Nucleotide pools of Novikoff rat hepatoma cells growing in suspension culture. I. Kinetics of incorporation of nucleosides into nucleotide pools and pool sizes during growth cycle

Results from kinetic studies on the incorporation of ³H-5-uridine and ³H-8-adenosine into the acid-soluble nucleotide poor and nucleic acids by Novikoff hepatoma cells (subline N1S1-67) in suspension culture indicate that the uridine transport reaction is saturated at about 100 μM and that for adenosine at about 10 μM nucleoside in the medium, and that above 100 μM simple diffusion becomes the predominant mode of entry of both nucleosides into the cell. The Km of the transport reactions is approximately 1.3 × 10^?5 M for uridine and 6 × 10^?6 M for adenosine. The incorporation of these nucleosides into both the nucleotide pool and into nucleic acids seems to be limited by the rate of entry of the nucleic acid synthesis from the rate of incorporation of nucleosides. Other complicating factors are a change with time of labeling in the relative proporation of nucleoside incorporated into DNA and into the individual nucleotides of RNA, the splitting of uridine to uracil by th ecells, the deamination of adenosine kto inosine and the subsequent cleavage of inosine to hypoxanthine. Various lines of evidence are presented which indicate that the overall nucleotide pools of the cells are very small under normal growth conditions. During growth in the presence of 200 μM uridine or adenosine, however, the cells continue to convert the nucleosides into intracellular nucleotides much more rapidly than required for nucleic acid synthesis. This results in an accumulation of free uridine and adenosine nucleotides in the cells, the maximum amounts of which are at least equivalent to the amount of these nucleotides in total cellular RNA.     

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.     

Effects of the rat renotropic system on 14C-uridine incorporation into RNA and RNA precursors.

We used the incorporation of ¹⁴C-uridine into RNA of incubating kidney fragments from normal control rats to evaluate RNA metabolism. Sera from unilaterally nephrectomized rats (uni) obtained 20 hrs post-operatively stimulate ¹⁴C-uridine incorporation into RNA significantly more than sera from sham-operated rats (sham). Differently, sera from uni and sham rats have little influence on specific activities of endogenous uridine nucleotide pool in renal fragments. Renal extracts were obtained by homogenizing kidneys in saline. Extracts from kidneys of uni and sham rats 20 hrs post operation depress incorporation markedly, and each depresses to a similar extent, but kidney extracts dilute the specific activities of uridine pools. Correcting for the latter dilution demonstrates that kidney extracts alone have little effect on ¹⁴C-uridine incorporation into RNA. We then followed the results when these sera and extracts were combined. Compared to fragments incubating in sham sera and sham extracts, substitution of uni extracts or both uni extracts and uni sera enhances ¹⁴C-uridine into renal RNA, whether or not results are corrected for changes in the specific activities of the uridine pools. We conclude that after uninephrectomy there is a concurrent elevation in circulating renotropin and a tissue activating factor in the remaining kidney. The tissue factor can only form an excitor to ¹⁴C-uridine incorporation into RNA when serum is present. The rat renotropic system that enhances incorporation of ³H-thymidine into DNA also can stimulate ¹⁴C-uridine incorporation into renal RNA.     

Utilization of uridine in developing ovarioles of the kelp fly, Coelopa

The fate of ³H-uridine in ovaries of the kelp fly C. frigida after injection into the female is followed by autoradiography and by thin layer chromatography over a time period of 4 hr. Autoradiography demonstrates that the label is incorporated initially into nuclear material in the nurse cells and follicle cells, and is transported from the nuclei into the cytoplasm within the first hour after injection. Reduced incorporation into nuclear material, after the first 2 hr following injection, is interpreted as depletion of exogenous precursor. Only a very small amount of label is found over the nuclei after 4 hr when the nurse cell cytoplasm is densely labeled. This indicates that most of the label is retained in long-lived products and is not available for the salvage pool.Analysis of the relative distribution of radioactivity in derivatives over a 4 hr time span corroborates the autoradiographic observations. The amount of radioactivity present in uridine, cytidine, and sugar nucleotides increases rapidly, though with different velocity for each nucleotide. The pattern of utilization during the first 2 hr, particularly of UTP, suggests preferential utilization of the exogenous precursor. After depletion of the salvage pool, labeled precursors provide low levels of specific activity for the nucleotide pool. The macromolecules synthesized after this time period do not show radioactivity.     

