Effects of cocultivation with transformed cells on surface proteins of normal cells.

Virally transformed fibroblasts do not have on their surface a major protein (large external transformation-sensitive, LETS) which is present in normal cells. Cocultivation of the transformed cells with normal cells whose surface proteins have been prelabelled induces an accelerated release of the LETS protein from the normal cells. We have investigated various conditions which affect this phenomenon. Our results show that alteration of cell surface proteins by cocultivation with the transformed cells is time and dose-dependent and requires cell contact. Serum was depleted at least 99% of plasminogen by affinity chromatography and used in the cocultivation experiments. It was found that activation of plasminogen was not required for the accelerated turnover of the LETS protein. Other diffusible proteases are also unlikely to be involved. The possibility that transformed cells have a membrane bound activity is discussed. The role of plasminogen activation was also tested for its relevance in transformation related proteolysis, growth and morphology of cells.     

Restoration of normal morphology, adhesion and cytoskeleton in transformed cells by addition of a transformation-sensitive surface protein.

Transformed cells lack a large, external, transformation-sensitive (LETS) glycoprotein which is a major surface component of their normal counterparts. Addition of LETS glycoprotein isolated from normal cells to transfomed cells restores certain morphological features and adhesive properties characteristic of normal cells. LETS protein is detected on the cell surface both by iodination using lactoperoxidase and by immunofluorescent staining. The surface distribution pattern detected by immunofluorescence is strikingly similar to that of normal cells. After addition of LETS protein, transformed cells also exhibit well defined actin cables which are not seen in untreated, transformed cells. All these alterations can be blocked by treating LETS protein with specific antisera or by subjecting it to mild trypsinization prior to addition to transformed cells. The effects are rapidly reversible by mild trypsinization, which removes the added LETS protein. The high rate of uptake of 2-deoxyglucose, characteristic of transformed cells, is not affected by LETS protein. These results suggest that LETS protein may have a role in cell attachment and spreading, and affect the organization of cytoskeleton.     

Investigations of the possible role of proteases in altering surface proteins of virally transformed hamster fibroblasts

Virally transformed fibroblasts have on their surfaces zero or reduced amounts of a large external transformation-sensitive (LETS) glycoprotein. This protein is extremely sensitive to proteolysis. When prelabeled normal fibroblasts are cocultivated with transformed cells, the LETS glycoprotein of the normal cells shows an increased rate of turnover. Experiments are described which investigate the possibility that this phenomenon and the absence of LETS glycoprotein are due to proteolysis by the transformed cells. In particular, the role of plasminogen activation is examined by the use of protease inhibitors and plasminogen-depleted serum. It is concluded that activation of plasminogen is not required for the disappearance of the LETS glycoprotein although the involvement of other proteases cannot be ruled out. The role of proteases in affecting cell growth and behavior is discussed.     

Cell surface and metabolic labelling of the proteins of normal and transformed chicken cells.

We have studied the surface proteins of normal and transformed chick cells using four-labelling techniques with different specificities, (a) lactoperoxidase catalysed iodination (b) galactose oxidase/B3H4 (c) pyridoxal phosphate/B3H4 and (d) periodate/B3H4. All methods labelled a large external transformation-sensitive (LETS) protein, in agreement with previous studies. In addition, using galactose oxidase and periodate labelling techniques, we present evidence which suggests that the transformed cell surface glycoproteins are more sialylated. The LETS protein was also labelled with (14C) glucosamine and after trypsinization a small band of identical molecular weight to LETS remained, possibly representing an internal pool of the protein. In contrast LETS protein labelled with (3H) fucose was completely removed by trypsin, suggesting that the internal pool of the protein is incompletely glycosylated. Evidence is also presented to show that although the level of the protein is drastically reduced at the transformed cell surface, it is still synthesised and shed into the medium.     

