Inhibition of spontaneous aggregation by wheat germ agglutinin in suspensions of BALB/c-3T3 and BHK21 tissue culture fibroblasts

A quantitative method of measuring cytoaggregation based on the Coulter electronic cell counter has been applied to the agglutination of BALB/c-3T3 and BHK21 tissue culture fibroblasts by wheat germ agglutinin. When agglutinin is added to transformed or trypsinized cell suspensions high aggregation rates are seen, and the results obtained are in close agreement with the well-known sensitivity of transformed cells to agglutination by lectins.In the absence of agglutinin, a small but reproducible amount of spontaneous aggregation can also be detected. It is related in some way to growth, since it is absent in suspension prepared from confluent (density-inhibited) cultures and is induced by either transfer to low density, additional serum, or transformation by viruses. Under conditions favouring growth, both BALB/c-3T3 and BHK21 cells show aggregation indices close to 25, corresponding to 10% of the maximum aggregation rate seen.This spontaneous aggregation is susceptible to inhibition by agglutinin. Inhibition occurs at low concentration (about 10 μg/ml) and aggregation rates thus pass through a minimum as the concentration of agglutinin is increased. Among the four different cell lines studied, sensitivity to inhibition is inversely related to agglutination. Thus 3T3 cells, which are barely agglutinated by 1 mg/ml of agglutinin, show 90% inhibition; polyoma virus-transformed BHK cells, which are agglutinated by 10 μg of agglutinin, show no inhibition at all.It is suggested that the agglutination of transformed cells is a consequence of their failure to respond to an inhibitory effect exerted by lectins upon an intrinsic adhesive property of the cell surface.     

Effect of Interferon on Some Aspects of Transformation by Polyoma Virus

WHEN BHK 21 hamster cells are infected with polyoma virus¹, there is no vegetative growth of virus, but stably transformed cells appear. These transformed cells are more easily transplanted than BHK 21 cells; they initiate their growth cycle in otherwise restrictive cultural conditions such as the absence of serum, high density and suspension; they grow with random orientation and have exposed on their surfaces receptor sites for certain glycoprotein agglutinins^2–5. The proportion of stably transformed cells is low, even after high doses of virus. But a much higher proportion (sometimes all cells) shows abortive transformation—changes characteristic of transformation, but which last only a few days. In suspension cultures, for example, most of the infected cells grow into small colonies of four to thirty-two cells⁶. In surface cultures deprived of serum DNA synthesis is initiated and the cells may then divide at least once⁷: they also temporarily lose the normal parallel orientation and develop the typical random appearance of transformed cells. Moreover, the polyoma nuclear T-antigen and also a surface antigen detected by immunofluorescence, appear temporarily in most polyoma infected BHK 21 cells⁸, while 3T3 cells exposed to SV40 virus show transient exposure of cell surface sites reacting with conconavalin A (ref. 9).     

The response of normal and polyoma virus-transformed BHK-21 cells to exogenous purines

Adenosine (10 μM) stimulates the initial growth rate of BHK/21 cells seeded at low but not high density in monolayer culture; it does not affect final cell density or permit growth in agar. In labelling experiments With tritiated thymidine, adenosine also increases the response of quiescent cells to low concentrations of serum. Dialysis of serum to remove oxypurines only marginally reduces its effect on quiescent cell labelling or growth, indicating that BHK/21 cells are able to synthesise purines. The response of quiescent cells to 5% serum is inhibited by high MW (2 × 10⁶) dextran sulphate at 2 μg per milliliter. Low MW dextran sulphate (30,000) and heparin at 20 μg per milliliter produce the same effect. Exogenous adenosine (10 μM) prevents this inhibition. Many other purine derivatives replace adenosine for all the above activities but xanthine is completely inactive in all. It, therefore, appears that nucleotide synthesis is a necessary function of these compounds. The growth of cells of a polyoma-virus-transformed BHK/21 line in monolayer is not stimulated by exogenous purine, though their colony-forming ability in agar is increased five-fold. The stimulating effects of exogenous purines on normal BHK/21 cells and the absolute requirement for them in the presence of polyanions is discussed in relation to possible mechanisms of growth control.     

