Regulation of polyamine biosynthesis in normal and transformed hamster cells in culture

Several aspects of polyamine biosynthesis were compared in low-passage hamster embryo fibroblasts and transformed hamster fibroblasts. Earlier studies had demonstrated a larger and longer-lasting induction of ornithine decarboxylase activity in transformed cells than in hamster embryo fibroblasts. The increases in intracellular polyamine concentrations after serum stimulation were much greater in chemically transformed HE68BP cells than in normal hamster fibroblasts. Treatment of confluent cultures with the tumor promoter, 12-O-tetradecanoylphorbol-13-acetate, greatly potentiated ornithine decarboxylase induction by fresh medium in HE68BP cells, but not in hamster fibroblasts. A similar synergistic effect was observed when transformed cells, but not normal cells, were treated with the combination of insulin and promoter. HE68BP cells were capable of growth in medium containing serum concentrations as low as 0.5%, whereas only concentrations of 5% or more supported the growth of hamster embryo fibroblasts. Low serum concentrations induced ornithine decarboxylase in HE68BP cells but not in normal cells, and a given serum concentration always produced a greater induction of ornithine decarboxylase in transformed than in normal cells.Another enzyme involved in polyamine synthesis, $\text{S-}\text{adenosyl-}\text{L}\text{-methionine}$ decarboxylase was induced in normal and transformed cells by serum-containing medium or tetradecanoylphorbol acetate, but in contrast to ornithine decarboxylase, no synergistic effect was seen in transformed cells exposed to the combination of fresh medium and the tumor promoter. A macromolecular inhibitor of ornithine decarboxylase was readily detected in hamster fibroblast cultures treated with high concentrations of putrescine, but little or none of this inhibitor was found in HE68BP cultures. In both cell types, however, serum induction of ornithine decarboxylase was inhibited under conditions of excess putrescine.The results demonstrate several differences between normal and transformed hamster cells in the regulation of polyamine synthesis.     

Intercellular communication and tissue growth

Summary Epithelial cells of normal rat (adult) liver and hamster embryo in tissue culture communicate through membrane junctions: the membrane regions of cell contact are highly ion-permeable. Cancerous counterparts of these cells, cells from Morris' and Reuber's liver tumors and from x-ray-transformed embryo cultures, do not communicate under the same experimental conditions. These cells also fail to communicate with contiguous normal cells. Cancerous fibroblastic cells from a variety of tissues, including cells transformed by virus, x-radiation and chemicals, communicate as well as their normal counterparts; this is so for long- and short-term cell cultures. Communication in some fibroblastic cells is sensitive to components of blood serum: normal and transformed hamster embryo fibroblasts, which communicate when cultured in medium containing fetal calf serum, appear to lose communication in medium containing calf serum; the converse holds for hamster (adult) fibroblasts and 3T3 cells.The preceding papers of this series appeared in the Journal of Cell Biology.Trainee of the National Institutes of Health, National Cancer Institute, Grant CA 05011.     

Dynamics of the spreading of normal and transformed hamster cells]

Morphological peculiarities of spreading studied by scanning electron microscopy in two lines of transformed hamster fibroblasts (HETR and HEC--40) were compared to the normal hamster embryo fibroblasts (NHG). The surface of spherical not streading cells was of a mixed type microrelief (small blebs and microvilli). In transformed cells, the microvillous component was more developed than in their normal counterparts. During cell spreading distinct differences were observed between normal and transformed cells in their cell surface contact interaction with solid substratum. NHF cells formed a well-developed concentrically disposed thin lamelloplasm, while HEC-40 cells had asimmetrically disposed lamelloplasm in combination with long filopodia and HETR cells had a rather thick lamelloplasm consisting of several fragments (often forming star-like pattern). At the polarization stage of spreading neither HETR nor HEC-40 reached the same degree of spreading and flattening as NHF. Moreover, the dorsal surface of transformed cells had a complex microrelief in contrast to a rather smooth surface of NHF. These results are discussed in connection with earlier results on spreading of normal and transformed mouse fibroblasts.     

Elevation of a threonine phospholipid in polyoma virus transformed hamster embryo fibroblasts.

