Effect of cytochalasin D on DNA synthesis in cultured cells

The effect of cytochalasin D (CD), an agent specifically destroying actin cytoskeleton, on DNA replication of cultured mouse embryonic fibroblasts (MEF) and BALB/3T3 strain cells was studied. Incubation of normal cells with CD resulted in progressive inhibition of DNA synthesis: in the first 16-20 h the percentage of cells pulse-labelled with 3H-thymidine was similar to that in control cultures, on day 8 the percentage of labelled cells was 7-8 times lower than in the control. The transfer of cells into fresh medium upon 8-day incubation in the presence of CD resulted in the recovery of DNA synthesis. Similar curves of DNA synthesis inhibition in the presence of CD and of DNA synthesis recovery in fresh medium were observed both in mononuclear and binuclear cells. Thus, CD-induced reorganization of actin cytoskeleton can have an abrupt but reversible disturbing effect on normal cell cycle.     

Lectin-mediated stimulation of DNA synthesis in cultures of embryonic neural retina cells

Plant lectins and other agents which are mitogenic for lymphocytes and fibroblasts were tested for their effects on DNA synthesis in primary monolayer cultures of neural retina cells from 10-day chick embryos. Concanavalin A (ConA), phytohemagglutinin (PHA), wheat germ agglutinin (WGA), and anti-retina cell antiserum significantly stimulated [³H]TdR incorporation; the maximum increase was reached 15 h after exposure of the cultures to these agents. Cells stimulated by ConA to synthesize DNA subsequently divided. The divalent succinyl derivative of ConA had a considerably lesser effect than the native tetramer, suggesting that cross-linking of cell surface components may be an important aspect of the changes that lead to the stimulation of DNA synthesis in these cells.Using [¹²⁵I]ConA, the average number of ConA-binding sites per 10-day retina cell was estimated to be 1.7 × 10⁶ (under the culture conditions employed); binding of the lectin to 25–50% of these sites was sufficient to elicit the maximal stimulation of DNA synthesis. Continuous association of the lectin with the cell surface for up to 8 h was essential for the maximal effect, since removal of the lectin from the cell surface (with α-methyl mannose) prior to this time reduced or prevented the stimulation of DNA synthesis.The stimulation by ConA of DNA synthesis in these cultures was dependent on the cell density and was reduced or absent at lower than optimal densities. Examination of this effect suggested that the frequency of intercellular contacts or specific cell associations play a role in the responsiveness of these cells to stimulation of DNA synthesis by ConA.     

K-Opioid Agonist Modulation of [3H]Thymidine Incorporation into DNA: Evidence for the Involvement of Pertussis Toxin-Sensitive G Protein-Coupled Phosphoinositide Turnover

Abstract: A body of evidence has indicated that μ-opioid agonists can inhibit DNA synthesis in developing brain. We now report that K -selective opioid agonists (U69593 and U50488) modulate [³H]thymidine incorporation into DNA in fetal rat brain cell aggregates in a dose- and developmental stage-dependent manner. K agonists decreased thymidine incorporation by 35% in cultures grown for 7 days, and this process was reversed by the K -selective antagonist, norbinaltorphimine, whereas in 21-day brain cell aggregates a 3,5-fold increase was evident. Cell labeling by [³H]thymidine was also inhibited by the K -opioid agonist as shown by autoradiography. In addition, U69593 reduced basal rates of phosphoinositide formation in 7-day cultures and elevated it in 21-day cultures. Control levels were restored by norbin-altorphimine. Pertussis toxin blocked U69593-mediated inhibition of DNA synthesis. The action of K agonists on thymidine incorporation in the presence of chelerythrine, a protein kinase C (PKC) inhibitor, or in combination with LiCl, a noncompetitive inhibitor of inositol phosphatase, was attenuated in both 7- and 21-day cultures. These results suggest that K agonists may inhibit DNA synthesis via the phosphoinositide system with a pertussis toxin-sensitive G protein as transducer. In mixed glial cell aggregates, U50488 increased thymidine incorporation into DNA 3.1-fold, and this stimulation was reversed by the opioid antagonist naltrexone.     

