Kameron L. Inguito scite author profile

Actin is a central mediator between mechanical force and cellular phenotype. In tendon, it is speculated that mechanical stress deprivation regulates gene expression by reducing filamentous (F-)actin. However, the mechanisms regulating tenocyte F-actin remain unclear. Tropomyosins (Tpms) are master regulators of F-actin. There are over 40 Tpm isoforms, each having the unique capability to stabilize F-actin sub-populations. We investigated F-actin polymerization in stress-deprived tendons and tested the hypothesis that stress fiber-associated Tpm(s) stabilize F-actin to regulate cellular phenotype. Stress deprivation of mouse tail tendon downregulated tenogenic and upregulated protease (matrix metalloproteinase-3) mRNA levels. Concomitant with mRNA modulation were increases in G/F-actin, confirming reduced F-actin by tendon stress deprivation. To investigate the molecular regulation of F-actin, we identified that tail, Achilles, and plantaris tendons express three isoforms in common: Tpm1.6, 3.1, and 4.2. Tpm3.1 associates with F-actin in native and primary tenocytes. Tpm3.1 inhibition reduces F-actin, leading to decreases in tenogenic expression, increases in chondrogenic expression, and enhancement of protease expression in mouse and human tenocytes. These expression changes by Tpm3.1 inhibition are consistent with tendinosis progression. A further understanding of F-actin regulation in musculoskeletal cells could lead to new therapeutic interventions to prevent alterations in cellular phenotype during disease progression.

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Destabilization of F-actin by Mechanical Stress Deprivation or Tpm3.1 Inhibition Promotes a Pathological Phenotype in Tendon Cells

Parreno

Inguito

Schofield

et al. 2022

Preprint

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The actin cytoskeleton is a central mediator between mechanical force and cellular phenotype. In tendon, it is speculated that mechanical stress deprivation regulates gene expression by filamentous (F-) actin destabilization. However, the molecular mechanisms that stabilize tenocyte F-actin networks remain unclear. Tropomyosins (Tpms) are master regulators of F-actin networks. There are over 40 mammalian Tpm isoforms, with each isoform having the unique capability to stabilize F-actin sub-populations. Thus, the specific Tpm(s) expressed by a cell defines overall F-actin organization. Here, we investigated F-actin destabilization by stress deprivation of tendon and tested the hypothesis that stress fiber-associated Tpm(s) stabilize tenocyte F-actin to regulate cellular phenotype. Stress deprivation of mouse tail tendon fascicles downregulated tenocyte genes (collagen-I, tenascin-C, scleraxis, α-smooth muscle actin) and upregulated matrix metalloproteinase-3. Concomitant with mRNA modulation were increases in DNAse-I/Phallodin (G/F-actin) staining, confirming F-actin destabilization by tendon stress deprivation. To investigate the molecular regulation of F-actin stabilization, we first identified the Tpms expressed by mouse tendons. Tendon cells from different origins (tail, Achilles, plantaris) express three isoforms in common: Tpm1.6, 3.1, and 4.2. We examined the function of Tpm3.1 since we previously determined that it stabilizes F-actin stress fibers in lens epithelial cells. Tpm3.1 associated with F-actin stress fibers in native and primary tendon cells. Inhibition of Tpm3.1 depolymerized F-actin, leading to decreases in tenogenic expression, increases in chondrogenic expression, and enhancement of protease expression. These expression changes by Tpm3.1 inhibition are consistent with tendinosis progression. A further understanding of F-actin stability in musculoskeletal cells could lead to new therapeutic interventions to prevent alterations in cellular phenotype during disease progression.

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The application of mechanical load onto mouse tendons by magnetic restraining represses Mmp-3 expression

Mousavizadeh

West

Inguito

et al. 2022

Preprint

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Objectives: Mechanical loading is crucial for tendon matrix homeostasis. Under-stimulation of tendon tissue promotes matrix degradation and ultimately tendon failure. In this study, we examined the expression of tendon matrix molecules and matrix-degrading enzymes (matrix metalloproteinases) in stress-deprived tail tendons and compared to tendons that were mechanically loaded by a simple restraining method. Data description: Isolated mouse tail fascicles were either floated or restrained by magnets in cell culture media for 24 hours. The gene expression of tendon matrix molecules and matrix metalloproteinases in the tendon fascicles of mouse tails were examined by real-time RT-PCR. Stress deprivation of tail tendons increase Mmp3 mRNA levels. Restraining tendons represses these increases in MMP3. The gene expression response to restraining was specific to Mmp3 at 24 hours as we did not observe mRNA level changes in other matrix related genes that we examined (Col1, Col3, Tnc, Acan, and Mmp13). To elucidate, the mechansims that may regulate load transmission in tendon tissue, we examined filamentous (F-)actin staining and nuclear morphology. As compared to stress deprived tendons, restrained tendons had greater staining for F-actin. The nuclei of restrained tendons are smaller and more elongated. These results indicate that mechanical loading regulates specific gene expression potentially through F-actin regulation of nuclear morphology. A further understanding on the mechanisms involved in regulating Mmp3 gene expression may lead to new strategies to prevent tendon degeneration.

show abstract

The application of mechanical load onto mouse tendons by magnetic restraining represses Mmp-3 expression

et al. 2023

View full text Add to dashboard Cite

Objectives Mechanical loading is crucial for tendon matrix homeostasis. Under-stimulation of tendon tissue promotes matrix degradation and ultimately tendon failure. In this study, we examined the expression of tendon matrix molecules and matrix-degrading enzymes (matrix metalloproteinases) in stress-deprived tail tendons and compared to tendons that were mechanically loaded by a simple restraining method. Data description Isolated mouse tail fascicles were either floated or restrained by magnets in cell culture media for 24 h. The gene expression of tendon matrix molecules and matrix metalloproteinases in the tendon fascicles of mouse tails were examined by real-time RT-PCR. Stress deprivation of tail tendons increase Mmp3 mRNA levels. Restraining tendons represses these increases in Mmp3. The gene expression response to restraining was specific to Mmp3 at 24 h as we did not observe mRNA level changes in other matrix related genes that we examined (Col1, Col3, Tnc, Acan, and Mmp13). To elucidate, the mechanisms that may regulate load transmission in tendon tissue, we examined filamentous (F-)actin staining and nuclear morphology. As compared to stress deprived tendons, restrained tendons had greater staining for F-actin. The nuclei of restrained tendons are smaller and more elongated. These results indicate that mechanical loading regulates specific gene expression potentially through F-actin regulation of nuclear morphology. A further understanding on the mechanisms involved in regulating Mmp3 gene expression may lead to new strategies to prevent tendon degeneration.

show abstract

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