Rat prostate cancer cells contain functional receptors for transforming growth factor-beta

Clonally derived C-, D-, and T-family AXC/SSh rat prostate cancer cell lines contain transforming growth factor-beta (TGF beta) receptors. The content in C3, D1, T1, and T5 cells, respectively, was 8,560 +/- 1,450, 13,160 +/- 1,240, 2,425 +/- 490, and 10,540 +/- 1,025 sites/cell (mean +/- SEM). Respective Kd values were 160 +/- 48, 200 +/- 53, 24 +/- 3, and 115 +/- 15 pM (mean +/- SEM). T1 cell TGF beta receptor site content and Kd differed significantly from those of other prostate cancer cell lines (P less than 0.05). TGF beta is a bifunctional concentration-dependent modulator of T1 and T5 cell thymidine incorporation. At low concentrations, thymidine incorporation was inhibited, whereas as the medium TGF beta content was increased, T1 and T5 cell thymidine incorporation was stimulated. The concentrations of TGF beta causing half-maximum inhibition of T1 or T5 cell thymidine incorporation, respectively, were 0.11 and 0.24 pM, whereas the respective TGF beta concentrations causing half-maximum stimulation of thymidine incorporation were 14.4 and 134 pM. These findings establish that rat prostate cancer cell sensitivity to TGF beta inhibition of function is at least 2 orders of magnitude greater than that of most other mammalian cells. In contrast, the sensitivity of rat prostate cancer cells to TGF beta enhancement of function is comparable to that of other mammalian cells. TGF beta inhibited basic fibroblast growth factor (bFGF) stimulation of T1 and T5 cell thymidine incorporation. Because the concentration of bFGF required for half-maximum increase of T5 cell thymidine incorporation was independent of medium TGF beta content, the effect of TGF beta is distal to the T5 cell bFGF receptor. In contrast, the concentration of bFGF required for half-maximum increase in T1 cell thymidine incorporation increased 5-fold as the medium TGF beta content was increased; suggesting that the effect of TGF beta in T1 cells is proximal to the T1 cell bFGF receptor. Our studies establish that rat prostate cancer cells contain functional TGF beta receptors, imply the presence of functional bFGF receptors, and demonstrate that mitogen modulation of prostate cancer cell function is multifactorial. The finding that TGF beta is a bifunctional effector of prostate cancer cell DNA synthesis provides some insight into the potential complexity of mitogen modulation of prostate cancer cell proliferation. The mechanism by which these mitogens interact is unknown; however, our studies suggest that some interactive effects may be cell line specific.     

Cytokines modulate MIA PaCa 2 and CAPAN-1 adhesion to extracellular matrix proteins.

Variations in cancer cell adhesion to extracellular matrix (ECM) proteins might underlie an enhanced metastatic potential. ECM binding is mediated by cell-adhesion molecules, the membrane expression of which might be influenced by soluble mediators, such as cytokines. The aims of our study were to ascertain whether epidermal growth factor (EGF), transforming growth factor beta1 (TGF-beta1), interleukin 1alpha (IL-1alpha), or interleukin 1beta (IL-1beta) can modify MIA PaCa 2 (pancreatic cancer cell line) and CAPAN-1 (metastatic pancreatic cancer cell line) adhesion to fibronectin, laminin, or type I collagen, and whether these cytokines can shift the membrane expression of the hyaluronic acid receptor (CD44). EGF significantly enhanced MIA PaCa 2, but not CAPAN-1, adhesion to fibronectin, laminin, and type I collagen. TGF-beta1 reduced MIA PaCa 2 adhesion to type I collagen, but enhanced CAPAN-1 adhesion to fibronectin and laminin. IL-1alpha was found to enhance MIA PaCa 2 adhesion to fibronectin, while reducing adhesion to type I collagen, whereas IL-1beta reduced the adhesion to laminin. IL-1alpha enhanced CAPAN-1 adhesion to laminin in a dose-dependent manner; IL-1beta slightly increased the adhesion of these cells to laminin at low dosage, and to type I collagen at high dosage. Both IL-1alpha and IL-1beta reduced CD44 membrane expression of MIA PaCa 2, while TGF-beta1 increased the percentage of CD44-positive CAPAN-1 cells. We suggest that the effects on cell adhesion induced by different cytokines depend on the status of the target pancreatic cancer cell. EGF and, in part, IL-1alpha can favor nonmetastatic pancreatic cancer cell adhesion to ECM, possibly favoring tumor spread. Metastatic cells seem to lose the responsiveness to EGF, while becoming hyperresponsive to IL-1alpha. TGF-beta1 might exert an antidiffusive effect on primary, and a prodiffusive effect on metastatic pancreatic cancer cells. Only IL-1alpha, IL-1beta, and TGF-beta1 seem to influence CD44 membrane expression. All the results presented in this study were obtained in vitro, and in vivo studies are needed to verify whether the studied cytokines can favor or counteract pancreatic cancer spread.     

