Tppp3 + synovial/tendon sheath progenitor cells contribute to heterotopic bone after trauma

Ji-Hye Yea , Mario Gomez-Salazar , Sharon Onggo , Zhao Li , Neelima Thottappillil , Masnsen Cherief , Stefano Negri , Xin Xing , Qizhi Qin , Robert Joel Tower , Chen-Ming Fan , Benjamin Levi , Aaron W. James

Bone Research ›› 2023, Vol. 11 ›› Issue (1) : 39

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Bone Research ›› 2023, Vol. 11 ›› Issue (1) : 39 DOI: 10.1038/s41413-023-00272-x
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Tppp3 + synovial/tendon sheath progenitor cells contribute to heterotopic bone after trauma

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Abstract

Heterotopic ossification (HO) is a pathological process resulting in aberrant bone formation and often involves synovial lined tissues. During this process, mesenchymal progenitor cells undergo endochondral ossification. Nonetheless, the specific cell phenotypes and mechanisms driving this process are not well understood, in part due to the high degree of heterogeneity of the progenitor cells involved. Here, using a combination of lineage tracing and single-cell RNA sequencing (scRNA-seq), we investigated the extent to which synovial/tendon sheath progenitor cells contribute to heterotopic bone formation. For this purpose, Tppp3 (tubulin polymerization-promoting protein family member 3)-inducible reporter mice were used in combination with either Scx (Scleraxis) or Pdgfra (platelet derived growth factor receptor alpha) reporter mice. Both tendon injury- and arthroplasty-induced mouse experimental HO models were utilized. ScRNA-seq of tendon-associated traumatic HO suggested that Tppp3 is an early progenitor cell marker for either tendon or osteochondral cells. Upon HO induction, Tppp3 reporter + cells expanded in number and partially contributed to cartilage and bone formation in either tendon- or joint-associated HO. In double reporter animals, both Pdgfra + Tppp3 + and Pdgfra + Tppp3 - progenitor cells gave rise to HO-associated cartilage. Finally, analysis of human samples showed a substantial population of TPPP3-expressing cells overlapping with osteogenic markers in areas of heterotopic bone. Overall, these data demonstrate that synovial/tendon sheath progenitor cells undergo aberrant osteochondral differentiation and contribute to HO after trauma.

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Ji-Hye Yea, Mario Gomez-Salazar, Sharon Onggo, Zhao Li, Neelima Thottappillil, Masnsen Cherief, Stefano Negri, Xin Xing, Qizhi Qin, Robert Joel Tower, Chen-Ming Fan, Benjamin Levi, Aaron W. James. Tppp3 + synovial/tendon sheath progenitor cells contribute to heterotopic bone after trauma. Bone Research, 2023, 11(1): 39 DOI:10.1038/s41413-023-00272-x

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Negri S et al. Acetabular reaming is a reliable model to produce and characterize periarticular heterotopic ossification of the hip. Stem Cell Transl. Med, 2022, 11: 876-888

[2]

McCarthy E, Sundaram M. Heterotopic ossification: a review. Skeletal Radiol., 2005, 34: 609-619

[3]

Lin L, Shen Q, Xue T, Yu C. Heterotopic ossification induced by Achilles tenotomy via endochondral bone formation: expression of bone and cartilage related genes. Bone, 2010, 46: 425-431

[4]

Meyers C et al. Heterotopic Ossification: A Comprehensive Review. JBMR Plus, 2019, 3: e10172

[5]

Wittenberg RH, Peschke U, Botel U. Heterotopic ossification after spinal-cord injury-epidemiology and risk-factors. J. Bone Joint Surgery-British Volume, 1992, 74: 215-218

[6]

Garland DE. Clinical observations on fractures and heterotopic ossification in the spinal-cord and traumatic brain injured populations. Clin. Orthop. Relat. R, 1988, 233: 86-101

[7]

Kan C et al. Microenvironmental factors that regulate mesenchymal stem cells: lessons learned from the study of heterotopic ossification. Histol. Histopathol., 2017, 32: 977-985
[8]

Nelson ER, Wong VW, Krebsbach PH, Wang SC, Levi B. Heterotopic ossification following burn injury: the role of stem cells. J. Burn Care Res., 2012, 33: 463-470

[9]

Zhang Q, Zhou D, Wang HT, Tan J. Heterotopic ossification of tendon and ligament. J. Cellular Mol. Med., 2020, 24: 5428-5437

[10]

Agarwal S et al. Scleraxis-lineage cells contribute to ectopic bone formation in muscle and tendon. Stem Cells, 2017, 35: 705-710

[11]

Pagani CA et al. Novel lineage-tracing system to identify site-specific ectopic bone precursor cells. Stem Cell Rep., 2021, 16: 626-640