Fibronectin stimulates growth but not follicle-stimulating hormone-dependent differentiation of rat granulosa cells in vitro

Since fibronectin is a secretory product of immature rat granulosa cells in culture and may contribute to the follicular microenvironment in vivo, we have studied the effects of this adhesion factor on follicle-stimulating hormone (FSH)-dependent differentiation in short-term (2-3-day) cultures and on growth and protein synthesis in long-term (12-day) cultures. In comparison with cells plated on tissue culture plastic, those plated on an optimal fibronectin-coated substratum showed much greater cell spreading. There were no short-term effects of this morphological change on FSH-stimulation of cyclic AMP production, apparent activities of aromatase or cholesterol side-chain cleavage enzymes, or acquisition of luteinizing hormone (LH) responsiveness in cultured cells. However, progesterone metabolism to 20 alpha-hydroxypregnan-4-en-3-one was increased. Only cultures on fibronectin showed increases between days 3 and 9 in protein (2.5-fold) and DNA (1.4-fold) contents. Cells cultured on fibronectin also showed greater uptake and incorporation of [3H]leucine in comparison with cells cultured on plastic. FSH treatment caused cell aggregation and rounding and delayed the increase in protein content of cells cultured on fibronectin. The results presented demonstrate that the principal direct effect of fibronectin-mediated adhesion on rat granulosa cells is to enhance cell maintenance and growth, while having no generalized action on FSH-dependent differentiation.     

CHARACTERIZATION OF LYMPHOCYTE TRANSFORMATION INDUCED BY ZINC IONS

Lymphocyte cultures from all normal human adults are stimulated by zinc ions to increase DNA and RNA synthesis and undergo blast transformation. Optimal stimulation occurs at 0.1 mM Zn⁺⁺. Examination of the effects of other divalent cations reveals that 0.01 mM Hg⁺⁺ also stimulates lymphocyte DNA synthesis. Ca⁺⁺ and Mg⁺⁺ do not affect DNA synthesis in this culture system, while Mn⁺⁺, Co⁺⁺, Cd⁺⁺, Cu⁺⁺, and Ni⁺⁺ at concentrations of 10^-7–10^-3 M are inhibitory. DNA and RNA synthesis and blast transformation begin to increase after cultures are incubated for 2–3 days with Zn⁺⁺ and these processes reach a maximum rate after 6 days. The increase in Zn⁺⁺-stimulated lymphocyte DNA synthesis is prevented by rendering cells incapable of DNA-dependent RNA synthesis with actinomycin D or by blocking protein synthesis with cycloheximide or puromycin. Zn⁺⁺-stimulated DNA synthesis is also partially inhibited by 5'-AMP and chloramphenicol. Zn⁺⁺ must be present for the entire 6-day culture period to produce maximum stimulation of DNA synthesis. In contrast to its ability to independently stimulate DNA synthesis, 0.1 mM Zn⁺⁺ inhibits DNA synthesis in phytohemagglutinin-stimulated lymphocytes and L1210 lymphoblasts.     

Density-dependent growth control of adult rat hepatocytes in primary culture

Adult rat hepatocytes in primary culture, which show various liver functions, did not show any mitosis at confluent cell density, although they entered the S phase and remained in the G2 phase, judging by cytofluorometry, when insulin and epidermal growth factor (EGF) were added to 2-day cultures (Tomita, Y., Nakamura, T., & Ichihara, A. (1981) Exp. Cell Res. 135, 363-371). However, when the cell density was decreased by half or one third, the number of nuclei and cell number increased to 1.5-2.0 times that after culture for 35 h with insulin and EGF. Moreover, at these lower densities, DNA synthesis started much earlier, although at the usual high density DNA synthesis with these two hormones did not start until the hepatocytes had been cultured for over 40 h. These results suggest that proliferation of mature rat hepatocytes is regulated by the cell density. First, cells in G0 enter the G1 phase density-dependently; then cells in the G1 phase seem to be stimulated to enter the S phase by insulin and EGF, and a low cell density may permit cells after DNA synthesis to enter the M phase. DNA synthesis of rat hepatocyte cultures at low cell density was strongly inhibited by co-culture with a dense culture. Therefore, the density-dependent mechanism of hepatocyte proliferation seems to involve regulation by a soluble inhibitor(s) secreted by the hepatocytes into the culture medium.     

