Regulation of peripheral clock to expression of substance P/MRGPRX2 contributes to circadian activity of mast cell

doi:10.12092/j.issn.1009-2501.2026.04.001

Abstract

Abstract:

AIM: To investigate the role of substance P (SP) in the circadian activation of mast cells and its regulatory mechanisms. METHODS: Cell Counting Kit-8 (CCK8) colorimetric assay was used to detect the effects of different concentrations of SP on MCp815 cell activity, and the concentration for subsequent experiments was determined. MCp815 cell degranulation was induced using immunoglobulin E (IgE) to establish a degranulation model. A control group and a BMAL1 knockout group were set up, and both groups of cells were treated with 656.1 nmol/L SP for 30 minutes. Mast cell activation was monitored at different time intervals. Enzyme-linked immunosorbent assay (ELISA) was used to detect the release levels of histamine and tryptase. Quantitative real-time PCR was employed to detect the changes in mRNA levels of SP receptor Mrgprx2, Bmal1, Per2. Chromatin immunoprecipitation and luciferase reporter assays were used to analyze the DNA binding activity of the E-box in the Mrgprx2 gene and the promoter activity in the 2.0 kb upstream region of the transcription start site. C57BL/6 mice were randomly divided into a control group and an SP group, with 10 mice in each group. The mice were kept in either an LD10/10 (10h light/10h dark) cycle or an abnormal LD12/12 (12h light/12h dark) cycle for 8 weeks. HE staining was used to detect the pathological conditions of the nasal mucosa, and Ly6G staining was applied to observe the infiltration of myeloid neutrophils and mast cells in the nasal mucosa. ELISA was used to detect the levels of histamine and tryptase, and qPCR was performed to measure the changes in SP and Mrgprx2 mRNA levels in mouse nasal mucosa. RESULTS: (1) The dose of 656.1 nmol/L SP had no significant effect on mast cell activity and was chosen for use in subsequent experiments. In the control group, at 12 hours post SP treatment, histamine and tryptase secretion levels in mast cells (MC) were significantly higher compared to 24 hours. In the BMAL1 knockout group, there was no difference in the indicators between 12 and 24 hours. At 60 and 72 hours, there were no differences in the levels of histamine and tryptase produced by SP-stimulated MCs in either group. (2) Wild-type mice treated with SP showed more extensive neutrophil infiltration in the nasal cavity at ZT4, accompanied by increased secretion of histamine and tryptase, while at ZT16, this infiltration was less. (3) qPCR results showed that after SP treatment, Mrgprx2 expression in BMMCs at 12 hours was higher than at 24 hours in the control group, but this difference disappeared in BMAL1 knockout BMMCs. At 60 and 72 hours, there was no statistical difference in Mrgprx2 expression between the two groups of cells. At different time points, Mrgprx2 expression levels were consistent with PER2 changes and opposite to BMAL1 changes. The temporal changes in histamine and tryptase release from BMMCs were consistent with these expression patterns. (4) The non-canonical E-box (CATGTGA) in the Mrgprx2 gene showed significant BMAL1 binding activity and a clear time-dependent effect. Luciferase-reporter analysis showed that co-expression of BMAL1 and CLOCK upregulated luciferase activity, but when the E-box was mutated, Mrgprx2 transcription was abolished. (5) Mice housed in an LD10/10 cycle for 8 weeks lost the rhythm of SP-mediated neutrophil infiltration and mast cell Tac1/Mrgprx2 expression, while the rhythmic expression persisted in mice housed in the normal LD12/12 cycle. CONCLUSION: SP may play a key role in regulating the circadian activation of mast cells, with the potential mechanism involving BMAL1/CLOCK directly binding to the non-canonical E-box site in the promoter region of the SP receptor Mrgprx2 to regulate its transcription. Peripheral circadian signals may be an important pathway for MC activation in allergic rhinitis.

Key words: substance P, allergic rhinitis, mast cell activation, circadian rhythm, MRGPRX2

CLC Number:

R965.2

Xinrong LI, Yue HUANG, Wen SUI, Yulan CHEN, Zeyi LYU, Yu LI, Xi CHEN, Zhuo PAN, Man YIN, Qihong LI, Hao YANG. Regulation of peripheral clock to expression of substance P/MRGPRX2 contributes to circadian activity of mast cell[J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2026, 31(4): 433-442.

