Autocrine growth stimulation by transforming growth factor alpha in asbestos-transformed rat mesothelial cells.

Although the association between asbestos exposure and mesothelioma development has been established for decades, very little is known regarding the molecular mechanism(s) by which asbestos fibers induce this disease. In this series of experiments, the potential for transforming growth factor alpha (TGF-alpha) to act as an autocrine growth factor in transformed mesothelial cells was examined in rats, a model system frequently used to assess the tumorigenic potential of fibrous particulates. Both asbestos-transformed cells and spontaneously transformed cells expressed functional EGF receptors, although only the asbestos-transformed cells expressed TGF-alpha. Expression of TGF-alpha transcripts was correlated with secretion of picogram amounts of growth factor into conditioned medium by the asbestos-transformed cells. In addition, whereas TGF-alpha inhibited the growth of spontaneously transformed mesothelial cells, it stimulated the growth of asbestos-transformed cells. Neutralizing antibody that recognized TGF-alpha secreted by the asbestos-transformed cells was able to inhibit the growth of these cells. Taken together, these data indicate that TGF-alpha acts as an autocrine growth factor for asbestos-transformed rat mesothelial cells. Therefore, in asbestos-transformed mesothelial cells, altered production and responsiveness to TGF-alpha distinguish these cells from spontaneously transformed mesothelial cells. These data suggest that differences in mesothelioma etiology may be reflected in differences in the molecular alterations present in these tumors.

Expression of GPC3, an X-linked recessive overgrowth gene, is silenced in malignant mesothelioma.

Gene expression changes in rat asbestos-induced malignant mesothelioma (MM) cells were investigated by differential mRNA display. A mRNA transcript identified by this approach was abundant in normal rat mesothelial cells but not expressed in rat MM cell lines. Northern blot analysis confirmed that this transcript is uniformly silenced in rat MM cell lines and primary tumors. Nucleotide sequence analysis revealed that this transcript is encoded by the rat glypican 3 gene (GPC3), whose human homolog is mutated in the Simpson-Golabi-Behmel overgrowth syndrome. Allelic loss at the GPC3 locus was infrequent (6.9%) in MM cell lines, and no mutations were found. GPC3 transcript levels were markedly decreased in 16 of 18 primary tumors and 17 of 22 human MM cell lines. Most of the cell lines were shown to have aberrant methylation of the GPC3 promoter region. In two of four human MM cell lines tested, GPC3 expression was restored after 2-deoxy 5-azacytidine (DAC)-mediated demethylation of its promoter region. Ectopic expression of GPC3 inhibited in vitro colony formation of human MM cells. Collectively, these data suggest that down-regulation of GPC3 is a common occurrence in MM and that GPC3, an X-linked recessive overgrowth gene, may encode a negative regulator of mesothelial cell growth.

Protein kinase C inhibition by plant flavonoids. Kinetic mechanisms and structure-activity relationships.

Protein kinase C (PKC) from rat brain was inhibited by plant flavonoids in a concentration-dependent manner depending on flavonoid structure. Of the fifteen flavonoids studied, fisetin, quercetin and luteolin were the most potent, while hesperetin, taxifolin and rutin were among the least potent. The flavonol fisetin was almost 100% inhibitory at a concentration of 100 microM. The extent of inhibition was the same whether diacylglycerol or 12-O-tetradecanoylphorbol-13-acetate was used as enzyme activator. Inhibition was independent of Ca2+, phospholipid, and enzyme activator, as shown by inhibition of protamine phosphorylation in the absence of the regulatory components. Fisetin was a competitive inhibitor with respect to ATP binding and noncompetitive with respect to protein substrate. The X-ray crystal structure analysis of hesperetin monohydrate showed that the molecule is essentially planar despite the sofa conformation of the gamma-pyran ring and the 27 degrees twist of the 2-phenyl ring. Comparison of this inactive flavanone with those of the active flavones showed that, although hesperetin can adopt a planar profile similar to those of fisetin and quercetin, the 4'-methoxy substituent blocks an essential structural feature required for inhibitory activity. Analysis of these structure-activity data revealed a model of the minimal essential features required for PKC inhibition by flavonoids: a coplanar flavone structure with free hydroxyl substituents at the 3', 4' and 7-positions.

Alterations in growth factor pathways in multistage carcinogenesis of rat tracheal epithelial cells.