Responsiveness of articular cartilage from normal and inflamed mouse knee joints to various growth factors.

OBJECTIVE--Disturbed anabolic signalling might contribute to the decreased chondrocyte proteoglycan (PG) synthesis during joint inflammation. Articular cartilage obtained from mouse knee joints with experimentally-induced arthritis exhibits a state of nonresponsiveness towards stimulation of chondrocyte PG synthesis by insulin-like growth factor-1 (IGF-1). Investigations were carried out on the role of other growth factors apart from IGF-1 on regulation of chondrocyte PG synthesis under pathological conditions, that is, during repair after IL-1 exposure as well as during early and later arthritis. METHODS--Mouse patellae were obtained from normal knee joints and joints injected with IL-1 or zymosan. The patellae were cultured with basic fibroblast growth factor [bFGF], platelet-derived growth factor [PDGF], epidermal growth factor [EGF] or transforming growth factor beta [TGF beta] for 24 hours in the presence or absence of IGF-1. Chondrocyte PG synthesis was measured by 35S-sulphate incorporation. RESULTS--In normal cartilage none of the tested growth factors elicited stimulatory effects on the chondrocyte PG synthesis as caused by IGF-1. EGF and TGF beta even caused significant inhibition of chondrocyte PG synthesis. Combination of bFGF or PDGF with IGF-1 exerted significant additional stimulation of the 35S-sulphate incorporation. IL-1 exposed cartilage displayed reactivity to IGF-1 as well as to the other growth factors similar to control cartilage. Cartilage obtained from joints with experimentally-induced arthritis exhibited a state of nonresponsiveness towards all individually tested growth factors as well as growth factor combinations. CONCLUSION--Arthritis causes nonresponsiveness to stimulation of chondrocyte PG synthesis by the tested growth factors, which might be caused by a general receptor function defect.     

Specific binding to cultured cells of 125I-labeled type beta transforming growth factor from human platelets.

Purified type beta transforming growth factor from human platelets (TGF beta) radioiodinated with 125I-labeled Bolton and Hunter reagent was found to bind to a variety of cultured cells of both epithelial and mesenchymal origin, including normal human fibroblasts and keratinocytes. TGF beta binding sites have also been found on three mouse embryo-derived fibroblast-like cell lines with lower levels of TGF beta binding on the chemically transformed derivatives of these cell lines. A variety of human tumor cell lines was shown to have an inverse correlation between their level of TGF beta binding and their ability to form colonies in soft agar. The mouse embryo-derived AKR-2B (clone 84A) cells reached maximal binding of 125I-labeled TGF beta after 2 hr at 22 degrees C. Scatchard analysis of the equilibrium binding of TGF beta to AKR-2B (clone 84A) cells gives a Kd of 33 pM with approximately equal to 10,500 binding sites per cell. This Kd for TGF beta binding to AKR-2B (clone 84A) cells agreed well with the ED50 of 40 pM for stimulation of colony formation of these cells by TGF beta. The TGF beta binding sites on the AKR-2B cells were shown to be specific for TGF beta with no significant competition with epidermal growth factor, fibroblast growth factor, or insulin and only a small level of competition with high concentrations of platelet-derived growth factor. Partially purified preparations with TGF beta-like activity from mouse embryos and medium conditioned by mouse embryo-derived cells competed effectively for binding to the TGF beta receptor.     

