Investigating the role of heparin sulfate proteoglycans in hereditary multiple exostoses (HME) tumourigenesis |
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| Authors: | ZM Scholefield Jr Hassell L West P Govindraj JT Hecht G Rushton R Oldershaw T Hardingham CLR Merry JT Gallagher |
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| Institution: | Cancer Research UK Department of Medical Oncology, University of Manchester, Christie Hospital NHS Trust, Manchester, UK;;Shriners Hospital for Children, Tampa, FL, USA;;Department of Pediatrics, University of Texas-Houston Medical School, Houston, TX, USA;;School of Biological Sciences, University of Manchester, Manchester, UK |
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| Abstract: | Introduction Heparin sulfate (HS) has long been implicated in the bone deformity hereditary multiple exostoses (HME), and it is now clear that HME is associated with mutations in the HS biosynthetic genes EXT1 and EXT2. Interestingly, HME is also associated with an increased risk of chondro‐ and osteo‐sarcomas. Methods and results Preliminary analysis of GAG samples purified from fibroblasts of both HME and isolated non‐HME exostoses patients reveal a dramatic shift in the ratio of CS : HS, with the HME and isolated cases having a much higher proportion of CS relative to normal controls. This is true in the case of both shed and cell surface material but is far more extreme in the latter, with the HS reducing from approximately 45% in the controls to less than 10% in HME patients. Initial analysis also reveals shortened chain length within these samples; indeed they often have two populations of chains present. Simple analysis of the total disaccharide composition of these samples demonstrates no significant differences against controls. However, detailed analysis of the subpopulations of chains (as determined by chain length) within these samples as well as cartilaginous samples from exostoses patients may provide further insight into the changes that occur within the biosynthetic pathway following disrupted EXT function. We are also carrying out immunocytochemistry with a variety of HS‐specific antibodies with the aim to further investigate normal HS structure and localization. This is being carried out on human primary chondrocytes isolated from normal patients and also adult mesenchymal stem cells as they undergo differentiation into chondrocytes. HS has been identified in both these cell types, and it is hoped that the manipulation of these cells through RNAi of different enzymes of the HS biosynthetic pathway will provide a suitable model for studying what changes may occur in cellular HS structures over the initial differentiation process in the growth plate. Discussion Together, these investigations should provide a good model to allow us to determine the role of HS in chondrocyte differentiation and maturation in both normal and diseased states. |
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