloride channel increases endplate porosity and pain in a mouse spine degeneration model

Abstract

Chronic low back pain (LBP) can severely affect daily physical activity. Aberrant osteoclast-mediated resorption leads to porous endplates, which allow the sensory innervation that causes LBP. Here, we report that expression of the proton-activated chloride (PAC) channel was induced during osteoclast differentiation in the porous endplates via a RANKL/NFATc1 signaling pathway. Extracellular acidosis evoked robust PAC currents in osteoclasts. An acidic environment of porous endplates and elevated PAC activation–enhanced osteoclast fusion provoked LBP. Furthermore, we found that genetic knockout of the PAC gene Pacc1 significantly reduced endplate porosity and spinal pain in a mouse LBP model, but it did not affect bone development or homeostasis of bone mass in adult mice. Moreover, both the osteoclast bone-resorptive compartment environment and PAC traffic from the plasma membrane to endosomes to form an intracellular organelle Cl channel had a low pH of approximately 5.0. The low pH environment activated the PAC channel to increase sialyltransferase St3gal1 expression and sialylation of TLR2 in the initiation of osteoclast fusion. Aberrant osteoclast-mediated resorption is also found in most skeletal disorders, including osteoarthritis, ankylosing spondylitis, rheumatoid arthritis, heterotopic ossification, and enthesopathy. Thus, elevated Pacc1 expression and PAC activity could be a potential therapeutic target for the treatment of LBP and osteoclast-associated pain.

Authors

Peng Xue, Weixin Zhang, Mengxi Shen, Junhua Yang, Jiachen Chu, Shenyu Wang, Mei Wan, Junying Zheng, Zhaozhu Qiu, Xu Cao

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Figure 2

Knockout of the Pacc1 channel does not influence bone development or femur bone mass in adult mice.

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Knockout of the Pacc1 channel does not influence bone development or fem...
(A) Body length of Pacc1+/+ and Pacc1–/– mice (n ≥5). (B) Body weight of Pacc1+/+ and Pacc1–/– mice (n ≥5). (C) Representative μCT images of femurs from 3-month-old male Pacc1+/+ and Pacc1–/– mice. Scale bar: 1 mm. (D) Quantitative analysis of μCT result for BV/TV in femurs from 3-month-old male Pacc1+/+ and Pacc1–/– mice (n = 6). (E) Representative images of TRAP staining of coronal femur sections from 3-month-old male Pacc1+/+ and Pacc1–/– mice. Scale bar: 50 μm. (F) Quantitative analysis of the number of TRAP+ multinuclear cells in femurs (n = 6). (G) Representative images of immunofluorescent analysis of OCN staining and DAPI (blue) staining of nuclei for coronal femur sections from 3-month-old male Pacc1+/+ and Pacc1–/– mice. Scale bar: 50 μm. (H) Quantitative analysis of the number of OCN+ cells in femurs (n = 6). Data are presented as the mean ± SD.