Dissociation of increased hexose transport from initiation of fibroblast proliferation

Activation and proliferation signals in murine macrophages: stimulation of glucose uptake by hemopoietic growth factors and other agents

Purified colony-stimulating factor (CSF-1) (or macrophage colony stimulating factor [M-CSF]) stimulated the glucose uptake of murine bone marrow-derived macrophages (BMM) and resident peritoneal macrophages (RPM) as measured by 3H-2-deoxyglucose (2-DOG) uptake. Similar concentrations of CSF-1 stimulated the 2-DOG uptake and DNA synthesis in BMM. Other purified hemopoietic growth factors, granulocyte-macrophage CSF (GM-CSF) and interleukin-3 (IL-3) (or multi-CSF), and the tumor promoter, 12-O-tetradecanoyl-phorbol-13-acetate (TPA), even though differing in their mitogenic capabilities on BMM, were also stimulators of 2-DOG uptake in BMM and RPM. The nonmitogenic agents, lipopolysaccharide (LPS) and concanavalin A (Con A), were also active. The inhibition by cytochalasin B and by high concentrations of D-glucose suggest that the basal and stimulated 2-DOG uptake occurred via a carrier-facilitated D-glucose transport system. The responses of the two macrophage populations to the hemopoietic growth factors and to the other agents were quite similar, suggesting that events that are important for the induction of DNA synthesis are not tightly coupled to the earlier rise in glucose uptake. For the BMM, the ability of a particular agent to stimulate glucose uptake did not parallel its ability to promote cell survival. However, stimulation of glucose uptake could still be a necessary but insufficient early macrophage response for cell survival and subsequent DNA synthesis.

Metabolic iteration, evolution and cognition in cellular proliferation

A model for cellular proliferation is described according to which proliferation ensues when metabolism evolves towards commitment to DNA synthesis, and inhibition of proliferation occurs when enzymic interactions are iterated within a few metabolic pathways, another limiting factor being the supply of metabolites. The model successfully describes cellular growth and division as a 'cognitive process' based on interaction within enzymic elements and the genome, and affords an explanation in these terms of some empirical phenomena which have previously been understood only as isolated observations.

Growth factor regulation of membrane transport in human fibroblasts and its relationship to stimulation of DNA synthesis

Serum stimulation of serum-deprived or density-inhibited normal cells enhances the level of various nutrient and ionic transport systems. Certain of these systems have been implicated in the regulation of cell proliferation. However, the use of serum stimulation to activate quiescent cells leads to enhancement of numerous transport systems with little understanding of which component or components of serum are related to activation of which transport systems. In this study we attempt to identify the specific effect of three known growth promoting factors (insulin, dexamethasone and epidermal growth factor [EGF]) on the activation of four membrane transport systems (A-amino acids, L-amino acids, glucose and K+) in normal and SV40-transformed WI38 human fibroblasts. We have also evaluated the effect of these growth factors on the stimulation of DNA synthesis in growth factor deprived cells. Thus, we can correlate the effect on a given transport system with the relative mitogenic stimulation produced by the growth factor. We conclude a) that a growth factor can effect a transport system differently in a normal versus transformed cell, b) that a specific growth factor can effect multiple transport systems and, c) with the exception of K+ transport, enhanced transport induced by a given growth factor does not necessarily correlate with the mitogenic potency of the growth factor. This latter point is of particular significance since the activation of K+ transport reflects, based on other studies, activation of the Na+-H+ exchanger which has been implicated in cell-cycle activation.

Analysis of the reduced growth factor dependency of simian virus 40-transformed 3T3 cells

We have measured in a defined serum-free medium the platelet-derived growth factor (PDGF) and insulin requirements of normal Swiss 3T3 cells, simian virus 40-transformed 3T3 cells, and partial revertants of simian virus 40-transformed 3T3 cells. Swiss 3T3 cells displayed strong requirements for both PDGF and insulin. Both of these requirements were significantly diminished in simian virus 40-transformed 3T3 cells. Analysis of the PDGF and insulin requirements of the revertants indicated that the loss of either of these two growth factor requirements was not necessarily linked to the other; rather, the growth factor requirements were specifically associated with other parameters of transformation. The reacquisition of a PDGF requirement cosegregated with reversion to density-dependent growth inhibition, whereas reacquisition of a normal insulin requirement cosegregated with reversion to a normal growth dependence on calf serum. Anchorage dependence was dissociable from both growth factor requirements. The relationship between the PDGF requirement and density-dependent growth inhibition was further analyzed in normal 3T3 cells by measuring the PDGF requirement at different cell densities. At high cell densities, the requirement for PDGF became significantly greater. We suggest that at least in part the ability of transformed cells to grow to high saturation densities results from their loss of a requirement for PDGF.

