Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Scleraxis-Lineage Cells Contribute to Ectopic Bone Formation in Muscle and Tendon.

Literature DB >> 27862618

Scleraxis-Lineage Cells Contribute to Ectopic Bone Formation in Muscle and Tendon.

Shailesh Agarwal¹, Shawn J Loder¹, David Cholok¹, Joshua Peterson¹, John Li¹, Christopher Breuler¹, R Cameron Brownley¹, Hsiao Hsin Sung¹, Michael T Chung¹, Nobuhiro Kamiya², Shuli Li¹, Bin Zhao³, Vesa Kaartinen⁴, Thomas A Davis⁵, Ammar T Qureshi⁵, Ernestina Schipani⁶, Yuji Mishina⁴, Benjamin Levi¹.

Abstract

The pathologic development of heterotopic ossification (HO) is well described in patients with extensive trauma or with hyperactivating mutations of the bone morphogenetic protein (BMP) receptor ACVR1. However, identification of progenitor cells contributing to this process remains elusive. Here we show that connective tissue cells contribute to a substantial amount of HO anlagen caused by trauma using postnatal, tamoxifen-inducible, scleraxis-lineage restricted reporter mice (Scx-creERT2/tdTomatofl/fl ). When the scleraxis-lineage is restricted specifically to adults prior to injury marked cells contribute to each stage of the developing HO anlagen and coexpress markers of endochondral ossification (Osterix, SOX9). Furthermore, these adult preinjury restricted cells coexpressed mesenchymal stem cell markers including PDGFRα, Sca1, and S100A4 in HO. When constitutively active ACVR1 (caACVR1) was expressed in scx-cre cells in the absence of injury (Scx-cre/caACVR1fl/fl ), tendons and joints formed HO. Postnatal lineage-restricted, tamoxifen-inducible caACVR1 expression (Scx-creERT2/caACVR1fl/fl ) was sufficient to form HO after directed cardiotoxin-induced muscle injury. These findings suggest that cells expressing scleraxis within muscle or tendon contribute to HO in the setting of both trauma or hyperactive BMP receptor (e.g., caACVR1) activity. Stem Cells 2017;35:705-710.

Entities: CellLine Chemical Disease Gene Species

Keywords: Adult stem cells; Bone; Fibrodysplasia ossificans progressiva; Heterotopic ossification; Osteoblast; Progenitor cells; Skeleton; Tissue specific stem cells

Mesh：

Substances：

Year: 2016 PMID： 27862618 PMCID： PMC5529170 DOI： 10.1002/stem.2515

Source DB: PubMed Journal: Stem Cells ISSN： 1066-5099 Impact factor: 6.277

17 in total

Review 1. Skeletal muscle-resident MSCs and bone formation.

Authors: Dario R Lemos; Christine Eisner; Claudia I Hopkins; Fabio M V Rossi
Journal: Bone Date: 2015-06-21 Impact factor: 4.398

Review 2. Evaluation of the cellular origins of heterotopic ossification.

Authors: Lixin Kan; John A Kessler
Journal: Orthopedics Date: 2014-05 Impact factor: 1.390

3. Treatment of heterotopic ossification through remote ATP hydrolysis.

Authors: Jonathan R Peterson; Sara De La Rosa; Oluwatobi Eboda; Katherine E Cilwa; Shailesh Agarwal; Steven R Buchman; Paul S Cederna; Chuanwu Xi; Michael D Morris; David N Herndon; Wenzhong Xiao; Ronald G Tompkins; Paul H Krebsbach; Stewart C Wang; Benjamin Levi
Journal: Sci Transl Med Date: 2014-09-24 Impact factor: 17.956

4. A recurrent mutation in the BMP type I receptor ACVR1 causes inherited and sporadic fibrodysplasia ossificans progressiva.

Authors: Eileen M Shore; Meiqi Xu; George J Feldman; David A Fenstermacher; Tae-Joon Cho; In Ho Choi; J Michael Connor; Patricia Delai; David L Glaser; Martine LeMerrer; Rolf Morhart; John G Rogers; Roger Smith; James T Triffitt; J Andoni Urtizberea; Michael Zasloff; Matthew A Brown; Frederick S Kaplan
Journal: Nat Genet Date: 2006-04-23 Impact factor: 38.330

5. Gene targeting of the transcription factor Mohawk in rats causes heterotopic ossification of Achilles tendon via failed tenogenesis.

