THE SYNTHESIS OF CHOLINE PHOSPHOGLYCERIDES IN THE GIANT FIBRE SYSTEM OF THE SQUID

The mechanisms and pathways of synthesis of phosphatidylcholine in the giant fibre system of the squid (Loligo vulgaris) have been examined by incubating the stellate ganglion-nerve preparation or its separated compartments in an artificial bathing solution with labelled choline. Other experiments were done by dissecting the whole stellate ganglion into axoplasm, axon sheath, giant fibre lobe, small fibres and ganglion residue, after incubation. The initial rate of choline incorporation into choline phosphoglycerides was severalfold higher in the lobe than in the axon. Higher lipid radioactivity was recovered in the axon sheath as compared to the axoplasm, and in the small fibres as compared to the ganglion residue which contains its cell bodies. The production of phosphorylcholine and CDP-choline in the intact ganglion-nerve preparation during incubation with choline points to the occurrence of the net synthesis pathway for phosphatidylcholine in this material. Base-exchange activity was also observed in the axon and giant fibre lobe preparations in vitro, but no indication can yet be given whether it also takes place in intact preparations. Electrical stimulation and‘depolarizing’conditions enhance choline phosphorylation in the squid axon and lobe, but decrease phosphatidylcholine labelling.     

The synthesis of choline and ethanolamine phosphoglycerides in neuronal and glial cells of rabbit in vitro

Abstract— The de novo synthesis of phosphatidylcholine and phosphatidylethanolamine in isolated neuronal and glial cells from adult rabbit brain cortex was investigated in vitro, using labelled phosphorylcholine (phosphorylethanolamine) or cytidine-5′-phosphate choline (cytidine-5′-phosphate ethanolamine), as lipid precursors. Synthesis of phospholipid from phosphorylcholine and phosphorylethanolamine in both fractions was extremely low when compared to that derived from the corresponding cytidine nucleotides. The neuronal cell-enriched fraction was found to possess a much higher rate of synthesis of both lipids from all precursors. Neuronal/glial ratios of about 5–9 were found for the synthesis of phosphatidylcholine and phosphatidylethanolamine from cytidine-5′-phosphate choline and cytidine-5′-phosphate ethanolamine, respectively. Several kinetic properties of the choline-phosphotransferase (EC 2.7.8.2) and ethanolaminephosphotransferase (EC 2.7.8.1) were found to be similar both in neurons and in glia (e.g. K_m of cytidine-5′-phosphate ethanolamine, K_m of diacyl glycerol, pH optimum, need for divalent cations), but the K_m value for cytidine-5′-phosphate choline in glial cells was much lower (2.3 × 10^?4m ) than in neurons (1 × 10^?3m ). The K_mfor cytidine-5′-phosphate ethanolamine in both cells was much lower than in whole brain microsomes. It is concluded that the cytidine-dependent enzymic system for phosphatidylcholine and phosphatidylethanolamine synthesis is concentrated mostly in the neuronal cells, as compared to glia.     

Choline metabolism and membrane formation in rat hepatoma cells grown in suspension culture. 3. Choline transport and uptake by simple diffusion and lack of direct exchange with phosphatidylcholine