Induction of ornithine decarboxylase in synchronized BHK cells by calf serum after a short period of serum-starvation

Addition of calf serum to serum-starved cultures of synchronized BHK cells induced temporary production of ornithine decarboxylase, irrespective of the phase of the cell cycle of the BHK cells. The induction depended on the duration of serum starvation and on the amount of serum added. In addition, incorporation of 3H-thymidine into the acid-insoluble fraction of BHK cells in the S phase was stimulated by this treatment.     

Inhibition of Adenovirus Type 12 Induced DNA Synthesis in G1-arrested BHK21 Cells by Dibutyryl Adenosine Cyclic 3′ : 5′-Monophosphate

THE intracellular concentration of adenosine cyclic 3′ : 5′-monophosphate (cAMP) has been shown to increase in cells reaching confluency, that is, under conditions of contact inhibition and it has been proposed that contact inhibition may be mediated by the activation of adenyl cyclase¹. Because loss of contact inhibition is one of the important characteristics of transformed cells, it is possible that variations in the level of cAMP play a crucial role in events associated with cell transformation. Growth of tumorigenic cell lines has been shown to be inhibited (80–90%) in the presence of cAMP¹ and adenyl cyclase activity has been found to be much reduced in polyoma transformed cells². BHK21 cells have been shown to be arrested in the G1-phase of the cell cycle after growth for 48 h in medium supplemented with serum at a low concentration (0.5%)³. BHK21 cells are non-permissive for infection with oncogenic adenovirus type 12 (Ad 12). Infection of a G1-arrested cell population with Ad12 results in induction of cellular DNA replication⁴, early virus mRNA is transcribed⁵, infected cells synthesize T antigen⁶, but no viral DNA synthesis⁷ late mRNA⁸, or viral capsid proteins⁸ can be detected after infection. Infection induces the cells to enter mitosis but the chromosomes break down and most of the cells die⁶. As a result, DNA synthesis is limited to a single burst^4,6. Here we report the effects of dibutyryl-cAMP on induction of cellular DNA synthesis in G1-arrested BHK21 cells by infection with Adl2 or serum stimulation.     

Uridine transport and phosphorylation in mouse cells in culture: effect of growth-promoting factors, cell cycle transit and oncogenic transformation

The rapid increase in uridine uptake produced by the addition of serum to quiescent cultures of fibroblasts is primarily caused by an enhanced rate of nucleoside phosphorylation. While quiescent and serum-stimulated cells display identical initial rates of transport, they show a considerable change in the composition of the acid-soluble pools labelled with [3H] uridine for five seconds. The radioactivity recovered in the phosphorylated pools increases 2-, 3-, 4- and 6-fold after addition of serum to cultures of Swiss 3T3 cells, tertiary mouse embryo fibroblasts, Swiss 3T6 and Balb 3T3, cells respectively. Furthermore, insulin, a growth factor isolated from medium conditioned by SV40 BHK cells (FDGF) and epidermal growth factor (EGF) also stimulate uridine phosphorylation within minutes. The initial rate of uridine uptake is 2- to 3-fold faster in rapidly growing normal and Simian virus 40 or polyoma virus transformed 3T3 cells as compared to untransformed 3T3 cells in the quiescent state. When quiescent cultures of 3T3 or mouse embryo cells are stimulated to leave G1 and enter into DNA synthesis, transport increases several hours after addition of serum and apparently coincides with the S phase of the cell cycle. The results demonstrate that an increase in uridine phosphorylation is a rapid metabolic response elicited by growth-promoting agents in a variety of cell types and that uridine transport and phosphorylation are independently regulated.     

Studies on the nature of protease-induced growth stimulation in normal and transformed BHK cells.

