Gli2 and Gli3 synergistically mediate HH-TGF-β crosstalk in mesenchymal progenitor cells to orchestrate tooth root morphogenesis

Tao Zhou; Linyang Huang; Yaxin Xie; Yijia Yin; Yufei Yao; Li Mei; Paul R. Cooper; Hu Zhao; Xianglong Han; Junjun Jing

doi:10.1038/s41368-026-00427-6

International Journal of Oral Science ›› 2026, Vol. 18 ›› Issue (1) :30 DOI: 10.1038/s41368-026-00427-6

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Gli2 and Gli3 synergistically mediate HH-TGF-β crosstalk in mesenchymal progenitor cells to orchestrate tooth root morphogenesis

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Hedgehog (HH) signaling is essential in directing the fate determination of postmigratory cranial neural crest cells (CNCCs) to ensure proper craniofacial development. Gli transcription factors (TFs) are established as primary effectors of HH signaling, yet their distinct roles and regulatory mechanisms in governing cell commitment and differentiation of postmigratory CNCCs remain poorly understood. Here, using tooth root as a model, we combined transgenic mouse models with bioinformatic analyses to interrogate the functions of Gli2 and Gli3 in CNCC-derived root progenitor cells of the mouse molar. We revealed that loss of Gli3 alone in dental mesenchymal root progenitor cells caused shortened roots and that concurrent loss of Gli2 and Gli3 exacerbated root malformations, concomitant with profound impairments in cell proliferation and multilineage differentiation, suggesting a synergistic interaction between Gli2 and Gli3 during tooth root development. Mechanistically, Gli2 and Gli3 cooperatively regulated the transcription of Acvr2b, thereby modulating the activity of TGF-β/SMAD signaling within the dental mesenchyme. This Gli2/Gli3-TGF-β signaling cascade was critical for the lineage specification of tooth root progenitor cells during molar morphogenesis. Collectively, this work uncovers synergistic interactions of Gli2 and Gli3 in orchestrating tooth root morphogenesis and provides a novel insight into HH-TGF-β crosstalk in cell fate decisions of postmigratory CNCCs.

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Tao Zhou, Linyang Huang, Yaxin Xie, Yijia Yin, Yufei Yao, Li Mei, Paul R. Cooper, Hu Zhao, Xianglong Han, Junjun Jing. Gli2 and Gli3 synergistically mediate HH-TGF-β crosstalk in mesenchymal progenitor cells to orchestrate tooth root morphogenesis. International Journal of Oral Science, 2026, 18(1): 30 DOI:10.1038/s41368-026-00427-6

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Roth DM, Bayona F, Baddam P, Graf D. Craniofacial development: neural crest in molecular embryology. Head. Neck. Pathol.. 2021, 15: 1-15.

[2]	Jones NCet al. . Prevention of the neurocristopathy Treacher Collins syndrome through inhibition of p53 function. Nat. Med.. 2008, 14: 125-133.

[3]	Niu X, Zhang F, Gu W, Zhang B, Chen X. FBLN2 is associated with Goldenhar syndrome and is essential for cranial neural crest cell development. Ann. N. Y. Acad. Sci.. 2024, 1537: 113-128.

[4]	Musa REet al. . BRD4 binds to active cranial neural crest enhancers to regulate RUNX2 activity during osteoblast differentiation. Development. 2024, 151. dev202110

[5]	Dworkin S, Boglev Y, Owens H, Goldie SJ. The role of sonic hedgehog in craniofacial patterning, morphogenesis and cranial neural crest survival. J. Dev. Biol.. 2016, 4: 24.

[6]	Jeong J, Mao J, Tenzen T, Kottmann AH, McMahon AP. Hedgehog signaling in the neural crest cells regulates the patterning and growth of facial primordia. Genes. Dev.. 2004, 18937-951.

[7]	Li Jet al. . Suppressor of Fused restraint of Hedgehog activity level is critical for osteogenic proliferation and differentiation during calvarial bone development. J. Biol. Chem.. 2017, 292: 15814-15825.

