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  • Computational and experimental characterizations of the spatiotemporal activity and functional role of TGF-β in the synovial joint
Title: Computational and experimental characterizations of the spatiotemporal activity and functional role of TGF-β in the synovial joint
TGF-β is a prominent anabolic signaling molecule associated with synovial joint health. Recent work has uncovered mechanochemical mechanisms that activate the latent form of TGF-β (LTGF-β) in the synovial joint-synovial fluid (SF) shearing or cartilage compression-pointing to mechanobiological phenomena, whereby enhanced TGF-β activity occurs during joint stimulation. Here, we implement computational and experimental models to better understand the role of mechanochemical-activated TGF-β (aTGF-β) in regulating the functional biosynthetic activities of synovial joint tissues. Reaction-diffusion models describe the pronounced role of extracellular chemical reactions-load-induced activation, reversible ECM-binding, and cell-mediated internalization-in modulating the spatiotemporal distribution of aTGF-β in joint tissues. Of note, aTGF-β from SF shearing predominantly acts on cells in peripheral tissue regions (superficial zone [SZ] chondrocytes and synoviocytes) and aTGF-β from cartilage compression acts on chondrocytes through all cartilage layers. Further, ECM reversible binding sites in cartilage act to modulate the temporal delivery of aTGF-β to cells, creating a dynamic where short durations of joint activity give rise to extended periods of aTGF-β exposure at moderated doses. Ex vivo tissue models were subsequently utilized to characterize the influence of physiologic aTGF-β activity regimens in regulating functional biosynthetic activities. Physiologic exposure regimens of aTGF-β in SF induce strong 4-fold to 9-fold enhancements in the secretion rate of the synovial biolubricant, PRG4, from SZ cartilage and synovium explants. Further, aTGF-β inhibition in cartilage over 1-month culture leads to a pronounced loss of GAG content (30-35% decrease) and tissue softening (60-65% EY reduction). Overall, this work advances a novel perspective on the regulation of TGF-β in the synovial joint and its role in maintaining synovial joint health.  more » « less
Award ID(s):
1906469
PAR ID:
10472598
Author(s) / Creator(s):
; ; ; ;
Publisher / Repository:
Journal of Biomechanics
Date Published:
Journal Name:
Journal of Biomechanics
Volume:
156
Issue:
C
ISSN:
0021-9290
Page Range / eLocation ID:
111673
Subject(s) / Keyword(s):
Cartilage mechanobiology Growth factor transport modeling Lubricin Proteoglycan-4 TGF-beta activation
Format(s):
Medium: X
Sponsoring Org:
National Science Foundation
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