C Wolf

Matrix metalloproteinases are believed to play an important role in tumor invasion and metastasis. To examine the expression of the stromelysin 3 (ST3) gene, a new member of the matrix metalloproteinase gene family, 111 head and neck squamous cell carcinomas and 21 metastatic lymph nodes were analyzed by Northern blot. ST3 gene expression was observed in 106 carcinomas and 19 metastatic nodes, but in only 2 of 60 samples of corresponding normal tissue tested in parallel. ST3 RNA, by in situ hybridization, and ST3 protein, by immunohistochemical analysis, were specifically detected in fibroblastic cells immediately surrounding invasive cancer cells. This fibroblastic expression of the ST3 gene is characteristic among the matrix metalloproteinase genes known to be overexpressed in head and neck carcinomas, since stromelysin 2 transcripts were specifically detected in neoplastic cells, and type I collagenase transcripts in both neoplastic cells and stromal fibroblasts. Furthermore, there was a highly significant positive correlation (P < 0.0001) between ST3 RNA levels and local invasiveness by the cancer cells, suggesting that enhanced expression of the ST3 gene may contribute to the neoplastic phenotype in head and neck carcinomas.

The expression of the stromelysin 3 (ST3) gene, which encodes a putative matrix metalloproteinase, was studied during breast cancer progression. The ST3 gene is expressed in all invasive breast carcinomas, in a number of their metastases, and in some in situ carcinomas where the probability of detecting ST3 transcripts correlates with the known risk of these carcinomas to become invasive. ST3 RNA and protein were specifically detected in fibroblastic cells immediately surrounding the neoplastic cells in both primary and metastatic tumors. This expression pattern distinguishes the ST3 gene from other matrix metalloproteinase genes, most notably from the 72-kDa type IV collagenase gene, which can be expressed in fibroblastic cells distributed throughout the stroma of primary breast carcinomas. Furthermore, high levels of 72-kDa type IV collagenase, but not of ST3 transcripts, are detected in benign breast fibroadenomas. Interestingly, the urokinase and ST3 genes exhibit very similar patterns of expression in breast carcinomas, which suggests that their products may cooperate during cancer progression.

We have cloned from a mouse placenta cDNA library a mouse homologue of the human stromelysin-3 (ST3) cDNA, which codes for a putative matrix metalloproteinase expressed in breast carcinomas. The ST3 protein is well conserved between humans and mice, and the pattern of ST3 gene expression is similar in both species, and shows expression in the placenta, in the uterus, and during limb bud morphogenesis. We show that the ST3 gene can also be expressed in the normal mouse mammary gland. ST3 gene expression was not detected during mammary growth, neither in virgin nor in pregnant mice, but was specifically observed during postlactating involution of the gland, an apoptotic process associated with intense extracellular matrix remodeling. ST3 transcripts were found in fibroblasts immediately surrounding degenerative ducts, suggesting that ST3 gene expression may be associated with the basement membrane dissolution, which occurs during mammary gland involution. Since the ST3 gene is also specifically expressed in fibroblastic cells surrounding invasive neoplastic cells of breast carcinomas, we suggest that ST3 is implicated in extracellular matrix remodeling processes common to mammary apoptosis and breast cancer progression.