Analysis of the lipids of normal hamster embryo fibroblasts and polyoma virus transformed fibroblasts shows a decrease in phosphatidylcholine and phosphatidylethanolamine and a marked increase in a threonine phospholipid after transformation. Transformed cells also react differently with fluorodinitrobenzene and trinitrobenzenesulfonate. phosphatidylethanolamine of transformed cells reacts to a greater extent with both probes. Phosphatidylserine and the threonine phospholipid of both cells do not react with trinitrobenzenesulfonate. The threonine phospholipid is provisionally identified as phosphatidylthreonine.     

Transformed cells have lost control of ribosome number through their growth cycle.

Previous studies on the synthesis and function of the protein synthetic machinery through the growth cycle of normal cultured hamster embryo fibroblasts (HA) were extended here to a series of four different clonal lines of polyoma virus-transformed HA cells. Under our culture conditions, these transformed cells could enter a stationary phase characterized by no mitotic cells, very low rates of DNA synthesis, and arrest in a post-mitotic pre-DNA synthetic state. Cellular viability was initially high in stationary phase but, unlike normal cells, transformed cells slowly lost viability. The rate of protein synthesis in the stationary phase of the transformed cells fell to 25-30% of the exponential rate. Though this reduction was similar to that seen in normal cells, it was accomplished by different means. The specific reduction in the ribosome complement per cell to values below that of any cycling cell seen in normal cells, was not seen in any of the transformed lines. This observation, which implies a loss of normal control of ribisome synthesis through the growth cycle after transformation, was confirmed in normal Chinese hamster embryo fibroblasts and transformed CHO cell lines. Normal control of ribosome synthesis was restored in L-73 and LR-73, growth control revertants of one of the transformed CHO lines. The transformed lines reduced their protein synthetic rates in stationary phase either by a greater reduction in the proportion of functioning ribosomes than that seen in normal cells or by a decrease in the elongation rate of functioning ribosomes; the latter effect was not seen in the normal cells. A model for growth control of normal cells and its derangement in transformed cells is presented.     

Immunochemical purification of probe-labeled plasma membrane proteins: An approach to the molecular anatomy of the cell surface

The probe 2,4,6-trinitrobenzene sodium sulfonate may be used under appropriate conditions for selective labelling of plasma membrane proteins exposed at the outer cell surface. Labeled proteins, solubilized by detergents, can be purified by reverse immunoadsorption using antiprobe antibodies covalently linked to Sepharose 4B. This method has been applied to an investigation of the outer cell surface structure of chicken embryo and hamster fibroblasts. Coelectrophoresis in sodium dodecyl sulfate-polyacrylamide gels of probe-labeled membrane proteins purified from baby hamster kidney fibroblasts have shown that 7 major protein groups of different molecular weight are exposed on both control and Rous sarcoma or polyoma virus-transformed cells. Moreover, the transformed cells display a nonvirion component of 80–100 k daltons that is not labeled by the probe in normal cells. In fibroblasts transformed by a temperature sensitive Rous sarcoma virus mutant, that transforms at 37°C but not at 41°C, the expression of this component is related to the expression of the transformed phenotype.     

Phospholipid composition and turnover in normal and SV40 transformed fibroblasts. Effect of cell density]

The phospholipid composition and turnover in normal and in SV 40 transformed hamster fibroblasts were studied. The amount of phospholipid phosphorus relative to protein is lower in transformed hamster fibroblasts than in normal fibroblasts. This amount decreases with increasing cell density until stationary growth is reached. The decrease is largest for the normal fibroblasts. In transformed cells, less sphingomyelin and more diphosphatidyl glycerol are found than in normal cells. The turnover of 32P in sphingomyelin is slower in transformed cells than in normal cells ; the contrary is observed with diphosphatidyl glycerol. On the other hand, in transformed cells, phosphatidyl ethanolamine has a faster turnover than phosphatidyl choline, whereas the contrary is observed in normal cells. Finally, the change to stationary growth slows down the turnover of 32P of all phospholipids, this decrease being more important in transformed cells.     