Separate pyrimidine-nucleotide pools for messenger-RNA and ribosomal-RNA synthesis in HeLa S3 cells.

Kinetic analyses of mRNA and 28-S RNA labeling [3H]uridine revealed distinctly different steady-state specific radioactivities finally reached for uridine in mRNA and 28-S RNA when exogenous [3H]uridine was kept constant for several cell doubling times. While the steady-state label of (total) UTP and of uridine in mRNA responded to the same extent to a suppression of pyrimidine synthesis de novo by high uridine concentrations in the culture medium, uridine in 28-S RNA was scarcely influenced. Similar findings were obtained with respect to labeling of cytidine in the various RNA species due to an equilibration of UTP with CTP [5-3H]Uridine is also incorporated into deoxycytidine of DNA, presumably via dCTP. The specific radioactivity of this nucleosidase attained the same steady-state value as UTP, uridine in mRNA and cytidine in mRNA. The data indicate the existence of two pyrimidine nucleotide pools. One is a large, general UTP pool comprising the bulk of the cellular UTP and serving nucleoplasmic nucleic acid formation (uridine and cytidine in mRNA, deoxycytidine in DNA). Its replenishment by de novo synthesis can be suppressed completely by exogenous uridine above 100 muM concentrations. A second, very small UTP (and CTP) pool with a high turnover provides most of the precursors for nucleolar RNA formation (rRNA). This pool is not subject to feedback inhibition by extracellular uridine to an appreciable extent. Determinations of (total) UTP turnover also show that the bulk of cellular RNA (rRNA) cannot be derived from the large UTP pool.     

Effects of adenosine 3':5'-monophosphate and related agents on ribonucleic acid synthesis and morphological differentiation in mouse neuroblastoma cells in culture.

A variety of compounds were assessed for their ability to induce morphological differentiation and to affect the synthesis of RNA in uncloned mouse neuroblastoma cells in culture. The stimulation of morphological differentiation in uncloned cells after exposure for 48 hours to concentrations of 3 times 10-7 to 3 times 10-4 M papavarine or 10-9 to 10-3 M dibutyryl adenosine 3':5'-monophosphate (dibutyryl-cAMP) was associated, in part, with a concentration-dependent decrease in incorporation of [5-3H]uridine into ribosomal RNA (rRNA) and heterogeneous RNA (HnRNA). The latter effect on cellular RNA produced by papavarine occurred within 1 hour after its addition to the medium and was associated with impaired uptake of radioactive precursor into uridine nucleotides and reduction in the intracellular concentration of uridine 5'-triphosphate (UTP). Dibutytyl-cAMP produced a decreased in the specific radioactivity of UTP without affecting the concentration of UTP in the tumor cells. The effects of papavarine and dibutyryl-cAMP could be distinguished further by the 50% reduction of acetylcholinesterase activity produced by papavarine, but not by dibutyryl-cAMP. Papavarine did not, however, reduce the cellular level of the soluble enzyme, adenine phosphoribosyltransferase. Sodium butyrate, while producing morphological effects similar to those of papavarine and dibutyryl-cAMP at equimolar concentrations, caused no significant changes in the incorporation of [5-3H]uridine into rRNA and HnRNA; however, acetylcholinesterase activity was stimulated 6- to 7-fold above control levels. In contrast to the other differentiating agents examined, addition of 10-9 to 3 times 10-4 M concentrations of cAMP to the tissue culture medium enhanced morphological differentiation of nueroblastoma cells, and caused a 10- to 20-fold stimulation of the incorporation of [5-3H]uridine into rRNA and HnRNA at concentrations of 10-4 M and higher. This effect observed only at high concentrations of cyclic nucleotide was accompanied by an elevation in the specific acitivty of UTP, These studies suggest that the morphological response of neuroblastoma cells is not necessarily associated with concomitant alterations in the synthesis of RNA with agents other than cAMP. Observed changes in incorporation of [5-3H]uridine into RNA appear in most instances to be due to alterations in the uptake of uridine, and in the pool size and specific radioactivity of UTP.     

