Non-lytic, non-ionic detergent extractions of plasma membrane constituents from normal and transformed fibroblasts

A technique has been developed for the selective extraction of plasma membrane protein constituents from normal and transformed cells employing non-ionic detergents. The extraction procedure does not damage cells as judged by cell viability, ⁵¹Cr release, and trypan blue staining. Lactoperoxidase-catalyzed iodina- tion followed by detergent extraction permits demonstration of a 100 000 dalton protein which is found on the surface of normal but not transformed hamster and mouse fibroblasts.     

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.     

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.     

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.     

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 transformation 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.     

Lymphocyte-specific Ca2+-binding protein LSP1 is associated with the cytoplasmic face of the plasma membrane.

The gene for LSP1 is a lymphocyte-specific gene previously isolated by us using a subtractive hybridization technique. LSP1 mRNA is found in normal and transformed B lymphocytes and in normal T lymphocytes but not in transformed T lymphocytes. To study the expression of the mouse LSP1 protein, we prepared a polyclonal antiserum specific for the LSP1 protein. Here we report that the gene for LSP1 was expressed in transformed B-lymphoma cell lines and in normal mouse thymocytes as a protein doublet with apparent molecular masses of 52 and 50.5 kilodaltons when analyzed on a sodium dodecyl sulfate-10% polyacrylamide gel. BW5147 cells transfected with an LSP1 cDNA clone expressed only the 52-kilodalton protein. No LSP1 protein was expressed in nine T-lymphoma cell lines tested. Immunofluorescence studies of intact and permeabilized cells and subcellular fractionation experiments showed that the LSP1 protein was associated with the cytoplasmic side of the plasma membrane in transformed B-lymphoma cell lines and in normal thymocytes. Using a simple filter-binding assay, we showed that recombinant LSP1 protein was Ca2+ binding, as predicted on the basis of its deduced amino acid sequence. On the basis of the particular expression pattern, the subcellular localization, and the Ca2+-binding property of the LSP1 protein, we hypothesize that the LSP1 protein is a lymphocyte-specific component of a signal transduction pathway involved in the regulation of lymphocyte growth.     

Collagen synthesis in normal BHK cells and temperature-sensitive chemically transformed BHK cells.

Collagen synthesis in normal BHK 21/cl 13 and chemically transformed temperature sensitive BHK 21/cl 13 cells (Me2N4) was assessed by examination of hydroxyproline formation and collagenase-susceptible protein. The Me2N4 cells lost their ability to synthesize collagen at both permissive and nonpermissive temperatures for transformation. These conclusions were confirmed by polyacrylamide-gel eletrophoresis and CM-cellulose chromatography. Prolyl hydroxylase activity was present in both normal and transformed cells even when no collagen could be demonstrated. The production of noncollagen protein, although decreased in the transformed cell, did not change as drastically as the collagen synthesis.     

A new lymphocyte-specific gene which encodes a putative Ca2+-binding protein is not expressed in transformed T lymphocyte lines

The LSP1 gene is a new lymphocyte-specific gene which is expressed in normal mouse B and T lymphocytes and in transformed B cells but not (or in much smaller amounts) in nine T lymphoma lines tested. No LSP1 mRNA is found in myeloid cells or in liver, kidney, or heart tissue. Inspection of the predicted LSP1 protein sequence reveals the presence of two putative Ca2+-binding domains in the LSP1 protein. Southern blotting analysis of genomic DNA from mouse liver suggests that the LSP1 gene is present as one copy per haploid genome. Similar analysis of genomic DNA extracted from three transformed B cell lines and five transformed T cell lines shows that the absence of LSP1 mRNA in T cell lines is not due to deletion or gross rearrangements of the LSP1 locus. With the use of the mouse LSP1 cDNA as a probe we can detect a cross-hybridizing RNA species in four normal human functional T cell lines but not in three transformed human T cell lines. This suggests that at least part of the DNA sequence and the expression pattern of the LSP1 gene is conserved between mouse and man. These conserved features, together with the particular expression pattern and the protein sequence homologies, suggest that the LSP1 protein is involved in a Ca2+-dependent aspect of normal T cell growth.     

Vimentin-derived proteins : Differences between normal human fibroblasts and transformed human cells

Two-dimensional gel electrophoresis revealed a quantitative difference in a series of polypeptides ranging in MW from 45 000 to 51 000 and of lower isoelectric pH than vimentin, when comparing normal human fibroblasts with a virally transformed subline and with HeLa cells. Re-extraction of purified [³⁵S]vimentin with cold whole cell homogenates and peptide mapping showed that these polypeptides are derivatives of vimentin. They may be natural components of a normal fibroblast's architecture or they may arise from a pool of vimentin that is not structured within intermediate filaments at the time of extraction. Furthermore, we show that vimentin from the two transformed cell types is more resistant to proteolysis by whole cell homogenates than vimentin from normal fibroblasts. Structural alteration of vimentin may play an important role in the expression of transformation.     

Transformed mammalian cells secrete specific proteins and phosphoproteins.