Cell surface and metabolic labelling of the proteins of normal and transformed chicken cells

We have studied the surface proteins of normal and transformed chick cells using four-labelling techniques with different specificities, (a) lactoperoxidase catalysed iodination (b) galactose oxidase/B³H₄ (c) pyridoxal phosphate/B³H₄ and (d) periodate/B³H₄. All methods labelled a large external transformation-sensitive (LETS) protein, in agreement with previous studies. In addition, using galactose oxidase and periodate labelling techniques, we present evidence which suggests that the transformed cell surface glycoproteins are more sialylated.The LETS protein was also labelled with [¹⁴C]glucosamine and after trypsinization a small band of identical molecular weight to LETS remained, possibly representing an internal pool of the protein. In contrast LETS protein labelled with [³H]fucose was completely removed by trypsin, suggesting that the internal pool of the protein is incompletely glycosylated. Evidence is also presented to show that although the level of the protein is drastically reduced at the transformed cell surface, it is still synthesised and shed into the medium.     

A comparison of membrane components of normal and transformed BALB/c cells.

Membrane glycolipids, glycoproteins, and surface proteins of normal and transformed BALB/c cell lines have been compared. Several virally and spontaneously transformed cell lines showed differences in membrane components compared to normal A31 cells. These differences consisted of increased amounts of simpler gangliosides, absence of the large external transformation sensitive (LETS) protein, and the appearance of a major new glycoprotein band of about 105 000 molecular weight. In contrast, the spontaneously transformed cell line that caused the fastest growing tumors in vivo and the most rapid animal death (3T12T) did not have these changes. A31 and 3T12T glycolipid profiles appear similar as did glycoproteins and cell surface proteins detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. When Pronase-generated glycopeptides were analyzed by Sephadex G-50 chromatography, and enrichment in faster-eluting species was seen in two killing tumor lines (c5T and 3T12T) compared to A31. Regressing tumor lines (MSC, c5) did not show this change. Isolated membrane glycoproteins yield glycopeptides of different sized after Pronase digestion. In addition, several 3T12T glycoproteins yield glycopeptides that are larger than those from the corresponding glycoproteins of A31 cells. It appears that glycopeptide alterations associated with transformation occur in several membrane glycoproteins.     

Lack of correlation between the decreased expression of cell surface LETS protein and tumorigenicity in human cell hybrids

An analysis of the correlation between tumorigenicity and the loss of expression of the large external transformation-sensitive glycoprotein (LETS) was performed on human cell hybrids and their respective normal and tumorigenic parental cell lines. The distribution of cell surface LETS protein in a series of cell lines was examined by both specific immunofluorescent staining and by gel electrophoresis of lactoperoxidase-catalyzed, iodinated cell surface proteins. The tumorigenicity of these cell lines was assayed in nude mice. Although the series of cell lines studied provided a broad spectrum of LETS protein expression, both quantitatively and qualitatively, there does not appear to be a correlation between tumorigenicity and decreased expression of the LETS protein.In a series of transformed, nontumorigenic hybrids, the LETS protein expression was found to be altered with respect to both decreased organizational complexity and decreased content. These hybrids continue to express a number of other transformed phenotypes. Conversely, a number of tumorigenic hybrids continue to express relatively high levels of LETS protein when compared with nontumorigenic hybrids. Thus an alteration in LETS protein expression by itself, or in concert with a spectrum of other transformation properties, does not appear to be a sufficient requirement for tumorigenicity and lends further support to an apparent separate control of the transformed versus tumorigenic phenotype.     

Glucose-regulated membrane properties of untransformed and virus-transformed BHK21 cells.

BHK21 fibroblasts transformed by hamster sarcoma virus have a higher rate of uptake of hexoses than their untransformed counterparts, and therefore rapidly exhaust glucose from the culture medium. The effects of culturing normal and transformed BHK cells, both in limiting and in excess glucose, on several membrane properties related to malignant transformation have been studied. The increase in the rate of hexose uptake in transformed cells is partially but not entirely dependent on extracellular glucose concentration. Two transformation-increased membrane proteins of molecular weights 95 000 and 78 000 are shown to be regulated by extracellular glucose concentration in both normal and transformed cells. The loss of LETS-protein, the high density of intramembranous particles, the increase in the amount of a 177K integral plasma membrane protein and the increase in the amount of high molecular weight surface glycopeptides in transformed cells, are not related to glucose depletion of the medium. Beside LETS, another iodinated protein, of molecular weight 160 000, is decreased in transformed cells. The exposure of this protein increased in both normal and transformed cells when arrested in G1 by asparagine deprivation.     