The role of peptide growth factors in the process of multistage carcinogenesis of rat tracheal epithelial (RTE) cells was assessed by examining growth factor requirements and expression of growth factors and their receptors in normal and transformed RTE cells. Transformed RTE cell lines show decreased requirements for bovine pituitary extract, insulin and epidermal growth factor compared to primary RTE cells in culture. An autocrine role for TGF alpha in transformed RTE cells is suggested by data showing TGF alpha production and decreased proliferation in the presence of TGF alpha antisera and TGF alpha/EGF receptor kinase inhibitor. Therefore, decreased EGF requirements in transformed RTE cells could be explained by autocrine TGF alpha regulation. In contrast, no evidence for an insulin/IGF-I autocrine pathway could be detected in transformed RTE cells. These data indicate that multiple alterations in growth factor pathways occur in transformed RTE cells.

Regulation of normal and transformed tracheobronchial epithelial cell proliferation by autocrine growth factors.

Several peptide growth factors have been identified as autocrine regulators of normal tracheobronchial epithelial cells, including the transforming growth factors alpha and beta. Using in vitro tissue culture models of multistep neoplastic transformation as well as cell lines derived from human bronchogenic tumors, a significant number of growth factors have been found to function as autocrine factors for neoplastic tracheobronchial cells as well. In several instances, the regulation of the autocrine pathway is disrupted in neoplastic tracheobroncial cells compared with their normal counterparts. These results indicate that there are multiple aberrations in growth factor pathways occurring in tracheobronchial epithelial cells during progression to the neoplastic phenotype.

Fibronectin expression and organization in mesothelial and mesothelioma cells.

Mesothelial cells are believed to be the progenitor cells for malignant mesothelioma, a tumor associated with exposure to asbestos and other mineral fibers. Little is known regarding fibronectin (Fn) function in mesothelial and mesothelioma cells. Fn RNA, protein levels, and localization were assessed in secondary cultures and later passages of spontaneously immortalized rat pleural mesothelial (NRM) cells and in neoplastic cell lines derived from asbestos-induced mesotheliomas. NRM cells expressed similar levels of Fn RNA regardless of passage number or cell density, as determined by Northern blotting and ribonuclease protection assays. Western blotting showed that Fn protein was both secreted by NRM cells and associated with cell lysates. Immunofluorescent confocal laser scanning microscopy demonstrated that secondary cultures of NRM cells assembled Fn into abundant homogeneous fibrillar arrays organized primarily between cells, whereas later passages of NRM cells displayed abundant but less homogeneous Fn organization. Fn RNA and protein levels in neoplastic mesothelial cells were slightly less or similar to levels in NRM cells. Organization of Fn in neoplastic cells was heterogeneous compared with secondary cultures of NRM cells, but Fn fibril formation was still apparent. F-actin microfilaments were organized in both NRM and neoplastic cells; however, actin stress fibers were maintained in neoplastic cells, whereas NRM cells displayed dense actin peripheral bands at high density. The maintenance of organized Fn and actin in mesothelioma cells is surprising and may contribute to the localized growth and invasive properties of these tumors.

Cellular uptake of phosphorothioate oligodeoxynucleotides is negatively affected by cell density in a transformed rat tracheal epithelial cell line: implication for antisense approaches.

Antisense oligodeoxynucleotides have been used to specifically inhibit the expression of a variety of genes. In the process of testing phosphorothioate oligodeoxynucleotides (S-oligos) as specific inhibitors of transforming growth factor alpha synthesis, we observed that the efficiency of cellular uptake of S-oligos was not constant throughout the culture period but decreased as the cell densities increased. Our data suggest that the mechanism by which oligonucleotides enter cells is negatively affected by increased cell density. These results emphasize the importance of determining uptake kinetics before designing and interpreting antisense experiments using phosphorothioate oligonucleotides.

Thiazide diuretics inhibit chloride absorption by rabbit distal colon.

In order to investigate the cellular mechanisms of action of thiazide diuretics, the effect of diuretic and nondiuretic thiazide compounds on Cl- absorption across rabbit distal colon was assessed in tissues mounted in Ussing chambers. This epithelium absorbs Cl- via an active electroneutral transport process. Net 36Cl- absorption across short-circuited tissues was decreased 53, 36 and 20% after addition of 10(-4) M trichlormethiazide, bendroflumethiazide or hydrochlorothiazide, respectively, to the mucosal bathing solution. This inhibitory effect was a result of a decrease in the mucosa-to-serosa unidirectional Cl- flux (P less than .02). Neither the serosa-to-mucosa Cl- flux nor Isc was affected by the thiazides. Thiazide diuretics may exert their effect on Cl- transport across rabbit distal colon through inhibition of a Cl(-)-HCO-3 exchange mechanism. The nondiuretic thiazide, diazoxide, had no effect on Cl- transport. The similarity between the diuretic potency of these compounds and their potency as inhibitors of Cl- absorption by rabbit colon suggests that the thiazides have a similar mechanism of action in renal epithelia.