Stimulation of bone formation by prostaglandin E2

We examined the effect of prostaglandin E2 (PGE2), in the presence or absence of cortisol, on bone formation in 21-day fetal rat calvaria maintained in organ culture for 24 to 96 h. [3H]Thymidine and [3H] proline incorporation were used to assess DNA and collagen synthesis, respectively. Changes in dry weight and DNA content were assessed after 96 h. PGE2 (10(-7) M) stimulated both DNA and collagen synthesis in calvaria. The effect on DNA synthesis was early (24 h), transient and limited to the periosteum. Collagen synthesis was stimulated at a later time (96 h), predominantly in the central bone. Cortisol (10(-7) M) inhibited DNA and collagen synthesis. The addition of PGE2 reversed the inhibitory effects of cortisol on DNA synthesis and content and increased collagen synthesis in central bone to levels above control untreated cultures. We conclude that PGE2 has stimulatory effects on bone formation and can reverse the inhibitory effects of cortisol. Hence the effects of cortisol may be mediated in part by their ability to reduce the endogenous production of prostaglandins.     

A comparative study of the DNA structural damages and synthesis in embryos of the silkworm Bombyx mori irradiated with gamma rays at different developmental stages]

Studies have been made on formation and reparation of apurine-apyrimidine (AP) regions, monothread DNA ruptures, as well as on inhibition and recovery of DNA synthesis in gamma-irradiated 3- and 7-day embryos of the silkworm which sharply differ in their radiosensitivity. It was shown that in 3-day embryos, the number of AP regions and DNA ruptures immediately after irradiation is significantly higher than in 7-day embryos. DNA synthesis is more radiosensitive in 3-day embryos as compared to that in 7-day ones. Kinetics of postradiation recovery of regions and DNA ruptures in 3- and 7-day embryos is heterogeneous and significantly different. However, radiation inhibition and postradiation recovery of DNA synthesis in irradiated 3- and 7-day embryos are associated mainly with postradiation survival of these embryos.     

A novel explant outgrowth culture model for mouse pancreatic acinar cells with long-term maintenance of secretory phenotype

The development of in vitro models able to support the long-term viability and function of acinar cells is critical for exploring pancreatic pathophysiology. Despite considerable efforts, no long-term culture models for non-transformed pancreatic acini exist. Our aim was to develop and validate culture conditions for this purpose. An explant outgrowth culture design was established in which mouse pancreatic explants were cultured at the gas-liquid interphase. An enriched culture medium, pH 7.8, was employed to promote the selective outgrowth of acinar cells and to support their differentiated phenotype. After 7 days, the outgrown primary acinar cells were subcultured and maintained up to an additional 7 days as secondary monolayers on tissue culture plastic. Measurements of basal and caerulein-induced amylase secretion, phase-contrast microscopy and immunohistochemical analyses were used to characterize the cultures. Explants retained their pancreatic cytoarchitecture for 2 days in vitro. A triphasic dose response to caerulein was detected in 7-day primary cultures. The maximal rate of secretion was 1.2-fold versus basal (p=0.009) and 1.7-fold versus 1 pM caerulein (p=0.014). In secondary cultures the response was biphasic with maximal rates of secretion being 1.9-fold in 3- to 4-day cultures at 0.01 nM (p=0.049) and 2-fold in 6- to 7-day cultures at 0.1 nM (p=0.003). The present culture model provides a means to obtain functionally competent normal mouse acinar cells for long-term in vitro experimentation.     

