Effects of N-monobutyryl-cyclic AMP on glutamate decarboxylase activity in fetal rat brain cells and glial tumor cells in culture

Cultures of fetal rat brain cells were treated chronically with 1 mM N⁶-monobutyryl-3′,5′-cyclic adenosine monophosphate and assayed at various times for protein and for activity of glutamate decarboxylase. Treated cultures increased their protein content very slowly, but showed a very early 2.5-fold stimulation of enzyme specific activity. This degree of stimulation persisted during temporal development of the enzyme activity. The stimulated levels of specific activity were nearly as great as those in adult rat brain homogenates. Similar treatment of cells from two rat gliomas, which also contain the enzyme activity, did not mimic the effect found in brain cultures. The effects on glutamate decarboxylase were very different from those on another enzyme of neurotransmitter synthesis, choline acetyltransferase, suggesting that different cell types may have been responsible for the two dissimilar effects of the treatment with the cyclic nucleotide.     

Effect of CDP-Choline on Hypocapnic Neurons in Culture

Neuronal cultures from chick embryo cerebral hemispheres were protected against a hypocapnic injury by adding to their growth medium 10(-6)M CDP-choline before or after the injury. The protection obtained with CDP-choline was analyzed by a morphometric analysis and showed that pretreatment of neuronal cultures with CDP-choline maintained the number of cell aggregates and of primary neuronal processes at control values after hypocapnic shock. Various experiments showed that the intact molecule was responsible for the protective action, since pretreatment with different concentrations of various nucleosides and nucleotides (up to 10(-5) M), choline, and phosphorylcholine was without protective effect. The addition of CDP-choline after the hypocapnic injury resulted in a protection of the cultures as shown by morphological observation. Incubation of neurons with radioactive choline showed that hypocapnia increased the incorporation of the label into phospholipids whereas the presence of CDP-choline reduced it. The de novo synthesis of choline was affected by neither hypocapnia nor CDP-choline treatment. The results indicate that CDP-choline may have the capacity to protect neurons under conditions of basic pH and that cellular proliferation may be stimulated by the compound.     

Studies on in vitro colony formation by mouse bone-marrow cells using different sources of colony-stimulating factor

Summary Conditioned media of a primary mouse embryo and a mouse cell line were compared as sources of colony-stimulating factor. The incorporation of embryo cell conditioned medium into semisolid cultures of mouse bone-marrow cells induced the formation of a larger number of in vitro colonies than did the addition of equal volumes of LM cell conditioned medium. This finding did not appear to be the result of quantitative differences in the levels of C.S.F. between the sources since concentration of the LM cell conditioned preparation did not enhance effectively the number of colonies produced. Both the colonial morphology and the cellular components of the developing colonies were found to differ in accordance with the C.S.F. source employed for stimulation. Colonies that developed under the influence of embryo cell conditioned medium were typically larger and more disperse than were those produced in cultures stimulated with the LM cell conditioned source. The latter colonies were smaller, more compact and contained fewer cells. Differences also were noted in the relative proportion of granulocytes to mononuclear cells comprising the colonies. Those colonies stimulated with LM cell conditioned medium rapidly underwent a transition from primarily a granulocytic composition to one comprised principally of mononuclear cells. Cultures stimulated with embryo cell conditioned medium contained a greater number of granulocytic colonies which persisted for a protracted period during cultivation. The addition of 2-mercaptoethanol to cultures stimulated with embryo cell conditioned medium increased the number of colonies produced. Such synergy did not occur in cultures stimulated with the LM cell conditioned medium. Supported by United States Public Health Service Research Grant CA 13752.     

