D-glucosamine-induced changes in nucleotide metabolism and growth of colon-carcinoma cells in culture.

Human colon-carcinoma cells were exposed to D-glucosamine at 2.5, 5 and 10 mM, concentrations that were growth-inhibitory but not cytocidal in the presence of a physiological glucose concentration. Labelling of these HT-29 cells with D-[14C]-glucosamine, followed by nucleotide analyses, demonstrated that UDP-N-acetyl-hexosamines represented the major intracellular nucleotide pool and the predominant metabolite of the amino sugar. D-[14C]Glucosamine was not a precursor of UDP-glucosamine. After 4h exposure to D-glucosamine (2.5 mM), the pool of UDP-N-acetylhexosamines was increased more than 6-fold, whereas UTP and CTP were markedly decreased. UDP-glucuronate content increased by more than 2-fold, whereas purine nucleotide content was little altered. Uridine (0.1 mM) largely reversed the decrease in UTP, CTP, UDP-glucose and UDP-galactose, while intensifying the expansion of the UDP-N-acetylhexosamine pool. Uridine did not reverse the D-glucosamine-induced retardation of growth in culture. A 50% decrease in growth also persisted when uridine and cytidine, cytidine alone, or UDP, were added together with D-glucosamine. The growth-inhibitory effect of the amino sugar could therefore be best correlated with the quantitative change in the pattern of sugar nucleotides, and, in particular, with the many-fold increase in UDP-N-acetylglucosamine and UDP-N-acetylgalactosamine.     

Stimulation of uridine phosphorylation in primary cultures of Xenopus laevis hepatocytes by estradiol-17 beta

The effects of estrogen on the uridine uptake into cells were examined in primary cultures of liver parenchymal cells from Xenopus laevis. The total uptake of [3H]uridine into the estrogen-treated cells and its incorporation into RNA were about 1.5 times higher than the values for control cells. The uptake of [3H]adenosine and its incorporation into RNA were not affected by estrogen. An experiment in which liver parenchymal cells were double labeled with [3H]uridine and [3H]adenosine showed that estrogen elevated the specific radioactivity of the UTP pool 1.4-fold the value found for the control cells, but that of the ATP pool was not altered by estrogen. Short term labeling revealed that estrogen did not significantly alter the rate of the initial uptake of [3H]uridine into the cells, but it did stimulate [3H]uridine phosphorylation about 1.7-fold. Uridine kinase activity measured in cell-free extracts of hepatocytes treated with estrogen had a value 1.6 times that of the control cells. These data indicate that the stimulation of [3H]uridine uptake and phosphorylation in Xenopus laevis hepatocytes in the presence of estrogen is caused by the enhancement of uridine kinase activity.     

The intracellular accumulation of UDP-N-acetylhexosamines is concomitant with the inability of human colon cancer cells to differentiate

The relationship between the intracellular concentration of various nucleotides as measured by high-performance liquid chromatography analysis, and the differentiation of 2 human colon cancer cell lines was studied. HT-29 cells were induced to undergo both structural and functional enterocytic differentiation (as determined by electron microscopy and the presence of brush-border specific enzymes, respectively) by changing the carbon source or adding Na butyrate to standard tissue culture media. This differentiation occurred after the cells reached confluency when they were cultured in galactose, uridine, inosine, or without nucleosides (all in the absence of glucose) and in the presence of glucose plus Na butyrate. Cells cultured in 25 mM fructose or glucose +/- nucleosides did not differentiate. In all culture conditions where HT-29 cells did not differentite, the intracellular concentrations of 2 compounds which co-migrated with UDP-N-acetylglucosamine and UDP-N-acetylgalactosamine rose approximately equal to 10-fold at confluency and remained elevated throughout the stationary phase, whereas their concentrations remained constant and low after confluency in cells that underwent differentiation. This indicated that the accumulation of these compounds is associated with the inability of these cells to differentiate since other nucleotides and nucleotide sugars did not change in a similar fashion. Purification of the presumed UDP-N-acetylhexosamines, followed by the identification of the products from their chemical and enzymatic hydrolysis, confirmed the identity of these two peaks. Nucleotide analysis of Caco-2 cells, which undergo enterocytic differentiation after they reach confluency even when cultured on glucose, revealed the same pattern of UDP-N-acetylhexosamine levels as differentiated HT-29 cells, with its concentration remaining relatively constant and very low, even after the cells were confluent. The significance of the accumulation of UDP-N-acetylhexosamines in cells unable to differentiate is discussed.     