In the presence of growth-limiting serum concentrations trypsin displays mitogenic activity on actively-growing but not quiescent BHK cells. These results suggest that BHK cells arrested in G1 (G0) are not sensitive to protease-induced growth stimulation. Previous work strongly suggested that the trypsin active-site is not directly involved in its mitogenic activity on BHK cells. Additional studies on denatured trypsin fragments further indicate that the molecular conformation and size of native trypsin may not be absolutely required for mitogenic activity. Cellular multiplication induced by the addition of fresh serum to quiescent BHK cultures is not inhibited by high concentrations of soybean trypsin inhibitor. Similar to our previous findings with trypsin, it has been further observed that plasmin is not sufficient to initiate the growth of BHK cells in soft agar. Trypsin also fails to enhance the growth of a thermosensitive polyoma-transformed BHK line in soft agar at the restrictive temperature. Finally, the growth of transformed BHK cells in soft agar does not display a requirement for plasminogen and is not inhibited by soybean trypsin inhibitor. These studies argue against the involvement of plasmin or other exogenous trypsin-like enzymes in the growth and transformation of BHK cells.     

Regulation of cyclic nucleotide phosphodiesterase forms by serum and insulin in cultured fibroblasts.

A rapid reduction of cyclic nucleotide phosphodiesterase activity occurs after the replating of confluent cultures of BHK 21 c/13 fibroblasts into fresh medium. This reduction in activity depends on the density to which the cultures are reseeded and the concentration of serum in the medium. Enzyme activity in BHK cells is restored after 24 to 48 hours if cells are diluted into medium containing 10% fetal calf serum or 0.5% fetal calf serum supplemented with insulin (10(-6)M), but not into 0.5% serum alone. The restoration in enzyme activity is blocked by cycloheximide or Actinomycin D. When BHK cells become quiescent by maintanance in 0.5% serum conditions for 48 hours, a rapid (15--60 minutes) increase in cyclic AMP phosphodiesterase activity occurs when 10% serum is added to the cultures. Enzyme activity is increased even further after 24 to 48 hours in the 10% serum. Cycloheximide or Actinomycin D do not affect the rapid increase in enzyme activity in response to serum, but completely inhibit the long term increase. In contrast to serum, insulin (10(-8) to 10(-6)M) has no short term effect, but does increase enzyme activity after 24 to 48 hours to levels comparable to those seen with addition of 10% serum. As is the case with serum, this long term effect of insulin on enzyme activity is prevented by inhibitors of protein and RNA synthesis. Kinetic analyses of cyclic AMP phosphodiesterase activity in homogenates of quiescent BHK cells indicate the presence of only high Km (congruent to 20 muM) enzyme activity. Addition of serum or insulin to quiescent cells results in the appearance of apparent low Km enzyme activity in homogenates. Sucrose gradient analysis of BHK cells displays two forms of cyclic AMP phosphodiesterase enzyme activity: a 3--4 S form and 5--6 S form. In quiescent cells, the 5--6 S form greatly predominates relative to the 3--4 S form. Addition of serum to quiescent cells results in a rapid appearance of increased 3--4 S form enzyme activity. Insulin also increases the activity of this higher affinity 3--4 S enzyme form after 24 to 48 hours in culture. The functional significance of short and long term regulation of cyclic nucleotide phosphodiesterase(s) in cells is discussed.     

G2 cell cycle arrest induced by glycopeptides isolated from the bovine cerebral cortex

The ability of glycopeptides, isolated from bovine cerebral cortex, to alter cell division was studied by cell-cycle analyses. The results showed that glycopeptides arrested baby hamster kidney (BHK)-21 cells and Chinese hamster ovary (CHO) cells in the G2 phase of the cell cycle. Upon removal of the growth inhibition from arrested BHK-21 cells, the mitotic index in colchicine-treated cultures increased from 5 to 40% within 6 h and the increase in mitotic activity was accompanied by a complete doubling of all arrested cells within this 6- h time period. Determination of DNA content in growth-arrested BHK-21 cells showed that growth-arrested cells contained about twice the DNA of control cell cultures. Although CHO cells treated in a like manner with growth inhibitor could not be arrested for the same length of time as BHK-21 cells (18 h vs. 72 h before initiation of escape) and to the same degree (60% of the cell population vs. 99% of BHK-21 cells), the escape kinetics of CHO cells did indicate a G2 arrest. Approximately 3.5 h after escape began, CHO cell numbers in treated cultures attained the cell numbers found in control cultures. This rapid growth phase occurring in less than 4 h indicated that the growth inhibitor induced a G2 arrest-point in CHO cells that was not lethal since the entire arrested cell population divided.     