Effects of Choline Depletion on the Circadian Rhythm in Neurospora crassa

One approach to identifying components of the circadian oscillator is to screen for clock defects in mutants with known biochemical lesions. The chol-1 mutant of Neurospora crassa is defective in the first methylation step of phosphatidylcholine synthesis, the conversion of phosphatidylethanolamine to phosphatidylmonomethylethanolamine, and requires choline for normal growth. Choline depletion of this mutant inhibits growth and lengthens the period of the rhythm of conidiation. On high levels of choline (above 20 µM), the growth rate and the period of the rhythm are normal. Below about 10 µM choline, the growth rate and period length depend on the choline concentration, and the period is about 58 h on minimal medium without choline. Choline depletion decreases period stability, and replicate cultures do not remain in phase due to variability in period within each culture. At intermediate levels of choline (around 10 µM) cultures are often arrhythmic. The choline requirement for growth can be met by the phosphatidylcholine precursors monomethylethanolamine and dimethylethanolamine, and these supplements also restore a normal period. Choline depletion of the chol-1 strain exaggerates the rhythm in growth rate previously reported in a chol + strain. Growth rate during formation of a conidial band (measured as forward advance of the mycelial front) is less than half of the maximum rate during non-conidiating interband formation. Choline-depleted cultures can be entrained to light/dark (LD) cycles with periods near to their free-running periods. Cultures on 10 µM choline (with a free-running period of about 25 h) can be entrained to a 24 h (12:12) LD cycle, but not to a 36 h (18:18) or 48 h (24:24) LD cycle. Cultures on 0.5 µM choline (free-running period of about 52 h) or minimal medium (free-running period of about 58 h) can be entrained to 18:18 and 24:24 LD cycles, but not a 12:12 cycle. The phase relationship of the conidiation rhythm to the zeitgeber for low-choline cultures in LD 24:24 is similar to high choline cultures in LD 12:12. Continuous light abolishes rhythmicity in choline-depleted cultures. These results may indicate a role for membrane phospholipids, and the metabolites of phosphatidylcholine in particular, in the control of the period of the circadian oscillator in Neurospora .     

Effects of Choline Depletion on the Circadian Rhythm in Neurospora crassa

One approach to identifying components of the circadian oscillator is to screen for clock defects in mutants with known biochemical lesions. The chol-1 mutant of Neurospora crassa is defective in the first methylation step of phosphatidylcholine synthesis, the conversion of phosphatidylethanolamine to phosphatidylmonomethylethanolamine, and requires choline for normal growth. Choline depletion of this mutant inhibits growth and lengthens the period of the rhythm of conidiation. On high levels of choline (above 20 µM), the growth rate and the period of the rhythm are normal. Below about 10 µM choline, the growth rate and period length depend on the choline concentration, and the period is about 58 h on minimal medium without choline. Choline depletion decreases period stability, and replicate cultures do not remain in phase due to variability in period within each culture. At intermediate levels of choline (around 10 µM) cultures are often arrhythmic. The choline requirement for growth can be met by the phosphatidylcholine precursors monomethylethanolamine and dimethylethanolamine, and these supplements also restore a normal period. Choline depletion of the chol-1 strain exaggerates the rhythm in growth rate previously reported in a chol + strain. Growth rate during formation of a conidial band (measured as forward advance of the mycelial front) is less than half of the maximum rate during non-conidiating interband formation. Choline-depleted cultures can be entrained to light/dark (LD) cycles with periods near to their free-running periods. Cultures on 10 µM choline (with a free-running period of about 25 h) can be entrained to a 24 h (12:12) LD cycle, but not to a 36 h (18:18) or 48 h (24:24) LD cycle. Cultures on 0.5 µM choline (free-running period of about 52 h) or minimal medium (free-running period of about 58 h) can be entrained to 18:18 and 24:24 LD cycles, but not a 12:12 cycle. The phase relationship of the conidiation rhythm to the zeitgeber for low-choline cultures in LD 24:24 is similar to high choline cultures in LD 12:12. Continuous light abolishes rhythmicity in choline-depleted cultures. These results may indicate a role for membrane phospholipids, and the metabolites of phosphatidylcholine in particular, in the control of the period of the circadian oscillator in Neurospora.     

