Postnatal changes to the mechanical properties of articular cartilage are driven by the evolution of its collagen network

Gannon, Alanna R.; Nagel, Thomas; Bell, Alan P.; Avery, Nicholas C.; Kelly, Daniel J.

doi:10.22203/ecm.v029a09

Cited by 74 publications

(78 citation statements)

References 71 publications

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“…It is only over postnatal life that the tissue grows in thickness and acquires its distinct zonal organization and cell columnar arrangement (Gannon et al, 2015; Julkunen et al, 2009), while the total number of cell layers remains about the same. How this transition occurs is a question that has vexed researchers for years.…”

Section: Introductionmentioning

confidence: 99%

Cell origin, volume and arrangement are drivers of articular cartilage formation, morphogenesis and response to injury in mouse limbs

Decker

Dyment

et al. 2017

Developmental Biology

123

162

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Limb synovial joints are composed of distinct tissues, but it is unclear which progenitors produce those tissues and how articular cartilage acquires its functional postnatal organization characterized by chondrocyte columns, zone-specific cell volumes and anisotropic matrix. Using novel Gdf5CreERT2 (Gdf5-CE), Prg4-CE and Dkk3-CE mice mated to R26-Confetti or single-color reporters, we found that knee joint progenitors produced small non-migratory progenies and distinct local tissues over prenatal and postnatal time. Stereological imaging and quantification indicated that the columns present in juvenile-adult tibial articular cartilage consisted of non-daughter, partially overlapping lineage cells, likely reflecting cell rearrangement and stacking. Zone-specific increases in cell volume were major drivers of tissue thickening, while cell proliferation or death played minor roles. Second harmonic generation with 2-photon microscopy showed that the collagen matrix went from being isotropic and scattered at young stages to being anisotropic and aligned along the cell stacks in adults. Progenitor tracing at prenatal or juvenile stages showed that joint injury provoked a massive and rapid increase in synovial Prg4+ and CD44+/P75+ cells some of which filling the injury site, while neighboring chondrocytes appeared unresponsive. Our data indicate that local cell populations produce distinct joint tissues and that articular cartilage growth and zonal organization are mainly brought about by cell volume expansion and topographical cell rearrangement. Synovial Prg4+ lineage progenitors are exquisitely responsive to acute injury and may represent pioneers in joint tissue repair.

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Section: Introductionmentioning

confidence: 99%

Cell origin, volume and arrangement are drivers of articular cartilage formation, morphogenesis and response to injury in mouse limbs

Decker

Dyment

et al. 2017

Developmental Biology

123

162

View full text Add to dashboard Cite

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“…While the tissue is highly cellular and isotropic at birth, unique zones develop as the tissue matures. This unique zonal architecture allows the articular cartilage to withstand significant shear and compressive forces throughout a joint's range of motion (Gannon et al, 2014; Helminen et al, 2000; Mienaltowski et al, 2008). At the surface adjacent to the joint cavity, the superficial zone is composed of elongated, flattened cells oriented parallel to the articular surface.…”

Section: Introductionmentioning

confidence: 99%

Articular cartilage and joint development from embryogenesis to adulthood

Decker

2017

Seminars in Cell & Developmental Biology

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Within each synovial joint, the articular cartilage is uniquely adapted to bear dynamic compressive loads and shear forces throughout the joint's range of motion. Injury and age-related degeneration of the articular cartilage often lead to significant pain and disability, as the intrinsic repair capability of the tissue is extremely limited. Current surgical and biological treatment options have been unable to restore cartilage de novo. Before successful clinical cartilage restoration strategies can be developed, a better understanding of how the cartilage forms during normal development is essential. This review focuses on recent progress made towards addressing key questions about articular cartilage morphogenesis, including the origin of synovial joint progenitor cells and postnatal development and growth of the tissue. These advances have provided novel insight into fundamental questions about the developmental biology of articular cartilage, as well as potential cell sources that may participate in joint response to injury.

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“…Neonatal AC is functional but is not yet weight‐bearing and has not yet stratified into distinct functional zones like mature,adult AC(Brama, TeKoppele, Bank, Barneveld, & van Weeren, ; Brommer et al, ; Hunziker, Kapfinger, & Geiss, ). The cellular density of neonatal AC is much greater than in mature tissue, and it is primed to grow and expand as the body undergoes the rapid weight gain and increasing functional demands of early childhood development (Gannon, Nagel, Bell, Avery, & Kelly, ; Jadin, Bae, Schumacher, & Sah, ). A key result of this expansion and maturation takes the form of zone‐dependent collagen fibril organization and stiffening, which ultimately provide the tissue with its complex composite mechanical properties (Gannon et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…The cellular density of neonatal AC is much greater than in mature tissue, and it is primed to grow and expand as the body undergoes the rapid weight gain and increasing functional demands of early childhood development (Gannon, Nagel, Bell, Avery, & Kelly, ; Jadin, Bae, Schumacher, & Sah, ). A key result of this expansion and maturation takes the form of zone‐dependent collagen fibril organization and stiffening, which ultimately provide the tissue with its complex composite mechanical properties (Gannon et al, ). The rapid pace of AC expansion in early development also raises the possibility that it may be the appropriate phenotype to alleviate another long‐standing issue in the field of AC grafting—failure of the graft tissue to integrate with the surrounding native tissue.…”

Section: Introductionmentioning

confidence: 99%

Transcriptome dynamics of long noncoding RNAs and transcription factors demarcate human neonatal, adult, and human mesenchymal stem cell‐derived engineered cartilage

Vail

Somoza

Caplan

et al. 2019

J Tissue Eng Regen Med

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The engineering of a native‐like articular cartilage (AC) is a long‐standing objective that could serve the clinical needs of millions of patients suffering from osteoarthritis and cartilage injury. An incomplete understanding of the developmental stages of AC has contributed to limited success in this endeavor. Using next generation RNA sequencing, we have transcriptionally characterized two critical stages of AC development in humans—that is, immature neonatal and mature adult, as well as tissue‐engineered cartilage derived from culture expanded human mesenchymal stem cells. We identified key transcription factors (TFs) and long noncoding RNAs (lncRNAs) as candidate drivers of the distinct phenotypes of these tissues. AGTR2, SCGB3A1, TFCP2L1, RORC, and TBX4 stand out as key TFs, whose expression may be capable of reprogramming engineered cartilage into a more expandable and neonatal‐like cartilage primed for maturation into biomechanically competent cartilage. We also identified that the transcriptional profiles of many annotated but poorly studied lncRNAs were dramatically different between these cartilages, indicating that lncRNAs may also be playing significant roles in cartilage biology. Key neonatal‐specific lncRNAs identified include AC092818.1, AC099560.1, and KC877982. Collectively, our results suggest that tissue‐engineered cartilage can be optimized for future clinical applications by the specific expression of TFs and lncRNAs.

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Postnatal changes to the mechanical properties of articular cartilage are driven by the evolution of its collagen network

Cited by 74 publications

References 71 publications

Cell origin, volume and arrangement are drivers of articular cartilage formation, morphogenesis and response to injury in mouse limbs

Cell origin, volume and arrangement are drivers of articular cartilage formation, morphogenesis and response to injury in mouse limbs

Articular cartilage and joint development from embryogenesis to adulthood

Transcriptome dynamics of long noncoding RNAs and transcription factors demarcate human neonatal, adult, and human mesenchymal stem cell‐derived engineered cartilage

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