Sage Journals: Discover world-class research

Abstract

During orofacial tissue development, the anterior and posterior regions of the Meckel’s cartilage undergo mineralization, while the middle region undergoes degeneration. Despite the interesting and particular phenomena, the mechanisms that regulate the different fates of Meckel’s cartilage, including the effects of biomechanical cues, are still unclear. Therefore, the purpose of this study was to systematically investigate the course of Meckel’s cartilage during embryonic development from a biomechanical perspective. Histomorphological and biomechanical (stiffness) changes in the Meckel’s cartilage were analyzed from embryonic day 12 to postnatal day 0. The results revealed remarkable changes in the morphology and size of chondrocytes, as well as the occurrence of chondrocyte burst in the vicinity of the mineralization site, an often-seen phenomenon preceding endochondral ossification. To understand the effect of biomechanical cues on Meckel’s cartilage fate, a mechanically tuned 3-dimensional hydrogel culture system was used. At the anterior region, a moderately soft environment (10-kPa hydrogel) promoted chondrocyte burst and ossification. On the contrary, at the middle region, a more rigid environment (40-kPa hydrogel) enhanced cartilage degradation by inducing a higher expression of MMP-1 and MMP-13. These results indicate that differences in the biomechanical properties of the surrounding environment are essential factors that distinctly guide the mineralization and degradation of Meckel’s cartilage and would be valuable tools for modulating in vitro cartilage and bone tissue engineering.

Keywords

mechanotransduction tissue engineering extracellular matrix chondrocyte burst hydrogel biomimetics

Get full access to this article

View all access options for this article.

References

Beaupré

Stevens

Carter

. 2000. Mechanobiology in the development, maintenance and degeneration of articular cartilage. J Rehabil Res Dev. 37(2):145–151.

Blain

. 2007. Mechanical regulation of matrix metalloproteinases. Front Biosci. 12(2):507–527.

Carter

Van der Meulen

Beaupré

. 1996. Mechanical factors in bone growth and development. Bone. 18(1):5S–10S.

Engler

Sen

Sweeney

Discher

. 2006. Matrix elasticity directs stem cell lineage specification. Cell. 126(4):677–689.

Farahat

Kazi

GAS

Taketa

Hara

Oshima

Kuboki

Matsumoto

. 2019. Fibronectin-induced ductal formation in salivary gland self-organization model. Dev Dyn. 248(9):813–825.

Frommer

Margolies

. 1971. Contribution of Meckel’s cartilage to ossification of the mandible in mice. J Dent Res. 50(5):1260–1267.

Guilak

Erickson

Ting-Beall

. 2002. The effects of osmotic stress on the viscoelastic and physical properties of articular chondrocytes. Biophys J. 82(2):720–727.

Hall

. 2015. Bones and cartilage: developmental and evolutionary skeletal biology. 2nd ed. Cambridge (MA): Academic Press.

Hara

Okada

Kuboki

Nakano

Matsumoto

. 2018. Rapid bioinspired mineralization using cell membrane nanofragments and alkaline milieu. J Mater Chem B. 6(38):6153–6161.

10.

Hara

Okada

Nagaoka

Hattori

Iida

Kuboki

Nakano

Matsumoto

. 2018. Chondrocyte burst promotes space for mineral expansion. Integr Biol (Camb). 10(1):57–66.

11.

Havens

Velonis

Kronenberg

Lichtler

Oliver

Mina

. 2008. Roles of FGFR3 during morphogenesis of Meckel’s cartilage and mandibular bones. Dev Biol. 316(2):336–349.

12.

Inoue

Tanikawa

Arai

. 2008. Micro-manipulation system with a two-fingered micro-hand and its potential application in bioscience. J Biotechnol. 133(2):219–224.

13.

Ishizeki

Nawa

. 2000. Further evidence for secretion of matrix metalloproteinase-1 by Meckel’s chondrocytes during degradation of the extracellular matrix. Tissue Cell. 32(3):207–215.

14.

Ishizeki

Shinagawa

Nawa

. 2003. Origin-associated features of chondrocytes in mouse Meckel’s cartilage and costal cartilage: an in vitro study. Ann Anat. 185(5):403–410.

15.

Ishizeki

Takahashi

Nawa

. 2001. Formation of the sphenomandibular ligament by Meckel’s cartilage in the mouse: possible involvement of epidermal growth factor as revealed by studies in vivo and in vitro. Cell Tissue Res. 304(1):67–80.

16.

Kantomaa

Tuominen

Pirttiniemi

. 1994. Effect of mechanical forces on chondrocyte maturation and differentiation in the mandibular condyle of the rat. J Dent Res. 73(6):1150–1156.

17.

Kim

Lee

Won

Lee

Kwak

Chun

. 2015. Matrix cross-linking-mediated mechanotransduction promotes posttraumatic osteoarthritis. Proc Natl Acad Sci U S A. 112(30):9424–9429.

18.

Kong

Liu

Riddle

Matsumoto

Leach

Mooney

. 2005. Non-viral gene delivery regulated by stiffness of cell adhesion substrates. Nat Mater. 4(6):460–464.

