低氧增强人牙周膜干细胞干性促进骨再生的作用研究

口腔生物医学 ›› 2025, Vol. 16 ›› Issue (2): 72-80.

低氧增强人牙周膜干细胞干性促进骨再生的作用研究

马佳慧¹,肖轶婧¹,李梓睿¹,陈旭¹,徐艳²

1. 南京医科大学附属口腔医院牙周病科，口腔疾病研究与防治国家级重点实验室培育建设点，江苏省口腔转化医学工程研究中心
2. 南京医科大学口腔医学院

收稿日期:2025-02-10 修回日期:2025-03-03 出版日期:2025-04-25 发布日期:2025-05-08
通讯作者: 徐艳 E-mail:yanxu@njmu.edu.cn
基金资助:
江苏省研究生实践创新计划;江苏省卫健委重点项目;国家自然科学基金;国家自然科学基金;江苏省卫健委重点项目;江苏省科教能力提升工程-江苏省研究型医院;江苏省医学创新中心

The study on the effect of hypoxia on enhancing the stemness of hPDLSCs to promote bone regeneration

Received:2025-02-10 Revised:2025-03-03 Online:2025-04-25 Published:2025-05-08

摘要/Abstract

摘要： 目的：研究低氧培养环境下人牙周膜干细胞(hPDLSCs)干性特征的改变及其对体内外成骨分化的影响。方法：常氧和低氧环境下培养hPDLSCs，通过CCK-8和集落形成实验研究其增殖能力，β-半乳糖苷酶染色检测细胞衰老情况，实时荧光定量PCR和Western blot实验检测干性相关基因性别决定区Y框蛋白2（SOX2）、八聚体结合转录因子4（OCT4）和NANOG表达水平。收集两种培养环境下的hPDLSCs上清液作为条件培养基配制成骨诱导液，在常氧环境下对hPDLSCs进行成骨诱导，利用碱性磷酸酶(ALP)染色、茜素红染色及实时荧光定量PCR实验检测成骨相关基因Ⅰ型胶原（COL-1）、骨桥蛋白（OPN）、骨钙蛋白（OCN）、Runt相关转录因子2（RUNX2）表达研究hPDLSCs体外促成骨分化能力。将两种培养环境预处理的hPDLSCs细胞膜片植入大鼠颅骨临界骨缺损，8周后取材进行显微计算机断层扫描（micro-CT）、HE染色、Masson染色、免疫组化染色和荧光染料标记新骨实验，检测hPDLSCs体内促成骨分化能力。结果：低氧环境下，hPDLSCs增殖能力增强（P＜0.05），衰老水平下降（P＜0.05），SOX2、OCT4、NANOG基因和蛋白表达均增强（P＜0.05）。低氧培养hPDLSCs条件培养基体外促进hPDLSCs成骨分化，ALP活性增高、钙结节形成增多（P＜0.05），COL-1、OPN、OCN、RUNX2基因表达升高（P＜0.05）。低氧培养hPDLSCs细胞膜片植入骨缺损区后，新骨形成增多，镜下新生骨发出荧光面积更大、强度更强，大鼠颅骨骨体积分数(BV/TV)明显升高（P＜0.05），HE和Masson染色观察骨缺损边缘可见大量新生骨组织，周围可见骨细胞及大量的胶原纤维。免疫组化结果显示OPN、OCN蛋白表达增高（P＜0.05）。结论：在低氧环境下，hPDLSCs的干性增强，低氧预处理的hPDLSCs体内外促进细胞成骨分化。