Effects of cortisol on serially propogated fibroblast cell cultures derived from the rabbit retal lung and skin.

Cortisol affects the growth of serially propogated, fibroblast cell cultures derived from the rabbit fetal lung in a manner which is dependent upon the gestational age of the material used: early in gestation (20 days), the hormone (10(-7)-10(-5) M) stimulates [6-3H]thymidine incorporation into DNA, while in late gestation (28 days), cortisol (10(-7) and 10(-6) M) inhibits this process. Cultures derived from the rabbit fetal skin are inhibited by cortisol (10(-5) M) at both gestational ages. Fibroblasts derived from lung, but not from skin, efficiently convert cortisone to cortisol and this activity increases with advancing gestation. Cortisol does not affect the incorporation of [3H]choline into lecithin by confluent cultures of any of the fibroblast types studied.     

Increased multiplication of dengue virus in mouse peritoneal macrophage cultures by treatment with extracts of Ascaris-Parascaris parasites

Methylcellulose-elicited peritoneal macrophages from BALB/c mice were cultivated in vitro and inoculated with dengue virus (DV). At intervals thereafter portions of the culture fluids were taken and titrated for viral infectivity. Extracts from Ascaris suum and Parascaris equorum, either crude or Sephadex G-100 fractionated, were examined for effects on the multiplication of DV. The macrophage cultures treated with the above substances produced larger amounts of DV compared with untreated control cultures. The enhancing effect of the substances depended on doses added and duration of treatment and was suppressed by co-treatment with carrageenan, a specific macrophage-inhibiting agent, but was not related to the viability of cultured cells. In fluorescent antibody (FA) as well as infectious center assay experiments, it was shown that the DV-infected cells were found more frequently in treated cultures than in untreated control cultures. In the treated cultures phagocytosis by cultured cells was also of a higher magnitude than that in untreated cultures. In cocultures of macrophages and splenocytes from the same line of mice, no additive effect of splenocytes was noted. The limulus amebocyte lysate clotting enzyme reaction (Limulus test) indicated that involvement of bacterial lipopolysaccharides in the enhancement phenomena was negligible. The data so far obtained suggest that the enhancing effect was due to direct action of the parasitic extracts on macrophages. Four Sephadex G-100 fractions from the crude extracts showed similar activities; however, the effects of fractions I and III appeared to be comparatively strong. Significance of the findings in relation to the pathogenesis of DV infection was discussed.     

Regulation of phospholipid metabolism in differentiating cells from rat brain cerebral hemispheres in culture. Patterns of acetylcholine phosphocholine, and choline phosphoglycerides labeling from (methyl-14C)choline.

The uptake and metabolism of [14C]choline in dissociated rat brain embryo cell cultures was examined as a function of the extracellular choline concentration. Choline uptake did not follow normal Michaelis-Menten kinetics, but rather exhibited two components with apparent Km of 0.016 mM and 0.96 mM. At low choline concentrations (high affinity uptake) most of the [14C]choline label was present in the phosphocholine fraction prior to the appearance of label in phospholipids. At high choline concentrations (low affinity uptake) a large proportion of the radioactivity was converted into acetylcholine. The dissimilarities between the formation of phosphocholine and acetylcholine as a function of choline concentration might be explained by the existence of two mutually independent enzymatic activities with different Km affinities for choline. Kinetic data augmented by double label studies, suggested that formation of choline phosphoglyceride proceeds entirely via a phosphocholine intermediate. Nearly all radioactivity in the lipid fraction is incorporated into choline phosphoglycerides. A higher turnover rate of choline incorporation into choline phosphoglycerides, accompanied by an increase in the levels of glycerophosphocholine, was observed in older cultures as compared to younger cultures. The metabolic implications of these findings in cultured brain cells in comparison with other in vitro systems are discussed.     

