Mast cell–expressed Mrgprb2/MRGPRX2 mediates gout pain and inflammation via a neuroimmune axis
Lin Yang, Chengxi Liu, Jin Xiao, Yu Song, Huan Chen, Dan Li, Cong Zou, Tao Hong, Yinglan Liu, Dake Qi, Nathachit Limjunyawong, Wenjie Liu, Lintao Qu
Lin Yang, Chengxi Liu, Jin Xiao, Yu Song, Huan Chen, Dan Li, Cong Zou, Tao Hong, Yinglan Liu, Dake Qi, Nathachit Limjunyawong, Wenjie Liu, Lintao Qu
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Research Article Immunology Neuroscience

Mast cell–expressed Mrgprb2/MRGPRX2 mediates gout pain and inflammation via a neuroimmune axis

Abstract

Acute severe joint pain is a major symptom in gouty arthritis (GA), and its adequate treatment represents an unmet medical need. Mrgprb2, a specific mast cell receptor, has been implicated in the generation of chronic pain by mobilizing mast cell degranulation, yet its significance in GA pain and joint inflammation is still not well defined. Here, we found that Mrgprb2 was expressed in mouse synovial mast cells. In a murine model of GA, acute blockade or genetic deletion of Mrgprb2 significantly attenuated arthritis pain and hyperexcitability of joint nociceptors with significant reductions in innate immune cell recruitment in the synovium. Under naive conditions, activation of synovial Mrgprb2 was sufficient to excite peripheral terminals of joint nociceptors to induce acute joint hypernociception via the mobilization of mast cell degranulation. Additionally, the level of the neuropeptide substance P (SP) was elevated in the synovium of GA model mice. Using humanized MRGPRX2-knockin mice, we revealed that SP contributed to joint pain and inflammation by activating mast cells through Mrgprb2/MRGPRX2. These findings suggest that synovial mast cell–expressed Mrgprb2/MRGPRX2 merits consideration as a key neuroimmune player and a potential therapeutic target for treating GA pain and joint inflammation.

Authors

Lin Yang, Chengxi Liu, Jin Xiao, Yu Song, Huan Chen, Dan Li, Cong Zou, Tao Hong, Yinglan Liu, Dake Qi, Nathachit Limjunyawong, Wenjie Liu, Lintao Qu

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Figure 4

Mrgprb2 contributes to hyperexcitability of joint nociceptors following GA.

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Mrgprb2 contributes to hyperexcitability of joint nociceptors following ...
(A) Immunostaining showing c-Fos expression in the spinal cord of Mrgprb2+/+ and Mrgprb2–/– mice 1 day after vehicle control (Ctrl) and MSU (GA) challenge. Scale bar: 100 μm. (B) Quantification revealed an increase in c-Fos+ cells in the spinal cord dorsal horn layer I–II of Mrgprb2+/+ GA model mice. No such effects were observed in Mrgprb2–/– mice with GA. n = 6 mice per group; ***P < 0.001 vs. Ctrl; ###P < 0.001 vs. Mrgprb2+/+; 2-way ANOVA (repeated measures) followed by Bonferroni’s correction. (C) Representative traces of action potentials (APs) evoked by rheobase (RB) and twice (2×) RB in DiI-labeled joint nociceptors from Mrgprb2+/+ and Mrgprb2–/– mice 1 day after vehicle control (Ctrl) and MSU (GA) challenge. (DH) Joint nociceptors of Mrgprb2+/+ mice displayed a more depolarized resting membrane potential (RMP; D), lower mean rheobase (E), larger number of APs at twice rheobase (F), and increased input resistance (Rin; G) on day 1 after GA induction. Genetic deletion of Mrgprb2 prevented these changes. No significant difference in cell capacitance was observed between groups (H). n = 14–17 neurons; *P < 0.05, **P < 0.01 vs. Ctrl; ###P < 0.001vs. Mrgprb2+/+; 2-way ANOVA (repeated measures) followed by Bonferroni’s correction.