Cell growth, cell division and cell size homeostasis in Swiss 3T3 cells

By separating large and small 3T3 cells we show here that cell growth (in volume) after stimulation from quiescence is not 'autocatalytic'. Rather, large cells grow significantly more slowly, in relative terms, than small cells. It follows that 3T3 cells do not require a size control mechanism operating at the level of division timing in order to achieve cell size homeostasis.     

Cell surface and cell division

A mathematical model of the regulation of cell division is suggested. The model is based on the hypothesis that the process giving rhythm to cell division is located in the cell membrane: i.e., the process of free-radical oxidation of membrane lipids. Much depends on the physical state of the membrane. In the membrane, phase transitions take place because of the changes in lipid composition. These transitions differ in normal and tumor cells: in normal cells they are sharp and hysteretic owing to the presence of a framework (membrane skeleton) on the surface of the membrane, while in tumor cells the integrity of the surface is violated so that the transitions are smooth. This model makes it possible to explain differences in the regulation of normal and cancer cell proliferation. Within the limits of the model, such phenomena as density dependent inhibition of growth, reverse transformation, influence of cyclic AMP and ions of Ca2+ on the cell cycle, the actions of serum and of proteases on the cycle, and so on, are explained. A rational scheme for the appearance of the selective damage found in tumor cells is proposed.     

Cell surface glycolipids of transformed NIH 3T3 cells transfected with DNAs of human bladder and lung carcinomas.

Neutral glycolipids and gangliosides of NIH 3T3 cells oncogenically transformed by transfection of DNAs from human lung carcinoma (Lx-1) and human bladder carcinoma (Ej) have been investigated. The chemical quantity and the degree of cell surface exposure of gangliotriaosylceramide (Gg3) were greatly enhanced in NIH 3T3 cells transformed by transfection of DNAs of either Lx-1 or Ej carcinoma cells. An identical but more conspicuous change in cell surface exposure of Gg3 was observed in BALB/c 3T3 cells transformed by murine sarcoma virus Kirsten strain, but the same glycolipid was absent in the original Lx-1 or Ej human carcinomas. The mechanism that defines the chemical quantity and the organization of glycolipids is controlled by multiple factors. These include not only the quantity but also the organization of glycosyl transferases and hydrolases in membranes. This also involves membrane dynamics regulated through a cytoskeletal-membrane conjunction which may determine the degree of glycolipid exposure at the cell surface. The similarity of the chemical and organizational change of a single glycolipid, Gg3, between 3T3 transformants by Kirsten murine sarcoma virus and those by transfection of human cancer DNAs may indicate a common biochemical basis triggered by activation of the oncogene.     

Cell cycle dependent modulations of the surface membrane of normal and SV40 virus transformed 3T3 cells

Agglutinability with Concanavalin was studied as function of cell cycle transition in normal and SV40 virus transformed 3T3 cells. In synchronized cultures of normal cells, agglutinbility was high during mitosis and disappeared rapidly. Agglutinability of transformed cells remained high in G₁ phase but diminished gradually upon entering S phase and reached minimum in G₁ phase. Decreased agglutinability a the end of the cell cycle was also observed in synchronous SV3T3 cultures by a combined technique of haemadsorption and density gradient centrifugation. In normal 3T3 cells, similar variations in agglutin ability during interphase could not be observed.     

Population density and regulation of cell division in 3T3 cells. I. Inorganic phosphate levels, uptake and release.

Triggering mechanisms for initiating density dependent inhibition of cell division in 3T3 cell monolayers are activated approximately two to three population doublings prior to cessation of cell division at monolayer confluency. This activation occurs at a critical contact cell density of approximately 8 X 10(3) cells/cm2. During this period there are selective controls on transport and storage of required low molecular weight nutrients. A possible correlation between orthophosphate and rates of cell division has been investigated. We have demonstrated a relationship between cellular concentrations of orthophosphate and initiation of density dependent inhibition of cell division. Prior to critical intercellular contact, the [Pi] in 3T3 is 10 mM. During critical contact, this concentration is quickly reduced to approximately 2 mM and remains at this concentration to confluency. Similar alterations do not occur in Py 3T3 cells, which maintain a concentration of approximately 2 mM Pi regardless of cell density. After confluent 3T3 cells are released from inhibition of cell division the [Pi] must increase several-fold before DNA synthesis commences. These are physiological changes in 3T3 cellular [Pi] as a function of cell density, and cannot be attributed to nutrient depletion, altered transport of Pi into the cell, increased [ATP], or increased [PPi] levels. The controlled modulation of [Pi] may regulate glycolysis and coordinate counter-ion changes (Ca++) may regulate mitochondrial activity.     