Effect of anabolics on bovine granulosa-luteal cell primary cultures

Granulosa cell tumours are observed with increased frequency among calves slaughtered in Northern Italy. The use of illegal anabolics in breeding was taken into account as a cause of this pathology. An in vitro approach was used to detect the possible alterations of cell proliferation induced by anabolics on primary cultures of bovine granulosa-luteal cells. Cultures were treated with different concentrations of substances illegally used in cattle (17beta-estradiol, clenbuterol and boldione). Cytotoxicity was determined by means of MTT test, to exclude toxic effects induced by anabolics and to determine the highest concentration to be tested. Morphological changes were evaluated by means of routine cytology, while PCNA expression was quantified in order to estimate cell proliferation. Cytotoxic effects were revealed at the highest concentrations. The only stimulating effect on cell proliferation was detected in boldione treated cultures: after 48 h treated cells, compared to controls, showed a doubled expression of PCNA. In clenbuterol and 17beta-estradiol treated cells PCNA expression was similar to controls or even decreased. As the data suggest an alteration in cell proliferation, boldione could have a role in the early stage of pathogenesis of granulosa cell tumour in cattle.     

Increased ethylene and decreased phenolic compounds stimulate somatic embryo regeneration in leaf thin section cultures ofDoritaenopsis hybrid

The effects of endogenous levels of ethylene and phenolic compounds on somatic embryogenesis, medium-browning, and peroxidase activity were evaluated in thin section cultures ofDoritaenopsis. Cultures were maintained for 8 weeks with four different treatments: i) thick leaf segment culture, ii) thin leaf section culture, iii) thin leaf section culture with ventilation, or iv) thin leaf section culture after expiants were first washed. Expiants cultured in closed vessels produced a larger number of somatic embryos than those reared in the ventilated vessels. This enhanced formation confirmed the greater involvement of accumulated ethylene under non-ventilated conditions, because wound-induced tissues from thin leaf sections normally release high level of ethylene. When expiants were washed in the liquid medium and inoculated on the same solid medium, somatic embryo production was 1.7 and 18.5 times higher than in the thin section cultures and thick segment cultures, respectively. Reducing the level of phenolics in expiants at the initial stage of culturing apparently stimulated this embryo regeneration.     

Development and characterization of embryogenic suspension cultures of pecan

A method for the establishment and proliferation of developmentally stable, embryogenic suspension cultures in pecan is described, and the growth and development of cultures characterized. Suspension cultures were generated from somatic embryos derived from zygotic embryo cotyledon explants induced on a solidified medium with naphthaleneacetic acid. Cultures were repetitively embryogenic and proliferated in growth-regulator-free medium. The suspensions consisted of a mixture of globular stage embryo-aggregates, freely suspended globular embryos and pre-globular stage embryo masses. Culture growth and proembryo production were evaluated with respect to several liquid media and pH conditions. Significant differences in growth and productivity were observed between cultures. Pre-globular stage embryo masses collected on filter paper and overlaid on solidified medium continued ontological development and converted into plants. Thus a method has been developed for pecan suspension culture, which presents a major improvement in embryogenic tissue culture within the Juglandaceae. This revised version was published online in June 2006 with corrections to the Cover Date.     

Cell cultures derived from early zebrafish embryos differentiate in vitro into neurons and astrocytes

The zebrafish is a polular nonmammalian model for studies of neural development. We have derived cell cultures, initiated from blastula-stage zebrafish embryos, that differentiate in vitro into neurons and astrocytes. Cultures were initiated in basal nutrient medium supplemented with bovine insulin, trout serum, trout embryo extract and fetal bovine serum. After two weeks in culture the cells exhibited extensive neurite outgrowth and possessed elevated levels of acetylcholinesterase enzyme activity. Ultrastructural analysis revealed that the neurites possessed microtubules, synaptic vessicles and areas exhibiting growth cone morphology. The cultures expressed proteins recognized by antibodies to the neuronal and astrocyte-specific markers, neurofilament and glial fibrillary acidic protein (GFAP). Poly-D-lysine substrate stimulated neurite outgrowth in the cultures and inhibited the growth of nonneuronal cells. Medium conditioned by the buffalo rat liver line, BRL, promoted the growth and survival of the cells in culture. Mitotically active cells were identified in cultures that had undergone extensive differentiation. The embryo cell cultures provide an in vitro system for investigations of biochemical parameters influencing zebrafish neuronal cell growth and differentiation.     

