免疫缺陷鼠和非免疫缺陷鼠切牙稳态维持和损伤修复比较

doi:10.3969/j.issn.1006-7795.2025.06.008

首都医科大学学报 ›› 2025, Vol. 46 ›› Issue (6): 1011-1018.doi: 10.3969/j.issn.1006-7795.2025.06.008

免疫缺陷鼠和非免疫缺陷鼠切牙稳态维持和损伤修复比较

苌旭，张婧，李娟娟，刘亮亮，史暄阁，尚宇彤，王福^*

大连医科大学附属口腔医院口腔综合科，大连 116044

收稿日期:2025-08-13 修回日期:2025-10-01 出版日期:2025-12-21 发布日期:2025-12-19
通讯作者: 王福 E-mail:fuwang@dmu.edu.cn
基金资助:
辽宁省教育厅高校基本科研项目（LJKFZ20220249）。

Comparison of incisor homeostatic maintenance and injury repair in immunodeficient mice and immunocompetent mice

Chang Xu, Zhang Jing, Li Juanjuan, Liu Liangliang, Shi Xuange, Shang Yutong, Wang Fu^*

Department of General Stomatology, Affiliated Stomatological Hospital of Dalian Medical University, Dalian 116044, China

Received:2025-08-13 Revised:2025-10-01 Online:2025-12-21 Published:2025-12-19
Supported by:
This study was supported by Basic Scientific Research Project of the Educational Department of Liaoning Province (LJKFZ20220249).

摘要/Abstract

摘要： 目的探究免疫缺陷鼠和非免疫缺陷鼠在切牙稳态维持和损伤修复的过程对切牙生长速度、矿化的影响以及免疫的参与情况，为临床再生医学提供新的思路和理论基础。方法选用8~10周龄雄性BALB/c Nude小鼠（n=10），BALB/c小鼠(n=10)和C57BL/6J小鼠（n=10），通过机械方法构建切牙损伤修复模型，连续3 d在每天固定的时间测量各组鼠断牙侧、非断牙侧和正常对照侧切牙长度，计算其生长速度，检测免疫反应变化，组织形态学分析对比牙体硬组织矿化程度；实时荧光定量反转录聚合酶链式反应（real-time quantitative reverse transcription polymerase chain reaction, RT-qPCR），免疫组化（immunohistochemistry，IHC）和免疫荧光（immunofluorescence，IF）法检测小鼠颈环处免疫相关细胞因子受体的表达和干细胞增殖情况等。结果 BALB/c Nude小鼠无论是在稳态维持还是切牙损伤情况下，其切牙生长速度均慢于BALB/c和C57BL/6J小鼠（P<0.05），提示免疫反应可能参与小鼠切牙的修复再生过程。小鼠切牙生长速度夜间明显快于昼间。切牙损伤刺激牙齿加速生长（P<0.05），且断牙侧颈环处干细胞增殖水平升高，SOX2⁺干细胞和Ki67⁺细胞数量增加（P<0.05）。组织学染色显示，断牙侧牙体硬组织矿化程度低于非断牙侧和正常对照侧（P<0.05），与其修复相关的Dspp、Ambn的mRNA表达增强（P<0.05）。IF结果显示Th2细胞因子IL4受体(interleukin 4 receptor alpha,IL4rα)的表达显著高于非断牙侧和正常对照侧，相关mRNA表达也与其一致。结论损伤会加速切牙生长速度，刺激颈环干细胞增殖和分化。初期修复的硬组织矿化程度低。T细胞缺乏可能影响切牙的稳态维持和修复再生能力，Ⅱ型免疫细胞因子受体IL4rα的高表达与修复过程密切相关，其具体功能机制有待进一步研究。

