Gli1 + Periodontal Mesenchymal Stem Cells in Periodontitis

Abstract

Periodontal mesenchymal stem cells (MSCs) play a crucial role in maintaining periodontium homeostasis and in tissue repair. However, little is known about how periodontal MSCs in vivo respond under periodontal disease conditions, posing a challenge for periodontium tissue regeneration. In this study, Gli1 was used as a periodontal MSC marker and combined with a Gli1-cre ERT2 mouse model for lineage tracing to investigate periodontal MSC fate in an induced periodontitis model. Our findings show significant changes in the number and contribution of Gli1⁺ MSCs within the inflamed periodontium. The number of Gli1⁺ MSCs that contributed to periodontal ligament homeostasis decreased in the periodontitis-induced teeth. While the proliferation of Gli1⁺ MSCs had no significant difference between the periodontitis and the control groups, more Gli1⁺ MSCs underwent apoptosis in diseased teeth. In addition, the number of Gli1⁺ MSCs for osteogenic differentiation decreased during the progression of periodontitis. Following tooth extraction, the contribution of Gli1⁺ MSCs to the tooth socket repair was significantly reduced in the periodontitis-induced teeth. Collectively, these findings indicate that the function of Gli1⁺ MSCs in periodontitis was compromised, including reduced contribution to periodontium homeostasis and impaired injury response.

Keywords

periodonal disease cell lineage alveolar bone loss inflammation regeneration biomarkers

Get full access to this article

View all access options for this article.

References

Chrepa

Pitcher

Henry

Diogenes

. 2017. Survival of the apical papilla and its resident stem cells in a case of advanced pulpal necrosis and apical periodontitis. J Endod. 43(4):561–567.

de Molon

Park

Jin

Sugai

Cirelli

. 2018. Characterization of ligature-induced experimental periodontitis. Microsc Res Tech. 81(12):1412–1421.

Shen

Huang

Fuh

. 2020. Risk factors related to late failure of dental implant-a systematic review of recent studies. Int J Environ Res Public Health. 17(11):3931

Hajishengallis

. 2015. Periodontitis: from microbial immune subversion to systemic inflammation. Nat Rev Immunol. 15(1):30–44.

Hienz

Paliwal

Ivanovski

. 2015. Mechanisms of bone resorption in periodontitis. J Immunol Res. 2015:615486.

Iwayama

Iwashita

Miyashita

Sakashita

Matsumoto

Tomita

Bhongsatiern

Kitayama

Ikegami

Shimbo

, et al. 2022. Plap-1 lineage tracing and single-cell transcriptomics reveal cellular dynamics in the periodontal ligament. Development. 149(19):1–9.

Jung

Ioannidis

Hämmerle

CHF

Thoma

. 2018. Alveolar ridge preservation in the esthetic zone. Periodontol 2000. 77(1):165–175.

Kitaura

Marahleh

Ohori

Noguchi

Shen

Nara

Pramusita

Kinjo

Mizoguchi

. 2020. Osteocyte-related cytokines regulate osteoclast formation and bone resorption. Int J Mol Sci. 21(14):5169.

Lei

Lin

Zhou

Wang

. 2022. Treatment of inflammatory bone loss in periodontitis by stem cell-derived exosomes. Acta Biomater. 141:333–343.

10.

Liang

Liu

. 2021. Pyrophosphate inhibits periodontal ligament stem cell differentiation and mineralization through MAPK signaling pathways. J Periodontal Res. 56(5):982–990.

11.

Liang

Luan

Liu

. 2020. Recent advances in periodontal regeneration: a biomaterial perspective. Bioact Mater. 5(2):297–308.

12.

Liang

Shakya

Liu

. 2022. Biomimetic tubular matrix induces periodontal ligament principal fiber formation and inhibits osteogenic differentiation of periodontal ligament stem cells. ACS Appl Mater Interfaces. 14(32):36451–36461.

13.

Liu

Zhang

Chen

Sui

Liu

Zhai

Bai

Chen

Jin

, et al. 2020. Mechanosensing by Gli1⁺ cells contributes to the orthodontic force-induced bone remodelling. Cell Prolif. 53(5):e12810.

14.

Men

Wang

Jing

Luo

Shen

Stenberg

Chai

Feng

, et al. 2020. Gli1+ periodontium stem cells are regulated by osteocytes and occlusal force. Dev Cell. 54(5):639–654.

15.

Ouchi

Nakagawa

. 2020. Mesenchymal stem cell -based tissue regeneration therapies for periodontitis. Regen Ther. 14:72–78.

16.

Roguljic

Matthews

Yang

Cvija

Mina

Kalajzic

. 2013. In vivo identification of periodontal progenitor cells. J Dent Res. 92(8):709–715.