Nutritional effects on precursor uptake and compartmentalization of intracellular pools in relation to RNA synthesis.

The effects of nutritional variables on the processing of exogenous precursors into RNA was examined. General nutritional deprivation, or asparagine depletion, led to significant changes in the absolute pool sizes, especially of ATP, UTP and CTP. Fluctuations were found depending on the elapsed time after the nutritional perturbations occurred, and the cell density of the cultures. Depletion of the medium by 28 h of growth, or 1 h of guinea pig asparaginase action, led to considerable inhibition of the conversion of exogenous uridine to CTP by the cells. A series of experiments indicated that in 6C3HED lymphoma cells the uridine nucleotide pool which provided the immediate precursors to RNA (denoted UTP-NA) behaves as a small compartment in rapid equilibrium with exogenously supplied nucleosides. The resemblance to the compartmentation model described by Plagemann (Plagemann, P.G.W. (1972) J. Cell Biol. 52, 131-146 and (1971) J. Cell. Physiol. 77, 241-258) for rat hepatoma cells was close. The UTP-NA pool of the 6C3HED cells constitutes no more than 5% of the cellular UTP pool and is relatively slow in equilibrating with the general cell pool. Correction of the rates of incorporation of isotope into RNA by using some function of the whole cell UTP specific activity to normalize the pool effects, was shown to be invalid.     

Incorporation of exogenous precursors into uridine and ribonucleic acid. Nucleotide compartmentation in the renal cortex in vivo

The possibility of compartmentation of UTP in vivo was investigated in the renal cortex of unanaesthetized rats. In addition, liver and spleen were studied in order to compare tissues with different utilization of precursors for pyrimidine nucleotide synthesis. After continuous 2h infusions of [(3)H]uridine or [(3)H]orotate, their incorporation into UTP, UDP-sugars and RNA was quantified. Rates of RNA synthesis were calculated by dividing the incorporation of precursor into RNA by the average specific radioactivity of the UTP pool. Although similar RNA-synthesis rates might have been expected with the two precursors, higher rates were found with uridine than with orotate. The relative incorporation into UDP-sugars of these precursors was also different. Similar results were obtained in the liver. In the spleen, equal amounts of both precursors were incorporated into UTP, but [(3)H]orotate incorporation did not lead to labelling of RNA. To evaluate the heterogeneity of cells with respect to the metabolism of pyrimidines, precursor incorporation was studied in isolated glomeruli and by radioautography. Incorporation into glomeruli was qualitatively similar to but quantitatively different from results in the renal cortex. Although there is obvious tissue heterogeneity, compartmentation of UTP pools is the most credible explanation for the results obtained with the renal cortex and liver. Consequently RNA and UDP-sugars may originate from two different UTP pools. Tissue heterogeneity is the likely explanation for the results obtained in the spleen. Studies of synthesis of pyrimidine and RNA, particularly in relation to growth and regeneration, must take into consideration the precursor used, the apparent existence of UTP compartmentation and the degree of cellular heterogeneity.     

Mechanism of Apparent Transcription Inhibition by Methyl Mercury in Cerebellar Neurons

Abstract: We have investigated the mechanism of inhibition of RNA synthesis by methyl mercury (MeHg) in isolated neonatal rat cerebellar cells. Each of the three component steps involved in the incorporation of exogenous [³H]uridine into cellular RNA was examined separately in whole-cell and/or subcellular preparations. Nuclear RNA polymerase activity was measured in preparations containing both free nuclei and whole cells. Incorporation of [³H]UTP into nuclear RNA was found to be unimpaired at concentrations of MeHg that inhibited whole-cell incorporation of [³H]uridine by > 75%. Cellular uptake of [³H]uridine was assayed in cerebellar cells treated with KCN to deplete ATP levels and block subsequent phosphorylation reactions of transported uridine. Uptake activity under these conditions was unaffected by MeHg. Measurement of intracellular phosphorylation of [³H]uridine indicated that inhibition of this activity closely paralleled that of RNA synthesis. Quantitation of individual uridine nucleotides by polyethyleneimine-cellulose TLC revealed reduced levels of UTP and UDP whereas levels of UMP were elevated, suggesting that impairment of phosphorylation was not the result of cellular ATP depletion but, more likely, a direct effect on phosphouridine kinase enzymes. This mechanism of MeHg-induced inhibition of RNA synthesis was confirmed by assays of uridine phosphorylation using cell-free extracts in which exogenous ATP was supplied.     