Analysis of the reduced growth factor dependency of simian virus 40-transformed 3T3 cells

We have measured in a defined serum-free medium the platelet-derived growth factor (PDGF) and insulin requirements of normal Swiss 3T3 cells, simian virus 40-transformed 3T3 cells, and partial revertants of simian virus 40-transformed 3T3 cells. Swiss 3T3 cells displayed strong requirements for both PDGF and insulin. Both of these requirements were significantly diminished in simian virus 40-transformed 3T3 cells. Analysis of the PDGF and insulin requirements of the revertants indicated that the loss of either of these two growth factor requirements was not necessarily linked to the other; rather, the growth factor requirements were specifically associated with other parameters of transformation. The reacquisition of a PDGF requirement cosegregated with reversion to density-dependent growth inhibition, whereas reacquisition of a normal insulin requirement cosegregated with reversion to a normal growth dependence on calf serum. Anchorage dependence was dissociable from both growth factor requirements. The relationship between the PDGF requirement and density-dependent growth inhibition was further analyzed in normal 3T3 cells by measuring the PDGF requirement at different cell densities. At high cell densities, the requirement for PDGF became significantly greater. We suggest that at least in part the ability of transformed cells to grow to high saturation densities results from their loss of a requirement for PDGF.

Demonstration of a late amiloride-sensitive event as a necessary step in initiation of DNA synthesis by thrombin

Amiloride, a Na+ influx inhibitor, has been shown to inhibit initiation of DNA synthesis by thrombin in mouse embryo fibroblast-like cells. Long exposures (24 hr) to high concentrations of amiloride inhibited incorporation of thymidine into the DNA of both thrombin-stimulated and nonstimulated cells, suggesting that this inhibition might not be specific for thrombin-initiated DNA synthesis. Fluorescence microscopy and spectrofluorimetry showed that amiloride was internalized with an apparent mitochondrial association and that the internalized amiloride was readily released from the cells after removing amiloride from the medium. Based on this reversibility, cells were exposed to amiloride for short periods of time during thrombin treatment to determine the temporal relationship between any amiloride-sensitive event(s) and initiation of DNA synthesis. The presence of amiloride (100 microM) during a 12-hr exposure to thrombin did not block thrombin-initiated DNA synthesis or cell division but did delay the onset of DNA synthesis and the peak of thymidine incorporation into DNA by approximately 3 hr, suggesting that early initiation events might proceed in the presence of amiloride. 86Rb+ transport studies demonstrated that in this system ouabain-sensitive K+ uptake via the Na, K-ATPase was stimulated by thrombin during both an early and a late period. This stimulation was amiloride-sensitive under the same conditions used for growth experiments, suggesting that amiloride was inhibiting thrombin-stimulated Na+ transport in this system. Additional experiments showed that exposing cells to amiloride only during the first 8 hr after thrombin addition did not inhibit initiation. The presence of amiloride from 8-12 hr after thrombin addition maximally inhibited thrombin-stimulated DNA synthesis. Together these results demonstrate that amiloride inhibits thrombin-initiated DNA synthesis not by inhibiting an early event occurring during the first 8 hr, but rather by inhibiting some later event 8-12 hr after thrombin addition.