Platelet-derived growth factor synthesis in mesangial cells: induction by multiple peptide mitogens.

Platelet-derived growth factor (PDGF) has been implicated in several nonmalignant pathophysiological processes, including proliferative diseases of the kidney. Glomerular mesangial cells secrete a PDGF-like factor and express the PDGF A-chain and c-sis (or B-chain) mRNAs. We report here that both mRNAs are induced by serum and this effect can be mimicked by recombinant PDGF, which also markedly stimulates DNA synthesis. Other growth factors, such as epidermal growth factor (EGF), transforming growth factor type alpha, basic fibroblast growth factor (bFGF), and tumor necrosis factor type alpha (TNF-alpha) also are mitogenic for human mesangial cells and induce expression of the PDGF mRNAs. EGF, TNF-alpha, and bFGF also stimulate these cells to secrete a PDGF-like factor. Furthermore, anti-PDGF antibody partially abrogates the mitogenic effect of EGF, suggesting that mitogen-stimulated PDGF synthesis in mesangial cells is at least partly responsible for cell growth induced by other growth factors. In contrast to these results, transforming growth factor type beta (TGF-beta), while inducing both mRNAs, is not mitogenic, indicating that its effect on message levels can be dissociated from DNA synthesis. These data suggest that several peptide growth factors regulate the growth of mesangial cells and that PDGF may be an effector molecule that plays a role in the mitogenic response to many of these growth stimuli.     

Distinct and overlapping direct effects of macrophage inflammatory protein-1 alpha and transforming growth factor beta on hematopoietic progenitor/stem cell growth

Both transforming growth factor beta (TGF beta) and macrophage inflammatory protein 1 alpha (MIP-1 alpha) have been shown to be multifunctional regulators of hematopoiesis that can either inhibit or enhance the growth of hematopoietic progenitor cells (HPC). We report here the spectrum of activities of these two cytokines on different hematopoietic progenitor and stem cell populations, and whether these effects are direct or indirect. MIP-1 alpha enhances interleukin-3 (IL- 3)/and granulocyte-macrophage colony-stimulating factor (GM- CSF)/induced colony formation of normal bone marrow progenitor cells (BMC) and lineage-negative (Lin-) progenitors, but has no effect on G- CSF or CSF-1/induced colony formation. Similarly, TGF beta enhances GM- CSF/induced colony formation of normal BMC and Lin- progenitors. In contrast, TGF beta inhibits IL-3/ and CSF-1/induced colony formation of Lin- progenitors. The effects of MIP-1 alpha and TGF beta on the growth of Lin- progenitors were direct and correlate with colony formation in soft agar. Separation of the Lin- cells into Thy-1 and Thy-1lo subsets showed that the growth of Thy-1lo Lin- cells is directly inhibited by MIP-1 alpha and TGF beta regardless of the cytokine used to stimulate growth (IL-3), GM-CSF, or CSF-1). In contrast, two other stem cell populations (0% to 15% Hoechst 33342/Rhodamine 123 [Ho/Rh123] and Lin- Sca-1+ cells) were markedly inhibited by TGF beta and unaffected by MIP- 1 alpha. Furthermore, MIP-1 alpha has no effect on high proliferative potential colony-forming cells 1 or 2 (HPP-CFC/1 or /2) colony formation in vitro, whereas TGF beta inhibits both HPP-CFC/1 and HPP- CFC/2. Thus, MIP-1 alpha and TGF beta are direct bidirectional regulators of HPC growth, whose effects are dependent on other growth factors present as well as the maturational state of the HPC assayed. The spectrum of their inhibitory and enhancing activities shows overlapping yet distinct effects.     