The initial rate of incorporation of methyl-labeled choline into the acid-soluble pool (phosphorylcholine) of Novikoff hepatoma cells growing in suspension culture was investigated as a function of the choline concentration in the medium. Below, but not above, 20 micro m, choline incorporation followed simple Michaelis-Menten kinetics at 24, 33, or 37 degrees C with an apparent K(m) of 4-7 micro m, and the V(max) values decreased with a Q(10) of about 2.3 with a decrease in temperature. Between 20 and 500 micro m, on the other hand, the rate of incorporation increased linearly with an increase in choline concentration in the medium, and the increase in incorporation rate with increase in choline concentration was about the same at all temperatures tested. The data suggest that at low concentrations choline is taken up mainly by a transport reaction, whereas at concentrations above 20 micro m, simple diffusion becomes the principal mode of uptake. The energy of activation for choline transport was estimated from an Arrhenius plot of the V(max) values as 67,000 J (16 kcal)/mole. At concentrations below 20 micro m, choline incorporation into membrane phosphatidylcholine also followed simple Michaelis-Menten kinetics, and the apparent K(m) was about the same as that for choline transport. The data support the conclusion that the transport of choline into the cell is the rate-limiting step in the conversion of choline to phosphorylcholine and its incorporation into phosphatidylcholine. At concentrations above 100 micro m, on the other hand, the ultimate rate of choline incorporation into phosphatidylcholine was independent of the choline concentration in the medium or the intracellular level of phosphorylcholine. Further, the rate of turnover of the choline moiety of phosphatidylcholine (half-life, 20-24 hr) either in whole cells or during incubation of isolated membrane fractions was unaffected by the presence of an excess of choline in the medium. The overall results indicate that a direct exchange between free choline and the choline moiety of phosphatidylcholine does not play a significant role in the incorporation of choline into phosphatidylcholine by Novikoff cells or in the turnover of the choline moiety of phosphatidylcholine, and that labeled choline therefore is a useful precursor in studying the synthesis and turnover of membrane phosphatidylcholine in these cells.     

FORMATION OF MITOCHONDRIA IN NEUROSPORA CRASSA : A Study Based on Mitochondrial Density Changes

The choline concentration used in the growth medium influences the density of mitochondria produced by the chol-1 mutant of Neurospora. Isopycnic centrifugation in sucrose gradients can be used to determine the density of mitochondria, and can resolve into two populations, mitochondria derived from a mixture of cells grown at low (1 µg/ml choline chloride) and high (10 µg/ml choline chloride) choline levels. In an experiment in which cells are shifted from low to high choline growth conditions, mitochondria obtained after varying time periods show a gradual decrease in density tending toward the level typical of high choline mitochondria. Over a 90-minute period of observation, during which time there is an increase of mitochondrial protein mass of ~ 50 per cent over that initially present, the mitochondria change density as a single population. These results are consistent with the view that mitochondria grow by random accretion of new lecithin into existing mitochondrial structures, and also that the mitochondrial population increases by division.     

The oxidation of choline by liver slices and mitochondria during liver development in the rat

Betaine is the major oxidation product of [Me-¹⁴C] choline produced by rat liver slices. Liver slices from adult rats rapidly oxidize [Me-¹⁴C] choline to betaine and the bulk of the betaine produced is recovered in the incubation medium. Considerably more choline is oxidized to betaine than is phosphorylated to phosphorylcholine. The rate of phosphorylation of choline appears to be independent of the rate of choline oxidation. Liver slices from fetal and young rats oxidize choline to betaine at a lower rate than adult liver slices.The ability of mitochondria to oxidize [Me-¹⁴C] choline to betaine aldehyde and betaine is considerably lower in fetal liver than in adult liver. The major product with both fetal and adult mitochondria is betaine aldehyde. Choline oxidation by mitochondria begins to increase 1 day prior to birth and increases progressively to adult levels by 18 days. The developmental pattern for choline oxidation is similar to the pattern for succinic dehydrogenase activity.     

The effects of insulin on choline kinase activity in cultured rat liver cells

The effect of insulin on phosphatidylcholine biosynthesis in cultured rat liver cells was assessed by measuring changes in the activity of the first enzyme in the choline pathway of phosphatidylcholine biosynthesis, choline kinase (ATP: cholinephosphortransferase, EC 2.7.1.32), in the presence or absence of the hormone. Choline kinase specific activity in liver cells incubated for 18 hours in the presence of 10^?7M insulin increased two-fold from 3.4 ± 0.3 nmoles phosphorylcholine formed/min/mg protein to 7.5 ± 0.6 nmoles/min/mg protein. This effect was dose dependent and reversed by the addition of actinomycin D and cycloheximide. It is concluded that the increase in specific activity is due to synthesis of new enzyme rather than activation of existing enzyme.     

