Mario A. Anzano

Type beta transforming growth factor (TGF-beta) is a two-chain polypeptide of 25,000 daltons isolated from many tissues, including bovine kidney, human placenta, and human platelets. It has been characterized by its ability to stimulate reversible transformation of nonneoplastic murine fibroblasts, as measured by the formation of colonies of these cells in soft agar (ED50 = 4 pM TGF-beta for NRK fibroblasts). We now show that the response of cells to TGF-beta is bifunctional, in that TGF-beta inhibits the anchorage-dependent growth of NRK fibroblasts and of human tumor cells by increasing cell cycle time. Moreover, the anchorage-independent growth of many human melanoma, lung carcinoma, and breast carcinoma cell lines is inhibited by TGF-beta at concentrations in the same range as those that stimulate colony formation of NRK fibroblasts (average ED50 = 10-30 pM TGF-beta for inhibition). Whereas epidermal growth factor and TGF-beta synergize to induce anchorage-independent growth of NRK fibroblasts, their effects on the growth of A-549 human lung carcinoma cells are antagonistic. The bifunctional response of cells to TGF-beta is further demonstrated in Fischer rat 3T3 fibroblasts transfected with a cellular myc gene. In these cells TGF-beta synergizes with platelet-derived growth factor to stimulate colony formation but inhibits the colony formation induced by epidermal growth factor. The data indicate that the effects of TGF-beta on cells are not a function of the peptide itself, but rather of the total set of growth factors and their receptors that is operant in the cell at a given time.

Proteins potentiated by epidermal growth factor (EGF) to induce a transformed phenotype in non-neoplastic rat kidney fibroblasts in cell culture have been isolated from many non-neoplastic tissues of the adult mouse, including submaxillary gland, kidney, liver, muscle, heart, and brain. They resemble previously described transforming growth factors (TGFs) isolated from neoplastic cells as follows: they are extractable by acid/ethanol and are acid-stable, low molecular weight (6000-10,000) polypeptides requiring disulfide bonds for activity; and they cause anchorage-independent growth of non-neoplastic indicator cells that will not grow in soft agar in their absence. Partial purification of these TGFs from submaxillary glands of male mice shows that they are distinct from EGF. Unlike previously described extracellular TGFs, but like certain cellular TGFs from neoplastic cells, they are potentiated by EGF in their ability to promote anchorage-independent growth. The isoelectric point of the submaxillary gland TGF protein is near neutrality. Chromatography on Bio-Gel P-30 followed by high-pressure liquid chromatography has resulted in a 22,000-fold overall purification. The most purified protein is active in inducing growth in soft agar at 1 ng/ml when assayed in the presence of EGF. The data add further evidence to the concept that neoplasia may result from a quantitative, rather than qualitative, alteration in non-neoplastic biochemical processes.

Sarcoma growth factor (SGF) derived from conditioned medium of Moloney sarcoma virus-transformed cells and partially purified by gel filtration (crude SGF) has been characterized by its ability both to compete with epidermal growth factor (EGF) for binding to membrane receptors and to induce anchorage-independent growth of untransformed cells. We now show that further purification of crude SGF by reverse-phase HPLC on muBondapak C18 and CN columns at pH 2 resolves it into two distinctly different polypeptides, which we call types alpha and beta transforming growth factors (TGFs). Type alpha TGF (TGF-alpha), but not type beta TGF (TGF-beta), competes for binding to the EGF receptor and induces the formation of small colonies (1,000-2,000 micron2) of normal rat kidney cells in soft agar. Both TGF-beta and EGF or TGF-alpha must be present in order to induce the formation of large colonies (7,000-15,000 micron2). Based on EGF competing equivalents as determined from a radioreceptor assay with 125I-labeled EGF in normal rat kidney cells, the relative ability of EGF and TGF-alpha to potentiate TGF-beta-dependent colony formation is in the order conditioned-medium TGF-alpha greater than EGF greater than intracellular TGF-alpha. Suboptimal concentrations of the same polypeptides give additive potentiation of the TGF-beta-dependent colony-forming response; saturating levels potentiate a similar maximum response whether used alone or in various combinations. The data indicate that the EGF-competing activity of crude SGF is due to its TGF-alpha component alone, whereas the soft-agar colony-forming activity is due to the combined action of two distinct polypeptides, TGF-alpha and TGF-beta.

Type beta transforming growth factor (TGF-beta) has been purified 200 000-fold from bovine kidneys. This peptide is characterized by its ability to induce anchorage-dependent normal rat kidney cells to grow in soft agar in the presence of epidermal growth factor (EGF); TGF-beta is not mitogenic for cells grown in monolayer culture. Purified TGF-beta does not compete with EGF for binding to membrane receptors. The concentration of TGF-beta required to elicit a half-maximal response for formation of colonies greater than 3100 micron2 in the soft agar assay is 2-3 pM (55 pg/mL) when assayed in the presence of 0.8 nM EGF (5 ng/mL). The four-step purification procedure which includes chromatography of acid--ethanol tissue extracts on polyacrylamide sizing gels, cation exchange, and two steps of high-pressure liquid chromatography results in a 10% overall yield of colony-forming activity with a recovery of 3-4 micrograms/kg. Amino acid analysis of purified TGF-beta shows 16 half-cystine residues per mole. Analysis of the purified polypeptide by electrophoresis on sodium dodecyl sulfate-polyacrylamide gels indicates that TGF-beta is composed of two closely related polypeptide chains cross-linked by disulfide bonds. In the absence of beta-mercaptoethanol, the colony-forming activity is associated with a single silver-staining band of molecular weight 25 000; in the presence of beta-mercaptoethanol, the TGF-beta is converted to an inactive species that migrates as a single band of molecular weight 12 500-13 000. Sequence analysis indicates that at least the first 15 N-terminal amino acids of the two TGF-beta subunits are identical.