Nucleotide pools of Novikoff rat hepatoma cells growing in suspension culture. II. Independent snucleotide pools for nucleic acid synthesis

Novikoff rat hepatoma cells (subline NlSl-67) in suspension culture incorporate ³H-5-uridine into the acid-soluble nucleotide pool more rapidly than into RNA, resulting in the accumulation of labeled UTP in the cells. When labeled uridine is removed from the medium after 20 minutes or 4.75 hours of labeling, the rate of incorporation of label from the nucleotide pool into RNA decreases to less than 10% of the original rate within five to ten minutes, in spite of the presence of a large pool of labeled UTP in the cells, and incorporation ceases completely if an excess of unlabeled uridine is present during the chase. Upon addition of ¹⁴C-uridine to ³H-uridine pulse-labeled, chased cells, the ¹⁴C begins to be incorporated into RNA without delay and at a rate predetermined by the concentration of ¹⁴C-uridine in the medium and without affecting the fate of the free ³H-nucleotides labeled during the pulse-period. The results are interpreted to indicate that uridine is incorporated into at least two different pools, only one of which serves as primary source of nucleotides for RNA synthesis. During active synthesis of RNA, the latter pool of free nucleotides is very small and rapidly exhausted when uridine is removed from the medium. However, UTP accumulates in this pool when cells are labeled at 4–6°, since at this temperature RNA synthesis is blocked while uridine is still phosphorylated by the cells, and the UTP is rapidly incorporated into RNA during a subsequent ten-minute chase at 37°. From these types of experiments it is estimated that only 20–25% of the total uridine nucleotides formed in the cells from uridine in the medium is directly available for RNA synthesis and that the remainder becomes available only at a slow rate. Evidence is presented which suggests that one uridine nucleotide pool is located in the cytoplasm and another in the nucleus and that mainly the nuclear pool supplies nucleotides for RNA synthesis. The size of the latter pool is under strict regulatory control, since preincubation of the cells with 0.5 mM unlabeled uridine has little or no effect on the subsequent incorporation of ³H-uridine, although it results in an increase of the overall cellular uridine nucleotide content to at least 5 mM. Other results indicate that adenosine is also incorporated into two independent nucleotide pools, whereas the cells normally appear to possess a single thymidine nucleotide pool.     

Stimulation of facilitated [3H]uridine transport by thyroid hormone in GH1 cells. Evidence for regulation by the thyroid hormone nuclear receptor

We have previously shown that 3,5,3'-triiodo-L-thyronine (L-T3) stimulates cell growth and a 4- to 8-fold increase in growth hormone mRNA in GH1 cells. These effects appear to be mediated by a thyroid hormone nuclear receptor with an equilibrium dissociation constant for L-T3 of 0.2 nM and an abundance of about 10,000 receptors per cell nucleus. In this report, we show that L-T3 exerts a pleiotypic effect on GH1 cells to rapidly (within 2 h) stimulate [3H]uridine uptake to a maximal value of 2.5- to 3-fold after 24 h. This results from an increase in the number of functional uridine "transport sites" as shown by studies documenting an increase in the apparent Vmax with no change in the Km, 17 microM. Although the labeling of the cellular uridine pool and pools of all phosphorylated uridine derivatives was increased by L-T3, there was no change in the relative amounts of the individual pools in cells incubated with or without hormone. The intracellular concentration of [3H]uridine was estimated to be similar to that of the medium, suggesting that facilitated transport mediates [3H]uridine uptake. That this increase in [3H]uridine transport was nuclear receptor-mediated is supported by the excellent correspondence of the L-T3 dose-response curve for [3H]uridine uptake and that for L-T3 binding to receptor. Finally, inhibition of protein synthesis by cycloheximide and RNA synthesis by actinomycin D demonstrated that the L-T3 effect required continuing protein and RNA synthesis. These results are consistent with an effect of the L-T3-nuclear receptor complex to increase uridine uptake in GH1 cells by altering the expression of gene(s) essential for the transport process.     

Transport enhancement and reversal: glucose and 3-O-methyl glucose.