We have examined the proteins secreted into the growth medium by normal and transformed cells. Transformed cell lines from several mammalian species all secrete proteins in the 58,000 dalton molecular weight range. These proteins are all immunologically related and are secreted at low levels or not at all by the parental normal cell lines. Secretion of the 58K proteins occurs with either DNA or RNA virus transformation and with spontaneous transformation. The transformed cells also secrete phosphoproteins in the same size range, but these are immunologically distinct from the 58K proteins mentioned above. The sizes of the phosphoproteins are species-specific and unrelated to the transforming virus. Incubation of conditioned media from transformed cell cultures with gamma-32P-ATP labels phosphoproteins of the same sizes, indicating the presence in the media of both protein kinase and substrate. All three properties (58K protein, phosphoprotein, in vitro phosphorylation) are closely correlated with transformation in cells transformed by temperature-sensitive viruses. The biological implications of these results remain unknown, but the results may be relevant to recent data on the (phospho)proteins and protein kinase encoded by RNA tumor viruses and the molecular basis of the transformed phenotype.     

Absence of fibronectin and presence of plasminogen activator in both normal and malignant human mammary epithelial cells in culture

Primary monolayer cultures of normal and malignant human mammary epithelial cells were tested for fibronectin by indirect immunofluorescence using antisera specific for fibronectin. This protein was not detectable on either the normal or malignant epithelial cells. Similar results were obtained for normal and malignant mouse mammary epithelial cell cultures. Control normal and transformed fibroblasts exhibited the expected result: the normal cells were positive and the transformed cells were negative. With the use of supernatant fluids from the same cultures or an agar-overlay assay on viable cells, high levels of plasminogen-dependent fibrinolytic activity were detectable in both the normal and malignant mammary cells. Thus, two characteristics that distinguish normal from transformed fibroblasts do not serve as markers of malignancy in mammary epithelial/carcinoma systems.     

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.     

Alteration of protein phosphorylation patterns in cell lines morphologically transformed by human cytomegalovirus

Human fibroblastic cell lines morphologically transformed by either live virus or DNA fragments of human cytomegalovirus had altered plasma membrane protein composition; quantitative changes, and gains and losses in protein composition in comparison to normal parent cell lines were detected. These transformed cell lines showed altered total cell protein phosphorylation patterns when compared to parent cell lines. A two to four fold increase in in vivo protein phosphorylation at serine and threonine residues was observed; no increase in phosphorylation at total cell tyrosine residues was detected. Analysis of the in vivo phosphorylated protein by two dimensional gel electrophoresis revealed some similarities as well as differences in the types of polypeptides phosphorylated between transformed and control cell lines. Increased (two-to sixfold over parent cell extracts) casein kinase and polyamine dependent casein kinase activities were detected in HCMV transformed cell extracts.     

Regulation of the microfilament system in normal and polyoma virus transformed cultured (BHK) cells

The content and state of actin in baby hamster kidney (BHK) cells before and after transformation with polyoma virus were examined by deoxyribonuclease assay and gel electrophoresis followed by dye elution. The actin content of the transformed cells, relative to total cell protein, was lower than that of the normal cells by 30-50%. In both the normal and transformed cells the greater part of the total actin was found on lysis to be in the monomeric state. Cytoplasmic and membrane fractions of the two cell lines were, in qualitative terms, very similar in their protein compositions. The plasma membrane isolated from the transformed cells was richer in actin than that from the untransformed, and both membrane fractions contained proteins corresponding to myosin, filamin and alpha-actinin on SDS-polyacrylamide gels. The cell extract from both the normal and transformed lines formed an actin-based gel on incubation at 30 degrees C, although the amount of the cross-linked actin was much smaller in the latter. This was a consequence not only of the lower concentration of total actin in the cell, but also, presumably, of a gross relative deficiency in the concentration or activity of filament cross-linking protein(s) in the cytoplasm. Thus, small aliquots of cytoplasmic fractions from transformed cells, when added to an excess of exogenous F-actin, were able to cross-link the filaments to a much smaller extent than those from the normal cells. A similar range of proteins was found to be associated with the actin gels formed from both cell extracts. One conspicuous difference was that a species migrating in SDS-gel electrophoresis as a doublet with a subunit molecular weight of about 58,000, and tentatively identified as intermediate filament protein, was replaced in the transformed cells by a single band. Filament cross-linking activity of the cytoplasmic fractions was enhanced by addition of Triton extracts of crude membranes, although the latter were not capable of cross-linking exogenous F-actin on their own. The effect of Triton extracts was much greater in the case of membranes from the transformed cells. The cytoplasmic fractions of BHK cells contain capping protein(s) and/or complexes of such proteins with actin; these reveal themselves by the propensity of the extracts to nucleate polymerization of exogenous G-actin. This activity was more abundant in transformed cells, despite their lower actin content. Their membranes were also more effective in nucleating G-actin polymerization, indicating the presence of a greater number of filament ends.(ABSTRACT TRUNCATED AT 400 WORDS)     

Kirsten murine sarcoma virus transformed cell lines and a spontaneously transformed rat cell-line produce transforming factors