Sulfation of chondroitin sulfate secreted by baby hamster kidney cells and their polyoma virus-transformed counterparts

Sulfation of glycosaminoglycans (GAGs) secreted by baby hamster kidney (BHK) cells and the polyoma virus-transformants (PY-BHK) was investigated. It has been reported that chondroitin sulfate (CS) of cell membranes from PY-BHK cells is undersulfated compared to that from BHK cells (Cancer Res. 43, 2712-2717, 1983). In the first series of experiments of the present study, cells were incubated with [3H]glucosamine and [35S]sulfate, and GAGs isolated from the culture medium were examined. GAG composition was comparable between the BHK and PY-BHK cultures. Disaccharide analysis of the chondroitinase ACII digests of the hyaluronate lyase-resistant materials showed a high proportion (68% for BHK and 47% for PY-BHK) of delta Di-0S, with delta Di-4S (32% for BHK and 53% for PY-BHK) as the major sulfated disaccharide on the basis of 3H-radioactivities. The beta-D-xyloside treatment did not alter the degree of undersulfation of the CS of either culture. In the second series of experiments, disaccharide analysis of the chondroitinase ABC digests of unlabeled GAGs demonstrated similar disaccharide composition for the two cell types. The BHK and PY-BHK preparations showed 28 and 17% (mol percent) of delta Di-0S, 58 and 72% of delta Di-4S, and 14 and 11% of delta Di-6S, respectively. These results indicate a considerable degree of undersulfation of secretory CS from both cells, and a slightly higher degree, if any, of under-sulfation of secretory CS from BHK cells if compared between the two cell types, which is in contrast to the results reported for membrane CS.     

Modification of diamine oxidase activity in vitro by metabolites of asparagine and differences in asparagine decarboxylation in normal and virus-transformed baby hamster kidney cells.

1. The oxidation of putrescine in vitro by pig kidney diamine oxidase (EC 1.4.3.6) was increased in the presence of 2-oxosuccinamic acid and malonamic acid. 2. It was inhibited by 3-aminopropionamide, oxaloacetate and pyruvate. 3. 2-Oxosuccinamate was derived from asparagine in virus-transformed baby hamster kidney (BHK) cells growing in tissue culture. 4. Asparagine was decarboxylated more efficiently by transformed than by normal BHK cells. 5. In BHK cells transformed by polyoma virus (Py BHK), 2-oxosuccinamate is the most likely immediate precursor of the 14CO2 arising from [U-14C]asparagine, and there was some evidence for its formation in an asparagine-dependent clone of BHK cells before and after their transformation by hamster sarcoma virus (respectively Asn- and HSV Asn-). 6. The relationship between 2-oxosuccinamate and pyruvate and the possible roles of these two substances in controlling cellular diamine oxidase activity are discussed.     

Effects of growth conditions on cyclic nucleotide phosphodiesterases of cultured fibroblasts.

Cyclic nucleotide phosphodiesterase activities of baby hamster kidney cells (BHK) grown in surface cultures were altered by modifying growth conditions. The untransformed BHK cells grown in medium containing 10% fetal calf serum showed non-linear LineweaverBurk plots for cyclic AMP phosphodiesterase activity with apparent Michaelis constants for cyclic AMP of approximately 5 and 30 muM. When these cells were placed in medium containing 1% fetal calf serum, linear kinetic plots for cyclic AMP phosphodiesterase with an apparent Km for cyclic AMP of approximately 20 muM were obtained. Modification of the apparent Km of BHK cell phosphodiesterase was detectable within 20 minutes after dillution of cells grown in 10% serum into fresh medium containing 1% serum. With the BHK cell line transformed with Rous sarcoma virus, differences in enzyme kinetics were not seen when these cells were diluted in 1% or 10% serum. In addition to the serum induced differences in the apparent Km of cyclic AMP phosphodiesterases of BHK cells, total cyclic AMP and cyclic GMP phosphodiesterase activities were also modified by growth conditions. BHK cells grown to high cell densities had three to five-fold higher total cyclic AMP activity than did the cells in less dense cultures. When the dense cell cultures were diluted into fresh medium containing 10% serum, total enzyme activities fell to levels comparable to those found in the rapidly growing cells at low cell densities. The reduction in total enzyme activity after dilution of BHK cells occurred rapidly and was influenced by cell density. A similar reduction of total enzyme activity was also seen in diluted RSV cells; however, the time course of the response differed from that seen in the untransformed cells.     