Thyrotropin-Releasing Hormone Enhances Choline Acetyltransferase and Creatine Kinase in Cultured Spinal Ventral Horn Neurons

The effect of 0.1 mM thyrotropin-releasing hormone (TRH) on ventral horn neurons was investigated in eight experimental sets of tissue cultures established from ventral and dorsal portions of spinal cords of 13-15-day rat embryos. Cultures were treated with TRH from day 1 for 2-5 weeks. TRH-treated ventral spinal cord cultures (VSCC), compared with control VSCC, had more numerous and more healthy-appearing neurons and thicker bundles of long cell processes. In TRH-treated VSCC, choline acetyltransferase (ChAT) activity was greater than 16 times (p less than 0.005) and creatine kinase greater than 3 times (p less than 0.005) that of control VSCC. Morphologic and biochemical parameters of dorsal spinal cord cultures remained unchanged by TRH treatment. Since lower motor neurons are numerous in the ventral spinal cord (and not present in the dorsal cord) and since lower motor neurons are the major ChAT-containing spinal cord cells, our data demonstrating a beneficial effect of TRH on VSCC suggest a tropic effect of TRH on lower motor neurons.     

Microtubules, microfilaments and the transport of acetylcholine receptors in embryonic myotubes

Both microtubules and microfilaments have been implicated in the exocytotic and endocytotic transport of coated and smooth surfaced membrane vesicles. We have reexamined this question by using specific pharmacological agents to disrupt these filaments and assess the effect on the movement of acetylcholine receptor (AChR) containing membrane vesicles in embryonic chick myotubes. Myotube cultures treated with nocodazole (0.6 microgram/ml) or colcemid (0.5 microgram/ml) (to disrupt microtubules) show only a 20-25% decrease in the number of cell surface AChRs after 48 h. Addition of chick brain extract (CBE) to cultured myotubes causes a significant increase in the total number of cell surface AChRs (measured by [125I]alpha-bungarotoxin (alpha-BGT) binding), thus providing us with a way to manipulate receptor and transport vesicle populations. Cultures treated with CBE plus nocodazole or colcemid show a 1.7-fold increase in AChR number over drug treatment alone, the same increase seen in cultures treated with CBE alone, although the total number remains about 20-25% less than that seen in control cultures. In cultures treated with cytochalasin D (0.2 microgram/ml) or dihydrocytochalasin B (5.0 micrograms/ml) (to disrupt microfilaments), 35 and 65% decreases in cell surface AChR number were seen after 48 h. However, in cultures treated with CBE and cytochalasin D, the same total number of AChRs was found as in cultures treated with CBE alone. No significant effects were seen with any of these drugs on the receptor incorporation rate (the appearance of new alpha-BGT-binding sites) after 6 h. The half-life for AChRs in control cultures was 23.0 h. In cytochalasin D and dihydrocytochalasin B it was 21.9 and 19.0 h, respectively; with colcemid and nocodazole, it increased to 37.1 and 28.1 h. These results suggest that non-myofibrillar microfilament bundles are not involved in the movement of AChR-containing membrane vesicles; further, the small effects seen with microtubule inhibitors tend to rule out a major role for microtubules in this transport.     