关键词: 损伤修复, 小鼠切牙生长, 颈环, 矿化, 免疫, 再生

Abstract: Objective To evaluate the different responses in immunodeficient mice and immunocompetent mice during incisor homeostasis maintenance and injury repair. Methods The mice aged 8-10 weeks were used, which include male BALB/c Nude mice (n=10), BALB/c mice (n=10), and C57BL/6J mice (n=10). A mechanical injury model was established in the incisors, and the length of the incisors was measured at a fixed time every day for three consecutive days, and their growth rate was calculated. Comparisons were made between clipped and non-clipped sides, as well as normal controls. Immunological responses were assessed, and histological analyses were conducted to evaluate mineralization in dental hard tissues. Real-time quantitative reverse transcription polymerase chain reaction (RT-qPCR), immunohistochemistry (IHC), and immunofluorescence (IF) staining were employed to detect the expression of immune-related cytokine receptors and to assess stem cell proliferation in the cervical loop. Results BALB/c Nude mice demonstrated significantly lower incisor growth rates under both homeostatic maintenance and injury conditions compared to BALB/c and C57BL/6J mice (P<0.05), suggesting that immune responses may contribute to incisor regeneration. Growth rates were markedly higher at night than during the day. The injury stimulated an accelerated incisor growth (P<0.05), with increased proliferation of cervical loop stem cells, as indicated by elevated numbers of SOX2⁺ and Ki-67⁺ cells (P<0.05). Histological staining revealed reduced mineralization on the clipped side compared to the unclipped and normal control side (P<0.05). Additionally, expression levels of Dspp, Ambn, genes involved in dentin and enamel formation, were significantly upregulated (P<0.05). IF staining showed that the expression of the Th2 cytokine receptor interleukin 4 receptor alpha（IL4rα）was significantly increased on the clipped side, consistent with mRNA expression levels. Conclusion The incisor injury promotes growth and enhances stem cell proliferation and differentiation in the cervical loop. Early repair is characterized with reduced mineralization of hard tissues. This study suggests that T cell deficiency may affect the homeostatic repair and regeneration ability of incisors, and the high expression of type Ⅱ immune cytokine receptor IL4rα is closely related to the repair process. Further, it is necessary to study the specific functional mechanism to delineates the role of immune participation, thereby providing a novel theoretical framework for clinical regenerative medicine.

Key words: injury repair, mouse incisor growth, cervical loop, mineralization, immunity, regeneration

中图分类号:

R782.1

苌旭, 张婧, 李娟娟, 刘亮亮, 史暄阁, 尚宇彤, 王福. 免疫缺陷鼠和非免疫缺陷鼠切牙稳态维持和损伤修复比较[J]. 首都医科大学学报, 2025, 46(6): 1011-1018.

Chang Xu, Zhang Jing, Li Juanjuan, Liu Liangliang, Shi Xuange, Shang Yutong, Wang Fu. Comparison of incisor homeostatic maintenance and injury repair in immunodeficient mice and immunocompetent mice[J]. Journal of Capital Medical University, 2025, 46(6): 1011-1018.