In chick embryo fibroblast cultures the 15- to 30-fold enhancement of D-glucose uptake observed when cells are starved of glucose for 24 hours is not duplicated for derivatives of glucose that compete effectively for uptake and have generally been considered to use the same carrier. 2-deoxy-D-glucose, D-mannose, D-galactose and D-glucosamine are derepressed progressively less sharply in that order with glucosamine uptake never more than doubled by starvation. D-glucose at a concentration of 5.5 mM in the 24-hour conditioning medium is a strong "repressor" resulting in low "transport" behavior for each of the five sugars cited. D-glucosamine is equally effective at the same concentration. A 10-fold reduction in the concentration of glucosamine (0.55 mM) allows for the escape from repression of mannose, glucose, and deoxyglucose uptake while the others remain repressed. Mannose uptake escapes as well when the glucose concentration in the "conditioning" medium is similarly reduced. Under certain conditions of starvation and cell density dramatic effects of supplemental stimulation by insulin can be achieved. Insulin withdrawal interrupts the supplemental stimulation process. Cycloheximide, actinomycin D and cordycepin block both non-insulin and insulin-induced derepression. Short exposure (15-30 minutes) of 24-hour starved cells to glucose (5.5 mM) reduces glucose sharply but does not affect 3-O-methyl glucose uptake. If the exposure is to 2-deoxyglucose (5.5 mM) further derepression of glucose uptake results.     

Uridine uptake by isolated intestinal epithelial cells of guinea pig

Uptake of uridine was studied in isolated intestinal epithelial cells of guinea pig. Uptake was not severely influenced by metabolism. Free uridine was accumulated within cells 13-fold. Uptake was saturable with an apparent Km value of 46 microM and a Vmax of 0.9 nmol/mg protein per min. Uracil inhibited uptake only slightly; adenosine, guanosine and cytosine inhibited strongly. Antimycin A and ouabain inhibited almost 90%. If the extracellular Na+ concentration was decreased to 5 mM, the rate of uptake decreased 6.5-fold. The stimulatory effect of Na+ was related to the transmembraneous Na+-gradient. Cells from jejunum transported about 30% faster than cells from ileum. In conclusion, isolated enterocytes of guinea pig posses an active transport system for uridine.     

Inhibition of uridine transport in cultured mammalian cells by theophylline

Theophylline (theobromine, caffeine) reversibly inhibits the incorporation of labeled RNA precursors both in confluent 37 RC and in exponentially growing HeLa cells. As measured in 37 RC after 2 h labeling, 20 mM theophylline reduces the incorporation of [3H]UTP and [14C]uridine into acid-precipitable material to 5% and 9% of the control, respectively. This reduction is paralleled by a comparably lowered incorporation of the same precursors into the acid-soluble pool. The initial rate of incorporation into total cell material is similarly affected by theophylline, the inhibition being of a simple competitive type. Theophylline does not alter the turnover rate of pulse labeled RNA during actinomycin D chase nor does it preclude the utilization of the endogenous pool of nucleoside phosphates. Upto a concentration of 10 mM, it does not inhibit uridine kinase neither in 37 RC nor in HeLa cells. The mentioned inhibitory effects of theophylline cannot be mimicked by exogenously added cyclic AMP. All the data support the conclusion that theophylline inhibits the transport of uridine into the cell.     

Uridine uptake by isolated intestinal epithelial cells of guinea pig

Uptake of uridine was studied in isolated intestinal epithelial cells of guinea pig. Uptake was not severely influenced by metabolism. Free uridine was accumulated within cells 13-fold. Uptake was saturable with an apparent K_m value of 46 μM and a V_max of 0.9 nmol/mg protein per min. Uracil inhibited uptake only slightly; adenosine, guanosine and cytosine inhibited strongly. Antimycin A and ouabain inhibited almost 90%. If the extracellular Na⁺ concentration was decreased to 5 mM, the rate of uptake decreased 6.5-fold. The stimulatory effect of Na⁺ was related to the transmembraneous Na⁺-gradient. Cells from jejunum transported about 30% faster than cells from ileum. In conclusion, isolated enterocytes of guinea pig posses an active transport system for uridine.     