Ovarian thecal cells produce transforming growth factor-beta which can regulate granulosa cell growth

Ovarian thecal cells in culture were found to synthesize and secrete transforming growth factor-beta (TGF beta). A component in thecal cell-conditioned medium was immunologically similar to TGF beta, as assessed with a RIA, and inhibited specific binding of TGF beta to its cell surface receptors. Thecal cell-secreted proteins also contained TGF beta biological activity, which was determined by stimulation of soft agar colony formation by AKR-2B indicator cells. Specific TGF beta antibodies precipitated a 25 K protein from radiolabeled thecal cell-secreted protein that comigrated with purified platelet-derived TGF beta. Both bovine thecal cell and rat thecal/interstitial cell preparations produced TGF beta, which required acid treatment to obtain fully active samples. The physiological significance of TGF beta production by thecal cells was addressed through an analysis of the effects of TGF beta on bovine granulosa cell growth. TGF beta inhibited epidermal growth factor stimulation of granulosa cell growth, but alone it had no apparent influence. Observations indicate that ovarian thecal cells produce TGF beta, which can regulate granulosa cell growth and differentiation. Discussion of thecal cell-granulosa cell interactions and the possible functions of TGF beta in the ovary is presented.     

Androgens and transforming growth factor beta modulate the growth response to epidermal growth factor in human prostatic tumor cells (LNCaP)

Treatment of LNCaP human prostatic cancer cells with 0.1 nM of the synthetic androgen, R1881, resulted in a three-fold stimulation of growth in 6 days. Of several growth factors tested (epidermal growth factor (EGF), platelet-derived growth factor, insulin-like growth factor, and insulin) only EGF (1 ng/ml) stimulated cell growth (two-fold). This stimulatory effect of EGF was inhibited for approximately 70% by 0.02 ng transforming growth factor beta (TGF beta)/ml. EGF (1 ng/ml) acted synergistically with R1881 (0.1 nM) on LNCaP cells to induce cell proliferation (seven-fold increase in cell growth). The synergistic effect of androgen and EGF was inhibited by TGF beta (0.05 ng/ml). In conclusion: human prostatic LNCaP cells are sensitive to EGF. Androgen increases and TGF beta decreases the growth response to EGF. This effect of TGF beta on an androgen-responsive system has not been observed before.     

Expression of the transforming growth factor-alpha/epidermal growth factor receptor pathway in normal human breast epithelial cells

To better understand the possible roles and interactions of transforming growth factor-alpha (TGF alpha) and its receptor, the epidermal growth factor (EGF) receptor in human breast epithelium, we have studied the expression of TGF alpha and the EGF receptor in a series of normal human mammary epithelial cells derived from reduction mammoplasty before in vitro propagation, during short term proliferation in vitro, and after immortalization. Increased TGF alpha mRNA expression coincided with conversion of the cells to a proliferative state in vitro. After establishment, propagation, and proliferation in vitro, the cells expressed high levels of both TGF alpha and EGF receptor mRNAs. Addition of diverse growth inhibitory agents, including 12-O-tetradecanoylphorbol-13-acetate (TPA), TGF beta, and sodium butyrate, to one of these rapidly proliferating cell populations (no. 184) failed to reduce the expression of either TGF alpha or the EGF receptor. Likewise, cessation of growth associated with both senescence and confluence of the 184 cells did not result in reduced expression. However, regulation of TGF alpha mRNA could be demonstrated by withdrawal of EGF from the medium or by antibody-mediated blockade of the EGF receptor in 184 cells. Antibody-mediated EGF receptor blockade also results in inhibition of growth and [3H]thymidine labeling. An autoregulatory autocrine loop appears operant in proliferating breast epithelial cells. Both growth and levels of TGF alpha mRNA expression are controlled by binding of ligand to the EGF receptor. These studies suggest a role for the TGF alpha/EGF receptor pathway in normal breast cell physiology.     

Production of transforming growth factor alpha in human pancreatic cancer cells: evidence for a superagonist autocrine cycle.