[8]	Meng Pet al. . Three GLI2 mutations combined potentially underlie non-syndromic cleft lip with or without cleft palate in a Chinese pedigree. Mol. Genet. Genom. Med.. 2019, 7. e714

[9]	Chang CF, Chang YT, Millington G, Brugmann SA. Craniofacial ciliopathies reveal specific requirements for GLI proteins during development of the facial midline. PLoS. Genet.. 2016, 12: e1006351.

[10]	Vortkamp A, Gessler M, Grzeschik KH. GLI3 zinc-finger gene interrupted by translocations in Greig syndrome families. Nature. 1991, 352539-540.

[11]	Mo Ret al. . Specific and redundant functions of Gli2 and Gli3 zinc finger genes in skeletal patterning and development. Development. 1997, 124: 113-123.

[12]	Elliott KHet al. . Gli3 utilizes Hand2 to synergistically regulate tissue-specific transcriptional networks. Elife. 2020, 9: 24.

[13]	Cobourne MT, Sharpe PT. Tooth and jaw: molecular mechanisms of patterning in the first branchial arch. Arch. Oral. Biol.. 2003, 481-14.

[14]	Li J, Parada C, Chai Y. Cellular and molecular mechanisms of tooth root development. Development. 2017, 144: 374-384.

[15]	Hosoya A, Shalehin N, Takebe H, Shimo T, Irie K. Sonic Hedgehog signaling and tooth development. Int. J. Mol. Sci.. 2020, 21: 1587.

[16]	Liu Yet al. . An Nfic-hedgehog signaling cascade regulates tooth root development. Development. 2015, 1423374-3382

[17]	Nakatomi M, Morita I, Eto K, Ota MS. Sonic hedgehog signaling is important in tooth root development. J. Dent. Res.. 2006, 85: 427-431.

[18]	Jing Jet al. . Spatiotemporal single-cell regulatory atlas reveals neural crest lineage diversification and cellular function during tooth morphogenesis. Nat. Commun.. 2022, 13. 4803

[19]	Feng Jet al. . BMP signaling orchestrates a transcriptional network to control the fate of mesenchymal stem cells in mice. Development. 2017, 144: 2560-2569.

[20]	Wang Y, Cox MK, Coricor G, MacDougall M, Serra R. Inactivation of Tgfbr2 in Osterix-Cre expressing dental mesenchyme disrupts molar root formation. Dev. Biol.. 2013, 382: 27-37.

[21]	Zhang Ret al. . Transforming growth factor-β signaling regulates tooth root dentinogenesis by cooperation with Wnt signaling. Front. Cell. Dev. Biol.. 2021, 9: 687099.

[22]	Iwata Jet al. . Transforming growth factor-beta regulates basal transcriptional regulatory machinery to control cell proliferation and differentiation in cranial neural crest-derived osteoprogenitor cells. J. Biol. Chem.. 2010, 2854975-4982.

[23]	Ferguson CAet al. . The role of effectors of the activin signalling pathway, activin receptors IIA and IIB, and Smad2, in patterning of tooth development. Development. 2001, 128: 4605-4613.

[24]	Chen Cet al. . Ganoderma lucidum polysaccharide inhibits HSC activation and liver fibrosis via targeting inflammation, apoptosis, cell cycle, and ECM-receptor interaction mediated by TGF-β/Smad signaling. Phytomedicine. 2023, 110. 154626

[25]	Okuhara Set al. . Temporospatial sonic hedgehog signalling is essential for neural crest-dependent patterning of the intrinsic tongue musculature. Development. 2019, 146. dev180075

[26]	Sun MRet al. . Sonic hedgehog signaling in cranial neural crest cells regulates microvascular morphogenesis in facial development. Front. Cell. Dev. Biol.. 2020, 8: 590539.

[27]	Xu Ret al. . Gnas loss causes chondrocyte fate conversion in cranial suture formation. J. Dent. Res.. 2022, 101931-941.

[28]	Li Jet al. . BMP-SHH signaling network controls epithelial stem cell fate via regulation of its niche in the developing tooth. Dev. Cell.. 2015, 33: 125-135.

[29]	Pei Fet al. . Sensory nerve regulates progenitor cells via FGF-SHH axis in tooth root morphogenesis. Development. 2024, 151. dev202043

[30]	Prochazka Jet al. . Migration of founder epithelial cells drives proper molar tooth positioning and morphogenesis. Dev. Cell.. 2015, 35: 713-724.

