N.G. Bloks scite author profile

Aging-associated muscle wasting and impaired regeneration are caused by deficiencies in muscle stem cell (MuSC) number and function. We postulated that aged MuSCs are intrinsically impaired in their responsiveness to omnipresent mechanical cues through alterations in MuSC morphology, mechanical properties, and number of integrins, culminating in impaired proliferative capacity. Here we show that aged MuSCs exhibited significantly lower growth rate and reduced integrin-α7 expression as well as lower number of phospho-paxillin clusters than young MuSCs. Moreover, aged MuSCs were less firmly attached to matrigel-coated glass substrates compared to young MuSCs, as 43% of the cells detached in response to pulsating fluid shear stress (1 Pa). YAP nuclear localization was 59% higher than in young MuSCs, yet YAP target genes Cyr61 and Ctgf were substantially downregulated. When subjected to pulsating fluid shear stress, aged MuSCs exhibited reduced upregulation of proliferation-related genes. Together these results indicate that aged MuSCs exhibit impaired mechanosensitivity and growth potential, accompanied by altered morphology and mechanical properties as well as reduced integrin-α7 expression. Aging-associated impaired muscle regenerative capacity and muscle wasting is likely due to aging-induced intrinsic MuSC alterations and dysfunctional mechanosensitivity.

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Fluid shear stress-induced mechanotransduction in myoblasts: Does it depend on the glycocalyx?

Haroon

Bloks

Deldicque

et al. 2022

Experimental Cell Research

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A high-impactCOL6A3mutation alters the response of chondrocytes in neo-cartilage organoids to hyper-physiologic mechanical loading

Bloks

Harissa

Adkar

et al. 2022

Preprint

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Dysregulation of mechano-transduction via chondrocyte pericellular matrix (PCM) has been shown to induce osteoarthritis (OA), a highly prevalent degenerative disease of joint tissues. By performing exome sequencing in symptomatic OA patients, a high impact mutation in COL6A3 encoding one of the monomeric sub-unit-3 of collagen type VI (COLVI) was identified. COLVI is an essential and specific protein functioning in the PCM. To study the downstream effects of the mutation in interaction with hyper-physiologic mechanical loading conditions, genetically COL6A3-edited human induced pluripotent stem cells (hiPSCs) were employed in our established in-vitro cartilage organoid model. We showed mutated COLVI had significant lower binding to fibronectin (FN) and provoked an osteoarthritic chondrocyte state. Moreover, the COL6A3 mutation abolished the initial stress responses of chondrocytes to hyper-physiological mechanical loading conditions. Together, the established sustainable cartilage organoid model provides unique opportunities to study the transduction of mechanical cues to chondrocytes and explore ways to counteract effects. Acquired insights could guide effective treatment development for OA

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A disease-risk mutation in COL6A3 alters the biologic response of chondrocytes to hyper-physiologic mechanical loading

Bloks

Dicks

Adkar

et al. 2021

Osteoarthritis and Cartilage

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CCN4/WISP1 Promotes Migration of Human Primary Osteoarthritic Chondrocytes

et al. 2022

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Objectives Previously, we have shown the involvement of cellular communication network factor 4/Wnt-activated protein Wnt-1-induced signaling protein 1 (CCN4/WISP1) in osteoarthritic (OA) cartilage and its detrimental effects on cartilage. Here, we investigated characteristics of CCN4 in chondrocyte biology by exploring correlations of CCN4 with genes expressed in human OA cartilage with functional follow-up. Design Spearman correlation analysis was performed for genes correlating with CCN4 using our previously established RNA sequencing dataset of human preserved OA cartilage of the RAAK study, followed by a pathway enrichment analysis for genes with ρ ≥|0.6.| Chondrocyte migration in the absence or presence of CCN4 was determined in a scratch assay, measuring scratch size using a live cell imager for up to 36 h. Changes in expression levels of 12 genes, correlating with CCN4 and involved in migratory processes, were determined with reverse transcription-quantitative polymerase chain reaction (RT-qPCR). Results Correlation of CCN4 with ρ ≥|0.6| was found for 58 genes in preserved human OA cartilage. Pathway analysis revealed “neural crest cell migration” as most significant enriched pathway, containing among others CORO1C, SEMA3C, and SMO. Addition of CCN4 to primary chondrocytes significantly enhance chondrocyte migration as demonstrated by reduced scratch size over the course of 36 h, but at the timepoints measured no effect was observed on mRNA expression of the 12 genes. Conclusion CCN4 increases cell migration of human primary OA chondrocytes. Since WISP1 expression is known to be increased in OA cartilage, this may serve to direct chondrocytes toward cartilage defects and orchestrate repair.

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Osteoarthritis-Risk Mutation in Pericellular Matrix Col6a3 Fibrils Alters Biologic Response of Chondrocytes to Hyper-Physiologic Mechanical Loading Conditions

Bloks

Harissa

Dicks

et al. 2022

Osteoarthritis and Cartilage

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Opposite Effects of Hyper-Physiological Mechanical Stress and Inflammation on WNT Signaling in Human Chondrocyte Neo-Cartilage Pellets

Timmermans

Bloks

Lent

et al. 2022

Osteoarthritis and Cartilage

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N.G. Bloks

A human in vitro 3D neo-cartilage model to explore the response of OA risk genes to hyper-physiological mechanical stress

Reduced growth rate of aged muscle stem cells is associated with impaired mechanosensitivity

Fluid shear stress-induced mechanotransduction in myoblasts: Does it depend on the glycocalyx?

A high-impactCOL6A3mutation alters the response of chondrocytes in neo-cartilage organoids to hyper-physiologic mechanical loading

A disease-risk mutation in COL6A3 alters the biologic response of chondrocytes to hyper-physiologic mechanical loading

CCN4/WISP1 Promotes Migration of Human Primary Osteoarthritic Chondrocytes

Osteoarthritis-Risk Mutation in Pericellular Matrix Col6a3 Fibrils Alters Biologic Response of Chondrocytes to Hyper-Physiologic Mechanical Loading Conditions

Opposite Effects of Hyper-Physiological Mechanical Stress and Inflammation on WNT Signaling in Human Chondrocyte Neo-Cartilage Pellets

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