TRPC1 links calcium signaling to cellular senescence in the protection against posttraumatic osteoarthritis
Meike Sambale, Starlee Lively, Osvaldo Espin-Garcia, Pratibha Potla, Chiara Pastrello, Sarah Bödecker, Linda Wessendorf, Simon Kleimann, Peter Paruzel, Rojiar Asgarian, Alexandra Tosun, Johanna Intemann, Jessica Bertrand, Francesco Dell’Accio, Mohit Kapoor, Thomas Pap, Joanna Sherwood
Meike Sambale, Starlee Lively, Osvaldo Espin-Garcia, Pratibha Potla, Chiara Pastrello, Sarah Bödecker, Linda Wessendorf, Simon Kleimann, Peter Paruzel, Rojiar Asgarian, Alexandra Tosun, Johanna Intemann, Jessica Bertrand, Francesco Dell’Accio, Mohit Kapoor, Thomas Pap, Joanna Sherwood
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Research Article Bone biology Cell biology

TRPC1 links calcium signaling to cellular senescence in the protection against posttraumatic osteoarthritis

Abstract

Transient receptor potential channel 1 (TRPC1) is a widely expressed mechanosensitive ion channel located within the endoplasmic reticulum membrane, crucial for refilling depleted internal calcium stores during activation of calcium-dependent signaling pathways. Here, we have demonstrated that TRPC1 activity is protective within cartilage homeostasis in the prevention of cellular senescence–associated cartilage breakdown during mechanical and inflammatory challenge. We revealed that TRPC1 loss is associated with early stages of osteoarthritis (OA) and plays a nonredundant role in calcium signaling in chondrocytes. Trpc1–/– mice subjected to destabilization of the medial meniscus–induced OA developed a more severe OA phenotype than WT controls. During early OA development, Trpc1–/– mice displayed an increased chondrocyte survival rate; however, remaining cells displayed features of senescence including p16INK4a expression and decreased Sox9. RNA-Seq identified differentially expressed genes related to cell number, apoptosis, and extracellular matrix organization. Trpc1–/– chondrocytes exhibited accelerated dedifferentiation, while demonstrating an increased susceptibility to cellular senescence. Targeting the mechanism of TRPC1 activation may be a promising therapeutic strategy in OA prevention.

Authors

Meike Sambale, Starlee Lively, Osvaldo Espin-Garcia, Pratibha Potla, Chiara Pastrello, Sarah Bödecker, Linda Wessendorf, Simon Kleimann, Peter Paruzel, Rojiar Asgarian, Alexandra Tosun, Johanna Intemann, Jessica Bertrand, Francesco Dell’Accio, Mohit Kapoor, Thomas Pap, Joanna Sherwood

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Figure 6

In vitro analysis of the effect of Trpc1 deficiency upon chondrocyte phenotypic stability.

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In vitro analysis of the effect of Trpc1 deficiency upon chondrocyte phe...
(AD) qPCR analysis of sox9, aggrecan, col2a1, and col10a1 gene expression in murine WT and Trpc1–/– chondrocytes during serial in vitro passage. Two-way ANOVA with Tukey’s multiple-comparison test (n = 3). (E) Representative images of SA–β-Gal staining (blue) of WT and Trpc1–/– chondrocytes at equivalent confluence, visible by DIC counterimage, during serial passage. Scale bar: 50 μm. (F) Quantification of number of SA–β-Gal+ cells normalized for total number of cells during WT and Trpc1–/– chondrocytes during serial passage. Two-way ANOVA with multiple comparisons (n = 4, 20 images per condition). (G) qPCR analysis of p16INK4a gene expression in WT and Trpc1–/– chondrocytes during serial passage. Two-way ANOVA with multiple comparisons (n = 3). (H) Western blot of p16INK4a protein levels in WT and Trpc1–/– chondrocytes during serial passage. GAPDH used as a loading control. (I) Quantification of Western blotting for p16INK4a in WT and Trpc1–/– chondrocytes during serial passage. Two-way ANOVA with multiple comparisons (n = 3).