[31]	Nagata Met al. . A Hedgehog-Foxf axis coordinates dental follicle-derived alveolar bone formation. Nat. Commun.. 2025, 16. 6061

[32]	Hwang SH, White KA, Somatilaka BN, Wang B, Mukhopadhyay S. Context-dependent ciliary regulation of hedgehog pathway repression in tissue morphogenesis. PLoS. Genet. 2023, 19. e1011028

[33]	Takahashi Yet al. . Counterregulatory roles of GLI2 and GLI3 in osteogenic differentiation via Gli1 expression. J. Cell. Sci.. 2025, 138: jcs263556.

[34]	Lopez-Rios Jet al. . GLI3 constrains digit number by controlling both progenitor proliferation and BMP-dependent exit to chondrogenesis. Dev. Cell.. 2012, 22837-848.

[35]	Veistinen Let al. . Loss-of-function of Gli3 in mice causes abnormal frontal bone morphology and premature synostosis of the interfrontal suture. Front. Physiol.. 2012, 3: 121.

[36]	Lei Q, Zelman AK, Kuang E, Li S, Matise MP. Transduction of graded Hedgehog signaling by a combination of Gli2 and Gli3 activator functions in the developing spinal cord. Development. 2004, 1313593-3604.

[37]	Motoyama Jet al. . Essential function of Gli2 and Gli3 in the formation of lung, trachea and oesophagus. Nat. Genet.. 1998, 20: 54-57.

[38]	Buttitta L, Mo R, Hui CC, Fan CM. Interplays of Gli2 and Gli3 and their requirement in mediating Shh-dependent sclerotome induction. Development. 2003, 130: 6233-6243.

[39]	Sasaki H, Nishizaki Y, Hui C, Nakafuku M, Kondoh H. Regulation of Gli2 and Gli3 activities by an amino-terminal repression domain: implication of Gli2 and Gli3 as primary mediators of Shh signaling. Development. 1999, 126: 3915-3924.

[40]	Ruiz I, Altaba A. Gli proteins encode context-dependent positive and negative functions: implications for development and disease. Development. 1999, 126: 3205-3216.

[41]	Gozum, G. et al. Specific and redundant roles for Gli2 and Gli3 in establishing cell fate during murine hair follicle development. Embo. J. (2025).

[42]	Bai CB, Stephen D, Joyner AL. All mouse ventral spinal cord patterning by hedgehog is Gli dependent and involves an activator function of Gli3. Dev. Cell.. 2004, 6: 103-115.

[43]	Tominaga K, Suzuki HI. TGF-β signaling in cellular senescence and aging-related pathology. Int. J. Mol. Sci.. 2019, 20: 5002.

[44]	Mullen AC, Wrana JL. TGF-β family signaling in embryonic and somatic stem-cell renewal and differentiation. Cold. Spring Harb. Perspect. Biol.. 2017, 9a022186.

[45]	Rothstein M, Azambuja AP, Kanno TY, Breen C, Simoes-Costa M. TGF-β signaling controls neural crest developmental plasticity via SMAD2/3. Dev. Cell.. 2025, 601686-1701.e1687.

[46]	Rowan, C. J. et al. Hedgehog-GLI signaling in Foxd1-positive stromal cells promotes murine nephrogenesis via TGFβ signaling. Development145, dev159947, (2018).

[47]	Liu Yet al. . Hedgehog signaling reprograms hair follicle niche fibroblasts to a hyper-activated state. Dev. Cell.. 2022, 57: 1758-1775.e1757.

[48]	Dias JMet al. . A Shh/Gli-driven three-node timer motif controls temporal identity and fate of neural stem cells. Sci. Adv.. 2020, 6. eaba8196

[49]	Li Qet al. . Stromal Gli signaling regulates the activity and differentiation of prostate stem and progenitor cells. J. Biol. Chem.. 2018, 293: 10547-10560.

Funding

National Natural Science Foundation of China (National Science Foundation of China)(82370915)

National Key R&D Program of China (2024YFC2510700), Innovative Research Group of the National Natural Science Foundation of Sichuan Province (2025NSFTD0026).