Identification of a cell surface component of Swiss 3T3 cells associated with an inhibition of cell division

Polyclonal IgG, prepared to a purified bovine cell surface sialoglycopeptide (SGP) inhibitor of cell division, was used to identify an antigenically related molecule on the surface of Swiss 3T3 cells. SDS-PAGE and Western analyses showed that the anti-SGP antibody was monospecific and primarily recognized a 66-kDA protein of 3T3 cell membranes. Treatment of intact 3T3 cells or 3T3 cell membranes with either broad and phosphatidylinositol-specific phospholipase C enzymes suggested that the antigenic material most likely existed as an integral membrane molecule, or associated as a multimeric complex, and was not anchored at the cell surface by a phospholipid. The addition of anti-SGP IgG to 3T3 cell monolayer cultures was shown to promote cell division, suggesting a regulatory function for the membrane-associated molecule.     

Heparan sulfates of mouse cells. Analysis of parent and transformed 3T3 cell lines.

Heparan sulfate from the surface of a variety of mouse cells at different cell densities was examined by ion-exchange chromatography. The results of this analysis show that: (1) The heparan sulfate from new isolates of Swiss 3T3 cells transformed by SV40 virus (a DNA tumor virus) elutes from DEAE-cellulose at a lower ionic strength than that from the parent cell type. This finding confirms our earlier observation with an established SV40-transformed cell line (Underhill and Keller, '75) and eliminates the possibility that this change is caused by extended passage in culture. (2) For both parent and transformed 3T3 cells, the heparan sulfates from low and high density cultures were the same as judged by chromatography on DEAE-cellulose. This result demonstrates that the transformation-dependent change which we have observed is independent of cell density. (3) The heparan sulfate from Balb/c 3T3 cells transformed with Kirsten murine sarcoma virus (an RNA tumor virus) elutes from DEAE-cellulose prior to that from parent Balb/c 3T3 cells. This result extends the transformation dependent change in heparan sulfate to the Balb/c 3T3 cell line and to cells transformed with an RNA virus.     

Cationic ferritin binding sites and surface charge densities of transformed cells

Bioelectric surface properties of the high and low tumor-producing cell lines, NCTC 2472 and NCTC 2555, respectively, were determined by cationic ferritin binding and the electrophoretic mobility of intact cells. Measurements of anionic sites were bases on the number of cationic ferritin particles per 0.01 mu 2 that were electronically tagged and counted by an image analyzer. The average particle count was 45 for the control "high" cells and 34 for the control "low" cells. The surface charge densities, expressed as electrostatic units per cm-2 x 10(-13) were 2.34 and 1.18 at 50 V (2 mA) for the "high" and "low" control cells, respectively. Enzymic cleavage of sialic acid and other carbohydrate moieties resulted in up to an 81% reduction in the charge densities and a 57% reduction of the anionic sites of the "high" cells. The electrophoretic mobility of cells with bound cationic ferritin showed that up to 50% of the exposed anionic sites fail to bind cationic ferritin. Preliminary findings on the particle size/distribution by image analysis showed wide ranges in both particle size and interparticle distances that may limit cationic ferritin binding.     

Lys-tRNA4 levels and cell division in mouse 3T3 cells

tRNA₄^lys is an isoaccepting tRNA^lys which has been proposed as a necessary requirement for cell division in mammalian cells. We have measured the levels of this tRNA^lys during the growth cycle of mouse 3T3 fibroblasts. High levels of tRNA₄^lys were seen throughout exponential growth. However, a marked decrease in tRNA₄^lys occurred 24 h before the cells became confluent. This decrease was observed in three different 3T3 cell lines, but was not seen in a transformed 3T3 cell line. Trypsinization and replating of contact-inhibited cells returned tRNA₄^lys to the levels characteristic of exponential cells. Data from these and other cell lines show a direct relationship between the levels of tRNA₄^lys and the growth rate of cells in culture.     