关键词: 人牙周膜干细胞, 低氧, 干性, 骨再生

Abstract: Objective: To investigate the changes in stemness characteristics of human periodontal ligament stem cells (hPDLSCs) under hypoxia environment and their effects on osteogenic differentiation in vitro and in vivo. Methods: hPDLSCs were cultured under normoxia and hypoxia environment, and their proliferative ability was studied by CCK-8 and colony forming unit experiments. The senescence was detected by β-galactosidase staining. The expression of stemnessrelated genes sex determining region of Y-box protein 2 (SOX2), octamer binding transcription factor 4 (OCT4) and NANOG was studied by qRT-PCR and Western blot experiments. The supernatant of hPDLSCs under two culture environments was collected and used as the conditioned medium to configure the osteogenic induction medium, then osteogenic induction of hPDLSCs was performed under normoxia. The alkaline phosphatase (ALP) staining, alizarin red staining and the expression of osteogenicrelated genes collagen type Ⅰ(COL-1), osteopontin (OPN), osteocalcin (OCN) and runt related transcription factor 2 (RUNX2) detected by qRT-PCR assay were used to study the ability of hPDLSCs to promote osteogenic differentiation in vitro. Cell membrane sheets of hPDLSCs pretreated in two culture environments were implanted into the critical bone defects of rats skulls, tissue samples were collected after 8 weeks, and microcomputed tomography (micro-CT), HE staining, Masson staining, immunohistochemical staining and fluorescent dyes labeling new bone experiment were used to study the ability of hPDLSCs to promote osteogenic differentiation in vivo. Results: Under hypoxia conditions, the proliferation ability of hPDLSCs was increased (P＜0.05), the level of senescence was decreased (P＜0.05), and the expressions of SOX2, OCT4, and NANOG genes and proteins were all enhanced (P＜0.05). Using hPDLSCs conditioned medium cultured in hypoxia to promote hPDLSCs osteogenic differentiation in vitro, the ALP activity increased, calcium nodule formation increased (P＜0.05), and the expressions of COL-1, OPN, OCN and RUNX2 were increased (P＜0.05). After implanting the hypoxia cultured hPDLSCs cell sheets into the bone defects, new bone formation increased, the area of fluorescent emitted by new bone was larger and the intensity was stronger. Bone volume fraction of rat skull ［bone volume (BV)/tissue volume (TV)］ was significantly increased (P＜0.05), and a large number of new bone tissues at the edge of the bone defect with surrounding osteocytes and a large number of collagen fibers were observed by HE and Masson staining. Immunohistochemical results showed increased expression of OPN and OCN proteins (P＜0.05). Conclusion: Under hypoxia environment, the stemness of hPDLSCs is enhanced, and hypoxia pretreated hPDLSCs promote osteogenic differentiation of cells in vitro and in vivo.

Key words: Human periodontal ligament stem cells, Hypoxia, Stemness, Bone regeneration

马佳慧肖轶婧李梓睿陈旭徐艳. 低氧增强人牙周膜干细胞干性促进骨再生的作用研究[J]. 口腔生物医学, 2025, 16(2): 72-80.

参考文献

[3]W L ,X H ,W Y , et al.Activation of Functional Somatic Stem Cells Promotes Endogenous Tissue Regeneration.[J].Journal of dental research,2022,101(7):220345211070222-220345211070222.
[6]Kengo I ,Motohiro K ,Keiko A , et al.Spontaneous differentiation of periodontal ligament stem cells into myofibroblast during ex vivo expansion.[J].Journal of cellular physiology,2019,234(11):20377-20391.
[8]Daniel O ,Amancio C .Cellular senescence or stemness: hypoxia flips the coin.[J].Journal of experimental & clinical cancer research : CR,2021,40(1):243-243.
[12]Dos Santos F, Andrade PZ, Boura JS, et al. Ex vivo expansion of human mesenchymal stem cells: a more effective cell proliferation kinetics and metabolism under hypoxia [J]. Cell Physiol, 2010，223(1): 27-35
[13]Jin Y, Kato T, Furu M, et al. Mesenchymal stem cells cultured under hypoxia escape from senescence via down-regulation of p16 and extracellular signal regulated kinase [J]. Biochem Biophys Res Commun, 2010, 391(3): 1471-1476
[14]Hung SP, Ho JH, Shih YR, et al. Hypoxia promotes proliferation and osteogenic differentiation potentials of human mesenchymal stem cells[J]. Orthop Res, 2012, 30(2): 260-266
[20]Okano T, Yamada N, Sakai H, et al.A novel recovery system for cultured cells using plasma-treated polystyrene dishes grafted with poly(N-isopropylacrylamide)[J].J Biomed Mater Res,1993, 27 (10): 1243-51
[21]Akahane M, Nakamura A, Ohgushi H, et al.Osteogenic matrix sheet-cell transplantation using osteoblastic cell sheet resulted in bone formation without scaffold atan ectopic site[J].J Tissue Eng Regen Med,2008, 2 (4): 196-201.
[22]Wang F, Hu Y, He D, et al.Scaffold-free cartilage cell sheet combined with bone- phase BMSCs-scaffold regenerate osteochondral construct in mini-pig model[J].Am JTransl Res,2018, 10 (10): 2997-3010.

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