17.

Sadek

El Moshy

Radwan

Rady

Abbass

MMS

El-Rashidy

Dörfer

Fawzy El-Sayed

. 2023. Molecular basis beyond interrelated bone resorption/regeneration in periodontal diseases: a concise review. Int J Mol Sci. 24(5):4599.

18.

Shalehin

Seki

Takebe

Fujii

Mizoguchi

Nakamura

Yoshiba

Iijima

Shimo

, et al. 2022. Gli1⁺-PDL cells contribute to alveolar bone homeostasis and regeneration. J Dent Res. 101(12):1537–1543.

19.

Shi

Lee

McKenzie

Silva

Long

. 2017. Gli1 identifies osteogenic progenitors for bone formation and fracture repair. Nat Commun. 8(1):2043.

20.

Slots

Bragd

Wikström

Dahlén

. 1986. The occurrence of Actinobacillus actinomycetemcomitans, Bacteroides gingivalis and Bacteroides intermedius in destructive periodontal disease in adults. J Clin Periodontol. 13(6):570–577.

21.

Snipes

Sun

. 2021. Inhibition of sphingosine-1-phosphate receptor 2 attenuated ligature-induced periodontitis in mice. Oral Dis. 27(5):1283–1291.

22.

Tomokiyo

Wada

Maeda

. 2019. Periodontal ligament stem cells: regenerative potency in periodontium. Stem Cells Dev. 28(15):974–985.

23.

Tonetti

Eickholz

Loos

Papapanou

van der Velden

Armitage

Bouchard

Deinzer

Dietrich

Hughes

, et al. 2015. Principles in prevention of periodontal diseases: consensus report of group 1 of the 11th European Workshop on Periodontology on Effective Prevention of Periodontal and Peri-Implant Diseases. J Clin Periodontol. 42(Suppl 16):S5–S11.

24.

Tonetti

Van Dyke

. 2013. Periodontitis and atherosclerotic cardiovascular disease: consensus report of the joint EFP/AAP workshop on periodontitis and systemic diseases. J Periodontol. 84(4 Suppl):S24–S29.

25.

Wei

Fei

Wang

. 2018. Activation of autophagy in periodontal ligament mesenchymal stem cells promotes angiogenesis in periodontitis. J Periodontol. 89(6):718–727.

26.

Xie

Wang

Zhang

Jing

Wang

Zhao

Feng

. 2019. Axin2⁺-mesenchymal PDL cells, instead of K14⁺ epithelial cells, play a key role in rapid cementum growth. J Dent Res. 98(11):1262–1270.

27.

Xie

Zhao

Wang

Feng

. 2021. A biphasic feature of Gli1⁺-mesenchymal progenitors during cementogenesis that is positively controlled by Wnt/β-catenin signaling. J Dent Res. 100(11):1289–1298.

28.

Liu

Men

Wang

Zhao

. 2022. Advances in periodontal stem cells and the regulating niche: from in vitro to in vivo. Genesis. 60(8-9):e23494.

29.

Stenberg

Luo

Feng

Zhao

. 2021. Alveolar bone marrow gli1+ stem cells support implant osseointegration. J Dent Res. 101(1):73–82.

30.

Yuan

Pei

Zhao

Tulu

Liu

Helms

. 2018. A Wnt-responsive PDL population effectuates extraction socket healing. J Dent Res. 97(7):803–809.

31.

Zhang

Wang

Xue

Sheng

Xiong

Wen

Fan

, et al. 2020. LepR-expressing stem cells are essential for alveolar bone regeneration. J Dent Res. 99(11):1279–1286.

32.

Zhang

Deng

Hao

Tang

. 2021. Periodontal ligament stem cells in the periodontitis niche: inseparable interactions and mechanisms. J Leukoc Biol. 110(3):565–576.

33.

Zheng

Chen

Albiero

Vieira

GHA

Wang

Feng

Graves

. 2018. Diabetes activates periodontal ligament fibroblasts via NF-κB in vivo. J Dent Res. 97(5):580–588.

34.

Zheng

Wang

Jin

. 2015. Periodontitis promotes the proliferation and suppresses the differentiation potential of human periodontal ligament stem cells. Inter J Mol Med. 36(4):915–922.

35.

Zheng

Dong

Yang

Jin

Zheng

Zhou

Liang

Bao

Feng

, et al. 2019. Exosomal microRNA-155-5p from PDLSCS regulated Th17/Treg balance by targeting sirtuin-1 in chronic periodontitis. J Cell Physiol. 234(11):20662–20674.

36.

Zhou

Graves

. 2022. Impact of the host response and osteoblast lineage cells on periodontal disease. Front Immunol. 13:998244.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

12.34 MB

0.12 MB