Distribution of cell surface lets protein in co-cultures of normal and transformed cells

When LETS protein positive and negative cells were co-cultured, the positive cells remained as positive and the negative cells remained as negative. Apparently the transformed cells do not secrete factors which are sufficient to influence the distribution of surface LETS protein on normal cells.     

Cell surface protein decreases microvilli and ruffles on transformed mouse and chick cells.

Transformation of cultured fibroblasts usually results in a decrease in a high molecular weight cell surface glycoprotein (LETS protein) and often in increased numbers of surface microvilli and ruffles. We have isolated such a major cell surface glycoprotein from chick embryo fibroblasts; this protein, CSP, is decreased after transformation. Treatment of a mouse tumor cell line (SV1), L929 cells, and transformed chick fibroblasts with CSP results in a decrease in the number of microvilli and marginal ruffles, accompanied by restoration of a more normal morphology.     

Quantitation of a transformation-sensitive, adhesive cell surface glycoprotein. Decrease of several untransformed permanent cell lines

We have quantitated the transformation-sensitive, cell surface LETS glycoprotein on many untransformed cell types. By SDS-polyacrylamide gel electrophoresis, this trypsin-sensitive iodinatable glycoprotein comprises 1-3% of total cellular protein of the seven early passage cell types tested. In contrast, it constitutes less than 0.15% of the protein in four of six continuous cell lines. This decrease is reflected in alterations both in [14C]glucosamine labeling and in the immunofluorescent staining of early passage vs. these four permanent cell lines. These results help to clarify previous experiments in which CSP, a purified LETS protein, partially restored a fibroblastic phenotype to cells transformed by tumor viruses. These findings also indicate that a major decrease in this cell surface glycoprotein can occur in the establishment of a continuous cell line without resulting in cellular transformation.     

Surface distribution of LETS protein in relation to the cytoskeleton of normal and transformed cells

The organization of LETS protein on the surface of NIL8 hamster cells has been examined by immunofluorescence staining. The distribution of LETS protein was found to depend on the culture conditions; in subconfluent, low-serum arrested cultures the LETS protein is predominantly located at the cell-substrate interface and also in regions of cell-cell contact, whereas in dense cultures the cells are surrounded by a network of LETS protein fibrils. Transformed derivatives of these cells exhibit only sporadic staining for LETS protein, in the form of short intercellular bridges. Agents that cause alterations in cell shape and cytoplasmic filaments have been used to explore the relationship of LETS protein to the internal cytoskeletal elements. Reciprocally, perturbations of the cell surface were examined for their effects on internal filaments. The arrangement of microtubules seems to be unrelated to the presence of LETS protein in the cells studied. Actin microfilament bundles and LETS protein respond in a coordinate fashion to some perturbants but independently with respect to others. The patterns of staining for LETS protein are consistent with an involvement in cell-to-cell and cell-to-substrate adhesion.     

Leukemia virus infection of mammalian cells: effect on two "transformation-associated" surface properties.

We demonstrated that the productive infection of three different mammalian cell lines with two separate leukemia viruses is sufficient to induce a change in surface architecture that may be detected as enhanced agglutinability with two different plant lectins. Subsequent transformation of one of these cell lines with a chemical carcinogen did not further modify the agglutinability of the cell lines. Using a polyoma virus-transformed derivative of one of the parental lines, we have demonstrated that the LETS protein (whose absence from the surface membrane has been considered a marker of the transformed phenotype) may be present in cells displaying the capacity to plate in soft agar.     

Effects of LETS glycoprotein on cell motility

Addition of LETS glycoprotein to normal or transformed cells produces increased migration of the cells, as determined by formation of phagokinetic tracks on gold particle-coated coverslips. These tracks arise by a combination of phagocytosis of the gold particles and cellular migration. Increased motility is also evident on plastic in the absence of gold particles. The added LETS protein attaches to the cells in a fibrillar network, and binding is greater to normal than to transformed cells. The effects of LETS protein on migration are consistent with its effects on cell adhesion, morphology and cytoskeleton, and have potential implications for the determination of cellular migration in vivo.     