The effect of 1,25-dihydroxyvitamin D3 on in vitro immunoglobulin production in human B cells

1,25-Dihydroxyvitamin D3 (1,25(OH)2D3) dose-dependently suppressed immunoglobulin (Ig) production of human B cells, as evaluated by IgG-plaque-forming cells (IgG-PFC) in the culture of pokeweed mitogen (PWM)-activated B cells. Similar suppressive effect of 1,25(OH)2D3 on Ig production of B cells was observed in the Staphylococcus aureus Cowan I(SAC)-induced Ig-producing system. The mean percentage of inhibitions at a concentration of 10(-9) M were 60.0 +/- 8.2% (mean +/- SE, n = 6) and 65.1 +/- 4.7% (n = 10) in PWM- and SAC-stimulated cultures, respectively. The suppression was strongly exhibited only when 1,25(OH)2D3 was added at the start of the 6-day culture, accompanied by a decrease in DNA synthesis of B cells in both culture systems. On the other hand, the addition of 1,25(OH)2D3 on day 4, when DNA synthesis reached at plateau and IgG-PFC began to be detectable, had no noticeable affect on either the number of PFC or DNA synthesis of B cells. Furthermore, 1,25(OH)2D3 suppressed Ig production even when B cells were exposed to the agent for 4 hr after the activation with PWM or SAC, but not before the activation. These results indicate that 1,25(OH)2D3 inhibits B cell proliferation before differentiation to Ig-secreting cells, consequently reducing Ig production; and that its action appears to be mediated by the cytosol receptors expressed on activated B cells. Thus, the agent may serve as an immunoregulating hormone in vivo, as well as in vitro.     

Cell density downregulates DNA synthesis and proliferation during osteogenesis in vitro

Abstract. The classical models of in vitro cell culture comprise fibroblasts and epithelial cells. Osteogenic cells represent another interesting cell model; however, it is not known whether during osteogenesis cell density regulates cell growth as seen in cultures of fibroblasts and epithelial cells. We selected MC3T3-E1 cells for study because they are an osteogenic cell line that, when subcultured, grow to confluence and form multilayers of cells in conventional cultures by continued proliferation, as do fibroblasts. Once maximum cell density is obtained, proliferation is down regulated resulting in a mixed population of quiescent and dividing cells. We used this model to determine whether downregulation of proliferation as expressed by cell number and DNA synthesis is cell density-dependent. MC3T3-E1 cells were cultured over a period of 34 days to determine their kinetics, viability, ability to synthesize DNA, distribution within phases of the cell cycle and cell number-response relationships. Our results show that (1) viability ranged between 92% and 96% and the cell number 2.5 x 10⁵ per cm² once cultures reached steady state, (2) most cells entered the G₀/G₁ phase of the cell cycle on day 7, (3) there was no correlation between the proportion of cells in S phase and downregulation of DNA synthesis, (4) a direct relationship exists between cell density and downregulation of DNA synthesis on day 8, (5) the minimum time for cells to be cultured before downregulation of DNA synthesis begins is independent of cell number, and (6) downregulation of DNA synthesis is reversible. These results suggest that density-dependent downregulation of DNA synthesis may be a mechanism of growth control for osteogenic cells in vitro that operates more like density-dependent growth control in cultures of fibroblasts rather than epithelial cells.     

Effect of insulin at dilution endpoint concentrations on macromolecular synthesis in normal mouse mammary and human breast cancer epithelial cells

Employing defined media conditions, the insulin sensitivities of mouse mammary gland epithelial cells in primary culture and MCF-7 human mammary epithelial cells were determined. Insulin stimulated the rates of (3H] uridine incorporation into RNA and [3H] leucine incorporation into protein in both primary mouse mammary gland epithelial cell cultures and MCF-7 cell cultures at concentrations approximating the dilution endpoint of the hormone (10-21 M). Insulin stimulated the rate of [3H] thymidine incorporation into DNA in primary mouse mammary gland epithelial cells at the dilution endpoint concentrations. However, MCF-7 cells required insulin concentrations 100-1000-times that necessary in mouse mammary epithelial cultures to elicit an increased rate of [3H] thymidine incorporation into DNA. Evidence is presented which suggests that the increased rates of uptake of 3H- uridine, [3H] thymidine and [3H] leucine into their respective precursor pools is not responsible for the apparent stimulation of RNA, DNA and protein synthesis.     