Authors: Hidetsugu Suzuki; Yoshiaki Ito; Masahiro Shinohara; Satoshi Yamashita; Shizuko Ichinose; Akio Kishida; Takuya Oyaizu; Tomohiro Kayama; Ryo Nakamichi; Naoki Koda; Kazuyoshi Yagishita; Martin K Lotz; Atsushi Okawa; Hiroshi Asahara
Journal: Proc Natl Acad Sci U S A Date: 2016-07-01 Impact factor: 11.205

6. Scx+/Sox9+ progenitors contribute to the establishment of the junction between cartilage and tendon/ligament.

Authors: Yuki Sugimoto; Aki Takimoto; Haruhiko Akiyama; Ralf Kist; Gerd Scherer; Takashi Nakamura; Yuji Hiraki; Chisa Shukunami
Journal: Development Date: 2013-04-24 Impact factor: 6.868

7. Glast-expressing progenitor cells contribute to heterotopic ossification.

Authors: Lixin Kan; Chian-Yu Peng; Tammy L McGuire; John A Kessler
Journal: Bone Date: 2012-12-20 Impact factor: 4.398

8. Tendon progenitor cells in injured tendons have strong chondrogenic potential: the CD105-negative subpopulation induces chondrogenic degeneration.

Authors: Shuji Asai; Satoru Otsuru; Maria Elena Candela; Leslie Cantley; Kenta Uchibe; Ted J Hofmann; Kairui Zhang; Keith L Wapner; Louis J Soslowsky; Edwin M Horwitz; Motomi Enomoto-Iwamoto
Journal: Stem Cells Date: 2014-12 Impact factor: 6.277

9. Analysis of the tendon cell fate using Scleraxis, a specific marker for tendons and ligaments.

Authors: R Schweitzer; J H Chyung; L C Murtaugh; A E Brent; V Rosen; E N Olson; A Lassar; C J Tabin
Journal: Development Date: 2001-10 Impact factor: 6.868

10. Lineage tracing of resident tendon progenitor cells during growth and natural healing.

Authors: Nathaniel A Dyment; Yusuke Hagiwara; Brya G Matthews; Yingcui Li; Ivo Kalajzic; David W Rowe
Journal: PLoS One Date: 2014-04-23 Impact factor: 3.240

47 in total

Review 1. Stem cells and heterotopic ossification: Lessons from animal models.

Authors: John B Lees-Shepard; David J Goldhamer
Journal: Bone Date: 2018-01-31 Impact factor: 4.398

2. Characterizing the Circulating Cell Populations in Traumatic Heterotopic Ossification.

Authors: Shawn J Loder; Shailesh Agarwal; Michael T Chung; David Cholok; Charles Hwang; Noelle Visser; Kaetlin Vasquez; Michael Sorkin; Joe Habbouche; Hsiao H Sung; Joshua Peterson; David Fireman; Kavitha Ranganathan; Christopher Breuler; Caitlin Priest; John Li; Xue Bai; Shuli Li; Paul S Cederna; Benjamin Levi
Journal: Am J Pathol Date: 2018-08-22 Impact factor: 4.307

Review 3. TGF-β Family Signaling in Mesenchymal Differentiation.

Authors: Ingo Grafe; Stefanie Alexander; Jonathan R Peterson; Taylor Nicholas Snider; Benjamin Levi; Brendan Lee; Yuji Mishina
Journal: Cold Spring Harb Perspect Biol Date: 2018-05-01 Impact factor: 10.005

4. Activin-A enhances mTOR signaling to promote aberrant chondrogenesis in fibrodysplasia ossificans progressiva.

Authors: Kyosuke Hino; Kazuhiko Horigome; Megumi Nishio; Shingo Komura; Sanae Nagata; Chengzhu Zhao; Yonghui Jin; Koichi Kawakami; Yasuhiro Yamada; Akira Ohta; Junya Toguchida; Makoto Ikeya
Journal: J Clin Invest Date: 2017-07-31 Impact factor: 14.808

5. Immobilization after injury alters extracellular matrix and stem cell fate.

Authors: Amanda K Huber; Nicole Patel; Chase A Pagani; Simone Marini; Karthik R Padmanabhan; Daniel L Matera; Mohamed Said; Charles Hwang; Ginny Ching-Yun Hsu; Andrea A Poli; Amy L Strong; Noelle D Visser; Joseph A Greenstein; Reagan Nelson; Shuli Li; Michael T Longaker; Yi Tang; Stephen J Weiss; Brendon M Baker; Aaron W James; Benjamin Levi
Journal: J Clin Invest Date: 2020-10-01 Impact factor: 14.808

6. Shared ACVR1 mutations in FOP and DIPG: Opportunities and challenges in extending biological and clinical implications across rare diseases.

Authors: Harry J Han; Payal Jain; Adam C Resnick
Journal: Bone Date: 2017-08-02 Impact factor: 4.398

10. Tendon-derived cathepsin K-expressing progenitor cells activate Hedgehog signaling to drive heterotopic ossification.

Authors: Heng Feng; Wenhui Xing; Yujiao Han; Jun Sun; Mingxiang Kong; Bo Gao; Yang Yang; Zi Yin; Xiao Chen; Yun Zhao; Qing Bi; Weiguo Zou
Journal: J Clin Invest Date: 2020-12-01 Impact factor: 14.808