Nucleotide Metabolism during Pine Pollen Germination

The metabolism of purine- and pyrimidine nucleotides in pine pollen (Pinus mugo) grown in suspension cultures have been examined. In the ungerminated dehydrated pollen, the presence of ATP has been demonstrated. Incubation of the pollen in a germination medium leads to an exhaustion of the ATP pool, which is restored with the onset of oxygen uptake. By labelling pollen cultures with ³²P-orthophosphate, it has been possible to quantitate the nucleotide components of the pollen, and thereby to measure changes in the nucleotide pattern at various growth stages. The most marked changes occur during the initial phase of tube growth when a large increase in the ribonucleoside triphosphate and the sugar nucleotide pools is observed. The contents of ATP and UDP-glucose are further increased if starch synthesis is initiated by the addition of sucrose to the culture medium. In order to determine whether nucleotides in pine pollen are synthesized from de novo pathways or via reutilization pathways, from breakdown products of nucleic acids, pollen was incubated with ¹⁴C-labelled precursors of both the de novo and the reutilization pathways. Incorporation experiments established de novo synthesis of ATP and GTP from glycine, and de novo synthesis of CTP and UTP from orotic acid. The operation of pathways for the utilization of exogenous nucleosides was also demonstrated. While uridine, cytidine and adenosine are incorporated into nucleoside triphosphate to a great extent, only minor incorporation of inosine and guanosine is observed. These reutilization pathways might be of importance for the synthesis of nucleotides during tube growth in situ. Addition of inhibitors of glycolysis and oxidative phosphorylation drastically reduces the level of ribonucleoside triphosphates, indicating a rapid turnover of the nucleotide pool.     

Uridine transport and RNA synthesis in growing and in density-inhibited animal cells

Both chick embryo fibroblasts and mouse 3T3 cells reduce the rate at which they incorporate H³ uridine into RNA as their growth becomes inhibited at high cell density. This reduction occurs as a function of the cell population density, and with chick embryo cells (in contrast to 3T3 cells) it is not accompanied by significant medium alterations. This indicates the importance of the cell population density in the control of cellular metabolism. The decline in H³ uridine incorporation is paralleled by a decline in the rate of uptake of the isotope into the acid-soluble pool, suggesting that decreased entry of H³ uridine into the cell, rather than a decreased rate of RNA synthesis, is responsible for the reduced rate of incorporation into RNA of density-inhibited cells. This suggestion was confirmed by finding that when the restriction on uridine uptake was overcome by increasing the concentration of uridine in the medium, the density-dependent inhibition of uridine incorporation was largely reversed. We conclude that, even though the rate of H³ uridine incorporation into RNA is reduced three- to five-fold in density-inhibited cells, the rate of synthesis of pulse-labeled RNA continues at 70 to 85% of the rapidly-growing rate.     

Size and specific activity of the UTP pool and overall rates of RNA synthesis in early mouse embryos

Mouse embryos from the one-cell to the blastocyst stage were cultured for 2 hr in the presence of 5 μM [³H]uridine or 10 μM [³H]adenosine, and the size and specific activity of the UTP and ATP pools were determined by an Escherichia coli RNA polymerase assay using synthetic poly(dA-dT) as template. The total UTP pool increased in size and specific activity with development from 0.05 pmole (0.06% labeled) in the one-cell stage to 0.54 pmole (27% labeled) in the blastocyst stage. The total ATP pool remained relatively constant in size at about 1 pmole/embryo, but increased in specific activity from 2.6 to 52% from one-cell to blastocyst. The turnover of the [³H]UTP pool was also examined under pulse-chase conditions in eight-cell and morula-stage embryos. The UTP pool decayed with approximately first-order kinetics up to 20 hr of chase, but the rate of decay was slower in eight-cell embryos (t_0.5 = 5.5 hr) than in morulae (t_0.5 = 2.8 hr). The observed specific activities of the UTP pools were used to calculate the overall rates of uridine incorporation into acid-precipitable material during early development. The rate of uridine incorporation per embryo increased from 3.6 × 10^?3 pmole/2 hr in the two-cell embryo to 1.8 × 10^?1 pmole/2 hr in the blastocyst. The rate of RNA synthesis per cell over a 2-hr period was estimated at 2.5 pg in the two- to four-cell embryo, 5 pg in the eight-cell, and 10 pg in the morula-early blastocyst.     