Glucose uptake and ornithine decarboxylase activity in tetradecanoyl phorbol acetate non-proliferative variants

The potent tumor promoter 12-0-tetradecanoyl phorbol-13-acetate (TPA) is also an excellant mitogen for 3T3 cells. We have previously isolated two independent variants, 3T3-TNR-2 and 3T3-TNR-9, that are unable to divide in response to TPA (Butler-Gralla and Herschman, 1981). We have now tested two components of the pleiotypic response, elevation of 2-deoxyglucose uptake and ornithine decarboxylase induction, in these cells. Basal levels of 2-deoxyglucose uptake were nearly tenfold higher in confluent 3T3-TNR-2 and 3T3-TNR-9 cells than in 3T3 cells. In contrast, basal ornithine decarboxylase levels were five- to tenfold lower in the variants. TPA stimulation of 2-deoxyglucose uptake was as great in absolute terms in the variant cell lines as that of 3T3 cells but was only half that observed with serum. TPA was unable to induce any elevation of ornithine decarboxylase in 3T3-TNR-9 cells. Although an elevation of ornithine decarboxylase levels occurred in 3T3-TNR-2 cells treated with TPA, the maximal specific activity in the variant was less than the unstimulated value for 3T3 cells.

Effect of glucose uptake on growth rate of mouse 3T3 cells

The objective of this investigation was to determine whether the rate of glucose uptake by mouse 3T3 cells was a primary determinant of growth rate. The experimental approach was to control the rate of glucose uptake into intracellular pools by supplying this sugar at varying concentration in minimal Eagle's medium with dialyzed serum in the absence and presence of 6-deoxy-D-glucose, a metabolically inert homomorphic analog of D-glucose that competitively inhibits the uptake of D-glucose. Total hexose (D-glucose and 6-deoxy-D-glucose) concentration was maintained at the physiological concentration of 5.5 mM, in order to maintain saturation and maximum activity of the D-glucose transport system; thus the flux of D-glucose into the cell was controlled by adjusting its concentration relative to its competing nonmetabolizable analog. It was found that even when the concentration of D-glucose was reduced to 0.7 mM, one eighth of the "normal" level of 5.5 mM, and 6-deoxy-D-glucose was present in sevenfold excess (4.8 mM), conditions under which glucose uptake was reduced to 20% of that shown by cells in the presence of 5.5 mM D-glucose, and intracellular pools of glucose and phosphorylated sugars derived from glucose were reduced to approximately 14% of normal, there was not a significant decrease in growth rate. These data support the view that the rate of glucose uptake is not a primary determinant of growth rate under the usual conditions of cell culture.

Studies on the regeneration of the skin barrier and the changes in 32P incorporation into the epidermis after stripping

The epidermis of the rabbit ear was stripped and the effects on percutaneous absorption and 32P incorporation into lipid, TCA-soluble, RNA and DNA fractions in the epidermis was studied for 21 days. Skin penetration by 14C-propylene glycol increased 300-fold immediately after stripping twenty times. Three to five days after stripping, penetration had returned almost to normal levels, but it required several additional days for the barrier function to become normal. The process of regeneration of the skin barrier paralleled the morphological changes in the epidermis but was inconsistent with the biochemical data. A significant increase in 32P incorporation was observed at 10 days, when the hyperplasia had disappeared and percutaneous absorption had returned to normal. The discrepancy between 32P incorporation and morphology or percutaneous absorption after stripping is discussed.

Modulation of mammalian cell growth by a choline analog, N-isopropylethanolamine

The choline analog, N-isopropylethanolamine (IPE), inhibits the growth of both Chinese hamster ovary CHO-K1 and mouse L-M cells by two kinetically distinct mechanisms; I, a reversible and concentration-dependent reduction in the logarithmic population doubling rate and the saturation density of cultures by low IPE levels in the media; and II, an irreversible and time-dependent killing of cells by high IPE concentrations. Both types of inhibition are independent of media depletion, cell density, or the time of treatment after cell plating; however, the actual IPE concentration that is necessary to elicit Type I or Type II inhibition in each cell line is dependent on the choline level of the media. Ethanolamine, methionine, or betaine have no effect on IPE-induced growth inhibition. From a mutagenized population of CHO-K1 cells we isolated variant cell strains that are resistant to the lethal effect of IPE. It was determined that with both the wild type and variant strains the sensitivity of cells to growth inhibition by IPE (both Type I and Type II) was proportional to the degree by which choline uptake was inhibited by the analog. Retinoic acid, which inhibits the growth of some fibroblast and epithelial cell lines by a concentration-dependent reduction in population doubling rate and saturation density, behaves synergistically with IPE to inhibit the growth of CHO-K1 cells. Dibutyryl cyclic AMP, on the other hand, causes only an additive increase in the growth inhibition of CHO-K1 populations that also are treated with IPE.