Stimulation of DNA synthesis in senescent human cells following incubation with plasma membranes

DNA synthesis and mitosis were increased in mitogen-stimulated senescent WI-38 cells following incubation with plasma membranes prepared from young or senescent WI-38 cells, A431 cells, 3T3 cells, or NR6 cells. The percentage of [3H]thymidine-labeled nuclei in senescent cultures was two- to fivefold greater than that seen in controls in which cells were incubated in the absence of membranes or in the presence of boiled membranes. The effect was trypsin sensitive, suggesting that a protein moiety is necessary for stimulation of DNA synthesis. As the culture age increased, basal levels of DNA synthesis, as well as maximal stimulation of DNA synthesis following incubation with plasma membranes, decreased. These observations are consistent with the hypothesis that different subpopulations exist in senescing cultures and suggest a complex pattern of inhibitory and stimulatory regulation of cell proliferation.     

Biosynthesis and Expression of Gangliosides During Differentiation of Chick Embryo Retina Cells In Vitro

Cells from neural retina from 7-day chick embryos were cultured on polylysine-coated dishes up to 7 days. The small, round-shaped cells at seeding differentiated progressively, and after 4 days in vitro the majority had enlarged bodies and abundant processes. The content of protein and DNA was essentially unchanged during the entire period of culture. The incorporation of radioactivity from [3H]glucosamine into gangliosides declined slightly, reaching about 65% of the initial values at the end of the culture period. The proliferating activity measured by the incorporation of [3H]thymidine into DNA decreased to 10% or less of the initial value after 3 days in vitro. Almost at the same chronological times as in ovo, the synthesis of GD3 and of a ganglioside partially identified as GT3 decreased from 70 and 19% of the total incorporation into gangliosides in the first 20 h of culture to about 7 and 5%, respectively, after 3 days in vitro. Conversely, the synthesis of GD1a increased from about 6% at the beginning to about 70% at the end of the culture times. Immunocytochemical analyses of the expression of gangliotetraosyl gangliosides in cultured cells showed that these gangliosides appeared in the bodies and processes of cells having neuronal morphology; very little immunostaining of the scarce flattened cells, probably Müller cells, was found. The results indicate that the changes in ganglioside metabolism, which lead to decreased synthesis of gangliosides lacking the galactosyl-N-acetyl-galactosaminyl disaccharide end and to increased synthesis of gangliotetraosyl gangliosides, occur in cells that in culture differentiate into neurons.     

Pyridine nucleotides in normal and nicotinamide depleted adrenal tumor cell cultures

Mouse adrenal tumor cell line Y-129 was grown in cell culture in medium without nicotinamide. Inhibition of growth occurred after the second subculture in the vitamin-deficient medium. Pyridine nucleotides were measured in control and nicotinamide-starved cultures. DPN⁺ decreased to less than 10% of the normal level after 7 days of vitamin starvation. TPNH dropped to 25% of its normal level in the same period. Plating efficiency decreased from 20% in controls to 10% in 7-day nicotinamide-starved cultures. Steroid production was reduced by approximately 50% in the starved cultures. Sensitivity of the cultures to the lethal effects of the nicotinamide antagonist, 3-acetylpyridine, was inversely proportional to the pyridine nucleotide content of the cells. Reconstitution of nicotinamide in depleted cultures caused a rapid renewal of the pyridine nucleotide levels and complete protection against the effects of 3-acetylpyridine. Recovery and subsequent growth of the cultures did not restore the decreased capacity to produce steroids. Nicotinic acid was not utilized by the cells for the synthesis of pyridine nucleotides in depleted cultures and azaserine did not inhibit the utilization of nicotinamide indicating that DPN⁺ was synthesized directly via nicotinamide ribonucleotide.     