Soluble Receptor Potentiates Receptor-Independent Infection by Murine Coronavirus

Mouse hepatitis virus (MHV) infection spreads from MHV-infected DBT cells, which express the MHV receptor CEACAM1 (MHVR), to BHK cells, which are devoid of the receptor, by intercellular membrane fusion (MHVR-independent fusion). This mode of infection is a property of wild-type (wt) JHMV cl-2 virus but is not seen in cultures infected with the mutant virus JHMV srr7. In this study, we show that soluble MHVR (soMHVR) potentiates MHVR-independent fusion in JHMV srr7-infected cultures. Thus, in the presence of soMHVR, JHMV srr7-infected DBT cells overlaid onto BHK cells induce BHK cell syncytia and the spread of JHMV srr7 infection. This does not occur in the absence of soMHVR. soMHVR also enhanced wt virus MHVR-independent fusion. These effects were dependent on the concentration of soMHVR in the culture and were specifically blocked by the anti-MHVR monoclonal antibody CC1. Together with these observations, direct binding of soMHVR to the virus spike (S) glycoprotein as revealed by coimmunoprecipitation demonstrated that the effect is mediated by the binding of soMHVR to the S protein. Furthermore, fusion of BHK cells expressing the JHMV srr7 S protein was also induced by soMHVR. These results indicated that the binding of soMHVR to the S protein expressed on the DBT cell surface potentiates the fusion of MHV-infected DBT cells with nonpermissive BHK cells. We conclude that the binding of soMHVR to the S protein converts the S protein to a fusion-active form competent to mediate cell-cell fusion, in a fashion similar to the fusion of virus and cell membranes.     

The effect of polyoma virus,serum factors,and dibutyryl cyclic AMP on dihydrofolate reductase synthesis,and the entry of quiescent cells into S phase

Three procedures were used to induce dihydrofolate reductase synthesis in quiescent cultures of methotrexate resistant mouse fibroblasts: (1) lytic infection with polyoma virus, (2) growth stimulation by replating cells at lower density in fresh cell culture medium, and (3) the addition of fresh medium to confluent cells. Following polyoma infection, an increase in the percentage of S-phase cells began at approximately 20 hours; dihydrofolate reductase synthesis also increased following a lag of 20 hours or more, and continued to increase throughout the late phase of lytic infection, reaching values nearly fivefold greater than that originally present in the quiescent cells. When quiescent cells received fresh medium (with or without replating), the percentage of cells in S phase began to increase by 10 hours and was accompanied by an increase in dihydrofolate reductase synthesis which reached a maximum by approximately 25 hours. These observations show that the initial entry of cells into S phase following mitogenic stimulation is associated with an induction of dihydrofolate reductase synthesis. Dibutyryl cyclic AMP blocked the stimulation of dihydrofolate reductase synthesis and the increase in the percentage of S-phase cells that resulted from the addition of fresh medium to confluent cells. When dibutyryl cyclic AMP was added at various times following the addition of fresh medium, the block in the induction of dihydrofolate reductase synthesis was correlated with a corresponding block in the increase in S-phase cells. These results suggest that dibutyryl cyclic AMP blocks cells at a point in Gl prior to either the induction of dihydrofolate reductase synthesis or the beginning of S phase. The relationship between the control of dihydrofolate reductase synthesis and entry into S phase suggests some form of coordinate control over these two parameters.     

Contact-mediated changes in cycloheximide-induced agglutinability of BHK cells

Suspension cultures of BHK cells grow in MEM supplemented with 10% fetal calf serum at about 50% the rate of corresponding monolayer cultures. If the serum supplement is reduced to 2% no increase in cell number is observed. When 10% serum is used small spheroids comprising 3–4 cells form within a 24 h period, but in 2 % serum the cells remain single over the same period. The addition of cycloheximide to contact-inhibited monolayer cultures induces high levels of ConA agglutinability within 6 h, yet growing non-confluent cells are rendered only about half as agglutinable by the same treatment. Cycloheximide treatment of suspension cultures causes growing cells to become agglutinable, but non-growing cells, which do not form spheroids, remain non-agglutinable even after 24 h of treatment. This suggests that the pronounced effect of cycloheximide on the agglutinability of contact-inhibited cells in monolayer culture reflects their confluence rather than suspended growth, and that the turnover rate of surface molecules determining the agglutinability state of cells is enhanced as cell-to-cell contact increases.     