Membrane transport properties differ following return of serum-deprived versus Ca++-deprived human fibroblasts to a proliferative state

Human lung fibroblasts (W138) can be brought to a quiescent state by removal of serum from the medium or by lowering of the extracellular Ca++. Upon return of Ca++ or serum, the cells enter the G1 phase and progress to S within 15-18 hours. Since multiple G1 phase blocks have been demonstrated, we wished to determine whether the Ca++ and serum block were equivalent since previous data suggested that these two medium components may act at a common point in the initiation of proliferation. We have evaluated the membrane transport of 86Rb, 3-O-methylglucose, AIB, and cycloleucine following stimulation of quiescent cells by Ca++ or serum. Serum stimulation results in large increases in the influx of all the substances tested. These increases are prevented if Ca++ is absent upon serum stimulation or they are rapidly diminished following Ca++ removal. In contrast, Ca++ stimulation of Ca++-deprived cells causes little or no enhancement of any of the transport system, yet the cells progress to S phase in a manner similar to serum-stimulated cells. These results indicate that the Ca++ and serum G0 and G1 block are not equivalent and that the serum-induced change in transport of these components does not appear necessary for successful G1 phase progression. Furthermore, the data suggest that the sequence in which Ca++ or serum are presented to the cells alters the ability of Ca++ to modulate the transport systems. Quiescent cells which are exposed to Ca++ prior to serum possess a Ca++ modulation of several transport systems. Cells which are exposed to Ca++ subsequent to serum do not appear to possess this Ca++ regulation.

D-glucose uptake in human liver cell cultures

The kinetics parameters for D-glucose uptake were studied in human liver cell cultures under strictly defined experimental conditions. Using a wide concentration range (0.005 to 30 mmol/l), the kinetic data obtained suggested strongly that D-glucose in human liver cell cultures can be transported by two separate systems. For the high-affinity system, the apparent Km was 0.645 +/- 0.21 mmol/l and the Vmax, 12.49 +/- 3.74 nmol/mg protein per min. For the low-affinity system, the apparent Km was 6.91 +/- 0.58 mmol/l and the Vmax, 79.90 +/- 5.27 nmol/mg protein per min. At a concentration of 2.1 x 10(-7) mol/l, cytochalasin B preferentially inhibited the high-affinity D-glucose site or transport system. The time course of D-glucose uptake, studied in two cell lines from patients with hereditary fructose intolerance, was significantly higher than for the control lines.

Hexose sugar transport activity in a mouse fibroblast cell line temperature sensitive for expression of the transformed phenotype

A temperature-sensitive mouse fibroblast cell line was used to examine the relationship between hexose sugar uptake rates and the control of cell growth. The cell line (ts-H6-15) is a derivative of SV-3T3 cells, exhibiting a transformed phenotype at 32 degrees C and a normal phenotype at 39 degrees C. For cells actively growing at either temperature, a marked decrease in the rate of 3-O-methyl-D-glucose (3-O-MeG) transport is observed as cell population density increases. At cell population densities tested, 3-O-MeG transport rates (at a common assay temperature) were greater in H6-15 cells grown at 32 degrees C than at 39 degrees C, with the enhancement being maximal at the lowest cell densities. The effect of low serum-arrest on H6-15 cells revealed that cells growing at 39 degrees C arrest in G1, while cells at 32 degrees C stop more randomly throughout their cycle. Under conditions of low serum-arrest the rate of 3-O-MeG transport remained as high as in actively growing cells at both 32 degrees C and 39 degrees C. However, 2-deoxyglucose uptake rates were growth state-dependent at 39 degrees C, indicating perhaps metabolic as well as membrane-level control of sugar accumulation. These results further demonstrate that rates of hexose sugar transport by themselves are not always absolutely correlated with rates of cell proliferation and, thus, may be reliable predictors of cell growth potential.