The migration of labeled phosphatidylcholine from the nuclear-associated endoplasmic reticulum to plasma membranes in L-929 cells

Summary The nuclear-associated endoplasmic reticulum of L-929 cells was found to contain the highest amount of labeled phosphatidylcholine after a 60 min incubation with¹⁴C-choline. Radioactivity was otherwise distributed relatively evenly among other membrane-containing organelles (nuclei, mitochondria, plasma membranes and endoplasmic reticulum membranes). During a 120 min chase following removal of isotope and addition of cold choline chloride, there was a considerable reduction in labeled phosphatidylcholine in the NER and nuclei. The decrease in radioactivity in these fractions was matched by an almost identical increase in the fraction containing mitochondria and plasma membranes. Separation of mitochondria and plasma membranes by centrifugation on discontinuous gradients showed that¹⁴C-choline labeled phosphatidylcholine appeared most rapidly in the plasma membranes. The results indicate that phospholipid molecules migrate within a short period of time from their site of synthesis in the NER to plasma membranes.     

Evidence for a regulatory role of CTP : choline phosphate cytidylyltransferase in the synthesis of phosphatidylcholine in fetal lung following premature birth

The sequence of reactions which function to incorporate choline into phosphatidylcholine was investigated in lung from fetuses following premature delivery. The rate of [methyl-14C]choline incorporation by rat lung slices into phosphatidylcholine increases following premature delivery at both 20 and 21 days gestation. The increase in choline incorporation is primarily due to an increased specific activity of phosphorylcholine resulting from a decreased pool size of phosphorylcholine. The decrease in the concentration of phosphorylcholine following premature delivery is apparently caused by an increased activity of cytidylyltransferase which leads to an increase in the conversion of phosphorylcholine to phosphatidylcholine. The total activity of choline kinase, cytidylyltransferase, cholinephosphotransferase and phosphatidate phosphohydrolase did not change significantly. However, the cytidylyltransferase activity in the microsome fraction increased following premature delivery at 20 and 21 days gestation. The amount of cytidylyltransferase in the H form in the cytosol fraction increased following premature delivery at 21 days gestation but not at 20 days gestation. The results are interpreted to indicate that the active form of cytidylyltransferase in lung cells is the membrane-bound enzyme and this form increases following birth resulting in an increased synthesis of phosphatidylcholine.     

Canine spinal cord energy state after in situ freezing

[Methyl-³H]choline has been injected intraventricularly into adult rabbits, and the rate of synthesis of phosphatidylcholine, choline plasmalogen and sphingomyelin (and their hydrosoluble precursors) in isolated neuronal and glial cells has been investigated. At all time intervals examined, the injected radioactivity was incorporated only into the base moiety of the choline lipids in both cell types. Maximum labelling of the two choline phosphoglycerides occurred in neurons 150 min after administration, whereas the highest specific radioactivity for glial phosphatidylcholine and choline plasmalogen was reached at 6 and 10 h, respectively. At any time interval examined, the neuronal and glial choline plasmalogen displayed a higher specific radioactivity than the corresponding diacyl-derivative. The two phosphoglycerides incorporated the base in both cell populations at a faster rate than did whole brain tissue. Sphingomyelin was labelled in both cells at a low rate and acquired measurable radioactivity levels only after 2 h from isotope administration. Highest levels of radioactivity for phosphorylcholine and cytidine-5′-diphosphocholine were reached in both neurons and glia 1-2 h after administration, but these levels per unit protein were higher in glial than in neuronal cells.     