Selective high metabolic lability of uridine triphosphate in response to glucosamine feeding of untransformed and polyoma virus-transformed hamster fibroblasts

Derepression of hexose transport in a line of Syrian hamster fibroblasts (Nil) and polyoma-transformed (PyNil) hamster fibroblasts is obtained when cells are either starved for glucose or fed with fructose as the only hexose source. D-glucosamine feeding of these cells does not alter the repressed state with regard to hexose transport. High, derepressed rates of galactose transport were changed to low, repressed rates, within 18 hours of refeeding glucose-starved cells with D-glucosamine as the only hexose source. Nil and PyNil cells, when cultured in the presence of D-glucosamine, undergo rapid reductions in total cellular uridine 5′-triphosphate (UTP) pool sizes. By contrast, the total cellular pools of adenosine 5′-triphosphate, guanosine 5′-triphosphate, and cytosine 5′-triphosphate (ATP, GTP, and CTP) were only moderately affected by the treatment of the cells with glucosamine. The metabolic drain of the UTP pools in PyNil cells was much more pronounced than in the untransformed cells. The larger and more rapid metabolic lability of UTP pools in the transformed cells may be the primary reason for the selective toxicity of glucosamine on tumor cells. A comparison of the effects of glucosamine on hexose-starved Nil and PyNil cells demonstrated that only the untransformed cells were able to utilize glucosamine to increase the hexose starvation-depleted pools of all nucleoside triphosphates. Accumulation of UDP-glucosamine and UDP-N-acetylglucosamine followed the reduction in the UTP pools. Inhibition of protein synthesis by cycloheximide during glucosamine feeding led to higher levels of UDP-glucosamine and UDP-N-acetylglucosamine accumulation. It is suggested that the drain of UTP pools during glucosamine treatment proceeds through the formation of the UDP-aminosugars which turn over due to the action of intracellular UDP-aminosugar pyrophosphatase activities.     

Studies of the effect of experimental inflammation on rat liver nucleotide sugar pools

The effect of experimental inflammation on levels of nucleotide sugars was studied in rat liver. There was an increase of about 2-fold in the levels of UDP-N-acetylhexosamines and GDP-Man at 8 and 4 hr after inflammation, respectively. At 48 hr after inflammation GDP-Man had returned close to control values, but UDP-N-acetylhexosamines were still about 50% above controls. There was a 30% reduction in CMP-NeuAc and UDP-Gal at 8-12 hr after inflammation before increasing to slightly above controls at 16-48 hr after inflammation. Inflammation resulted in an increase in activities of glucosamine-6-phosphate synthase and UDP-GlcNAc-2'-epimerase to about twice control activities at 24 and 8 hr after inflammation, respectively, before declining; CMP-NeuAc synthase activities did not show large changes following inflammation.     

Orotate leads to a specific increase in uridine nucleotide levels and a stimulation of sucrose degradation and starch synthesis in discs from growing potato tubers

Freshly cut discs from growing potato tubers were incubated for 3 h with 10 mM orotate or 10 mM uridine. Control discs incubated without precursors showed a 30–40% decrease of uridine nucleotides, but not of adenine nucleotides. Orotate- and uridine-feeding led to a 1.5- to 2-fold increase in the levels of uridine nucleotides compared with control discs, and a 15–30% increase compared with the original values in intact tubers, but did not alter the levels of adenine nucleotides. Between 70–80% of the uridine nucleotides were present as UDPglucose, 15–25% as UTP, and 2–3% as UDP. The increase of uridine nucleotides involved a similar relative increase of UDPglucose, UTP and UDP. It was accompanied by a slight stimulation of the rate of [¹⁴C]sucrose uptake, a 2-fold stimulation of the rate at which the [¹⁴C]sucrose was subsequently metabolised, a small increase in the levels of hexose phosphates, glycerate-3-phospate and ADPglucose, and a 30% shift in the allocation of the metabolised label in favour of starch synthesis, resulting in a 2.4-fold stimulation of the rate of starch synthesis. Orotate led to a similar increase of uridine nucleotide levels in the presence of [¹⁴C]glucose, but did not significantly alter the rate of glucose uptake and metabolism to starch, nor did it increase the rate of sucrose resynthesis. The levels of uridine nucleotides were high in tubers on 6 to 10-week-old potato plants, and declined in tubers on 12 to 15-week-old plants. Comparison with the effect of the uridine nucleotide level in discs shows that the high levels of uridine nucleotides in tubers on young plants will play an important role in determining the rate at which sucrose can be converted to starch, and that the level of uridine nucleotides is probably co-limiting for sucrose-starch conversions in tubers on older plants. Received: 25 September 1998 / Accepted: 29 December 1998     