Amino acid and hexose transport by cultured crypt cells from rat small intestine

The characteristics of amino acid and sugar transport in intestinal crypt epithelial cells have been examined by measuring substrate uptake in an established epithelial cell line. These cells (IEC-6 cells) have been characterized as derived from rat small intestinal crypt cells on the basis of morphological criteria (J. Cell. Biol. 80: 248-265, 1979). Amino acid transport appeared to be mediated by both Na+-dependent and Na+-independent systems. Hexose uptake was stereospecific and Na+ independent, and was markedly inhibited by phloretin and cytochalasin B. Since glucocorticoids are known to have profound effects on maturation of the intestinal epithelium in vivo, their effects on transport properties of the cultured crypt cells were studied. Hydrocortisone, while completely inhibiting cell growth, increased the initial uptake rates of various hexoses, while having little or nor effect on the initial rate of amino acid uptake. The increased hexose uptake appeared to be due to a change in Vmax rather than Km. Appearance of the Na+-dependent hexose transport system, which is present in differentiated enterocytes, was not elicited by in vitro treatment with glucocortcoids.

Relationship between increased aerobic glycolysis and DNA synthesis initiation studied using glycolytic mutant fibroblasts

Reports from several laboratories have suggested increased rates of glycolysis play an essential part in the initiation of DNA synthesis. This is based on observations that aerobic glycolysis: (1) occurs at low rate in resting mammalian cells and at very high rate in tumour cells; (2) increases rapidly after DNA synthesis is initiated by addition of serum or purified growth factors, and (3) correlates with the expression of the transformed phenotype. Also, specific inhibitors of aerobic glycolysis prevent the initiation of DNA synthesis. To determine whether the rapid activation of phosphofructokinase--and therefore glycolysis--by purified growth factors is necessary for the initiation of cell proliferation, we have isolated and studied two classes of glycolytic mutants. The first, isolated from Chinese hamster fibroblasts, has a total block in the glycolytic pathway. The second, from hamster and Fisher rat fibroblasts maintains a permanent high rate of glycolysis. We have found that both classes of mutants retain normal control of DNA synthesis in response to serum. This dissociation indicates that growth-factor-stimulated glycolysis is not involved in the control of initiation of DNA synthesis and cell proliferation.

Isolation of a Chinese hamster fibroblast mutant defective in hexose transport and aerobic glycolysis: its use to dissect the malignant phenotype

A procedure is described for the selection of glucose uptake mutants based upon radiation suicide of Chinese hamster fibroblasts by 2-deoxy[3H]glucose. In one of these mutants, DS 7, the ability to transport either 2-deoxyglucose or 3-O-methylglucose was decreased to one-fifth to one-fourth. Besides this defect, DS7 produces 1/14th the lactic acid produced by the parent when grown on 5 mM glucose. This block in aerobic glycolysis is due to a mutation that affects the expression of the phosphoglucose isomerase gene because no isomerase activity is detected in cell extracts of DS7. This glycolytic block makes that cell line dependent exclusively on respiration for its energy requirement. Consequently, DS7 survives well after removal of glucose but dies quickly in the presence of oligomycin. The parental line O23 (subclone of CCl39) grows at low serum concentration, is anchorage-independent, and is tumorigenic in nude mice. The derived glycolytic mutant DS7 has retained both the in vitro transformed phenotype (low serum dependence and loss of anchorage dependence) and the tumor-forming capability. The tumor cells derived from the injection of DS7 cells have kept the original glycolytic defect. This finding suggests that the transformed properties (high hexose transport and aerobic glycolysis) that can be uncoupled from abnormal growth control are not necessary for the expression of the malignant phenotype in fibroblasts.

