Fibrous dysplasia is an isolated skeletal disorder caused by a somatic activating mutation of GNAS1 gene with abnormal unmineralized matrix overproduction and extensive undifferentiated bone cell accumulation in fibro-osseous lesions. The aim of the investigation was to identify genes that are differently expressed in fibrous vs. non-fibrous human bone and to describe the relationships between these genes using multivariate data analysis.
Materials and methods: Six bone tissue samples from fibrous dysplastic female patients and 7 bone tissue samples from non-fibrous dysplastic women were examined. The 6 female fibrous samples were taken from the fibrous dysplastic lesion itself while the control samples of 7 non-fibrous dysplastic females were taken from the femoral neck during the hip replacement procedure. The expression differences of selected 118 genes were analyzed in TaqMan probe based quantitative real-time RT-PCR system.
Results: The Mann-Whitney U test indicated significant differences in the expression of 27 genes of fibrous dysplasial and non fibrous dysplasial individuals (p≤0.05). Nine genes were significantly up-regulated in fibrous dysplasial women compared to non fibrous dysplasial ones and eighteen genes showed a down-regulated pattern. These significantly altered genes coding for minor collagen molecules, extracellular matrix digesting enzymes, transcription factors, adhesion molecules, growth factors, pro-inflammatory cytokines and lipid metabolism-affected substrates. Canonical variety analysis demonstrated that fibrous dysplastic and non fibrous dysplastic bone tissues can be distinguished by the multiple expression profile analysis of numerous genes controlled via a G-protein coupled pathway and BMP cascade as well as genes coding for extracellular matrix composing molecules.
Conclusions: The significantly altered gene expression profile observed in the fibrous dysplastic human bone tissue may provide further insight into the pathogenetic process of fibrous degeneration of bone.