Arginine deprivation in KB cells: I. Effect on cell cycle progress

When exponentially growing KB cells were deprived of arginine, cell multiplication ceased after 12 h but viability was maintained throughout the experimental period (42-48 h). Although tritiated thymidine ([(3)H]TdR) incorporation into acid-insoluble material declined to 5 percent of the initial rate, the fraction of cells engaged in DNA synthesis, determined by autoradiography, remained constant throughout the starvation period and approximately equal to the synthesizing fraction in exponentially growing controls (40 percent). Continous [(3)H]TdR-labeling indicated that 80 percent of the arginine-starved cells incorporated (3)H at some time during a 48-h deprivation period. Thus, some cells ceased DNA synthesis, whereas some initially nonsynthesizing cells initiated DNA synthesis during starvation. Flow microfluorometric profiles of distribution of cellular DNA contents at the end of the starvation period indicated that essentially no cells had a 4c or G2 complement. If arginine was restored after 30 h of starvation, cultures resumed active, largely asynchronous division after a 16-h lag. Autoradiographs of metaphase figures from cultures continuously labeled with [(3)H]TdR after restoration indicated that all cells in the culture underwent DNA synthesis before dividing. It was concluded that the majority of cells in arginine-starved cultures are arrested in neither a normal G1 nor G2. It is proposed that for an exponential culture, i.e. from most positions in the cell cycle, inhibition of cell growth after arginine with withdrawal centers on the ability of cells to complete replication of their DNA.     

Human T-cell cultures with selective autotumor reactivity

Summary T-cell cultures derived from the blood of 14 patients with solid tumors were propagated with T-cell growth factor (TCGF). The cultures were initiated from lymphocytes exposed to autologous tumor-biopsy cells. TCGF was added either immediately or 3–10 days later. In the former culture type the cell yield on day 7 was considerably higher. The cytotoxic potential of the cultured cells was assayed on two occasions, between days 7 and 10 and between weeks 5 and 8. Cells of all but two cultures had the potential to lyse autologous tumor-biopsy cells.On the population level, cytotoxicity was specific for autologous tumor in those cultures that were driven to growth with TCGF after the 3rd day. These lymphocytes did not lyse allogeneic tumor-biopsy cells. In contrast, all five cultures initiated in the presence of TCGF exhibited a broader cytotoxic potential, i.e., in addition to the stimulator autologous-tumor cells, they also lysed other targets. Another difference between the two culture types was their behavior toward K562. Tested on the 7th day they all lysed K562; however, this function declined in strength or disappeared later in the cultures exposed to TCGF after the 3rd day.Reexposure of the lymphocytes to autologous tumor-biopsy cells after 2 weeks of culture period, but not on the 7th day, induced DNA synthesis. This secondary response was specific inasmuch as allogeneic tumor cells had little or no effect.One of the autotumor restimulated cultures was tested for cytotoxic potential. It increased against the autologous but not against other tumors or K562 cells.     

Effects of medium and substratum conditions on the rates of DNA synthesis in primary cultures of bile ductular epithelial cells

Summary Select medium and substratum conditions were investigated for their effects on semiconservative DNA synthesis in essentially pure primary cultures of bile ductular epithelial cells that were initially isolated from cholestatic rat livers at 6 to 10 wk after bile duct ligation. DNA synthesis in these cultured cells was serum-dependent, being at its highest level when the concentration of fetal bovine serum present in the medium was maintained at 10%. This serum-dependent DNA synthesis was completely inhibited when 10 mM hydroxyurea was also included in the medium, and bile ductular cells cultured in the continued presence of 1.0% fetal bovine serum showed only marginal DNA synthesis during 8 to 10 d of primary culture when compared with no-serum controls. Maximum rates of serum-dependent DNA synthesis were obtained when the bile ductular cells were cultured for 7 to 14 d on tissue culture plastic coated with obtained when the bile ductular cells were cultured for 7 to 14 d on tissue culture plastic coated with either fibronectin from bovine plasma or type I rat-tail collagen. Cells cultured on plastic coated with basement membrane Matrigel exhibited the lowest levels of DNA synthesis, whereas those on plastic alone had intermediate amounts. Furthermore, the addition of epidermal growth factor (50 ng·ml⁻¹·d⁻¹) to medium supplemented with 1.0% fetal bovine serum greatly enhanced the rate of DNA synthesis in bile ductular cells after 6 d in primary culture on type I collagen-coated plastic over that measured in solvent control cultures. These findings indicate that our bile ductular epithelial cell culture model is potentially useful in the study of biliary cell growth regulation and carcinogenesis. This investigation was supported by USPHS grant RO1 CA 39225 to A. E. Sirica by the National Cancer Institute, Department of Health and Human Services, Bethesda, MD. During the period of this study, G. A. Mathis was a recipient of a Fellowship from the Fund for Academic Career Development of the State of Zurich, Switzerland.     