Ribosome biosynthesis is not necessary for initiation of DNA replication.

Synthesis of mature 28-S ribosomal RNA and 60-S ribosomal subunits is inhibited in baby hamster kidney (BHK) cell line ts 422E at non-permissive temperature (39 degrees C). This leads to a 66% decrease of total ribosomes per cell, a marked imbalance between the large and small ribosomal subunits in the cytoplasm and a decrease of cells per dish after prolonged culture at 30 degrees C. However, inhibition of ribosome synthesis does not affect progression of cells through the G1 period of the cell division cycle, the length of the pre-replicative period, and the rate of entry of cells into S phase. In contrast to culture at non-permissive temperature, culture of BHK ts 422E cells in the presence of 0.04 micrograms/ml actinomycin D at 33 degrees C inhibits markedly the entry into S period. It is concluded that low doses of actinomycin D exert their inhibitory effect on cell growth by preventing maturation and transport of mRNA rather than by interfering with ribosome synthesis. Microfluorometric analysis revealed only slight differences in the distribution of BHK ts 422E cells in G1, S and G2 phases of the cycle either when cultured at 33 degrees C or at 39 degrees C. When too few ribosomes per cell are produced in BHK ts 422E cells at 39 degrees C, cells do not seem to be arrested reversibly at a specific point of the cell cycle but rather to die at random.     

Polyoma virus and cyclic AMP-mediated control of dihydrofolate reductase mRNA abundance in methotrexate-resistant mouse fibroblasts.

As a model cell culture system for studying polyoma-mediated control of host gene expression, we isolated methotrexate-resistant 3T6 cells in which one of the virus-induced enzymes, dihydrofolate reductase, is a major cellular protein. In highly methotrexate-resistant cell lines dihydrofolate reductase synthesis accounts for over 10% that of soluble portein, corresponding to an increase of approximately 100-fold over the level in parental cells. This increase in dihydrofolate reductase synthesis is due to a corresponding increase in the abundance of dihydrofolate reductase mRNA and gene sequences. We have used these cells to show that infection with polyoma virus results in a 4- to 5-fold increase in the relative rate of dihydrofolate reductase synthesis and a corresponding increase in dihydrofolate reductase mRNA abundance. The increase in dihydrofolate reductase synthesis begins 15 to 20 h after infection and continues to increase until cell lysis. These observations represent the first direct evidence that viral infection of eukaryotic cells results in the increased synthesis of a specific cellular enzyme and an increase in the abundance of a specific cellular mRNA. In order to gain additional insight into the control of dihydrofolate reductase synthesis we examined other parameters affecting dihydrofolate reductase synthesis. We found that the addition of fresh serum to stationary phase cells results in a 2-fold stimulation of dihydrofolate reductase synthesis, beginning 10 to 12 h after serum addition. Serum stimulation of dihydrofolate reductase synthesis is completely inhibited by the presence of dibutyryl cyclic AMP as well as by theophylline or prostaglandin E1, compounds which cause an increase in intracellular cyclic AMP levels. In fact, the presence of dibutyryl cyclic AMP and theophylline results in a 2- to 3-fold decrease in the rate of dihydrofolate reductase synthesis and the abundance of dihydrofolate reductase mRNA. However, in contrast to the effect on serum stimulation, dibutyryl cyclic AMP and theophylline do not inhibit polyoma virus induction of dihydrofolate reductase synthesis or dihydrofolate reductase mRNA levels. These observations suggest that dihydrofolate reductase gene expression is controlled by at least two regulatory pathways: one involving serum that is blocked by high levels of cyclic AMP and another involving polyoma induction that is not inhibited by cyclic AMP.     