Alkaline phosphodiesterase I and alkaline phosphatase I in plasma membranes of herpes simplex virus type 1 transformed hamster cells

Plasma membrane extracts from Herpes simplex virus type 1 transformed hamster embryo fibroblasts were chromatographed on Lens culinaris lectin coupled to Sepharose (LcH-Sepharose) and analysed by dodecyl sulphate polyacrylamide gel electrophoresis. Coomassie blue-staining revealed two major protein bands with apparent molecular weights of 125 000 and of about 75 000–90 000. In plasma membranes isolated from these tumor cells prior labeled with [³H]fucose or [³H]glucosamine these bands contained the highest amounts of incorporated radioactivity. Separation by LeH-Sepharose-affinity chromatography as well as metabolic labeling clearly demonstrates their glycoprotein character. The 125 000 protein coincides with alkaline phosphodiesterase I activity with a K_m of 6 · 10^?4 M for TMP p-nitrophenyl ester and is competitively inhibited by UDP-N-acetylglucosamine. This enzymatic activity is also present in normal hamster embryo fibroblasts. Gel electrophoresis of the Lens culinaris lectin-binding glycoproteins from plasma membranes of normal hamster embryo fibroblasts additionally revealed a strong alkaline phosphatase activity represented by an apparent molecular weight of 150 000, while HSV₁ hamster tumor cells contain only a very weak activity of this enzyme activity. HSV-lytically infected cells, however, have unchanged levels of alkaline phosphatase activity, whereas alkaline phosphodiesterase activity increases slightly.     

Increased phosphorylation of ribosomal protein S6 in hamster fibroblasts transformed by polyoma virus and simian virus 40

The extent of phosphorylation of ribosomal protein S6 was compared in normal hamster fibroblasts and in fibroblasts transformed by polyoma virus or simian virus 40. In both strains of transformed cells the protein was more highly phosphorylated than in the normal cells.     

Analysis of pp60c-src protein kinase activity in hamster embryo cells transformed by simian virus 40, human adenoviruses, and bovine papillomavirus 1.

We have examined the effect of DNA tumor virus transformation of primary hamster embryo cells on the tyrosyl kinase activity of pp60c-src. Our present study demonstrates that some clones of hamster embryo cells transformed by simian virus 40, adenovirus type 2, adenovirus type 12, or bovine papillomavirus 1 can possess elevated pp60c-src kinase activity when compared with normal hamster embryo cells. However, other clones of hamster embryo cells transformed by these same viruses were found to have normal levels of pp60c-src kinase activity. In those clones of transformed cells where pp60c-src kinase activity was elevated, the increased levels of kinase activity were the result of an apparent increase in the specific activity of the pp60c-src phosphotransferase rather than an increase in the amount of the src gene product. Additionally, pp60c-src was not found to be physically associated with tumor antigens known to be encoded by these viruses. These results indicate that elevated levels of pp60c-src kinase activity can be found in hamster embryo cells transformed by several different DNA tumor viruses and suggest that the molecular mechanism by which pp60c-src kinase activity is elevated may differ from that previously observed in polyomavirus-transformed cells. These results also imply that elevation of pp60c-src kinase activity is not required for the transformation of hamster cells by these viruses.     

Aggregation of normal and transformed cells attached to a substrate]

On the surface of the nirtocellulose membrane filter (pore size 0.3--0.5 mem), normal mouse or hamster embryo fibroblasts formed discrete cell aggregates. Behaviour of transformed fibroblast-like cells of 9 different lines was compared with that of normal cells. Cells of 3 transformed lines grew on this substratum as a uniform monolayer displaying no tendency to aggregation. The following 3 cell lines exposed a slightly "patchy" cell distribution on the 3rd--4th day of cultivation but were unable to form discrete aggregates. The remaining 3 lines did form aggregates but the dynamics of aggregation and the final aggregation pattern for two of them were abnormal. Only one of the 9 investigated transformed lines had the normal aggregation behaviour. Hence, in the course of the neoplastic evolution, cells lose their ability fo form aggregates on the filter surface. Mechanisms of cell aggregation and possible reasons of differencies in the aggregation behaviour between normal and transformed cells, are discussed.     

Solubilization of adenylate cyclase from normal and Rous sarcoma-transformed chicken embryo fibroblasts.

Adenylate cyclase activities in membranes prepared from Rous sarcoma-transformed chicken embryo fibroblasts are 2 to 4 times lower than in membranes prepared from normal chicken embryo fibroblasts. Adenylate cyclase activities were solubilized from normal and transformed membranes with five different nonionic detergents. In all cases, the specific activities of the enzyme solubilized from normal and transformed preparations were essentially identical. These data suggest that the microenvironment of adenylate cyclase in transformed membranes may be wholly or partially responsible for the decreased activities of this enzyme.     

