Endochondral Growth Defect and Deployment of Transient Chondrocyte Behaviors Underlie Osteoarthritis Onset in a Natural Murine Model

OBJECTIVE: To explore whether aberrant transient chondrocyte behaviors occur in the joints of STR/Ort mice (which spontaneously develop osteoarthritis [OA]) and whether they are attributable to an endochondral growth defect. METHODS: Knee joints from STR/Ort mice with advanced OA and age‐matched CBA...

Descripción completa

Detalles Bibliográficos
Autores principales: Staines, K. A., Madi, K., Mirczuk, S. M., Parker, S., Burleigh, A., Poulet, B., Hopkinson, M., Bodey, A. J., Fowkes, R. C., Farquharson, C., Lee, P. D., Pitsillides, A. A.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: John Wiley and Sons Inc. 2016
Materias:
Osteoarthritis
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4832379/
https://www.ncbi.nlm.nih.gov/pubmed/26605758
http://dx.doi.org/10.1002/art.39508
_version_ 1782427247664168960
author Staines, K. A.
Madi, K.
Mirczuk, S. M.
Parker, S.
Burleigh, A.
Poulet, B.
Hopkinson, M.
Bodey, A. J.
Fowkes, R. C.
Farquharson, C.
Lee, P. D.
Pitsillides, A. A.
author_facet Staines, K. A.
Madi, K.
Mirczuk, S. M.
Parker, S.
Burleigh, A.
Poulet, B.
Hopkinson, M.
Bodey, A. J.
Fowkes, R. C.
Farquharson, C.
Lee, P. D.
Pitsillides, A. A.
author_sort Staines, K. A.
collection PubMed
description OBJECTIVE: To explore whether aberrant transient chondrocyte behaviors occur in the joints of STR/Ort mice (which spontaneously develop osteoarthritis [OA]) and whether they are attributable to an endochondral growth defect. METHODS: Knee joints from STR/Ort mice with advanced OA and age‐matched CBA (control) mice were examined by Affymetrix microarray profiling, multiplex polymerase chain reaction (PCR) analysis, and immunohistochemical labeling of endochondral markers, including sclerostin and MEPE. The endochondral phenotype of STR/Ort mice was analyzed by histologic examination, micro–computed tomography, and ex vivo organ culture. A novel protocol for quantifying bony bridges across the murine epiphysis (growth plate fusion) using synchrotron x‐ray computed microtomography was developed and applied. RESULTS: Meta‐analysis of transcription profiles showed significant elevation in functions linked with endochondral ossification in STR/Ort mice (compared to CBA mice; P < 0.05). Consistent with this, immunolabeling revealed increased matrix metalloproteinase 13 (MMP‐13) and type X collagen expression in STR/Ort mouse joints, and multiplex quantitative reverse transcriptase–PCR showed differential expression of known mineralization regulators, suggesting an inherent chondrocyte defect. Support for the notion of an endochondral defect included accelerated growth, increased zone of growth plate proliferative chondrocytes (P < 0.05), and widespread type X collagen/MMP‐13 labeling beyond the expected hypertrophic zone distribution. OA development involved concomitant focal suppression of sclerostin/MEPE in STR/Ort mice. Our novel synchrotron radiation microtomography method showed increased numbers (P < 0.001) and mean areal growth plate bridge densities (P < 0.01) in young and aged STR/Ort mice compared to age‐matched CBA mice. CONCLUSION: Taken together, our data support the notion of an inherent endochondral defect that is linked to growth dynamics and subject to regulation by the MEPE/sclerostin axis and may represent an underlying mechanism of pathologic ossification in OA.
format Online
Article
Text
id pubmed-4832379
institution National Center for Biotechnology Information
language English
publishDate 2016
publisher John Wiley and Sons Inc.
record_format MEDLINE/PubMed
spelling pubmed-48323792016-04-20 Endochondral Growth Defect and Deployment of Transient Chondrocyte Behaviors Underlie Osteoarthritis Onset in a Natural Murine Model Staines, K. A. Madi, K. Mirczuk, S. M. Parker, S. Burleigh, A. Poulet, B. Hopkinson, M. Bodey, A. J. Fowkes, R. C. Farquharson, C. Lee, P. D. Pitsillides, A. A. Arthritis Rheumatol Osteoarthritis OBJECTIVE: To explore whether aberrant transient chondrocyte behaviors occur in the joints of STR/Ort mice (which spontaneously develop osteoarthritis [OA]) and whether they are attributable to an endochondral growth defect. METHODS: Knee joints from STR/Ort mice with advanced OA and age‐matched CBA (control) mice were examined by Affymetrix microarray profiling, multiplex polymerase chain reaction (PCR) analysis, and immunohistochemical labeling of endochondral markers, including sclerostin and MEPE. The endochondral phenotype of STR/Ort mice was analyzed by histologic examination, micro–computed tomography, and ex vivo organ culture. A novel protocol for quantifying bony bridges across the murine epiphysis (growth plate fusion) using