Nucleotide pools of Novikoff rat hepatoma cells growing in suspension culture. IV. Nucleoside transport in cells depleted of nucleotides by treatment with KCN

Incubation of Novikoff rat hepatoma cells in glucose-free basal medium containing 2 mM KCN results in a rapid and almost complete loss of uracil and adenine nucleotides. By following the fate of radioactivity from ³H-nucleoside pulse-labeled cells during incubation with KCN it was shown that the nucleotides are degraded to nucleosides and bases which are released into the culture fluid. Depletion of the cells of nucleotides by incubation with KCN allows a direct analysis of the kinetics of uridine transport into the cell, since KCN-treated cells fail to phosphorylate uridine. Uridine uptake follows normal Michaelis-Menten kinetics with an apparent K_n of about 50 μm at 18°C. Uptake is by facilitated diffusion since it does not require energy and uridine is not transported against a concentration gradient. The effects of KCN are largely prevented by the presence of 10 mM glucose in the medium. They are also rapidly reversed by resuspending the cells in fresh medium without KCN. Upon removal of KCN, the cells rapidly regenerate their nucleotide pools and resume growth at the normal rate.     

Effect of ouabain on amino acid uptake by mouse ascites-tumour cells in the presence of nigericin.

Mouse ascites-tumour cells oxidizing lactate, in a modified Ringer solution, concentrated 2-aminoisobutyrate, L-methionine or 2-(methylamino)isobutyrate about 20-fold from a 0.4 mM solution in the presence of 2-3 micrograms of nigericin/mg cellular dry wt. The ionophore increased cellular [Na+] to almost 100 mM when extracellular [Na+] was about 45 mM. Either valinomycin or the two mitochondrial inhibitors oligomycin and antimycin acting together each markedly lowered the extent to which the tumour cells concentrated amino acid, from the above factor of about 20 to roughly 2-fold. Ouabain (1 mM) had a similar effect, and further raised cellular [Na+]. The sodium pump appeared to be closely involved in amino acid uptake under these conditions.     

Comparison of the equilibrium exchange of nucleosides and 3-O-methylglucose in human erythrocytes and of the effects of cytochalasin B, phloretin and dipyridamole on their transport

Because of similarities in the physical and molecular properties of the nucleoside and sugar transporters of human erythrocytes and the photoaffinity labeling of the sugar transporter by 8-azidoadenosine (Jarvis et al. (1986) J. Biol. Chem. 261, 11077-11085), we have directly compared the equilibrium exchange of uridine and 3-O-methylglucose in these cells as measured by rapid kinetic techniques under identical experimental conditions. Both the Michaelis-Menten constant and maximum velocity were about 100-fold higher for 3-O-methylglucose exchange than for uridine exchange so that the first order rate constants for both transporters were about the same. When calculated on the basis of the number of nucleoside and sugar carriers per red cell estimated by equilibrium binding of nitrobenzylthioinosine and cytochalasin B, respectively, the turnover numbers for the sugar and nucleoside carriers with 3-O-methylglucose and uridine, respectively, as substrates were quite similar. Various sugars up to concentrations of 108 mM had no effect on the exchange of 500 microM uridine or adenosine, and uridine up to a concentration of 50 mM had no effect on the exchange of 10 mM 3-O-methylglucose. Adenosine, on the other hand, inhibited 3-O-methylglucose exchange in a concentration dependent manner, though not very effectively (IC50 approximately equal to 3 mM). Both uridine and 3-O-methylglucose exchange were inhibited in a concentration dependent manner by cytochalasin B, phloretin and dipyridamole, but cytochalasin B and phloretin were 100-times more effective in inhibiting 3-O-methylglucose than uridine exchange, whereas the opposite was the case for the inhibition by dipyridamole.     