Figures/Tables 5

Fig.1 Mean proliferation multiples of MC after 48 hours of treatment with gradient concentrations of SP ($\bar x $±s, n=3) Overall proliferation of MC under different concentrations of SP. bP<0.05, compared with 0 nmol/L SP.

Fig.2 SP-mediated rhythmic activation of mast cells ($\bar x $±s, n=3) A: release of Histamine and Tryptase from the 12- or 24-hour cultured (after synchronization) shNC- or shBMAL1-treated BMCMCs. B: release of Histamine and Tryptase from the 60- or 72-hour cultured (after synchronization) shNC- or shBMAL1-treated BMCMCs. C: hematoxylin and eosin (HE) staining of the respiratory epithelia in the mouse nasal cavity (down-panel). Localization of and day-night variation in neutrophils (Ly6G+) in the mouse nasal mucosa (up-panel). D: release of Histamine and Tryptase from the 60- or 72-hour cultured (after synchronization) shNC- or shBMAL1-treated BMCMCs. bP<0.05, compared with 12 h; eP<0.05, compared with mock; hP<0.05, compared with ZT4.

Fig.3 The expression of SP receptor Mrgprx2 is associated with the circadian genes Bmal1 and Per2 ($\bar x $±s, n=3) A: changes in Mrgprx2 mRNA expression from the 12- or 24-hour cultured (after synchronization) shNC- or shBMAL1-treated BMCMCs. B: changes in Mrgprx2 mRNA expression from the 60- or 72-hour cultured (after synchronization) shNC- or shBMAL1-treated BMCMCs. C: changes in Mrgprx2 protein expression after synchronization shNC- or shBMAL1-treated BMCMCs. The expression of circadian genes Mrgprx2 (D), Bmal1 (E), and Per2 (F) showed circadian oscillations. The release of histamine (G’) and tryptase (H) by shNC or shBMAL1-treated BMCMCs showed rhythmic changes. (I) Changes in Mrgprx2 mRNA expression in mock- or SP-treated BMCMCs after synchronization. bP<0.05, compared with 12 h; eP<0.05, compared with mock; hP<0.05, compared with ZT4.

Fig.4 CLOCK/BMAL1 regulate the transcriptional rhythmicity of Mrgprx2in mast cells ($\bar x $±s, n=3) A: location of E-boxes in the 2.0 kb promoter region of Mrgprx2 gene. B: chromatin immunoprecipitation analysis shows the binding of BMAL1 to the Mrgprx2 promoter, with the non-classical E-box (CATGTGA) having a higher binding affinity; while the class II E-box (CATTTG) has no binding. C: BMAL1 antibody detection of tissues at different circadian phases shows the effect of circadian rhythm on the binding of BMAL1 to the non-classical E-box (CATGTGA) and (CATTTG) of the Mrgprx2 promoter. D: luciferase reporter assay to identify the role of the non-classical E-box (CATGTGA) in Mrgprx2 transcription. The promoter of Mrgprx2 reporter constructs (pGL3) containing normal or mutant E-boxes were transiently transfected into 293T cells with (+) or without (-) CLOCK and BMAL1 expression constructs. All results were normalized to the luciferase activity in cells transfected with pGL3 reporter containing normal non-classical E-box (CATGTGA) alone (designated value 1). pGL3-Control Vector was used as a positive control.

Fig.5 Rhythmic changes in neutrophil infiltration and SP/MRGPRX2 expression in the nasal mucosa of mice. Mice were housed under a regular 12-h light/12-h dark (LD12/12) cycle or a 10-h light/10-h dark (LD10/10) cycle for 8 weeks ($\bar x $±s, n=3) A: normalized body weight gain of mice in LD10/10 and LD12/12 condition. B: neutrophils infiltration into the nasal cavity at 10:00 a.m. or 10:00 p.m., and neutrophils were labeled with Ly-6G+. C: Quantitative analysis of Ly-6+ positive cells (n=4-5 per group). Histamine (D) and tryptase (E) levels released by wild-type mice housed under LD12/12 or LD10/10 conditions at 10:00 a.m. or 10:00 p.m., and Tac1 (F) and Mrgprx2 (G) mRNA expression levels in nasal mucosal tissue. bP<0.05, compared with LD12/12; eP<0.05, compared with 10:00 AM.

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