Cell cycle dependent rate of labelling of cellular and secreted glycosaminoglycans in mouse embryonic fibroblasts

Cultures of embryonic fibroblasts from Balb/c or CBA/J mice were given 12-h pulses of 14C-galactose, or were double-labelled with 3H-galactose and 35H-sulfate. The time course of the rates of labelling of glycosaminoglycans--galactose label was found in the uronic acid moiety--was studied in synchronously and asynchronously growing cultures. Partial synchrony was achieved by trypsinising quiescent, confluent cells and subsequent transfer of cells to new cultures with fresh medium. Synchrony was monitored by measurement of thymidine uptake in parallel cultures. The distribution of label in the hyaluronic acid, chondroitin sulfate, and heparan sulfate fractions from cells and culture media was determined at each time point. Peaks of DNA synthesis were accompanied by or followed 12 h later by a maximal rate of labelling with galactose of secreted glycosaminoglycans, and with the exception of hyaluronic acid--also of cellular glycosaminoglycans. The rate of labelling with galactose of glycosphingolipids in parallel cultures followed a different time course. In double-label experiments the rates of labelling of glycosaminoglycan sulfates with 3H-galactose and 35S-sulfate did not go parallel. In older, quiescent cultures the labelling rate with galactose decreased while the sulfation rate increased. It is discussed that the labelling rate with galactose is indicative of the biosynthetic rate of the glycosaminoglycans. The conclusion is reached that glycosaminoglycans are preferentially synthesized and secreted after the S phase of the cell cycle.

Responsiveness to insulin is a dominant characteristic in somatic cell hybrids

The mouse melanoma cell line PG19 has been found to be unresponsive to the growth-stimulatory action of insulin, although it responds well to other growth factors present in serum. Insulin stimulates DNA synthesis in mouse embryo fibroblasts, and responsiveness to insulin has been found to be a dominant characteristic in mouse fibroblast x PG19 hybrids. To examine the possibility that the unresponsiveness to insulin of the melanoma cells is attributable to a lack of insulin receptors, we have measured the binding of 125I-labeled insulin to the fibroblasts, melanoma cells, and fibroblast x melanoma hybrids. Insulin binds to the surface of the melanoma cells; however, the binding affinity appears to be lower than that observed for binding to diploid fibroblasts. In addition, the dissociation of insulin from the melanoma cells is not accelerated by excess unbound insulin, a kinetic effect observed in the dissociation of insulin from the fibroblasts and fibroblast x melanoma hybrids. This suggests that the class of insulin receptors characterized by this effect is absent on the PG19 cells, and present on the fibroblasts and fibroblast x PG19 hybrids.

Sodium concentrations affect metabolite uptake and cellular metabolism

Rates of uptake of glucose (measured with 3H-2-deoxy-d-glucose), galactose, and leucine after exposure of chick embryo cells to increasing concentrations of Na+ over the range 100 to 200 mM. Uptake of nucleosides was unaffected by [Na+] over this range. Prior exposure of cells was required for the [Na+] effect on uptake. Changes were measureable within two hours after changing [Na+], and although the capacity for deoxyglucose uptake remained constant thereafter, the capacity for leucine uptake continued to change during the next few hours. Inhibition of protein synthesis by cycloheximide, or of RNA synthesis by Actinomycin D, failed to prevent these uptake changes. Analysis of the kinetics of uptake showed that only the Km for uptake of deoxyglucose or leucine was affected by [Na+]; the maximum V for each compound remained the same. Effects of [Na+]; could be distinguished from the increased capacity for glucose uptake induced by glucose starvation. Incorporation of both radioactive uridine into RNA, and radioactive thymidine into DNA, were affected by [Na+[, but the differences were not correlated with uptake of other metoblites. No differences in countable mitoses were apparent, although the growth of chick embryo cells in increased slightly with increasing [Na+]. Changes in uptake due to differing [Na+] also were observed in mammalian (rat NRK) cells. However, no effects of [Na+] on rates of cell growth or saturation density were observed with these cells.

2-amino-isobutyric acid and 3-O-methyl-D-glucose transport in 3T3, SV 40-transformed 3T3 and revertant cell lines