Localization of chloride secretion in rabbit colon: inhibition by anthracene-9-carboxylic acid.

The substituted aromatic compound anthracene-9-carboxylic acid (A-9-C) was used to inhibit active Cl- secretion by the epithelium of short-circuited rabbit distal colon. Tissues were mounted in Ussing chambers and stimulated to secrete Cl- by the addition of 1 mM dibutyryl adenosine 3',5'-cyclic monophosphate to the serosal bath. Results of 36Cl-flux measurements showed that the addition of 0.1 mM A-9-C to the mucosal bath inhibited Cl- secretion by 48%. The site of Cl- secretion was determined by using conventional micro-electrodes to show that the cells of the crypt regions, and not the surface epithelial cells, responded to A-9-C by an increase in apical membrane fractional resistance from 0.75 to 0.80 and a hyperpolarization of the apical membrane from -64 to -68 mV (P less than 0.05). The sulfhydryl reagent dithiothreitol was added to the mucosal tissue bath to remove the mucus produced by goblet cells of the crypt regions of these tissues. The time for maximal inhibition of Cl- secretion by A-9-C was decreased from 30 to 15 min by removal of the mucus barrier. The effects of A-9-C on the crypt cells, as well as the effect of mucus on the inhibitory action of this compound, demonstrate that the crypt region is the site of Cl- secretion.

Epidermal growth factor dependence and TGF alpha autocrine growth regulation in primary rat tracheal epithelial cells.

We have examined dependence of primary rat tracheal epithelial (RTE) on exogenous epidermal growth factor (EGF) and determined whether a TGF alpha autocrine pathway is operating in these cells. Primary RTE cells plated in serum free media (SFM) without EGF and bovine pituitary factor (BPE) show little proliferation compared to cultures propagated in media containing EGF/BPE (CSFM). Removal of EGF/BPE shortly after plating, however, results in significant proliferation, although plateau cell densities are reduced and cell morphology is significantly altered compared to cells propagated in CSFM. Addition of EGF and/or BPE to cultures propagated in SFM minus EGF/BPE restores maximum cell density. The concentration of TGF alpha peptide in media conditioned by cells propagated without EGF/BPE is lower than the concentration in the media of CSFM cultures. TGF alpha mRNA and protein levels are also significantly lower in cells late in culture compared to logarithmically growing cells regardless of the presence or absence of EGF/BPE. The proliferation of primary RTE cells propagated without EGF/BPE is inhibited by neutralizing TGF alpha antiserum and by a tyrphostin compound that blocks TGF alpha/EGF receptor tyrosine kinase activity. These results indicate that primary RTE cells utilize TGF alpha as an autocrine growth factor and that the autocrine pathway is regulated as a function of growth state of the cells. However, this pathway does not provide growth autonomy to primary RTE cells, since cultures remain dependent on exogenous EGF/BPE for sustained proliferation.

Abnormalities in growth regulation of transformed rat tracheal epithelial cells.

We have examined the changes in growth regulation which take place during multistage transformation of rat tracheal epithelial (RTE) cells exposed to chemical carcinogens in vitro. Transformed RTE cells demonstrate: (1) altered negative growth factor sensitivity and (2) altered positive growth factor dependence and gene expression compared with primary RTE cells in culture. Primary RTE cells are sensitive to the growth inhibitory effects of retinoic acid and transforming growth factor beta (TGF beta). Enhanced growth variants of RTE cells, recognized 4-6 weeks after carcinogen treatment, lose sensitivity to the antiproliferative effects of retinoic acid. Likewise, many immortalized RTE cell lines lose responsiveness to growth inhibition by TGF beta. We also examined positive growth factor requirements and gene expression in primary and transformed RTE cells propagated in serum-free media. Many transformed cell lines lose dependence on epidermal growth factor in the media. These cell lines also overexpress TGF alpha mRNA and protein. Since TGF alpha acts at the epidermal growth factor receptor, these data suggest that TGF alpha plays an autocrine role in growth regulation of transformed RTE cells. Thus, alterations in both negative and positive growth factor regulation contribute to expression of the transformed phenotype in RTE cells.

Role of TGF alpha and its receptor in proliferation of immortalized rat tracheal epithelial cells: studies with tyrphostin and TGF alpha antisera.

