Mechanical force modulates scleraxis expression in bioartificial tendons.

Following tendon injury, cartilage, bone and fat metaplasia are often observed, making the optimization of tenocyte differentiation an important clinical goal. In this study we examined the effect of static and cyclic mechanical loading on the expression of genes which play a role in tenocyte differentiation and function, namely scleraxis (Scx) and Type I collagen (Col1a1), and determined the effect of varying mechanical parameters including (1) static vs dynamic load, (2) increasing strain magnitude, (3) inclusion of 10 s rest periods, and (4) increasing cycle number. Cyclic loading resulted in a greater increase of tenocyte gene expression than static loading over 3 weeks in culture. Increasing strain levels potentiated the induction of tenocyte genes. The insertion of a 10 s rest periods further enhanced tenocyte gene expression, as did increasing repetition numbers. These results suggest that mechanical signaling exerts an important influence on the expression of genes which play a role in determining the tendon phenotype. Further work is required to confirm and extend these findings in primary cells such as resident tendon progenitor/stem cells, in order to provide an improved understanding of biology from which optimized rehabilitation programs can be developed.

EGR1 reactivation by histone deacetylase inhibitors promotes synovial sarcoma cell death through the PTEN tumor suppressor.

Synovial sarcoma is a high-grade soft tissue malignancy, for which current cytotoxic chemotherapies provide limited benefit. Although histone deacetylase (HDAC) inhibitors are known to suppress synovial sarcoma in vitro and in vivo, the exact mechanism is not clear. In this study, we report a central role of the transcription factor, early growth response-1 (EGR1), in the regulation of HDAC inhibitor-induced apoptotic cell death in synovial sarcoma. The SS18-SSX oncoprotein, characteristic of synovial sarcoma, maintains EGR1 expression at low levels, whereas it is significantly increased after HDAC inhibitor treatment. On the contrary, EGR1 knockdown leads to a decrease in HDAC inhibitor-induced apoptosis. Moreover, we find that under these conditions phosphatase and tensin homolog deleted in chromosome 10 (PTEN) is upregulated and this occurs through direct binding of EGR1 to an element upstream of the PTEN promoter. Using a combination of gain- and loss-of-function approaches, we show that EGR1 modulation of PTEN contributes to HDAC inhibitor-induced apoptosis in synovial sarcoma. Finally, restoration of EGR1 or PTEN expression is sufficient to induce synovial sarcoma cell death. Taken together, our findings indicate that SS18-SSX-mediated attenuation of an EGR1-PTEN network regulates synovial sarcoma cell survival, and that HDAC inhibitor-mediated apoptosis operates at least in part through reactivation of this pathway.

Retinoid signalling and skeletal development.

Metabolites of vitamin A, including retinoic acid (RA), comprise a class of molecules known to be important in development and homeostasis. RA functions through a class of nuclear hormone receptors, the RA receptors (RARs), to regulate gene transcription. In the developing mammalian limb, RA affects the differentiation of many cell lineages, including those of the chondrogenic lineage. In excess, RA is a potent teratogen, causing characteristic skeletal defects in a stage- and dose-dependent manner. Genetic analysis has shown that the absence of RARs leads to severe deficiencies in cartilage formation at certain anatomical locations while promoting ectopic cartilage formation at other sites. Expression of either a dominant-negative or a weak constitutively active RAR in the developing limbs of transgenic mice adversely affects chondrogenesis leading to skeletal malformations. Together, these results show that RAR-mediated signalling plays a fundamental role in skeletogenesis. This chapter will focus on the function of RARs in regulating chondroblast differentiation and the contribution of RA signalling to appositional and longitudinal growth of the skeletal primordia.