Cytochalasin D inhibits the progression from the Go to S phase at the mid-prereplicative stage in GC-7 cells stimulated with serum

When the growth of serum-arrested GC-7 cells, a clone from African green monkey kidney, was induced by the addition of 10% calf serum, they began to enter S phase after 15-16 h. When stimulated cells were cultured in the presence of 0.6 micrograms/ml of cytochalasin D, the entrance into S phase was inhibited. Treatment of cells with cytochalasin D during the period earlier than 8 h or later than 11 h after the serum stimulation showed no or little inhibitory effect on the entrance of cells into S phase. Inhibition of the entrance into S phase was observed only when stimulated cells were treated with cytochalasin D during the periods including 9-10 h after stimulation. A rapid increase in protein synthesis occurred 9-12 h after the serum stimulation and was inhibited in the presence of cytochalasin D. These and other results suggested that in the course of the prereplicative process from Go through S phase only the stage around 9-10 h after the start of the cell cycle was sensitive to cytochalasin D and that the block of the cycle was correlated with the inhibition of protein synthesis at this stage.     

Action of cortisol on the proliferation of rainbow trout fibroblasts

The effect of cortisol on the proliferation of the rainbow trout fibroblast cell line, RTG-2, was examined in synchronous and asynchronous cultures. When the transition from G1 to S was synchronized by restoring serum to serum-deprived cultures, the addition of cortisol at the time of serum restoration delayed the entry of cells into S phase. However, if cortisol was added 24 h after serum restoration, at the G1/S transition point, the subsequent peak of DNA synthesis was unaffected. In asynchronous cultures cortisol inhibited [3H]-thymidine and [3H]-uridine but not [3H]-leucine incorporation into acid-insoluble material. If the exogenous nucleoside concentration was raised, [3H]-thymidine but not [3H]-uridine incorporation continued to be inhibited by cortisol. This suggested that cortisol's effect on [3H]-thymidine incorporation reflected a change in entry into S phase and not just on thymidine uptake and metabolism. Cortisol inhibited the proliferation of RTG-2 in asynchronous cultures. At 1000 ng/ml of cortisol a reduction in cell number became apparent before the RTG-2 cultures were confluent, whereas at 100 ng/ml the reduction only became evident in confluent cultures. The synthetic antiglucocorticoid, RU 486, which acts at the level of the corticosteroid receptor, blocked the growth inhibition by cortisol. These results suggest that cortisol regulates rainbow trout fibroblast proliferation via the corticosteroid receptor and that the G1/S transition is one point at which this regulation occurs.     

Analysis of BHK cell growth kinetics after microinjection of catalytic subunit of cyclic AMP-dependent protein kinase.

The effect of catalytic subunit (C) of cyclic AMP-dependent protein kinase on cell growth kinetics of BHK cells was assessed by microinjection with chicken erythrocyte ghosts as vehicles for introduction of the protein into the cytosol of large populations of cells. The advantage in using chicken erythrocytes for microinjection is that the inactive erythrocyte nuclei serve as a probe for identifying and analyzing microinjection events. By utilizing this procedure, BHK cells were microinjected with an amount of C that was 5- to 10-fold greater than their endogenous levels. Growth kinetics were analyzed by [3H]thymidine incorporation and autoradiography. Cells were stained after autoradiography to more clearly reveal the chicken nuclei, and at each time point, cells were categorized into four groups: (i) not microinjected, not in S phase, (ii) not microinjected, in S phase, (iii) microinjected, not in S phase, (iv) microinjected, in S phase. Those cells not microinjected served as internal controls. Two experimental protocols were used to test the notion that C is involved in blocking cell progression through G1 phase of the cell cycle. First, cells were arrested in G0 phase by serum deprivation, microinjected with C or control proteins, and stimulated to proceed to S phase by the addition of serum or purified growth factors. Second, cells were collected in mitosis, microinjected with C or control proteins, and stimulated to proceed to S phase by the addition of serum. The results of these studies indicate that a 5- to 10-fold increase in the intracellular concentration of C is not a sufficient signal to arrest cell growth in G1 phase. Thus, growth-inhibitory effects of cyclic AMP on BHK cells are unlikely to be the result of activation of cyclic AMP-dependent protein kinase.