19.

Ladoux

Mege

. 2017. Mechanobiology of collective cell behaviours. Nat Rev Mol Cell Biol. 18(12):743–757.

20.

Marchant

Anderson

Schwarz

Wiszniak

. 2020. Vessel-derived angiocrine IGF1 promotes Meckel’s cartilage proliferation to drive jaw growth during embryogenesis. Development. 147(11):dev190488.

21.

Matsumoto

Yung

Fischbach

Kong

Nakaoka

Mooney

. 2007. Mechanical strain regulates endothelial cell patterning in vitro. Tissue Eng. 13(1):207–217.

22.

Mauney

Sjostorm

Blumberg

Horan

O’Leary

Vunjak-Novakovic

Volloch

Kaplan

. 2004. Mechanical stimulation promotes osteogenic differentiation of human bone marrow stromal cells on 3-D partially demineralized bone scaffolds in vitro. Calcif Tissue Int. 74(5):458–468.

23.

Miyajima

Matsumoto

Sakai

Yamaguchi

Abe

Wakisaka

Lee

Egusa

Imazato

. 2011. Hydrogel-based biomimetic environment for in vitro modulation of branching morphogenesis. Biomaterials. 32(28):6754–6763.

24.

Pacifici

Golden

Oshima

Shapiro

Leboy

Adams

. 1990. Hypertrophic chondrocytes. The terminal stage of differentiation in the chondrogenic cell lineage? Ann N Y Acad Sci. 599:45−57.

25.

Rolfe

Roddy

Murphy

. 2013. Mechanical regulation of skeletal development. Curr Osteoporos Rep. 11(2):107–116.

26.

Sakakura

Hosokawa

Tsuruga

Irie

Nakamura

Yajima

. 2007. Contributions of matrix metalloproteinases toward Meckel’s cartilage resorption in mice: immunohistochemical studies, including comparisons with developing endochondral bones. Cell Tissue Res. 328(1):137–151.

27.

Sathi

Farahat

Hara

Taketa

Nagatsuka

Kuboki

Matsumoto

. 2017. MCSF orchestrates branching morphogenesis in developing submandibular gland tissue. J Cell Sci. 130(9):1559–1569.

28.

Sathi

Kenmizaki

Yamaguchi

Nagatsuka

Yoshida

Matsugaki

Ishimoto

Imazato

Nakano

Matsumoto

. 2015. Early initiation of endochondral ossification of mouse femur cultured in hydrogel with different mechanical stiffness. Tissue Eng Part C Methods. 21(6):567–575.

29.

Shimo

Kanyama

Sugito

Billings

Abrams

Rosenbloom

Iwamoto

Pacifici

Koyama

. 2004. Expression and roles of connective tissue growth factor in Meckel’s cartilage development. Dev Dyn. 231(1):136–147.

30.

Taketa

Gulsan

Farahat

Rahman

Sakai

Hirano

Kuboki

Torii

Matsumoto

. 2015. Peptide-modified substrate for modulating gland tissue growth and morphology in vitro. Sci Rep. 5:11468.

31.

Ten Cate

. 1998. Oral histology: development, structure, and function. 5th ed. St. Louis (MO): Mosby. p. 24–49.

32.

Trichilis

Wroblewski

. 1997. Expression of p53 and hsp70 in relation to apoptosis during Meckel’s cartilage development in the mouse. Anat Embryol. 196(2):107–113.

33.

Tsuzurahara

Soeta

Kawawa

Baba

Nakamura

. 2011. The role of macrophages in the disappearance of Meckel’s cartilage during mandibular development in mice. Acta Histochem. 113(2):194–200.

34.

van Donkelaar

Wilson

. 2012. Mechanics of chondrocyte hypertrophy. Biomech Model Mechanobiol. 11(5):655–664.

35.

Wozniak

Chen

. 2009. Mechanotransduction in development: a growing role for contractility. Nat Rev Mol Cell Biol. 10(1):34–43.

36.

Yang

Zhang

Liu

Zhou

. 2012. Autophagy prior to chondrocyte cell death during the degeneration of Meckel’s cartilage. Anat Rec. 295(5):734–741.

37.

Young

Chuang

Gefen

Kuo

Yang

Hsu

. 2017. A novel compressive stress-based osteoarthritis-like chondrocyte system. Exp Biol Med (Maywood). 242(10):1062–1071.

38.

Zhao

Wang

Zhao

Fang

. 2020. Mechanotransduction pathways in the regulation of cartilage chondrocyte homoeostasis. J Cell Mol Med. 24(10):5408–5419.

39.

Zhou

von der Mark

Henry

Norton

Adams

de Crombrugghe

. 2014. Chondrocytes transdifferentiate into osteoblasts in endochondral bone during development, postnatal growth and fracture healing in mice. PLoS Genet. 10(12):e1004820.

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

Effect of Biomechanical Environment on Degeneration of Meckel’s Cartilage

Abstract

Keywords

Get full access to this article

References

Supplementary Material