Previous work showed that cultured human pancreatic cancer cells overexpress the epidermal growth factor (EGF) receptor. In the present study, we sought to determine whether some of these cell lines produce transforming growth factor alpha (TGF-alpha). Utilizing a radiolabeled TGF-alpha cDNA in hybridization experiments, we determined that ASPC-1, T3M4, PANC-1, COLO-357, and MIA PaCa-2 cell lines expressed TGF-alpha mRNA. Serum-free medium conditioned by T3M4 and ASPC-1 cells contained significant amounts of TGF-alpha protein. Although unlabeled TGF-alpha readily competed with 125I-labeled EGF for binding, each cell line exhibited lower surface binding and internalization of 125I-labeled TGF-alpha as compared to 125I-labeled EGF. Both TGF-alpha and EGF significantly enhanced the anchorage-independent growth of PANC-1, T3M4, and ASPC-1 cells. However, TGF-alpha was 10- to 100-fold more potent than EGF. These findings suggest that the concomitant overexpression of EGF receptors and production of TGF-alpha may represent an efficient mechanism for certain cancer cells to obtain a growth advantage.     

Sarcoma growth factor from conditioned medium of virally transformed cells is composed of both type alpha and type beta transforming growth factors.

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.     

Transforming growth factor alpha is trophic to pancreatic cancer in vivo.

Pancreatic cancer cell lines overexpress epidermal growth factor (EGF) receptors and also have the capacity to produce transforming growth factor alpha (TGF alpha), the alternate agonist of the EGF receptor. The purpose of this study was to determine if TGF alpha had a trophic effect on the growth of pancreatic cancer in vivo. Syrian golden hamsters were inoculated with 50,000 H2T hamster ductal pancreatic cancer cells. The hamsters were then randomised to three equal groups: the groups received either saline (control), EGF, or TGF alpha, each by intraperitoneal injection, three times a day. Treatment continued for seven weeks, and each week the hamsters were weighed and tumour areas were measured. The hamsters were then killed, and the tumours were excised, weighed, and extracted for assay of DNA content as a measure of cellularity. From week four onwards both EGF and TGF alpha significantly stimulated tumour growth. Although tumour weights were not significantly different, tumour DNA content had nearly doubled after exposure to both EGF and TGF alpha. It is concluded that like EGF, TGF alpha can stimulate pancreatic cancer growth in vivo, and this may in part explain the aggressive nature of these cancers in clinical practice.     

Purification and initial characterization of a type beta transforming growth factor from human placenta.

A polypeptide transforming growth factor (TGF) that induces anchorage-dependent rat kidney fibroblasts to grow in soft agar has been isolated from human placenta and purified to homogeneity. This polypeptide is classified as a type beta TGF because it does not compete with epidermal growth factor (EGF) for membrane receptor sites but does require EGF for induction of anchorage-independent growth of indicator cells. Purification of this peptide was achieved by acid/ethanol extraction of the placenta, followed by gel filtration, cation exchange, and HPLC of the acid-soluble proteins. Homogeneity of the TGF-beta from the final column was shown by its constant specific activity and amino acid composition across the peak of soft agar colony-forming activity and by its migration as a single band at Mr 23,000-25,000 on NaDodSO4/polyacrylamide gel electrophoresis. Under reducing conditions, the protein migrated on a gel as a single band at Mr 13,000. The purified placental TGF-beta caused half-maximal growth stimulation of indicator cells in soft agar at 64-72 pg/ml (3 pM) in the presence of EGF at 2 ng/ml (0.34 nM).     

Regulation of bovine bone cell proliferation by fibroblast growth factor and transforming growth factor beta