Phospholipid metabolism in roots and microsomes of sunflower seedlings: Inhibition of choline phosphotransferase activity by boron

The action of boron on phospholipid composition and synthesis in roots and microsomes from sunflower seedlings has been studied. The fatty acid composition and relative amounts of individual molecular species of phospholipids in roots and microsomes were very similar. In both the content of phospholipids was decreased and the relative levels of their component fatty acids changed by treatment with 50 ppm of boron. This concentration of boron in the culture medium was found to inhibit the in vivo [1-^14C] acetate incorporation into root lipids and that of [Me-¹⁴C] choline into phosphatidylcholine of root microsomes. Cytidine-5-diphospho (CDP)-[Me-¹⁴C] choline incorporation into phosphatidylcholine of isolated microsomes was also inhibited by 50 ppm of boron when present in the growth medium of seedlings. These results indicate that the decrease in phosphatidylcholine labelling from [¹⁴C] choline observed when root microsomes were treated with boron would be caused by a decrease in CDP-choline phosphotransferase activity.     

Insulin stimulates turnover of phosphatidylcholine in rat adipocytes

The present study investigated the effect of insulin on phosphatidylcholine turnover in rat adipocytes labelled to equilibrium with [¹⁴C]-choline. Insulin induced a rapid turnover of this major phospholipid that was maximal by 1 min and transient in nature. Following a 1 min stimulation of the cells with insulin at a maximally effective concentration (7 nM), a 4–6% decrease in the percentage of total cellular choline associated with this phospholipid was observed. This reflected a significant transient increase in the percentage of total cellular choline associated with phosphorylcholine, which together with diacylglycerol are the phospholipase C cleavage products of phosphatidylcholine. These effects were observed over a physiological range of insulin concentrations. No effect of insulin on any other choline phospholipid or metabolite (sphingomyelin, lysophophatidylcholine, glycerophosphocholine or choline) was seen. These results suggest that insulin stimulates a phospholipase C-mediated turnover of phosphatidylcholine in rat adipocytes. The rapid nature of this turnover suggests a potential role in signal transduction.     

Effect of Mengovirus Replication on Choline Metabolism and Membrane Formation in Novikoff Hepatoma Cells

Infection of Novikoff rat hepatoma cells (subline NlSL-67) with mengovirus resulted in a two- to threefold increase in the rate of choline incorporation into membrane phosphatidylcholine at about 3 hr after infection, without affecting the rate of transport of choline into the cell or its phosphorylation. The time course of virus-stimulated phosphatidylcholine synthesis was compared with the time courses of other virus-induced processes during a single cycle of replication. The formation of viral ribonucleic acid (RNA) polymerase and of viral RNA commenced about 1 hr earlier than the virus-stimulated choline incorporation. Further, isopycnic centrifugation of cytoplasmic extracts indicated that the excess of phosphatidylcholine synthesized by infected cells is not located in the membrane structures associated with the viral RNA replication complex, but with structures of a lower density (1.08 to 1.14 g/cc). These membrane structures probably represent the smooth vesicles which accumulate in the cytoplasm of infected cells during the period of increased phosphatidylcholine synthesis between 3 and 5 hr after infection. They are formed with both newly synthesized phosphatidylcholine and phosphatidylcholine present prior to infection. However, concomitant protein synthesis is not required for the stimulated synthesis of membranes; the effect was not inhibited by treating the cells with inhibitors of protein synthesis at 3 hr after infection, although virus production was inhibited about 90% and virus-induced cell degeneration was markedly reduced and delayed. Production of mature virus began normally at about the same time as the stimulation of phosphatidylcholine synthesis. Treatment of infected cells with puromycin at 2 hr, on the other hand, completely inhibited the stimulation of phosphatidylcholine synthesis.     

Anabolic action of prolactin on phosphatidylcholine metabolism in guinea pig adrenocorticocytes]

Isolated adrenocortical cells of guinea pigs whom injected with prolactin (PRL) during 3 days incorporated [3H] choline into phosphatidylcholine more intensively than those cells of animals in control. Labelling of intracellular pools of choline and phosphorylcholine remained unchanged, though a part of radioactivity represented by the water-soluble precursors decreased due to PRL influence. The rate of disappearance of labelled phosphatidylcholine in adrenocortical cells prelabelled with [3H] choline was lower in cells obtained from PRL-treated animals. The discharge of [3N] choline accumulated during prelabeling accelerated simultaneously. Rate of the phosphorylcholine radioactivity fall remained unchanged. The obtained data showed that prolonged influence of PRL caused a shift of the phosphatidylcholine metabolism to anabolism. That effect might be a part of the mechanism of proliferative PRL action in the adrenal cortex.     