7,12-Dimethylbenz[a]anthracene-DNA adduct formation in Wistar rat and Syrian hamster embryo cell cultures

The binding of 7,12-dimethylbenz[a]anthracene (DMBA) to DNA was examined in Syrian hamster and Wistar rat embryo cell cultures exposed to DMBA for 5, 24, 48 and 72 h. The level of binding of DMBA to DNA was about twice as great in the hamster embryo cells as in the rat embryo cells at all times. Analysis of the DMBA-deoxyribonucleoside adducts by immobilized boronate chromatography demonstrated that the ratio of adducts with no cis vicinal hydroxyl groups to those containing cis vicinal hydroxyl groups was much greater in the rat embryo cells (from 2.2:1 to 2.9:1) than in the hamster embryo cells (from 1.3:1 to 1.6:1). The hamster embryo cells contained three major DMBADE-DNA adducts: based upon their chromatographic behavior and comparison with the three major DMBA-DNA adducts described by Dipple et al. in mouse embryo cell cultures (Biochemistry, 24 (1985) 2291), two were tentatively identified as resulting from the reaction of anti-DMBADE (the isomer of 1,2-epoxy-3,4-dihydroxy-1,2,3,4-tetrahydro-DMBA with the epoxide and benzylic hydroxyl on the opposite faces of the molecule) with deoxyguanosine and deoxyadenosine and one adduct resulted from reaction of syn-DMBADE (epoxide and benzylic hydroxyl on the same face of the molecule) with deoxyadenosine. The anti-DMBADE-deoxyguanosine, syn-DMBADE-deoxyadenosine, and anti-DMBADE-deoxyadenosine adducts were present in hamster embryo cell DNA in a ratio of 1.2:2:1. The Wistar rat embryo cell DNA contained a much larger proportion of the syn-DMBADE-deoxyadenosine adduct. The relative proportions of the three major DMBA-DNA adducts in Syrian hamster embryo cells were similar at all times, but the proportion of syn-DMBADE-deoxyadenosine adduct decreased slightly with time in the rat embryo cells. These results indicate that there are species specific differences in the stereospecificity of activation of DMBA to DNA-binding diol epoxides which parallel those observed for benzo[a]pyrene (BaP). The high proportion of deoxyadenosine adducts suggests that they may have an important role in the induction of biological effects by DMBA.     

Neural tube-derived factors influence differentiation of neural crest cells in vitro: effects on activity of neurotransmitter biosynthetic enzymes

Previously, we have demonstrated that a factor present in chick embryo extract or medium conditioned by neural tube cells supports adrenergic differentiation of some neural crest cells in vitro. These studies have been extended here to examine the effects of this factor(s) on the development of enzymes involved in neurotransmitter biosynthesis. The time course of expression of choline acetyltransferase (ChAT), a marker for cholinergic cells, and dopamine-beta-hydroxylase (DBH), a marker for adrenergic cells, was examined in neural crest cell cultures grown under three conditions: in medium containing 10% embryo extract, in medium containing 2% embryo extract, and in medium containing 2% embryo extract that was conditioned by neural tube cells (NTCM). Significant levels of DBH activity were measured in neural crest cell cultures grown in 10% embryo extract containing medium or in NTCM, while only low levels were present in cultures grown in medium containing 2% embryo extract. In contrast, ChAT activity was inhibited by NTCM in comparison to levels in both 10 and 2% embryo extract containing medium. As a preliminary characterization of the factor(s) present in chick embryo extract, we have fractionated embryo extract and find that a pool of 10 kDa or less can support adrenergic differentiation of some neural crest cells. These results suggest that low molecular weight factors present in embryo extract and NTCM support adrenergic expression of neural crest cells, whereas NTCM suppresses cholinergic expression.     