We have shown in the present study and in studies reported previously that preneoplastic and neoplastic rat tracheal epithelial (RTE) cell lines express TGF alpha and do so regardless of the mechanism by which they were transformed. In order to determine whether TGF alpha is an autocrine growth regulator of immortalized RTE cells, we have examined the function of TGF alpha/EGF receptors and the growth requirements for TGF alpha in these cells. The level of immunoprecipitated TGF alpha/EGF receptor protein in immortalized RTE cells was similar to or less than levels in primary RTE cells, indicating that chemically induced transformation of RTE cells does not involve overexpression of TGF alpha/EGF receptors. Scatchard analysis of TGF alpha/EGF receptors in the neoplastic EGV5T cell line revealed the presence of high-affinity (Kd = 0.4 nM) and low-affinity (Kd = 9.8 nM) binding sites. A tyrphostin TGF alpha/EGF receptor tyrosine kinase inhibitor decreased in a dose-dependent manner the proliferation as well as EGF-induced autophosphorylation of the TGF alpha/EGF receptor of transformed RTE cells. The inhibitory effect of tyrphostin on proliferation and receptor kinase activity was attenuated in late log and plateau phase cultures. The phosphotyrosine content of several other EGF-dependent and independent phosphoproteins was also decreased by the tyrphostin. Proliferation of transformed RTE cells was also inhibited when TGF alpha antisera was added to the media of growing cells. These data are consistent with the hypothesis that proliferation of transformed RTE cells involves autocrine regulation by TGF alpha and its receptor.

Alterations in the localization of F-actin, fibronectin, and thrombospondin occur prior to neoplastic transformation in rat tracheal epithelial cells.

Structural glycoproteins and cytoskeletal proteins play a major role in the regulation of cellular organization and function. Changes in the structure and function of these proteins are involved in the cascade of events which lead to neoplastic transformation. We evaluated RNA levels, protein localization, and organization of selected proteins in an in vitro model system of respiratory carcinogenesis to examine alterations in cell architecture. Localization of fibronectin (Fn), thrombospondin (Tsp), and F-actin was examined in (1) primary rat tracheal epithelial (RTE) cells; (2) spontaneously immortalized nonneoplastic cells (SPOC-1); and (3) neoplastic cells (EGV5T) derived from tumors arising following transplantation of an N-methyl-N'-nitro-N-nitrosoguanidine-transformed RTE cell line into nude mice. Proteins were stained with fluorescein-labeled antibodies or phalloidin compound and analysis was performed with a confocal laser scanning microscope. Primary RTE cells display organized F-actin stress fibers, perinuclear Fn and Tsp, and pericellular Fn in fibrillar arrays. In larger colonies, Tsp occurs between cells and occasionally in fibrillar arrays. SPOC-1 cells, unlike primary RTE cells and neoplastic EGV5T cells, seldom form junctions and exhibit few cell surface extensions. F-actin stress fibers are reduced in these immortalized cells. F-actin in SPOC-1 cells occurs in the perinuclear region, scattered diffusely throughout the cell and in punctate adhesions. Fn and Tsp are localized to the perinuclear region with Fn staining more intensely. EGV5T neoplastic cells also display a dramatic loss of stress fibers and F-actin is concentrated mainly near the cell periphery. Perinuclear staining of Fn and Tsp occurs in some cells within the colony. Levels of Tsp RNA and Fn RNA and protein are significantly reduced in both cell lines compared to primary RTE cells. We conclude that structural protein disruptions are early events in the transformation of these respiratory epithelial cells.

Altered growth factor dependence and transforming growth factor gene expression in transformed rat tracheal epithelial cells.

The role of peptide growth factors in neoplastic progression of transformed rat tracheal epithelial (RTE) cells was assessed by examining growth factor requirements and expression of growth factor and growth factor receptor genes in normal and transformed RTE cells. Neoplastically transformed cell lines showed decreased requirements for bovine pituitary extract, insulin, and epidermal growth factor compared to normal primary RTE cells. Neoplastic RTE cell lines expressed significantly increased levels of transforming growth factor alpha (TGF alpha) RNA and secreted TGF alpha into the media, suggesting an autocrine role for this growth factor. Increased levels of TGF alpha RNA were also observed in the preneoplastic stages of the same cell lines, indicating that increased TGF alpha expression is an early event in the multistage process of neoplastic transformation of RTE cells. TGF beta transcripts were also overexpressed in neoplastically transformed cell lines. Our studies suggest that aberrant expression of growth factors may play an important role in the development and/or maintenance of the transformed phenotype in RTE cells.

Abnormalities of growth factor systems in transformed airway epithelial cells.