Electrophoretic analysis of substrate-attached proteins from normal and virus-transformed cells.

The proteins which have been left tightly bound to the tissue culture substrate after ethylenebis (oxyethyl-enenitrilo) tetraacetic acid (EGTA)-mediated removal of normal, virus-transformed, and revertant mouse cells and which have been implicated in the substrate adhesion process have been analyzed by slab sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Three size classes of hyaluronate proteoglycans were resolved in the 5% well gel; approximately half of the protein in the substrate-attached material coelectrophoresed with these polysaccharides-so-called glycosaminoglycan-associated protein(GAP). A portion of the GAP was shown to be highly heterogeneous and displaced from the polysaccharide by preincubation with calf histone before electrophoresis. The relative proportions of the proteoglycans varied in material deposited during a variety of cellular attachment and growth conditions. The remainder of the cellular protein in substrate-attached material was resolved as several major and distinct protein bands in 8 or 20% separating gels (a limited number of distinct serum proteins have also been identified as substrate bound). Protein C0 (molecular weight 220 000) was a prominent component in the material from a variety of normal and virus-transformed cells and resembled the so-called LETS or CSP glycoprotein in several respects; protein Ca was myosin-like in several respects; protein C2 was shown to be actin; and protein C1 (molecular weight 56 000) does not appear to be tubulin. Histones were also present in most preparations of substrate-attached material, particularly at high levels in transformed cell meterial, and may result from EGTA-mediated leakiness of the cell and subsequent binding to the negatively charged polysaccharide. These substrate-attached proteins were (a) prominent in substrate-attached material from many cell types in characteristic relative proportions, (b) deposited by EGTA-subcultured cells during the first hour of attachment to fresh substrate, (c) deposited by cells growing on plastic or glass substrates (three additional) components were also prominent in glass-attached material), and (d) deposited during long-term growth on or initial attachment to substrates coated wit 3T3 substrate-attached material. Pulse-chase analyses with radioactive leucine indicated that these proteins exhibit different turn-over behaviors. These results are discussed with regard to the possible involvement of these substrate-attached proteins in the substrate adhesion process, with particular interest in the interaction of cytoskeletal microfilaments with other surface membrane components and with regard to alteration of substrate adhesion by virus transformation.     

Multilayering and loss of apical polarity in MDCK cells transformed with viral K-ras

The effects of viral Kirsten ras oncogene expression on the polarized phenotype of MDCK cells were investigated. Stable transformed MDCK cell lines expressing the v-K-ras oncogene were generated via infection with a helper-independent retroviral vector construct. When grown on plastic substrata, transformed cells formed continuous monolayers with epithelial-like morphology. However, on permeable filter supports where normal cells form highly polarized monolayers, transformed MDCK cells detached from the substratum and developed multilayers. Morphological analysis of the multilayers revealed that oncogene expression perturbed the polarized organization of MDCK cells such that the transformed cells lacked an apical--basal axis around which the cytoplasm is normally organized. Evidence for selective disruption of apical membrane polarity was provided by immunolocalization of membrane proteins; a normally apical 114-kD protein was randomly distributed on the cell surface in the transformed cell line, whereas normally basolateral proteins remained exclusively localized to areas of cell contact and did not appear on the free cell surface. The discrete distribution of the tight junction-associated ZO-1 protein as well as transepithelial resistance and flux measurements suggested that tight junctions were also assembled. These findings indicate that v-K-ras transformation alters cell-substratum and cell-cell interactions in MDCK cells. Furthermore, v-K-ras expression perturbs apical polarization but does not interfere with the development of a basolateral domain, suggesting that apical and basolateral polarity in epithelial cells may be regulated independently.     

Decreased adherence to the substrate in Rous sarcoma virus-transformed chicken embryo fibroblasts.