[12]

Regard JB et al. Activation of hedgehog signaling by loss of GNAS causes heterotopic ossification. Nat. Med., 2013, 19: 1505-1512

[13]

Dey D et al. Two tissue-resident progenitor lineages drive distinct phenotypes of heterotopic ossification. Sci. Transl. Medicine, 2016, 8: 366ra163

[14]

Kan C et al. Gli1-labeled adult mesenchymal stem/progenitor cells and hedgehog signaling contribute to endochondral heterotopic ossification. Bone, 2018, 109: 71-79

[15]

Farahani RM, Xaymardan M. Platelet-derived growth factor receptor alpha as a marker of mesenchymal stem cells in development and stem cell biology. Stem Cells Int, 2015, 2015: 362753

[16]

Bi Y et al. Identification of tendon stem/progenitor cells and the role of the extracellular matrix in their niche. Nat. Med., 2007, 13: 1219-1227

[17]

Lee CH et al. Harnessing endogenous stem/progenitor cells for tendon regeneration. J. Clinical Invest., 2015, 125: 2690-2701

[18]

Gumucio JP, Schonk MM, Kharaz YA, Comerford E, Mendias CL. Scleraxis is required for the growth of adult tendons in response to mechanical loading. JCI Insight, 2020, 5: e138295

[19]

Harvey T, Flamenco S, Fan CM. A Tppp3(+)Pdgfra(+) tendon stem cell population contributes to regeneration and reveals a shared role for PDGF signalling in regeneration and fibrosis. Nat. Cell Biol., 2019, 21: 1490-1503

[20]

Lee SY et al. NGF-TrkA signaling dictates neural in growth and aberrant osteochondral differentiation after soft tissue trauma. Nat. Commun, 2021, 12: 4939

[21]

Staverosky JA, Pryce BA, Watson SS, Schweitzer R. Tubulin polymerization‐promoting protein family member 3, Tppp3, is a specific marker of the differentiating tendon sheath and synovial joints. Dev. Dyn., 2009, 238: 685-692

[22]

Zhang Y-J et al. Concise review: stem cell fate guided by bioactive molecules for tendon regeneration. Stem Cell Transl. Med., 2018, 7: 404-414

[23]

Convente MR, Wang HT, Pignolo RJ, Kaplan FS, Shore EM. The immunological contribution to heterotopic ossification disorders. Curr. Osteoporos. Rep., 2015, 13: 116-124

[24]

Hwang C et al. Mesenchymal VEGFA induces aberrant differentiation in heterotopic ossification. Bone Res, 2019, 7: 36

[25]

Yang L, Tsang KY, Tang HC, Chan D, Cheah KS. Hypertrophic chondrocytes can become osteoblasts and osteocytes in endochondral bone formation. Proc. Natl. Acad. Sci., 2014, 111: 12097-12102

[26]

Tarafder S et al. Tendon stem/progenitor cells regulate inflammation in tendon healing via JNK and STAT3 signaling. Faseb J., 2017, 31: 3991-3998

[27]

Hsu GCY et al. Endogenous CCN family member WISP1 inhibits traumainduced heterotopic ossification. JCI Insight, 2020, 5: e135432

[28]

Yea J-H, Bae TS, Kim BJ, Cho YW, Jo CH. Regeneration of the Rotator Cuff Tendon-to-Bone Interface using Umbilical Cord-Derived Mesenchymal Stem Cells and Gradient Extracellular Matrix Scaffolds from Adipose Tissue in a Rat Model. Acta Biomater, 2020, 114: 104-116

[29]

Yea J-H et al. Regeneration of a full-thickness defect of rotator cuff tendon with freshly thawed umbilical cord-derived mesenchymal stem cells in a rat model. Stem Cell Res. Ther., 2020, 11: 1-13

[30]

Yea JH et al. Regeneration of a full-thickness defect in rotator cuff tendon with umbilical cord-derived mesenchymal stem cells in a rat model. PLoS One, 2020, 15: e0235239

[31]

Qin QZ et al. Neuron-to-vessel signaling is a required feature of aberrant stem cell commitment after soft tissue trauma. Bone Res, 2022, 10: 43

[32]

Qiu XJ et al. Reversed graph embedding resolves complex single-cell trajectories. Nat. Methods, 2017, 14: 979-982

[33]

Huang DW, Sherman BT, Lempicki RA. Systematic and integrative analysis of large gene lists using DAVID bioinformatics resources. Nat. Protoc., 2009, 4: 44-57

Funding

American Cancer Society (American Cancer Society, Inc.)(RSG-18-027-01-CSM)

U.S. Department of Health & Human Services | NIH | National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS)

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