AI Article Synopsis
- Mechanical tensions in tissues influence cell behaviors like proliferation and cycle arrest, but the specific mechanisms are unclear.
- YAP, an important factor in the Hippo signaling pathway, enhances Skp2 transcription and its inactivation leads to cell cycle exit by increasing p21/p27 levels.
- In a 3D tissue culture, targeting Skp2 reduces YAP-driven cancer behaviors, and a correlation between Skp2 and YAP expression was observed in breast cancer patients, highlighting their role in linking tissue stiffness to cancer progression.
Article Abstract
Mechanical tensions are usually generated during development at spatially defined regions within tissues. Such physical cues dictate the cellular decisions of proliferation or cell cycle arrest. Yet, the mechanisms by which mechanical stress controls the cell cycle are not yet fully understood. Here, we report that mechanical cues function upstream of Skp2 transcription in human breast cancer cells. We found that YAP, the mechano-responsive oncogenic Hippo signaling effector, directly promotes Skp2 transcription. YAP inactivation induces cell cycle exit (G0) by down-regulating Skp2, causing p21/p27 to accumulate. Both Skp2 reconstitution and p21/p27 depletion can rescue the observed defect in cell cycle progression. In the context of a tissue-mimicking 3D culture system, Skp2 inactivation effectively suppresses YAP-driven oncogenesis and aberrant stiff 3D matrix-evoked epithelial tissue behaviors. Finally, we also found that the expression of Skp2 and YAP is positively correlated in breast cancer patients. Our results not only reveal the molecular mechanism by which mechanical cues induce Skp2 transcription, but also uncover a role for YAP-Skp2 oncogenic signaling in the relationship between tissue rigidity and cancer progression.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC5579353 | PMC |
| http://dx.doi.org/10.15252/embj.201696089 | DOI Listing |
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