CHOLINE AND ACETYLCHOLINE IN RATS: EFFECT OF DIETARY CHOLINE

Abstract– The concentration of free choline in peripheral tissues (duodenum, heart, kidney, liver, stomach and plasma) of rats was found to be related to the amount of free choline in the diet. Under steady-state conditions, the concentration of free choline in plasma varied from a minimum of approx 6 nmol/ml (in rats fed a choline-deficient diet) to a maximum value not exceeding 21 nmol/ml. The concentration of plasma choline was elevated above 21 nmol/ml for a short time after parenteral administration of choline chloride or one of its precursors (CDP choline or phosphorylcholine), but was not affected by stress, endocrine manipulations, drug treatments or the time of day when rats were killed. The metabolism of intravenously administered [methyl-³H] choline was accelerated in peripheral tissues (except plasma) of choline-deficient rats, indicating that free choline is not preserved during choline deficiency by a reduction in its rate of turnover. Furthermore, the decrease in concentration of plasma choline that occurred in rats fed a choline-deficient diet was prevented by addition of deanol (dimethylaminoethanol) to the diet. These results indicate that free choline in peripheral tissues of rats is derived from both free choline in the diet, and from precursors of choline present within the diet. In contrast to the effects in peripheral tissues, the concentration of free choline in brain was not reduced by dietary deprivation of free choline; however, the increase in free choline that occurred when rats were decapitated was reduced in brains by deficiency of choline, suggesting a decrease in the concentration of esterified forms of cerebral choline. The concentration of acetylcholine was not reduced in the brain, duodenum, heart, kidney or stomach of 21-week old rats raised from birth on a choline-deficient diet, in the duodenum of rats given a choline-deficient diet for 1, 5 or 11 days, or in brains of rats deprived of free choline for 1 or 11 days. However, the rate of in vivo synthesis of ACh from [methyl-³H]choline was accelerated in cholinergic tissues that were depleted of free choline (i.e. duodenum, heart and stomach).     

Phosphatidylcholine Metabolism in Nuclei of Phorbol Ester-Activated LA-N-1 Neuroblastoma Cells

The agonist stimulation of a variety of cells results in the induction of specific lipid metabolism in nuclear membranes, supporting the hypothesis of an important role of the lipids in nuclear signal transduction. While the existence of a phosphatidylinositol cycle has been reported in cellular nuclei, little attention has been given to the metabolism of phosphatidylcholine in nuclear signaling. In the present study the metabolism of phosphatidylcholine in the nuclei of neuro-blastoma cells LA-N-1 was investigated. The incubation of LA-N-1 nuclei with radioactive choline, phosphocholine or CDP-choline led to the production of labelled phosphatidylcholine. The incorporation of choline and phosphocholine but not CDP-choline was enhanced in nuclei of TPA treated cells. Moreover the presence of choline kinase, phosphocholine cytidylyltransferase and phosphocholine transferase activities were detected in the nuclei and the TPA treatment of the cells stimulated the activity of the phosphocholine cytidylyltransferase. When cells prelabelled with [³H]palmitic acid were stimulated with TPA in the presence of ethanol, an increase of labelled diacylglycerol and phosphatidylethanol in the nuclei was observed. Similarly, an increase of labelled diacylglycerol and phosphatidic acid but not of phosphatidylethanol occurred in [³H]palmitic acid prelabelled nuclei stimulated with TPA in the presence of ethanol. However the production of phosphatidylethanol was observed when the nuclei were treated with TPA in the presence of ATP and GTPS. The stimulation of [³H]choline prelabelled nuclei with TPA also generated the release of free choline and phosphocholine. The results indicate the presence of PLD and probably PLC activities in LA-N-1 nuclei and the involvement of phosphatidylcholine in the production of nuclear lipid second messengers upon TPA stimulation of LA-N-1 cells. The correlation of the disappearance of phosphatidylcholine, the production of diacylglycerol and phosphatidic acid with the stimulation of phosphatidylcholine synthesis in nuclei of TPA treated LA-N-1 suggests the existence of a phosphatidylcholine cycle in these nuclei.     

