Microarray Analysis of Suppression Subtracted Hybridisation Libraries Identifies Genes Associated with Breast Cancer Progression

Background: A major challenge of cancer research is to identify key molecules which are responsible for the development of the malignant metastatic phenotype, the major cause of cancer death

Estrogen Receptor-Positive Proliferating Cells in the Normal and Precancerous Breast

Recently it has been shown that epithelial cell expression of the estrogen receptor (ER) and that of the proliferation-associated marker Ki-67 are almost mutually exclusive in the normal premenopausal human breast but that coexpression frequently occurs in estrogen receptor-positive (ER+) breast cancers. This coexpression may indicate disordered expression of ER in the cell cycle or failure to suppress division of ER+ cells and could be important in neoplastic transformation. The purpose of this study was to determine whether in situ proliferations known to be associated with different levels of risk for developing breast cancer contain these coexpressing cells and, if so, the stage at which they occur. We found that ER+ proliferating cells were rare in premenopausal lobules but increased with age in the normal breast. There was no difference in nonlesional tissue between cancerous and noncancerous breasts. The percentage of dual-expressing cells was significantly increased, however, in all of the in situ proliferations and correlated positively with the level of risk of developing breast cancer. We suggest that development of at least some human breast cancers is associated with increasing failure to down-regulate ER as cells enter the cycle or to suppress division of ER+ cells. The mechanism may involve the loss of a tumor suppresser gene

Examination of tumour histopathology and gene expression in a neu/S100A4 transgenic model of metastatic breast cancer

Elevated levels of the calcium-binding protein S100A4 have been causally linked to the metastatic spread of breast cancer cells in several in vitro and in vivo model systems and, more recently, correlated with patient death in a series of human breast cancer specimens. In transgenic mice expressing MMTV-neu transgenes in mammary gland, additional expression of S100A4 transgenes results in an enhanced metastatic capability. Despite this phenotypic difference arising from elevated S100A4, it is now shown that the primary breast tumours in all mice examined are histopathologically very similar and resemble those human tumours associated with elevated c-erbB-2. Using a panel of genes identified by suppression subtractive hybridization of cDNAs from individual primary tumours and a metastasis, some cDNAs were found to exhibit a differential pattern of expression associated with the expression of S100A4 protein (including osteopontin, S100A9, claudin 2 and several Expressed Sequence Tags sequences). Whilst confirming differential expression of these genes, it was demonstrated that individual primary tumours of matched transgenic status, histology and grade exhibit some degree of heterogeneity at the mRNA level by reverse Northern and Northern hybridizations. This intertumour heterogeneity of mRNA level was confirmed by cDNA array analysis and suggests that even in a transgenic model, which exhibits far less variation than the human disease, there may be multiple mechanisms of disease progression