Transport as the Rate-Limiting Step in the Incorporation of Uridine into Mengovirus Ribonucleic Acid in Novikoff Rat Hepatoma Cells

The incorporation of uridine into the nucleotide pool of actinomycin-treated, mengovirus-infected Novikoff rat hepatoma cells in culture follows simple Michaelis-Menten kinetics, and the apparent V(max) and K(m) values are similar to those for uridine transport by uninfected cells. Incorporation of uridine into mengovirus-specific ribonucleic acid (RNA) also follows Michaelis-Menten kinetics, and the apparent K(m) (about 10 mum) is approximately the same as for uridine transport. Inhibition of uridine transport by the presence of adenosine, persantin, or phenethyl alcohol inhibits simultaneously and to the same extent the incorporation of uridine into the nucleotide pool and into viral RNA, without affecting viral RNA synthesis per se. Phenethyl alcohol, however, also inhibits virus maturation. The inhibition of uridine incorporation into the nucleotide pool and into viral RNA is of the simple competitive type, indicating that transport into the cells is the rate-limiting step in the incorporation of uridine into mengovirus RNA. The results also indicate that treatment with actinomycin D or mengovirus infection does not affect uridine transport.     

The intracellular calcium antagonist, TMB-8, inhibits prolactin gene expression in GH3 cells

We examined the effects of the drug, TMB-8, which promotes sequestration of intracellular Ca2+, on the ability of extracellular Ca2+ to stimulate prolactin gene expression in GH3 cells. TMB-8 inhibited prolactin mRNA levels in a dose-dependent manner in the concentration range of 2.5-10 microM. Prolactin mRNA levels were increased about 18-fold by the addition of 0.1 mM CaCl2, and about 25-fold by the addition of 0.4 mM CaCl2. Addition of 10 microM TMB-8 reduced these levels to about 4-fold and 7-fold, respectively. At 10 microM TMB-8 did not effect total protein synthesis or the Ca2+-induced aggregation of the cells, indicating a selective inhibition by the drug of prolactin gene expression. Both TMB-8 and the calmodulin inhibitor, calmidazolium, reversed the effects of Ca2+ on prolactin mRNA levels in cells that had been pretreated for 2 days with 0.4 mM CaCl2.     

Exogenous nucleosides stimulate RNA synthesis in resting cells of a culture of scarlet rose

RNA synthesis in response to exogenous nucleoside precursors was studied in a suspension culture of rose cells. Exponentially growing and resting cells were prelabeled with [3H] uridine, an excess of unlabeled uridine added, and subsequent isotopic incorporation into nuclear and ribosomal fractions measured. The data were compared to control values in cells continuously labeled in the absence of unlabeled uridine. Addition of uridine to the growing culture reduced the further uptake, and incorporation of [3H] uridine into RNA. In contrast, in resting cells, the addition of uridine (or, purine nucleosides) enhanced the apparent utilization of [3H] uridine in RNA synthesis by 2- to 4-fold.     

Effect of plasma concentrations of uridine on pyrimidine biosynthesis in cultured L1210 cells

The concentration of uridine in the media of cultured L1210 cells was maintained within the concentration range found in plasma (1 to 10 microM) to determine if such concentrations are sufficient to satisfy the pyrimidine requirements of a population of dividing cells and to determine if cells utilize de novo and/or salvage pathways when exposed to plasma concentrations of uridine. When cells were incubated in the presence of N-(phosphonacetyl)-L-aspartate to block de novo biosynthesis, plasma concentrations of uridine maintained normal cell growth. De novo pyrimidine biosynthesis, as determined by [14C]sodium bicarbonate incorporation into uracil nucleotides, was affected by the low concentrations of uridine found in the plasma. Below 1 microM uridine, de novo biosynthesis was not affected; between 3 and 5 microM uridine, de novo biosynthesis was inhibited by approximately 50%; and above 12 microM uridine, de novo biosynthesis was inhibited by greater than 95%. Inhibition of de novo biosynthesis correlated with an increase in the uracil nucleotide pool. The de novo pathway was much more sensitive to the uracil nucleotide pool size than was the salvage pathway, such that when de novo biosynthesis was inhibited by greater than 95% the uracil nucleotide pool continued to expand and the cells continued to take up [14C]uridine. Thus, the pyrimidine requirements of cultured L1210 cells can be met by concentrations of uridine found in the plasma and, when exposed to such physiologic concentrations, L1210 cells decrease their dependency on de novo biosynthesis and utilize their salvage pathway. Circulating uridine, therefore, may be of physiologic importance and could be an important determinant in anti-pyrimidine chemotherapy.