Digestion of phosphatidylcholines,absorption, and esterification of lipolytic products by Aeshna cyanea larvae as studied in vivo and in vitro

Digestion and absorption of phosphatidylcholine by Aeshna cyanea larvae were studied in vivo and in vitro with the isolated digestive juice and isolated midgut. The experiments were performed with stable ether analogues (1-alkyl-2-acyl-,1,2-dialkyl phosphatidylcholine, and 1-monoalkyl-lysophosphati-dylcholine), with radioactive 1,2-diacylphosphatidylcholine alternatively labelled in the acyl- and choline moieties, and with several phosphatidylcholine derivatives (1-[1-¹⁴C]acyl- and 1-[³H] alkyl-lysophosphatidylcholine, [1-¹⁴C]oleic acid, [2-¹⁴C]glycerol, phosphoryl[methyl-¹⁴C]choline, and [methyl-¹⁴C]choline). Chromatographic analyses of the digestion products revealed that phosphatidylcholine was degraded via two interconnected hydrolytic pathways involving phospholipase C, phospholipase A₂, lipase, and alkaline phosphatase. Complete hydrolysis by these pathways yielded the same four end products: free fatty acid, glycerol, choline, and P_i, which were absorbed by the midgut enterocytes. Of the intermediate hydrolysates, lysophosphatidylcholine, monoacylglycerol, and possibly phosphorylcholine were also absorbed. Radiolabelled oleic acid, glycerol, lysophosphatidylcholine and monoacylglycerol (as judged from monoalkylglycerol absorption) were incorporated into phospholipids and acylglycerols of the midgut enterocytes and were released into the haemolymph primarily in the form of diacylglycerols. In the case of glycerol ingestion, a small fraction of haemolymph radioactivity was associated with free glycerol and glycerolphosphate. After absorption by the enterocytes, radiolabelled choline was partly oxidized to betaine, partly phosphorylated, and partly incorporated into lyso- and phosphatidylcholine. It was recovered from the haemolymph predominantly as free choline, phosphorylcholine, and betaine. Arch. Insect Biochem. Physiol. 36:273–293, 1997. © 1997 Wiley-Liss, Inc.     

Tyrosinase activities of cell-free extracts and living cells of cultured melanoma cells

Melanogenesis in the course of monolayer culture of a stably melanotic clonal line C₂M, derived from a mouse melanoma B 16, was investigated. Tyrosinase activity per cell of cell-free extracts was highest when the extract was prepared from cells in the mid-exponential phase of growth, when it was more than 6 times the activity of that prepared from a fully grown culture or a culture in the very early phase. On the other hand, the enzyme activity per cell of living cells in culture was highest in the early phase of culture and decreased rapidly to a level of less than one tenth of the maximum activity, in the stationary phase.The upper limit of population density of cultured melanoma cells permissive for melanin synthesis (2 to 3 × 10⁵ cells/cm²) was much higher than that of normal (nonneoplastic) melanocytes, which had been reported to produce melanin only under conditions of clonal growth.The relative efficiency of tyrosinase activity in situ, expressed by the ratio of tyrosinase activity in culture to that of cell-free extract, decreased rapidly in the exponential phase of growth. This decrease correlates to the cell density in the culture, and little if at all to the division rate, and suggests a suppressing mechanism of melanin synthesis working at the enzyme level.     