参考文献

［1］Sabeti M, Golchert K, Torabinejad M. Regeneration of pulp-dentin complex in a tooth with symptomatic irreversible pulpitis and open apex using regenerative endodontic procedures［J］. J Endod, 2021, 47(2):247-252.
［2］Li X L, Fan W, Fan B. Dental pulp regeneration strategies: a review of status quo and recent advances［J］. Bioact Mater, 2024, 38: 258-275.
［3］Volponi A A, Pang Y, Sharpe P T. Stem cell-based biological tooth repair and regeneration［J］. Trends Cell Biol, 2010, 20(12): 715-722.
［4］Walker J V, Zhuang H, Singer D, et al. Transit amplifying cells coordinate mouse incisor mesenchymal stem cell activation［J］. Nat Commun, 2019, 10(1): 3596.
［5］Chen S, Jing J J, Yuan Y, et al. Runx2+ niche cells maintain incisor mesenchymal tissue homeostasis through IGF signaling［J］. Cell Rep, 2020, 32(6): 108007.
［6］Pang Y W, Feng J F, Daltoe F, et al. Perivascular stem cells at the tip of mouse incisors regulate tissue regeneration［J］. J Bone Miner Res, 2016, 31(3): 514-523.
［7］An Z W, Akily B, Sabalic M, et al. Regulation of mesenchymal stem to transit-amplifying cell transition in the continuously growing mouse incisor［J］. Cell Rep, 2018, 23(10): 3102-3111.
［8］Seidel K, Marangoni P, Tang C, et al. Resolving stem and progenitor cells in the adult mouse incisor through gene co-expression analysis［J］. Elife, 2017, 6: e24712.
［9］Krivanek J, Soldatov R A, Kastriti M E, et al. Dental cell type Atlas reveals stem and differentiated cell types in mouse and human teeth［J］. Nat Commun, 2020, 11(1): 4816.
［10］An Z W, Sabalic M, Bloomquist R F, et al. A quiescent cell population replenishes mesenchymal stem cells to drive accelerated growth in mouse incisors［J］. Nat Commun, 2018, 9(1): 378.
［11］Klein O D, Minowada G, Peterkova R, et al. Sprouty genes control diastema tooth development via bidirectional antagonism of epithelial-mesenchymal FGF signaling［J］. Dev Cell, 2006, 11(2): 181-190.
［12］Yoshida R, Kobayashi K, Onuma K, et al. Enhancement of differentiation and mineralization of human dental pulp stem cells via TGF-β signaling in low-level laser therapy using Er: YAG lasers［J］. J Oral Biosci, 2025, 67(1): 100617.
［13］Zhang W B, Yelick P C. Tooth repair and regeneration: potential of dental stem cells［J］. Trends Mol Med, 2021, 27(5): 501-511.
［14］Zheng J X, Yu R C, Tang Y Q, et al. Cdc42 deletion yielded enamel defects by disrupting mitochondria and producing reactive oxygen species in dental epithelium［J］. Genes Dis, 2024, 11(5): 101194.
［15］Yu F Y, Li F F, Zheng L W, et al. Epigenetic controls of sonic hedgehog guarantee fidelity of epithelial adult stem cells trajectory in regeneration［J］. Sci Adv, 2022, 8(29): eabn4977.
［16］Annunziato F, Romagnani C, Romagnani S. The 3 major types of innate and adaptive cell-mediated effector immunity［J］. J Allergy Clin Immunol, 2015, 135(3): 626-635.
［17］Wynn T A. Type 2 cytokines: mechanisms and therapeutic strategies［J］. Nat Rev Immunol, 2015, 15(5): 271-282.
［18］Heredia J E, Mukundan L, Chen F M, et al. Type 2 innate signals stimulate fibro/adipogenic progenitors to facilitate muscle regeneration［J］. Cell, 2013, 153(2): 376-388.
［19］Jakovija A, Chtanova T. Skin immunity in wound healing and cancer［J］. Front Immunol, 2023, 14: 1060258.
［20］Moon S, Hong J, Go S, et al. Immunomodulation for tissue repair and regeneration［J］. Tissue Eng Regen Med, 2023, 20(3): 389-409.
［21］Chen F M, Tse J K, Jin L G, et al. Type 2 innate immunity drives distinct neonatal immune profile conducive for heart regeneration［J］. Theranostics, 2022, 12(3): 1161-1172.
［22］Shi C, Yuan Y, Guo Y, et al. BMP signaling in regulating mesenchymal stem cells in incisor homeostasis［J］. J Dent Res, 2019, 98(8): 904-911.
［23］Yang G, Zhou J, Teng Y, et al. Mesenchymal TGF-β signaling orchestrates dental epithelial stem cell homeostasis through Wnt signaling［J］. Stem Cells, 2014, 32(11): 2939-2948.
［24］Matsubara T, Iga T, Sugiura Y, et al. Coupling of angiogenesis and odontogenesis orchestrates tooth mineralization in mice［J］. J Exp Med, 2022, 219(4): e20211789.
［25］Barilla R M, Berard C, Sun L Y, et al. Type 2 cytokines act on enteric sensory neurons to regulate neuropeptide-driven host defense［J］. Science, 2025, 389(6757): 260-267.
［26］Tay E, Cremin M, Sanchez K, et al. The sympathetic nervous system enhances host immune responses to enteric bacterial pathogens in mice［J］. Brain Behav Immun, 2025, 129: 898-909.

免疫缺陷鼠和非免疫缺陷鼠切牙稳态维持和损伤修复比较

Comparison of incisor homeostatic maintenance and injury repair in immunodeficient mice and immunocompetent mice

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