We have tested the hypothesis that basic fibroblast growth factor (bFGF) and transforming growth factor beta (TGF beta) regulate the proliferation of osteoblast-like cells. Cells which migrated from central bone explants of fetal calf calvaria expressed markers characteristic of the osteoblast phenotype, including osteocalcin (bone Gla protein) secretion and increased cAMP production in response to treatment with PTH. Bone cells proliferated in response to bFGF in a dose- and time-dependent pattern (ED50 = 60 pg/ml media). bFGF increased both the rate of bone cell proliferation (1.7-fold above controls) and final cell density at confluence (3-fold above controls). Acidic FGF (aFGF) exerted comparable effects though with lesser potency (ED50 = 2 ng/ml). In addition to its mitogenic effect, bFGF increased the osteocalcin content of conditioned media, suggesting that bFGF also modulates the function of osteoblast-like cells. Although TGF beta did not stimulate bone cell proliferation, it potentiated the mitogenic effects of aFGF and bFGF. In the presence of bFGF (0.7 ng/ml) the response to TGF beta was dose-dependent (ED50 = 1.7 ng/ml), with maximal stimulation at 5 ng/ml. These results demonstrate that aFGF and bFGF are mitogenic for bone cells in vitro. Furthermore, TGF beta potentiates the effects of bFGF and aFGF on the proliferation of bone cells. Since these growth factors are present in bone tissue in vivo, these data support the proposal that FGF and TGF beta may participate in the regulation of bone formation.     

Differential effect of transforming growth factor beta 1 on the proliferation of human lymphoid and myeloid leukemia cells

BACKGROUND. Transforming Growth Factor beta (TGF beta) exerts different effects on the hemopoietic system which range from the growth stimulation of more mature myeloid progenitors to the growth inhibition of more immature and multilineage hemopoietic precursors. TGF beta is also an inhibitor of the proliferation and functional activities of normal T and B lymphocytes. The aim of this study was to evaluate its effect on the growth of a human leukemic cells of lymphoid and myeloid origin. METHODS. We tested its activity on the doubling time, the DNA synthesis rate and the clonal growth of a panel of lymphoid and myeloid leukemic cell lines. RESULTS. Among the myeloid cell lines, the proliferation in liquid cultures as well as the clonal growth of KG1, HL60 and U937 were suppressed by TGF beta 1 at doses ranging from 0.025 to 2.5 ng/ml; the degree of inhibition was, however, variable. BV 137, a Ph1-positive cell line derived from a very undifferentiated stem cell, was also highly responsive to TGF beta 1 inhibition. Among the six lymphoid neoplastic cell lines, only Nalm 6, a pre-B leukemic cell line, was consistently and reproducibly inhibited by the same doses of TGF beta 1. Conversely, two Burkitt lymphoma cell lines, Raji and Daudi, and three T-cell leukemias (Molt 4, Jurkat and PF 382) were insensitive to TGF beta inhibition.     

Effects of transforming growth factor beta s and basic fibroblast growth factor on articular chondrocytes obtained from immobilised rabbit knees.

OBJECTIVE: To clarify the effects of transforming growth factor beta 1 (TGF beta 1), TGF beta 2, and basic fibroblast growth factor (bFGF) on cell proliferation and proteoglycan (PG) synthesis in articular chondrocytes obtained from immobilised rabbit knees. METHODS: The right knees of rabbits were immobilised in full extension for up to 42 days using fiberglass casts. Specimens for histology were stained with safranin O. Chondrocytes were isolated from the weight bearing regions of the femur and tibia of the immobilised knees and cultured with combinations of growth factors. Cell proliferation and PG synthesis were determined by 3H-thymidine and 35S-sulphate incorporations. RESULTS: Histological study revealed loss of metachromasia in the articular cartilage at seven days, fissuring and cell clusters at 28 days, and loss of cartilage layers 42 days after immobilisation. Radioisotope assay of the chondrocytes revealed no remarkable change in DNA synthesis in the presence of either TGF beta 1 or TGF beta 2 alone. bFGF markedly stimulated cell proliferation in specimens obtained 0 to seven days after immobilisation. The combination of either TGF beta 1 or TGF beta 2 with bFGF had a synergistic effect, inducing significant increases in DNA synthesis four, seven, and 14 days after immobilisation. PG synthesis by chondrocytes from immobilised joints was not significantly altered by these agents. CONCLUSION: TGF beta 1 or TGF beta 2 in combination with bFGF exert synergistic effects on cell proliferation in articular chondrocytes obtained from the rabbit knee during the early days after immobilisation by a cast. These results suggest a critical role of cytokine combinations in the development of articular cartilage degeneration after immobilisation.     