Protein degradation in 3T3 cells and tumorigenic transformed 3T3 cells

To study the relation of overall rates of protein degradation in the control of cell growth, we determined if transformation of fibroblasts to tumorigenicity affected their rates of degradation of short- and long-lived proteins. Rates of protein degradation were measured in nontumorigenic mouse Balb/c 3T3 fibroblasts, and in tumorigenic 3T3 cells transformed by different agents. Growing 3T3 cells, and cells transformed with Moloney sarcoma virus (MA-3T3) or Rous sarcoma virus (RS-3T3), degraded short- and long-lived proteins at similar rates. Simian virus 40 (SV-3T3)- and benzo(a)pyrene (BP-3T3)-transformed cells had slightly lower rates of degradation of both short- and long-lived proteins. Reducing the serum concentration in the culture medium from 10% to 0.5%, immediately caused about a twofold increase in the rate of degradation of long-lived proteins in 3T3 cells. Transformed lines increased their rates of degradation of long-lived proteins only by different amounts upon serum deprivation, but none of them to the same extent as did 3T3. Greater differences in the degradation rates of proteins were seen among the transformed cells than between 3T3 cells and some transformed cells. Thus, there was no consistent change in any rate of protein degradation in 3T3 cells due to transformation to tumorigenicity.     

Cell adhesion and cell surface topography in aggregates of 3T3 and SV40-virus-transformed 3T3 cells. Visualization of interior cells by scanning electron microscopy

A technique for exposing the interior of aggregates of cultured cells has been developed and is described in this report. Using this technique, we have examined for the first time, by scanning electron microscopy, cell morphology and cell contact ultrastructure in the interior of aggregates of BALB/c 3T3 and SV40-transformed 3T3 cells. The 3T3 cells make initial intercellular contact by means of microvillar processes. Over a period of 3-8 h, some of these microvillar contacts are replaced by broader projections. In contrast, the SV40-transformed cells make initial intercellular contact by means of blebs or blunt projections which are also broadened and extended over a period of 3-8 h. For both 3T3 and SV40-3T3 cells, the surfaces of the cells which form the outer layer of the aggregate resemble the surfaces of single cells fixed in suspension, regardless of how long the aggregates have been cultured. Thse cells are covered with many cellular processes and are roughly hemispherical in profile. The surfaces of the internal cells of the aggregates, however, lose many of their cellular processes, develop smooth patches, and many become irregular in shape. This smooth morphology was also observed on the interior surfaces of the peripheral cell layer. From these observations we conclude that: (a) the stabilization of adhesive contacts is a slow process which takes at least 3-8 h; (b) the outer surfaces of peripheral cells differ significantly from the surfaces of interior cells; and (c) clear differences in surface topography exist between nonmalignant 3T3 cells and their malignant SV40 transformants.     

Cholera toxin stimulates division of 3T3 cells.

Cholera toxin was used in an attempt to inhibit epidermal growth factor stimulated 3T3 cell division. Instead, cholera toxin alone at low concentrations (10(-10) M), was able to stimulate cell division and could augment EGF stimulated cell division. The mitogenic effect of cholera toxin can occur despite a dramatic increase in the intracellular levels of cAMP in 3T3 cells. Cholera toxin stimulated mitogenesis could not be mimicked by choleragenoid, the binding but inactive subunit of cholera toxin, or by other agents which elevate cAMP levels in 3T3 cells.     

The high rate of aerobic glycolysis of transformed 3T3 cells persists after cell homogenization.

The high rate of lactic acid production by 3T3 cells which have been transformed by simian virus 40 or by polyoma virus as compared to confluent untransformed 3T3 cells persists after cell homogenization. This difference is also reflected by increased phosphofructokinase activity in the viral transformed cells. The findings imply that the increased aerobic glycolysis in the transformed cells results from changes in the glycolytic pathway rather than changes in sugar transport.     

Loss of density-dependent regulation of multiplication of BALB-3T3 cells chemically transformed in vitro

Balb/3T3 cells show density-dependent regulation of multiplication with the final cell density depending on serum concentration in the media. Chemically transformed Balb/3T3 cells (Balb/3T3-D) pile up on each other, multiply to a high cell density, but have decreased DNA synthesis at very high cell densities. Balb/3T3-D cells require less serum for multiplication compared with original Balb/3T3 cells. A rat serum fraction and a bovine β-globulin fraction stimulate the multiplication of Balb/3T3 cells but only slightly stimulate Balb/3T3-D cells indicating different serum factors stimulate growth of these two cell types. The multiplication properties of Balb/3T3-D cells are very similar to those of SV-40 transformed 3T3 cells, however, these properties were brought about by a single treatment by a chemical carcinogen, without an exogenous virus. The transformation altered the contact of cells to one another, indicating a permanent chemical change in the membrane structure.     

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.     

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.