We have examined culture fluids from a variety of Kirsten murine sarcoma virus (KiMSV) transformed rat and mouse cells for the presence of factors which induce normal Rat-1 cells to assume the transformed phenotype. All KiMSV transformants produced transforming factor (TF). Revertants of KiMSV transformed rat or mouse cells failed to relase TF as did normal rat or mouse cells. Cells transformed by a temperature sensitive mutant of KiMSV produced TF at the permissive temperature but not at the nonpermissive temperature. Further, cells from a spontaneous transformant of Rat-1 cells also produced TF. TF is a small polypeptide which competes for the epidermal growth factor receptor. Its effect upon normal cells is reversible and requires de novo RNA and protein synthesis. Cells treated with TF lose the actin fibers observed in normal fibroblasts, assume a transformed cell morphology, become anchorage independent for growth, grow in low concentrations of serum, grow to a high cell density, and have an increased rate of hexose uptake.     

Effects of novel maleimide derivatives on cell cultures with different properties

The paper is focused on pilot study of effects of novel synthetic protein kinase inhibitors—maleimide derivatives in different concentrations on normal, transformed and multipotent cell lines. Influence on cell proliferation and morphological characteristics has been demonstrated. The chosen agents cause antiproliferative effect on transformed cells and are not cytotoxic to normal cell lines. Moreover, different maleimide derivatives’ effects on multipotent cells in attached and floating states has been shown. Described results can be used for further research of the maleimide derivatives as antitumor agents.     

Altered protein kinase activities of lymphoid cells transformed by Abelson and Moloney leukemia viruses

Five different types of protein kinase activities have been evaluated in cell lines from murine lymphomas induced by Abelson leukemia virus (A-MuLV), whose oncogene codes for a tyrosine protein kinase. Such activities were compared with those of normal cells and of cells transformed by Moloney leukemia virus (M-MuLV), lacking oncogene sequences in its genome. While cAMP-dependent protein kinase and casein kinase-1 do not undergo significant changes, casein kinase-2 rises in both A-MuLV and M-MuLV infected lymphocytes, becoming largely associated with the particulate fraction of transformed cells. Protein kinase-C on the other hand is unchanged in M-MuLV transformed cells but it undergoes a 2-3-fold increment in both soluble and particulate fractions of A-MuLV transformed lymphocytes, which also display high tyrosine protein kinase activity.     

A calmodulin-dependent protein kinase in Rous sarcoma virus-transformed rat cells and normal liver

A calmodulin-dependent protein kinase has been purified extensively from a Rous sarcoma virus-transformed rat cell line (RR1022) and from normal rat liver. The calmodulin-dependent protein kinase activity was manifested by in vitro phosphorylation of a single Mr 57 000 endogenous phosphoprotein (pp57) present in both the virally transformed cells and normal rat liver. The calmodulin-dependent protein kinase from transformed cells fractionated with the viral src gene product, pp60v-src, through a 650-fold purification of the oncogene product. However, purification of the calmodulin-dependent protein kinase from normal liver demonstrated that the calmodulin-dependent kinase was distinct from pp60v-src. Phosphorylation of pp57 by the kinase purified from the transformed cell line required Ca2+ and calmodulin, was inhibited by EDTA and was unaffected by cAMP or the heat- and acid-stable protein inhibitor of cAMP-dependent protein kinase. Troponin C did not substitute for calmodulin. A virtually identical calmodulin-dependent protein kinase activity was purified from rat liver by affinity chromatography on calmodulin-Sepharose. Phosphorylation of pp57 by the affinity-purified liver protein kinase was also observed, and required Ca2+ and calmodulin. EGTA and trifluoroperazine inhibited pp57 phosphorylation. The calmodulin-dependent protein kinase reported here did not phosphorylate substrates of known calmodulin-dependent protein kinases in vitro (myosin light chain, phosphorylase b, glycogen synthase, microtubule-associated proteins, tubulin, alpha-casein). Because none of these proteins served as substrates in vitro and pp57 was the only endogenous substrate found, the properties of this enzyme appear to be different from any previously described calmodulin-dependent protein kinase.     

Synthesis of diacylglycerol de novo is responsible for permanent activation and down-regulation of protein kinase C in transformed cells

We measured the synthesis of diacylglycerol de novo in normal NIH/3T3 fibroblasts and in cells transformed by ras, src, sis and abl oncogenes. Analysis of the incorporation of glucose-derived 14C into diacylglycerol indicated that neosynthesis of diacylglycerol was constitutively active in the transformed cell lines. Elevated levels of diacylglycerol and persistent activation/down-regulation of protein kinase C reduced the binding of phorbol dibutyrate to transformed cells. This phenomenon could be reversed by blocking the glycolytic pathway, thus indicating that neosynthesized diacylglycerol was responsible for persistent activation and down-regulation of protein kinase C. In transformed cells, protein kinase C activity could not be stimulated by the addition of diolein; however, inhibition of glycolysis restored the ability of transformed cells to respond to diolein. Taken together these data indicate that constitutive synthesis of diacylglycerol de novo is responsible for activation and down-regulation of protein kinase C in transformed cells, and it may play a role in altered mitogenic signalling.