Transforming growth factor-alpha and -beta are potent and effective inhibitors of GH4 pituitary tumor cell proliferation

The mechanisms that restrict cell proliferation play an important regulatory role in differentiation and tumorigenesis. The growth of PRL-secreting cells of the anterior pituitary is known to be highly estrogen dependent; however, estrogen may act indirectly via growth regulatory polypeptides. We have used the GH4C1 rat pituitary cell line to investigate the action of two classes of growth regulatory polypeptides, transforming growth factor-alpha (TGF alpha) and TGF beta. TGF alpha and TGF beta each inhibit GH4 cell proliferation, as measured by cell number and [3H]thymidine incorporation, and given together arrest GH4 cell proliferation. The growth inhibitory action of TGF alpha is concentration dependent (IC50 = 100 pM) and saturable. Activin-A, a TGF beta-related polypeptide, also inhibits proliferation, but is less effective than TGF beta. TGF alpha and TGF beta each alter GH4 cell cycle distribution by decreasing in the percentage of S phase cells (74% and 34%, respectively) and increasing proportionally G0-G1 phase cells. The growth inhibitory action of TGF alpha differs from that of TGF beta in that TGF alpha also causes a temporary accumulation of cells in G2-M phases. We next initiated experiments to evaluate the role of protein kinase-C in the growth inhibitory actions of TGF alpha and TGF beta. The alpha- and beta-isoforms of protein kinase-C were down-regulated by pretreatment with 12-O-tetradecanoylphorbol-13-acetate, yet TGF alpha and TGF beta still substantially inhibited GH4 cell proliferation. We next compared the actions of TGF alpha and TGF beta on two other well characterized prolonged GH4 responses. TGF alpha and TGF beta each increased GH4 cell adhesion, but differed in their effects on PRL production. This indicates that TGF alpha and TGF beta activate different signaling pathways in GH4 cells. Activin-A acted like TGF beta by enhancing cell-substratum adhesion and inhibiting PRL production, consistent with an interaction at a common receptor site. Taken together these results identify biological functions for TGF alpha, TGF beta, and activin-A on PRL cells and open the possibility that they may represent the direct in vivo mediators of estrogen action to regulate the growth of PRL cells in the anterior pituitary gland.     

Resistance of human squamous carcinoma cells to transforming growth factor beta 1 is a recessive trait.

Because most human squamous carcinoma cell lines of the aerodigestive and genital tracts are refractory to the antiproliferative action of transforming growth factor beta 1 (TGF beta 1) in vitro, we have begun to identify the causes for resistance of squamous carcinoma cell lines to TGF beta 1 by using somatic cell genetics. Two stable hybrid cell lines (FaDu-HKc.1 and FaDu-HKc.2) were obtained by fusing a TGF beta 1-resistant human squamous carcinoma cell line, FaDu-HygR, with a human papilloma virus 16-immortalized, TGF beta 1-sensitive, human foreskin keratinocyte cell line, HKc-neoR. Whereas TGF beta 1 did not inhibit DNA synthesis in parental FaDu-HygR cells, it reduced DNA synthetic activity of HKc-neoR, FaDu-HKc.1, and FaDu-HKc.2 cells by 75-85% (IC50, 2-5 pM). Although squamous carcinoma cells express lower than normal levels of TGF beta 1 type II receptors on their cell surface, TGF beta 1 type II receptor mRNA was detected in all four cell lines. Recessive genes involved in TGF beta 1 signaling may be localized to the distal portion of chromosome 18q, as this was the sole chromosomal region of homozygous deletion in parental FaDu-HygR cells. Furthermore, our previous observation that mutant p53 decreases sensitivity of keratinocytes to TGF beta 1 was supported by the finding that the level of the mutant p53 protein expressed by the hybrid cell lines was greatly reduced. In summary, TGF beta 1 resistance of FaDu cells appears to be recessive and is presumably due to the loss of one or more post-receptor elements of the signaling pathway.