Obligatory Relationship Between the Sterol Biosynthetic Pathway and DNA Synthesis and Cellular Proliferation in Glial Primary Cultures

Primary cultures of newborn rat brain, which are composed predominantly of astroglia, were used to examine the relationship between the sterol biosynthetic pathway and DNA synthesis and cellular proliferation. Reduction of the fetal calf serum content of the culture medium from 10 to 0.1% (vol/vol) for an interval of 48 h between days 4 and 6 in culture resulted in a quiescent state characterized by inhibition of DNA synthesis and cellular proliferation. When 10% fetal calf serum was returned to the medium for these quiescent cells, within 24 h DNA synthesis increased markedly. Preceding the rise in DNA synthesis was an increase in sterol synthesis, which occurred within 12 h of the return of the quiescent cells to the 10% fetal calf serum. Exposure of the quiescent cells to mevinolin, a specific inhibitor of sterol synthesis at the 3-hydroxy-3-methylglutaryl-CoA reductase step, completely inhibited the increase in DNA synthesis that followed serum repletion. The increase in total protein synthesis that followed serum repletion was not similarly inhibited by mevinolin. When mevinolin was removed after causing the 24-h inhibition of DNA synthesis, the cultured cells underwent active DNA synthesis and proliferation. Thus, inhibition of the sterol biosynthetic pathway resulted in a specific and reversible inhibition of DNA synthesis and glial proliferation in developing glial cells. These findings establish a valuable system for the examination of glial proliferation, i.e., primary glial cultures subjected to serum depletion and subsequent repletion. Moreover, the data establish an obligatory relationship between the sterol biosynthetic pathway and DNA synthesis and cellular proliferation in developing glia.     

Dolichol-Linked Glycoprotein Synthesis in G1 Is Necessary for DNA Synthesis in Synchronized Primary Cultures of Cerebral Glia

Primary cultures of newborn rat cerebrum, which are composed of glial cells (principally astroglia), were used for examining the relationship between dolichol-linked glycoprotein synthesis and DNA synthesis in developing cerebral glia. The cells were synchronized by reducing the content of fetal calf serum in the culture medium from 10 to 0.1% (vol/vol) for 48 h between days 4 and 6 in culture. Reversal of the quiescent state by return of the cultures to 10% serum causes a marked increase in DNA synthesis 12-24 h later. A sharp increase in glycoprotein synthesis (incorporation of [3H]mannose) occurred in the first 12 h after serum repletion, preceding the increase in DNA synthesis. Tunicamycin, an inhibitor of the dolichol-linked pathway to glycoprotein synthesis at the first committed step in oligosaccharide formation, promptly and completely prevented the increase in glycoprotein synthesis and, in addition, the subsequent increase in DNA synthesis. The effects of tunicamycin on glycoprotein and DNA syntheses were reversible, and no comparable effect on total protein synthesis was observed. When tunicamycin was added only during a temporally circumscribed period in G1, i.e., from 3 to 9 h after serum repletion, the increase in DNA synthesis between 12 and 24 h after repletion was still markedly inhibited, i.e., to approximately 45% of the value in untreated cultures. The data thus show that there is a requirement for dolichol-linked glycoprotein synthesis for the subsequent occurrence of DNA synthesis and that this requirement is expressed late in the G1 phase of the cell cycle.