Uncoupled expression of mRNAs for alpha 1(I) and alpha 2(I) procollagen chains in chemically transformed Syrian hamster fibroblasts

Syrian hamster embryo fibroblasts transformed by 4-nitroquinoline-1-oxide (NQT-SHE cells) failed to synthesize the pro-alpha 1(I) subunit of type I procollagen but continued to synthesize altered forms of the other subunit, pro-alpha 2(I) (Peterkofsky, B., and Prather, W. (1986) J. Biol. Chem. 261, 16818-16826). This was unusual, since synthesis of the two subunits generally is coordinately regulated. Present experiments using cell-free translation and hybridization of RNA from normal and transformed Syrian hamster fibroblasts with labeled pro-alpha 1(I) DNA probes show that mRNA for pro-alpha 1(I) is absent from the transformant. In contrast, dot-blot and Southern blot hybridizations of cellular DNAs with pro-alpha 1(I) DNA probes demonstrated that the transformed cells contained pro-alpha 1(I) gene sequences and that the gross structure of the gene was unchanged by transformation. mRNA for the other type I procollagen subunit, pro-alpha 2(I), was present in transformed cells and the major collagenous polypeptide translated from this RNA migrated like the normal pro-alpha 2 subunit during sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The translated procollagen chain was cleaved to an alpha 2(I)-sized collagen chain by pepsin at 4 degrees C. These studies provide a molecular basis for the observed collagen phenotype of NQT-SHE cells.     

Effect of microinjected amine and diamine oxidases on the ultrastructure of eukaryotic cultured cells

Diamine oxide and serum amine oxidase, which catalyse the oxidation of diamines and polyamines, respectively, were trapped within reconstituted Sendai virus envelopes. These loaded envelopes were incubated with cultured normal chick fibroblasts or with fibroblasts transformed by Rous sarcoma viruses. The binding of the reconstituted envelopes to the cultured cells was confirmed by scanning electron microscopy. It has been shown that the reconstituted envelopes (1-3 microns diameter) were attached to the eukaryotic cells. No significant changes in the morphology of the normal chick embryo fibroblasts were noted upon treatment with enzyme-loaded envelopes. On the other hand, chick embryo fibroblasts transformed by Rous sarcoma virus were affected by the microinjected amine oxidases. Scanning electron microscopy demonstrated the formation of holes in the microinjected cells. Similar morphological changes were also observed when diamine oxidase was microinjected into cultured glioma cells. These holes may be the result of the ejection of the nucleus. These findings are in line with the observed effect of the injected amine oxidases on macromolecular synthesis in normal and transformed chick embryo fibroblasts.     

Biosynthesis and secretion of collagen in normal and SV-40 virus-transformed human embryonal fibroblasts

The biosynthesis and secretion of collagen proteins was studied in cultures of normal human embryo fibroblasts at different passages and growth stages as well as in cultures of human embryo fibroblasts transformed by oncogenic virus SV-40. It was found that normal fibroblasts maintain at a constant level the collagen synthesis throughout 20 passages, which is typical of proliferating and resting cells. Virus-transformed cells produce 3-4 times less collagen proteins on a per cell count. Normal and transformed fibroblasts do not differ in terms of total protein synthesis. Secretion of collagen and non-collagen proteins in transformed cell cultures appeared to be much lower than in normal cell cultures. Study of synthesized proteins by polyacrylamide gel electrophoresis showed that both types of cells secrete collagen proteins predominantly as polymers containing interchain S-S bonds of 3-helix molecules. Study of the protein-synthesizing activity of two polysomal fractions, i.e. membrane bound and free polysomes, isolated from the cells of both types in a cell-free system showed that membrane-bound polysomes from transformed fibroblasts synthesize collagen much less actively in comparison with normal cells. However, in transformed cells free polysomes, in contrast with normal cells, are active participants of a cell-free collagen protein synthesis.     

