SSX was initially identified as a melanoma associated tumour antigen MEL2 and in the SS18/SSX fusion gene of synovial sarcoma. It consists of a family of nine, highly homologous X chromosome genes, being SSX1, SSX2 and SSX4 the most commonly expressed in tumours. In normal tissue, SSX expression is restricted to germ cells, trophoblasts, and mesenchymal stem cells. In malignant cells, SSX expression is over-represented in sarcomas. SSX expression is epigenetically regulated by methylation and histone deacetylation. Aim. To investigate the oncogenic properties of SSX. Validate it as tumour target and identify lead compounds. Methods. RNAi system for conditional silencing of SSX expression, Protein analysis and Mass Spec, PCR arrays, tumour xenographs and drug library screening. Results. SSX expression peaks at the G1/S phase of the cell cycle where it interacts with histone H3, H4 and β-catenin. This interaction promotes the phosphorylation of β-catenin at tyrosine residues and the transactivation of β-catenin genes MMP2 and cyclin D1. The association of SSX and MMP2 expression resulted in an increased invasion capacity of tumour cells. In vivo, silencing of SSX in tumour xenographs significantly affected the tumour growth. These tumours were characterized by large necrotic areas, impaired vascularization and cytoplasmic β-catenin. In contrast, tumour xenographs expressing SSX were highly proliferative, vascularized and exibited nuclear β-catenin. We further screened a chemical library and have identified lead compounds that target SSX. Conclusion. Our results demonstrate that SSX is a tumour target for drug development. We hypothesise that drugs targeting of SSX could affect functions related with the mesenchymal cell phenotype having potential cytostatic effect in sarcomas and/or epithelial tumour cells that undergo a epithelial-to-mesenchymal transition prior to metastasis

The aims of this study were to evaluate the incidence of local argyria in patients with silver-coated megaprostheses and to identify a possible association between argyria and elevated levels of silver both locally and in the blood. Between 2004 and 2011, 32 megaprostheses with silver coatings were implanted in 20 female and 12 male patients following revision arthroplasty for infection or resection of a malignant tumour, and the levels of silver locally in drains and seromas and in the blood were determined. The mean age of the patients was 46 years (10 to 81); one patient died in the immediate post-operative period and was excluded.

Seven patients (23%) developed local argyria after a median of 25.7 months (interquartile range 2 to 44.5). Patients with and without local argyria had comparable levels of silver in the blood and aspiration fluids. The length of the implant did not influence the development of local argyria. Patients with clinical evidence of local argyria had no neurological symptoms and no evidence of renal or hepatic failure. Thus, we conclude that the short-term surveillance of blood silver levels in these patients is not required.

Cite this article: Bone Joint J 2013;95-B:988–92.