Induction of polyamine limitation in Chinese hamster ovary cells by α-methylornithine

Chinese hamster ovary (CHO) cells in culture were limited for polyamines through the use of α-methylornithine (αMO), a competitive inhibitor of ornithine decarboxylase. Initial exposure of the cells to the inhibitor caused growth rate and intracellular polyamine content to decline continuously. Reseeding the αMO-treated cells into medium containing the inhibitor resulted in steady-state (exponential) growth at cell densities below 5 × 10³ cells/cm², at a rate approximately twofold slower than untreated cells. Under these conditions, putrescine and spermidine were undetectable and spermine remained relatively constant at a level approximately half that found in untreated cells. Addition of exogenous putrescine elevated the polyamine content and stimulated the growth of αMO-treated cultures. Thus, growth rate correlated with polyamine content in the αMO-treated cells. The growth of reseeded. αMO-treated cells became nonexponential at a density (5 × 10³ cells/cm²) far below that at which untreated cells departed from exponential growth (1 × 10⁵ cells/cm²). Medium obtained from high density, αMO-treated cultures inhibited the growth of cells at low density in the presence of αMO. Doubling the concentration of the defined components of conditioned medium did not markedly affect its capacity to inhibit growth. However, dialysis completely removed the inhibitory activity from conditioned medium. The results imply that a low molecular weight inhibitor of growth is produced by polyamine-limited cells. This is a variable that must be controlled in studies with polyamine-limited animal cells. Morphological studies indicated that subcellular organelles, including mitochondria, were largely unaffected by treatment with αMO. The maintenance of mitochondrial integrity in the presence of αMO demonstrates that the swelling of mitochondria observed previously in cells treated with methylglyoxal bis(guanylhydrazone) was not due to polyamine limitation. αMO-treated cells did, however, accumulate numerous cytoplasmic vacuoles. The identity of these vacuoles and their relationship to cellular physiology is not yet understood.     

Relationship between uridine kinase activity and rate of incorporation of uridine into acid-soluble pool and into RNA during growth cycle of rat hepatoma cells

Uridine kinase activity measured in cell-free extracts of Novikoff rat hepatoma cells grown in suspension culture fluctuates about 10 fold during the growth cycle of the cells. Maximum specific activity (units/10⁶ cells) is observed early in the exponential phase and then decreases progressively until the stationary phase. The rate of incorporation of uridine into the acid-soluble pool by intact cells fluctuates in a similar manner and both the rate of uridine incorporation by intact cells and the uridine kinase actvity of the cells increase several fold before cell division commences following dilution of stationary phase cultures with freshmedium. Regardless of the stage of growth, uridine is rapidly phosphorylated to the triphosphate level by the cells. The rates of incorporation of uridine into the nucleotide pool and into RNA by intact cells fluctuate in a similar manner during the growth cycle. However, evidence is presented that indicates that alterations in the rate of incorporation of uridine into RNA are not simply due to changes in the rate of phosphorylation of uridine, but are regulated independently. Inhibition of protein synthesis by treating cells with puromycin or actidione causes a marked inhibition of incorporation of uridine into RNA, but has little effect on the phosphorylation of uridine to UTP for several hours. Thus the depression of incorporation of uridine into RNA probably reflects a decrease in the rate of RNA synthesis as a result of inhibition of protein synthesis. Inhibition of RNA synthesis by treating cells with actinomycin D does not affect the rate of conversion of uridine to UTP and thus results in the accumulation of labeled UTP in treated cells.     

CHANGES IN GLUCOSE OXIDATION DURING GROWTH OF EMBRYONIC HEART CELLS IN CULTURE

A rapid and convenient method has been utilized to investigate glucose oxidation during growth of chick embryo heart cells in tissue culture. Primary isolates of chick embryo heart cells showed exponential growth when plated at low densities and exhibited density-inhibited growth as cultures became confluent. The density-dependent growth inhibition of chick embryo heart cells is associated with a marked decrease in the specific activity of glucose oxidation to CO₂. This decrease in glucose oxidation was observed as density increased as either a function of time in culture or as related to initial plating density. The decrease in ¹⁴CO₂ production associated with density-dependent inhibition of growth is due to a marked decrease in activity of the pentose phosphate pathway.