synchrotron x‐ray computed microtomography was developed and applied. RESULTS: Meta‐analysis of transcription profiles showed significant elevation in functions linked with endochondral ossification in STR/Ort mice (compared to CBA mice; P < 0.05). Consistent with this, immunolabeling revealed increased matrix metalloproteinase 13 (MMP‐13) and type X collagen expression in STR/Ort mouse joints, and multiplex quantitative reverse transcriptase–PCR showed differential expression of known mineralization regulators, suggesting an inherent chondrocyte defect. Support for the notion of an endochondral defect included accelerated growth, increased zone of growth plate proliferative chondrocytes (P < 0.05), and widespread type X collagen/MMP‐13 labeling beyond the expected hypertrophic zone distribution. OA development involved concomitant focal suppression of sclerostin/MEPE in STR/Ort mice. Our novel synchrotron radiation microtomography method showed increased numbers (P < 0.001) and mean areal growth plate bridge densities (P < 0.01) in young and aged STR/Ort mice compared to age‐matched CBA mice. CONCLUSION: Taken together, our data support the notion of an inherent endochondral defect that is linked to growth dynamics and subject to regulation by the MEPE/sclerostin axis and may represent an underlying mechanism of pathologic ossification in OA. John Wiley and Sons Inc. 2016-03-28 2016-04 /pmc/articles/PMC4832379/ /pubmed/26605758 http://dx.doi.org/10.1002/art.39508 Text en © 2016 The Authors. Arthritis & Rheumatology published by Wiley Periodicals, Inc. on behalf of the American College of Rheumatology. This is an open access article under the terms of the Creative Commons Attribution (http://creativecommons.org/licenses/by/4.0/) License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.
spellingShingle Osteoarthritis
Staines, K. A.
Madi, K.
Mirczuk, S. M.
Parker, S.
Burleigh, A.
Poulet, B.
Hopkinson, M.
Bodey, A. J.
Fowkes, R. C.
Farquharson, C.
Lee, P. D.
Pitsillides, A. A.
Endochondral Growth Defect and Deployment of Transient Chondrocyte Behaviors Underlie Osteoarthritis Onset in a Natural Murine Model
title Endochondral Growth Defect and Deployment of Transient Chondrocyte Behaviors Underlie Osteoarthritis Onset in a Natural Murine Model
title_full Endochondral Growth Defect and Deployment of Transient Chondrocyte Behaviors Underlie Osteoarthritis Onset in a Natural Murine Model
title_fullStr Endochondral Growth Defect and Deployment of Transient Chondrocyte Behaviors Underlie Osteoarthritis Onset in a Natural Murine Model
title_full_unstemmed Endochondral Growth Defect and Deployment of Transient Chondrocyte Behaviors Underlie Osteoarthritis Onset in a Natural Murine Model
title_short Endochondral Growth Defect and Deployment of Transient Chondrocyte Behaviors Underlie Osteoarthritis Onset in a Natural Murine Model
title_sort endochondral growth defect and deployment of transient chondrocyte behaviors underlie osteoarthritis onset in a natural murine model
topic Osteoarthritis
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4832379/
https://www.ncbi.nlm.nih.gov/pubmed/26605758
http://dx.doi.org/10.1002/art.39508
work_keys_str_mv AT staineska endochondralgrowthdefectanddeploymentoftransientchondrocytebehaviorsunderlieosteoarthritisonsetinanaturalmurinemodel
AT madik endochondralgrowthdefectanddeploymentoftransientchondrocytebehaviorsunderlieosteoarthritisonsetinanaturalmurinemodel
AT mirczuksm endochondralgrowthdefectanddeploymentoftransientchondrocytebehaviorsunderlieosteoarthritisonsetinanaturalmurinemodel
AT parkers endochondralgrowthdefectanddeploymentoftransientchondrocytebehaviorsunderlieosteoarthritisonsetinanaturalmurinemodel
AT burleigha endochondralgrowthdefectanddeploymentoftransientchondrocytebehaviorsunderlieosteoarthritisonsetinanaturalmurinemodel
AT pouletb endochondralgrowthdefectanddeploymentoftransientchondrocytebehaviorsunderlieosteoarthritisonsetinanaturalmurinemodel
AT hopkinsonm endochondralgrowthdefectanddeploymentoftransientchondrocytebehaviorsunderlieosteoarthritisonsetinanaturalmurinemodel
AT bodeyaj endochondralgrowthdefectanddeploymentoftransientchondrocytebehaviorsunderlieosteoarthritisonsetinanaturalmurinemodel
AT fowkesrc endochondralgrowthdefectanddeploymentoftransientchondrocytebehaviorsunderlieosteoarthritisonsetinanaturalmurinemodel
AT farquharsonc endochondralgrowthdefectanddeploymentoftransientchondrocytebehaviorsunderlieosteoarthritisonsetinanaturalmurinemodel
AT leepd endochondralgrowthdefectanddeploymentoftransientchondrocytebehaviorsunderlieosteoarthritisonsetinanaturalmurinemodel
AT pitsillidesaa endochondralgrowthdefectanddeploymentoftransientchondrocytebehaviorsunderlieosteoarthritisonsetinanaturalmurinemodel

Ejemplares similares