Species-specific posttranscriptional regulation of interferon synthesis

Human fibroblast and Syrian hamster embryo cells were induced to synthesize interferon (IF) with rIn . rCn and rIn . rCn + DEAE-dextran, respectively. Following induction, these cells synthesized IF for only a short time before entering into a repressed state and shutting off the synthesis of IF. Homologous and heterologous whole cell translational systems were developed to investigate the molecular basis for the shut-off of IF synthesis. These systems allowedd for the introduction of exogenous hamster and human IF-mRNAs into intact normal and repressed hamster and human cells via an improved CaCl2 precipitation technique. Human IF-mRNA was translated in normal human and hamster cells and in repressed hamster cells but not in repressed human cells. In contrast, the hamster IF-mRNA was translated in normal human, normal hamster, and repressed human cells but not in repressed hamster cells. These results indicate that a species-specific mechanism inhibiting translation of IF-mRNA is directly responsible for the shut-off of IF synthesis in human fibroblasts and Syrian hamster embryo cells.     

A histochemical study of acid phosphatase in normal and virus-transformed cultured fibroblasts.

The distribution of acid phosphatase has been investigated in normal and virus-transformed cultured hamster and mouse fibroblasts. The enzyme was found to be present in lysosomes, autophagic vacuoles and elements of the Golgi apparatus. It was also found to be associated with a surface coat in some virus-transformed mouse cells and in the cytoplasm of both normal and transformed hamster cells.     

Pyrimidine nucleoside, pseudouridine, and modified nucleoside excretion by growing and resting fibroblasts.

We are examining the relationship of RNA metabolism and de novo pyrimidine synthesis as parameters of malignant transformation. These initial experiments on normal hamster embryo fibroblasts have shown that excreted nucleosides are markers for intracellular RNA metabolism. We employed affinity chromatography to concentrate the nucleosides in the medium and sensitive column chromatographic procedures to quantitatively measure them. The excretion of pyrimidine nucleoside from hamster embryo fibroblasts in sulture was found to be dependent on the growth state of the cells, with the greatest accumulation occurring cell quiescence. The major nucleoside excretion products, uridine and cytidine, were both normal end products of RNA metabolism and the major nucleoside excretion products from cultured cells. The modified nucleosides N-1-methylguanosine, N-2-methylguanosine, N-2-dimethylguanosine, N-4-acetylcytidine, N-1-methylinosine, pseudouridine, N-1-methyladenosine, N-3-methylcytidine, and 5-methyleycytidine were found, as were several unidentified nucleosides.     

Potassium fluxes and ouabain binding in growing,density-inhibited and rous sarcoma virus-transformed chicken embryo cells

Potassium fluxes, ouabain binding, and Na⁺ and K⁺ intracellular concentrations were determined for cultures of growing normal, density-inhibited and Rous sarcoma virus-transformed chicken embryo fibroblasts. No significant differences in K⁺ influx or ouabain binding were detected between growing normal cells and Rous sarcoma virus-transformed cells; however, ouabain binding and ouabain-sensitive K⁺ influx were 1.5- to 1.8-fold lower in density-inhibited cells. Thus, potassium influx in this system can be classified as a growth-related, but not transformation-specific change. As determined by both flame photometry and radioisotopic (⁴²K) equilibration, growing normal and density-inhibited cells had similar potassium contents, whereas transformed cells exhibited 1.4-fold higher potassium levels. Sodium ion levels, as measured by flame photometry, were also 2- to 4.5-fold higher in transformed than normal or density-inhibited cells. Complementary studies of potassium efflux showed a 1.3- to 1.5-fold higher rate (based on the percentage of pool exiting the cell) in growing normal versus density-inhibited or transformed fibroblasts. Because of the larger potassium pool in transformed cells, efflux based on absolute number of potassium ions is similar in normal and transformed chicken embryo fibroblasts.     

A comparison between adenylate cyclase solubilized from normal and Rous sarcoma virus-transformed chicken embryo fibroblasts

The specific activity of adenylate cyclase in membrane preparations obtained from Rous Sarcoma virus-transformed chicken embryo fibroblasts is two to four times lower than that found in untransformed membranes. Adenylate cyclase was solubilized from normal and transformed membranes in order to evaluate the influence of the membrane phase on the properties of the enzyme. Adenylate cyclase in normal and transformed membranes differed in specific activity, V for ATP, activation entropies, sensitivity to Ca2+, and stability at 37 degrees C. Solubilization with Brij 96 abolished or greatly reduced these differences. These data suggest that the differences between adenylate cyclase activities in normal and transformed chicken embryo fibroblasts are due either to differential modulation of enzyme activity by an effector which requires intact membranes for its effects, or indirect effects due to altered membrane properties.