The effect of synaptic stimulation on RNA and protein metabolism in the R2 soma of Aplysia

Excitatory synaptic stimulation of the R2 neuron in the abdominal ganglion of Aplysia californica causes an increased incorporation of ³Huridine into RNA. However, this could be the result of a change in precursor specific activity rather than an increase in RNA synthesis. We find that at low external uridine concentrations (1.5 μM) there is no increase in ³H-uridine incorporation correlated with synaptic stimulation. In addition, no change in incorporation of ³H-leucine into total protein or in the pattern of newly-synthesized proteins, resolved by electrophoresis on SDS-polyacrylamide gels, was detected with stimulation. Since the R2 neuron can be stimulated without a detectable change in RNA or protein synthesis, we conclude that the increase in incorporation observed at high external uridine concentrations (100 μM) could be caused by increased specific activity in a precursor pool rather than by an RNA synthesis change.     

Stimulation of the phosphorylation of uridine in skeletal muscle by insulin and vanadate

Summary The action of insulin and sodium vanadate on the phosphorylation of uridine by skeletal muscle was studied in vitro. Insulin significantly increased the incorporation of ³H-uridine into uracil nucleotides by pieces of rat diaphragm incubated for 15 min in a phosphate-buffered medium. This action of the hormone was exceptionally consistent when MgATP was added to the incubation medium. In experiments in which pieces of psoas muscle were incubated in TRIS buffer in the presence and absence of insulin, the hormone caused a significant activation of uridine kinase measured in cytosolic extracts of the incubated tissue. In experiments with rat diaphragm similar to those with insulin, the vanadate ion caused a significant increase in phosphorylation of uridine. The results of these experiments provide preliminary support for the proposal that uracil nucleotide metabolism is regulated by insulin and that insulin activates uridine kinase, the limiting enzyme in the synthesis of uracil nucleotides from uridine by the salvage pathway.     

Incorporation of labeled uridine into acid-soluble and acid-insoluble materials during development of chick embryo

The incorporation of [5-³H]uridine into acid-soluble and acid-insoluble materials has been studied during the first stages of chick embryo development.It has been found a constant rate of RNA biosynthesis from day 3 to day 12 of incubation except for around day 8. The drastic decrease of the incorporation of the labeled precursor into acid-in-soluble material found from day 3 to day 12 is due to a similar decrease of the UTP pool specific radioactivity. This in turn is due mainly to the external isotope availability and to its transport from the injection site to the site of RNA synthesis.     

Inhibition of nucleic acid synthesis in Ehrlich tumor cells by periodate-oxidized adenosine and adenylic acid

Periodate-oxidized adenosine and AMP were inhibitory to both RNA and DNA synthesis in Ehrlich tumor cells in culture. With periodate-oxidized adenosine, the inhibition of RNA synthesis paralleled the inhibition of DNA synthesis. Periodate-oxidized AMP, however, was more inhibitory to DNA synthesis than to RNA synthesis. With both compounds, there was a decrease in the conversion of [¹⁴C]cytidine nucleotides to [¹⁴C]deoxycytidine nucleotides in the acid-soluble pool. The borohy-dride-reduced trialcohol derivative of the periodate-oxidized adenosine compound was not inhibitory to DNA or RNA synthesis in the tumor cells. The incorporation of [³H]uridine into 28S and 18S ribosomal RNA was inhibited by both periodate-oxidized adenosine and AMP, but the incorporation of [³H]uridine in 45S, 5S, and 4S RNA was essentially unaffected by these compounds. Periodate-oxidized adenosine inhibited Ehrlich tumor cell growth in vivo.     