The role of the peptide growth factors transforming growth factor alpha (TGF alpha) and transforming growth factor beta (TGF beta) in the regulation of proliferation of normal and transformed airway epithelial cells was studied. Normal as well as transformed rat tracheal epithelial (RTE) cell cultures secrete similar amounts of TGF alpha during logarithmic growth. Once normal RTE cell cultures reach the plateau phase of growth, they down-regulate TGF alpha expression at the RNA and protein level; in contrast, transformed cells do not down-regulate TGF alpha. Using neutralizing TGF alpha antiserum and a tyrphostin TGF alpha/EGF receptor tyrosine kinase inhibitor, we show that the secreted TGF alpha is utilized by both normal and transformed cells as an autocrine mitogenic factor. Normal RTE cells are highly sensitive to the growth inhibitory effects of TGF beta, particularly during early phases of logarithmic growth. At late logarithmic and plateau phases of proliferation, cultures of normal RTE cells secrete large amounts of TGF beta. That the endogenous TGF beta is exerting growth inhibitory effects can be demonstrated by adding TGF beta antisera to the cultures which causes a burst of proliferation. Many transformed RTE cell lines exhibit a markedly reduced sensitivity to the growth inhibitory effects of TGF beta. However, the cells remain responsive to regulation of ECM genes by TGF beta. The transformed cell lines examined secrete less than one tenth the amount of TGF beta of normal cells. Our studies show that the autocrine TGF beta growth restraining mechanism is inoperative in many of the RTE cell transformants. We conclude, therefore, that alterations in TGF alpha and TGF beta regulation of cell proliferation are important factors contributing to the abnormal growth behavior of transformed RTE cells.

Phenotype and differentiation potential of a novel rat tracheal epithelial cell line.

In this report we described the establishment and characterization of a continuous rat tracheal epithelial (RTE) cell line spontaneously derived from secondary RTE cell cultures. Designated SPOC1, this cell line is nontumorigenic and maintains a diploid karyotype with specific, nonrandom chromosomal alterations involving chromosomes 1, 3, and 6. SPOC1 cells demonstrate decreased requirements for peptide growth factors, compared with primary RTE cells. Upon inoculation into denuded rat tracheas, which are then implanted into syngeneic hosts, SPOC1 cells initially form a stratified squamous epithelium, which becomes less stratified with time and forms glandlike invaginations into the surrounding lamina propria. No evidence of ciliated cell differentiation is detected. The epithelium formed by SPOC1 cells in tracheal grafts reacts with antibodies specific for keratin 14, 13, and 19 (but not keratin 18) at both early and late time points, although the localization of antibody staining changes as the epithelium becomes less stratified with time. The suprabasal epithelial cells become positive for alcian blue-periodic acid-Schiff staining at later time points. The near-normal karyotype and differentiation potential of SPOC1 cells make this cell line a unique window into early changes occurring during immortalization of airway epithelial cells and will allow studies of relationships between differentiation state and neoplastic transformation.

Mucin production by SPOC1 cells--an immortalized rat tracheal epithelial cell line.

An airway epithelial mucous goblet cell line would be useful towards understanding mechanisms underlying the common problem of respiratory mucus hypersecretion. SPOC1 is a novel rat tracheal epithelial (RTE) cell line that developed cytologic features suggestive of mucous goblet cells when grown in tracheal grafts in vivo (Am. J. Respir. Cell Mol. Biol. 1995; 12:385-395). Our aims were to determine whether SPOC1 cells were capable of mucin synthesis and to directly compare mucin production by SPOC1 cells and RTE cells. Towards this end, we validated the use of monoclonal antibody (mAb) RTE11 (Exp. Lung Res. 1992; 18:323-342) as an immunologic probe for rat airway secretory mucin. Our results strongly suggest that mAb RTE11 detects a carbohydrate antigen that is a sensitive and specific marker for rat tracheobronchial secretory mucin. SPOC1 cells in tracheal grafts in vivo contained granules with ultrastructural features similar to mucous granules in normal rat airway goblet cells and they were strongly stained by mAb RTE11. Retinoic acid (RA) and culture on porous supports are known to profoundly modify airway epithelial cell phenotype in vitro. Expression of several retinoid-responsive proteins was similar in cultured SPOC1 and primary RTE cells, but major differences in mucin production were noted. Primary RTE cells in vitro only made mucin when grown on porous supports in the presence of RA, whereas SPOC1 cells produced mucin when grown on plastic or glass surfaces and even in the absence of RA. Interestingly, RA enhanced mucin secretion by SPOC1 cells during the early plateau stage of culture but there were no differences due to RA late in the culture period. SPOC1 cells are capable of mucin production and will be a useful tool for studying select aspects of airway secretory cell differentiation and function.