Human breast cancer cells synthesize and release a variety of growth-modulating substances in response to estrogen stimulation, and it is generally accepted that the growth-promoting effects of estrogens are due at least in part to this autocrine/paracrine mechanism. Several of these growth-modulating substances, including transforming growth factor-alpha (TGF alpha) and its analogs, have been shown to require pericellular proteolysis for activation or release. Recently, we reported that MCF-7 human breast cancer cells are able to synthesize alpha(1)-antitrypsin (alpha(1)-AT), the major elastase inhibitor in human serum, and that there is a negative correlation between anchorage-independent growth of MCF-7 cells in soft agar and synthesis of alpha(1)-AT. The studies we present here were undertaken to gain an understanding of the mechanisms responsible for this observation. We show that release of TGF alpha from its membrane-bound precursor on MCF-7 cells is blocked by alpha(1)-AT whether the cells were maintained in the presence or absence of estradiol and that there is a clear dose-response relationship between the alpha(1)-AT concentration and both the release of TGF alpha and growth in soft agar. Consistent with this, TGF alpha release was increased in the presence of antibody to alpha(1)-AT. In contrast, TGF alpha release and growth in soft agar were not blocked by peptide inhibitors specific for trypsin- or chymotrypsin-like enzymes. The alpha(1)-AT concentration required for a half-maximal effect is lower for inhibition of TGF alpha release than-it is for inhibition of colony formation (0.4 vs. 1.5 mu mol/L). However, both values are in the range of concentrations one might expect at the cell surface in vivo. A new MCF-7 cell subline producing 10-fold higher levels of alpha(1)-AT than its parent cell line was constructed by stable transfection of MCF-7 ML cells (a subline producing low levels of alpha(1)-AT) with an alpha(1)-AT complementary DNA. Growth in soft agar and release of TGF alpha were significantly decreased in cells transfected with the alpha(1)-AT complementary DNA compared to those in cells transfected with vector alone, although, TGF alpha expression was the same. The above observations support a model for growth regulation in human breast ductal epithelial cells in which growth factor activation and release are dependent on the coordinate action of proteases and protease inhibitors. This model would predict that alpha(1)-AT can act as a tumor suppressor in inhibiting the growth of breast cancer cells.

• 出版日期1997-3