Metabolism ofAedes aegypti cells grown in vitro. 1. Incorporation of3H-uridine and14C-leucine

Summary Metabolic activity ofA. aegypti cells grown in vitro has been studied by incorporation of³H-uridine and¹⁴C-leucine. “Chase” experiments with unlabeled precursors, and the use of actinomycin D and puromycin, showed that³H-uridine was incorporated into cellular RNA, and that¹⁴C-leucine was incorporated into protein of these cells. Incorporation of³H-uridine was inhibited when actinomycin D was used at a concentration of 10 μg/ml, and¹⁴C-leucine incorporation was inhibited to the same extent by puromycin at a concentration of 100 μg/ml medium. Contribution No. 148.     

Rates of synthesis of major classes of RNA in Drosophila embryos.

We have been successful in labeling to high specific activity (3 × 10⁵ dpm/μg) the RNA synthesized by large numbers of Drosophila embryos. Embryos of various developmental stages were rendered permeable with octane and labeled with [³H]uridine for 1 hr. At each stage the total dpm incorporated into RNA and the specific activity of the UTP pool were measured and used to calculate the absolute rate of RNA synthesis per embryo. This rate increases during embryonic development, from 1 pmole UTP/hr at 2 hr after oviposition to 6 pmoles UTP/hr at 15 hr. The rates of synthesis of nuclear and cytoplasmic poly(A)^? and poly(A)⁺ RNAs were determined by analyzing the fractionated RNAs from each stage by sucrose gradient sedimentation. There is a significant activation of nuclear RNA synthesis at the blastoderm stage (approximately 2 hr after oviposition). After blastoderm, the rates of synthesis of nuclear and cytoplasmic poly(A)^? and poly(A)⁺ RNA per embryo increase continuously; the rate of synthesis of each of these classes per nucleus, however, remains fairly constant. After making corrections for turnover during the labeling period, we find that the rates of synthesis of the major classes of RNA per nucleus at the gastrula stage are: cytoplasmic poly(A)⁺ RNA, 0.06 fg/nucleus-min; hnRNA, 0.86 fg/nucleus-min; and ribosomal RNA, 0.46 fg/nucleus-min. These rates are compared to rates of RNA synthesis in sea urchin embryos.     

Evidence for compartmentation of uridine nucleotide pools in rat hepatoma cells

Interaction between the de novo and salvage pathways of pyrimidine metabolism was studied in a line of rat hepatoma cells by co-labelling with [14C]-uridine and [3H]orotate. A difference in the ratio of 14C/3H between CTP and UTP in acid-soluble nucleotide pool was reflected in the corresponding ratios in CMP and UMP in RNA, with uridine labelling cytidine nucleotides relatively more effectively than orotate. These results are not compatible with the concept of a single UTP pool, and a new model for pyrimidine anabolic pathways, based on compartmentation of de novo from salvage pathways, is proposed.     

Kinetics of uridine uptake and incorporation into RNA in tobacco pollen culture

The capacity of pollen tubes to utilize exogenous uridine during 8 h of cultivation in shaken suspension in a sugar-mineral medium was examined by continuous and pulse labelling with³H-uridine. The increase of uptake with increasing concentration of the nucleoside indicated a saturable transport system with an approximate K_m of 9.4 × 10⁻⁶ M and 12.5 × 10⁻⁶M as determined in 1-h and 6-h cultures, respectively. Maximal uptake took place at the beginning of germination reaching a rate of about 2 nmol h⁻¹ per 1 mg of dry pollen at 0.1 mM external uridine. The uptake activity decreased with the time of pollen tube growth to less than one third during the 8-h cultivation period. Moreover, the level of radioactivity taken up initially decreased later on during continuous cultivation in the presence of³H-uridine. The uptake took place against a concentration difference and the onset and rate of uridine release depended on its exogenous concentration. The activity of the nucleoside incorporation into RNA increased during the first 4 h of cultivation, decreasing later on. The proportion of RNA radioactivity in continuously labelled pollen tubes grew steadily during 6 h and reached 2.5% with respect to soluble pool at 0.4 μM uridine. The time course of RNA labelling was independent of uridine concentration within the range of 0.4 μM to 40 μM but this concentration rise resulted in an about fiftyfold increase of the total amount of external uridine incorporated.