Cell-substrate adherence in cultures of chicken embryo fibroblasts was examined by determining the number of cells which could be detached from the culture dish by a stream of medium. Transformed cells were significantly less adherent than their normal counterparts. In cultures infected with a mutant of Rous sarcoma virus which is temperature-conditional for transformation, adherence changed promptly following a temperature shift. This change did not require progression through the cell cycle. The transformation-specific decrease in adherence required new protein synthesis, but the restoration of adherence which occurred following a shift to the restrictive temperature could occur in the absence of new protein synthesis. Inhibitor experiments suggested the importance of microfilaments and perhaps microtubules in the changes in detachability. In addition, there was a positive correlation between levels of surface LETS protein and cell substrate adherence following a temperature shift, although it seems probable that the bulk of the surface LETS is neither necessary nor sufficient for maintenance of normal cell substrate adherence.     

Role of disulfide bonds in the attachment and function of large, external, transformation-sensitive glycoprotein at the cell surface

Reduction of disulfide linkages by dithiothreitol removes LETS (large, external, transformation-sensitive) protein from the cell surface. This process is dependent upon the concentration of dithiothreitol and the time and temperature of reaction. At 0 degrees C the release of LETS protein by dithiothreitol is completely blocked, but this is apparently not due to a requirement for metabolic energy. At this temperature, reduction of LETS protein is incomplete. These results suggest that intact disulfide bonds are involved in the retention of this protein on the cell surface. Furthermore, reduction of purified LETS protein interferes with its ability to confer flattened morphology and increased adhesivity when added to transformed cells. It appears, therefore, that disulfide bonds are functionally important at the cell surface.     

Transformation parameters in chicken fibroblasts transformed by AEV and MC29 avian leukemia viruses.

Infection of chicken fibroblasts with avian erythroblastosis virus (AEV) strain ES4 or with avian myelocytomatosis virus strain MC29 leads to a rapid morphological transformation of most cells. AEV-transformed fibroblasts are similar to Rous sarcoma virus (RSV)-transformed fibroblasts in that they exhibit microvilli at their surface, show a disappearance of actin cables, are agglutinable by lectins, and show a decrease in LETS protein and an increase in the rate of hexose uptake. They also elicit slightly increased levels of cell-associated proteolytic activity, but show no increase in the fibrinolytic activity of the harvest fluids. In addition, as shown previously, they are capable of anchorage-independent growth and of sarcoma induction.In contrast, MC29-transformed fibroblasts express a different pattern of transformation parameters. They are similar to both RSV- and AEV-transformed fibroblasts in that they are morphologically transformed, show a disappearance of actin cables and are agglutinable by lectins. They also elicit surface alterations which consist of bleb-like protrusions rather than of microvilli, and are capable of anchorage-independent growth. They are strikingly different from RSV- and AEV-transformed cells, however, in that they express normal levels of LETS protein and elicit no increase in the rate of hexose uptake or in proteolytic activity. They are not sarcomagenic although they show an accelerated growth rate in culture.In conjunction with the finding that MC29 and AEV do not contain sequences related to the fibroblast-transforming src gene of RSV, these results raise the possibility that MC29 and perhaps also AEV transform fibroblasts by a mechanism different from RSV.     

Complementation between urokinase-producing and receptor-producing cells in extracellular matrix degradation.

The respective roles of urokinase plasminogen activator (u-PA) and the u-PA receptor in extracellular matrix degradation was investigated. Human pro-u-PA and the human u-PA receptor were expressed independently by two different mouse LB6 cell lines. The matrix degradation capacity of these cell lines individually or in coculture was studied. Although pro-u-PA-producing cells alone degrade the matrix in the presence of plasminogen, u-PA-receptor producing cells do not. Cocultivation of a small fraction of pro-u-PA-producing cells with the receptor-producing cells increases the rate of matrix degradation at least threefold. By immunoprecipitation it was shown that cocultivation of the two cell lines increases the conversion of the inactive pro-u-PA to the active two chain u-PA. The enhancement of matrix degradation and of pro-u-PA activation requires actual binding of pro-u-PA to its receptor because it is inhibited by u-PA-receptor antagonists. The u-PA receptor must be cell associated, as binding of pro-u-PA to a receptor solubilized from the cell surface with phosphatidyl-inositol specific phospholipase C did not enhance the activation of pro-u-PA in the presence of plasminogen. The finding that activity of u-PA is enhanced when it is bound to its receptor, even when the receptor is produced by a different cell, might have important implications for the mechanisms of u-PA-induced extracellular proteolysis in vivo.