Uptake and metabolism of choline in primary isolated neurons and glial cells in culture

The influx and metabolism of choline have been studied in primary cultures of isolated neurons and glial cells from chick embryo dissociated cerebral hemispheres. The results showed a correlation between both influx and metabolism of choline and the exogenous concentrations of choline. When neurons and glial cells were preincubated (10 min) and incubated in Krebs-Ringer phosphate solution with concentrations of choline lower (0.5 μM) or higher (150 μM) than the one present in the growth medium, the metabolism of choline, as a function of time, approached saturation following unusual kinetics. This suggests a non steady state of the endocellular concentrations of free choline. Moreover, when both neurons and glial cells were preincubated (10 min) with 50 μM choline and then incubated (2 min) with various concentrations of choline, only one uptake mechanism was measured, while the preincubation in the absence of choline followed by the incubation of the cells with various concentrations of choline showed the presence of two apparent K_m's with different affinities.The results also indicate the capacity of glial cells to incorporate choline suggesting a storage function for the cells.     

Transformation of chick fibroblast cultures with avian myeloblastosis virus

Cellular transformation was induced with avian myeloblastosis virus strain BAI-A (standard AMV) and with a strain of AMV containing subgroup B only. Cultures of muscle tissues from either chick embryo or day old chicks were used for this study. Results were similar in C/O and C/A cells. Leukemogenic virus was continuously produced by these transformed cultures.     

Reversible alterations in the mitotic cycle of chick embryo cells in various states of growth regulation

Chick embryo cells which have been kept overnight at pH 6.8 in the absence of serum multiply very slowly. Only a small fraction of cells is in the S period at any given time, and the rate of uptake of 2-deoxy-D-glucose is very low. Upon raising the pH to 7.4 and adding serum (“turn-on”) the uptake of 2-deoxy-D-glucose increases immediately; the rate of DNA synthesis increases after a lag of about 4 hours, and represents an increase in the fraction of cells synthesizing DNA. The uptake of 2-deoxy-D-glucose is rapidly returned to its original low rate at any time by again lowering the pH and removing serum (“turn-off”). The synthesis of DNA in the culture remains constant or continues to rise at a markedly reduced rate following the same treatment. Lowering pH or removing serum independently of each other is less efficient at inhibiting the increase in DNA synthesis than the combined treatment but each accomplishes a similar result. Cultures which have been “turnedoff” during the early stages of the rapid increase in DNA synthesis, resume their prior rate of increase immediately if “turned-on” again within 2.5 hours. If the cultures have been “turned-off” for 5.5 hours before restoring the “turn-on,” there is a 2 hour delay before they resume an increased rate of DNA synthesis. The results indicate that chick embryo cells do not become committed to the initiation of DNA synthesis until shortly before, or at the time of the onset of the S period. Up to 96% of the cells in post-confluent cultures growing in conventional medium become labeled upon continuous, prolonged exposure to ³H-thymidine. Seventy-eight percent of the cells in serum-deprived cultures growing at a very low rate become labeled. These and other considerations suggest that the inhibition of cell multiplication by high population density or serum deprivation is caused by a lengthening of the time cells remain in the prereplicative G₁ period rather than by shifting cells into a qualitatively distinct G₀ period. There may, however, be a period common to all cells regardless of growth rate, in which cells are not progressing toward the S period. The length of this variable period would then determine the growth rate of a population of cells.     

Increased susceptibility of murine teratocarcinoma cells to Simian virus 40 and polyoma virus following treatment with 5-bromodeoxyuridine.

Cultures of the multipotential stem cell, embryonal carcinoma (EC), of a murine teratocarcinoma were treated with 5-bromodeoxyuridine (BrdU). Within 2-4 days at concentrations of 1-50 mugm/ml of BrdU, there was a marked change in the morphology of cells observed by light and electron microscopy. A comparison of the growth potential showed that for up to four days the BrdU-treated cultures were similar to untreated cultures. When these BrdU-treated cells were infected with Simian virus 40 (SV40) and polyoma virus (Py), there was an increase in susceptibility of the treated cells. The untreated embryonal carcinoma cells were refractory. These results suggest that BrdU modifies the embryonal carcinoma cells to allow infection with two DNA viruses.