Cargando…

Tendon Cells Root Into (Instead of Attach to) Humeral Bone Head via Fibrocartilage-Enthesis

Large joints are composed of two closely linked cartilages: articular cartilage (AC; rich in type II collagen, a well-studied tissue) and fibrocartilaginous enthesis (FE; rich in type I collagen, common disorder sites of enthesopathy and sporting injuries, although receiving little attention). For m...

Descripción completa

Detalles Bibliográficos
Autores principales: Wang, Zheng, Ma, Chi, Chen, Diane, Haslett, Caitlin, Xu, Chunmei, Dong, Changchun, Wang, Xiaofang, Zheng, Minghao, Jing, Yan, Feng, Jian Q.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Ivyspring International Publisher 2023
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9760439/
https://www.ncbi.nlm.nih.gov/pubmed/36594083
http://dx.doi.org/10.7150/ijbs.79007
_version_ 1784852475564523520
author Wang, Zheng
Ma, Chi
Chen, Diane
Haslett, Caitlin
Xu, Chunmei
Dong, Changchun
Wang, Xiaofang
Zheng, Minghao
Jing, Yan
Feng, Jian Q.
author_facet Wang, Zheng
Ma, Chi
Chen, Diane
Haslett, Caitlin
Xu, Chunmei
Dong, Changchun
Wang, Xiaofang
Zheng, Minghao
Jing, Yan
Feng, Jian Q.
author_sort Wang, Zheng
collection PubMed
description Large joints are composed of two closely linked cartilages: articular cartilage (AC; rich in type II collagen, a well-studied tissue) and fibrocartilaginous enthesis (FE; rich in type I collagen, common disorder sites of enthesopathy and sporting injuries, although receiving little attention). For many years, both cartilages were thought to be formed by chondrocytes, whereas tendon, which attaches to the humeral bone head, is primarily considered as a completely different connective tissue. In this study, we raised an unconventional hypothesis: tendon cells directly form FE via cell transdifferentiation. To test this hypothesis, we first qualitatively and quantitatively demonstrated distinct differences between AC and FE in cell morphology and cell distribution, mineralization status, extracellular matrix (ECM) contents, and critical ECM protein expression profiles using comprehensive approaches. Next, we traced the cell fate of tendon cells using Scx(Lin) (a tendon specific Cre Scx(CreERT2); R26R-tdTomato line) with one-time tamoxifen induction at early (P3) or young adult (P28) stages and harvested mice at different development ages, respectively. Our early tracing data revealed different growth events in tendon and FE: an initial increase but gradual decrease in the Scx(Lin) tendon cells and a continuous expansion in the Scx(Lin) FE cells. The young adult tracing data demonstrated continuous recruitment of Scx(Lin) cells into FE expansion during P28 and P56. A separate tracing line, 3.2 Col 1(Lin) (a so-called "bone-specific" line), further confirmed the direct contribution of tendon cells for FE cell formation, which occurred in days but FE ECM maturation (including high levels of SOST, a potent Wnt signaling inhibitor) took weeks. Finally, loss of function data using diphtheria toxin fragment A (DTA) in Scx(Lin) cells demonstrated a significant reduction of Scx(Lin) cells in both tendons and FE cells, whereas the gain of function study (by stabilizing β-catenin in Scx(Lin) tendon cells via one-time injection of tamoxifen at P3 and harvesting at P60) displayed great expansion of both Scx(Lin) tendon and FE mass. Together, our studies demonstrated that fibrocartilage is an invaded enthesis likely originating from the tendon via a quick cell transdifferentiation mechanism with a lengthy ECM maturation process. The postnatally formed fibrocartilage roots into existing cartilage and firmly connects tendon and bone instead of acting as a simple attachment site as widely believed. We believe that this study will stimulate more intense exploring in this understudied area, especially for patients with enthesopathy and sporting injuries.
format Online
Article
Text
id pubmed-9760439
institution National Center for Biotechnology Information
language English
publishDate 2023
publisher Ivyspring International Publisher
record_format MEDLINE/PubMed