In order to further investigate the connection between transport and growth control, 3T3 cells, SV40 transformed 3T3 cells (SV101), and three revertant cell lines derived from SV101 which have regained certain manifestations of growth control were used. Transport rates of 2-amino-isobutyric acid and 3-O-methyl-D-glucose were measured in sparse, confluent, serum-starved, and serum-stimulated cultures. As shown before, cessation of 3T3 cell growth in G0 under conditions of confluence or serum deprivation was associated with reduced rates of transport for both compounds, whereas the density and serum dependence of growth and transport was largely eliminated in SV101. The density revertant F1SV101, which has regained density regulation of growth similar to 3T3 cells, has also regained density regulation of transport. Neither growth nor transport were serum dependent. The serum revertants AgammaSV7 and LsSV6 have regained both density and serum regulation of growth, but not according to the original mechanism of 3T3 cells of entry into a Go state. Transport was high under conditions of confluence or serum deprivation. Thus for these cells rates of transport were not reduced simply as a consequences of slower cell growth nor were low transport rates responsible for growth arrest. The data are consistent with the possibility that growth arrest specifically in the G0 state could shut off a number of cellular activities, including transport.

Serum-stimulated phosphate uptake and initiation of fibroblast proliferation

Previous studies have shown that initiation of proliferation of density-inhibited fibroblasts by fresh serum is accompanied by a rapid increase in phosphate uptake. This increase might be a key event in the initiation of DNA synthesis. The present studies examined this possibility. Mouse 3T3, secondary chick embryo, or human diploid foreskin cultures were grown to quiescence in medium containing varying levels of serum. When proliferation of the cultures was initiated by addition of fresh serum, the changes in phosphate uptake were inversely related to the final increases in cell number. Additional experiments showed that the change in phosphate uptake following serum addition was determined by the level of phosphate uptake prior to serum addition. Addition of dexamethasone to quiescent 3T3 cultures caused them to proliferate but did not increase phosphate uptake. Similarly, trypsin or insulin stimulated proliferation of quiescent secondary chick embryo cultures, but caused little or no change in phosphate uptake. Quiescent 3T3 cultures switched to medium containing fresh serum and reduced levels of phosphate showed a decrease in both phosphate uptake and intracellular phosphate pool size. Cell proliferation in these cultures, however, was stimulated to the same degree as cultures switched to medium containing fresh serum and the normal amount of phosphate. In addition, quiescent secondary chick embryo cultures switched to medium containing fresh serum and no phosphate showed a decrease in the intracellular phosphate pool size. Thymidine incorporation and final cell number in these cultures, however, was stimulated to the same or higher degree than in cultures switched to medium containing fresh serum and the normal amount of phosphate. These results demonstrate that the rapid increase in phosphate uptake following addition of fresh serum to quiescent fibroblasts is not a necessary event for the initiation of proliferation.

Reversible release of chick embryo fibroblast cultures from density dependent inhibition of growth

Initiation of proliferation in density-inhibited chick embryo fibroblast cultures induced by insulin or trypsin was partially reversed by replacing the medium with supernatants from parallel non-stimulated cultures. Growth stimulation by neuraminidase, pokeweed mitogen, bacterial lipopolysaccharides or purified tuberculin was less, or not at all, affected by this procedure. Medium change per se caused some proliferation in non-stimulated cultures. Increased rate of sugar uptake in insulin-stimulated cultures returned to the level of that in non-stimulated cultures within a few hours after medium change. This reversion took place apparently irrespective of the phase of the cell cycle. Replacing the medium with supernatant from non-stimulated cultures induced a rapid decline in subsequent thymidine incorporation during the first S-phase, and completely abolished the second peak of DNA synthesis. The fraction of cells irreversibly committed to mitosis increased when the time after stimulation increased. Less than three hours' incubation with insulin or trypsin was needed to initiate proliferation of a significant fraction of the cell population. It is concluded that reversion of the initiated cycle of a given cell is no more possible after the cell has entered the S-phase.

Anchorage dependent changes in transport of glucose, adenosine, uridine and leucine in 3T3 cells

There is a low uptake of leucine in suspension cultures of 3T3 cells relative to the uptake in sparse monolayer cultures. The pattern of uptake of deoxyglucose is similar in suspension and monolayer cultures and changing the medium or adding serum stimulates uptake under both culture conditions. The uptake of uridine and adenosine is greater in suspension culture than in monolayer culture. Cells do not multiply in suspension culture but do multiply in monolayer culture and thus there is a correlation between uptake of leucine and conditions which stimulate cell multiplication, but not correlation of the uptake of deoxyglucose, uridine and adenosine with these conditions.