spelling pubmed-97604392023-01-01 Tendon Cells Root Into (Instead of Attach to) Humeral Bone Head via Fibrocartilage-Enthesis Wang, Zheng Ma, Chi Chen, Diane Haslett, Caitlin Xu, Chunmei Dong, Changchun Wang, Xiaofang Zheng, Minghao Jing, Yan Feng, Jian Q. Int J Biol Sci Research Paper Large joints are composed of two closely linked cartilages: articular cartilage (AC; rich in type II collagen, a well-studied tissue) and fibrocartilaginous enthesis (FE; rich in type I collagen, common disorder sites of enthesopathy and sporting injuries, although receiving little attention). For many years, both cartilages were thought to be formed by chondrocytes, whereas tendon, which attaches to the humeral bone head, is primarily considered as a completely different connective tissue. In this study, we raised an unconventional hypothesis: tendon cells directly form FE via cell transdifferentiation. To test this hypothesis, we first qualitatively and quantitatively demonstrated distinct differences between AC and FE in cell morphology and cell distribution, mineralization status, extracellular matrix (ECM) contents, and critical ECM protein expression profiles using comprehensive approaches. Next, we traced the cell fate of tendon cells using Scx(Lin) (a tendon specific Cre Scx(CreERT2); R26R-tdTomato line) with one-time tamoxifen induction at early (P3) or young adult (P28) stages and harvested mice at different development ages, respectively. Our early tracing data revealed different growth events in tendon and FE: an initial increase but gradual decrease in the Scx(Lin) tendon cells and a continuous expansion in the Scx(Lin) FE cells. The young adult tracing data demonstrated continuous recruitment of Scx(Lin) cells into FE expansion during P28 and P56. A separate tracing line, 3.2 Col 1(Lin) (a so-called "bone-specific" line), further confirmed the direct contribution of tendon cells for FE cell formation, which occurred in days but FE ECM maturation (including high levels of SOST, a potent Wnt signaling inhibitor) took weeks. Finally, loss of function data using diphtheria toxin fragment A (DTA) in Scx(Lin) cells demonstrated a significant reduction of Scx(Lin) cells in both tendons and FE cells, whereas the gain of function study (by stabilizing β-catenin in Scx(Lin) tendon cells via one-time injection of tamoxifen at P3 and harvesting at P60) displayed great expansion of both Scx(Lin) tendon and FE mass. Together, our studies demonstrated that fibrocartilage is an invaded enthesis likely originating from the tendon via a quick cell transdifferentiation mechanism with a lengthy ECM maturation process. The postnatally formed fibrocartilage roots into existing cartilage and firmly connects tendon and bone instead of acting as a simple attachment site as widely believed. We believe that this study will stimulate more intense exploring in this understudied area, especially for patients with enthesopathy and sporting injuries. Ivyspring International Publisher 2023-01-01 /pmc/articles/PMC9760439/ /pubmed/36594083 http://dx.doi.org/10.7150/ijbs.79007 Text en © The author(s) https://creativecommons.org/licenses/by/4.0/This is an open access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/). See http://ivyspring.com/terms for full terms and conditions.
spellingShingle Research Paper
Wang, Zheng
Ma, Chi
Chen, Diane
Haslett, Caitlin
Xu, Chunmei
Dong, Changchun
Wang, Xiaofang
Zheng, Minghao
Jing, Yan
Feng, Jian Q.
Tendon Cells Root Into (Instead of Attach to) Humeral Bone Head via Fibrocartilage-Enthesis
title Tendon Cells Root Into (Instead of Attach to) Humeral Bone Head via Fibrocartilage-Enthesis
title_full Tendon Cells Root Into (Instead of Attach to) Humeral Bone Head via Fibrocartilage-Enthesis
title_fullStr Tendon Cells Root Into (Instead of Attach to) Humeral Bone Head via Fibrocartilage-Enthesis
title_full_unstemmed Tendon Cells Root Into (Instead of Attach to) Humeral Bone Head via Fibrocartilage-Enthesis
title_short Tendon Cells Root Into (Instead of Attach to) Humeral Bone Head via Fibrocartilage-Enthesis
title_sort tendon cells root into (instead of attach to) humeral bone head via fibrocartilage-enthesis
topic Research Paper
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9760439/
https://www.ncbi.nlm.nih.gov/pubmed/36594083
http://dx.doi.org/10.7150/ijbs.79007
work_keys_str_mv AT wangzheng tendoncellsrootintoinsteadofattachtohumeralboneheadviafibrocartilageenthesis
AT machi tendoncellsrootintoinsteadofattachtohumeralboneheadviafibrocartilageenthesis
AT chendiane tendoncellsrootintoinsteadofattachtohumeralboneheadviafibrocartilageenthesis
AT haslettcaitlin tendoncellsrootintoinsteadofattachtohumeralboneheadviafibrocartilageenthesis
AT xuchunmei tendoncellsrootintoinsteadofattachtohumeralboneheadviafibrocartilageenthesis
AT dongchangchun tendoncellsrootintoinsteadofattachtohumeralboneheadviafibrocartilageenthesis
AT wangxiaofang tendoncellsrootintoinsteadofattachtohumeralboneheadviafibrocartilageenthesis
AT zhengminghao tendoncellsrootintoinsteadofattachtohumeralboneheadviafibrocartilageenthesis
AT jingyan tendoncellsrootintoinsteadofattachtohumeralboneheadviafibrocartilageenthesis
AT fengjianq tendoncellsrootintoinsteadofattachtohumeralboneheadviafibrocartilageenthesis