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 in a unicellular eukaryote during the interdivision period and after growth arrest

The rate of uridine uptake was measured in Tetrahymena after shiftdown to non-nutrient physiological salt solution. Uptake follows Michaelis-Menten kinetics and an apparent K_m of transport of 2 × 10⁻⁶ M has been estimated. This value is in good agreement with those reported for tissue-derived cells in culture. Incorporation of uridine into RNA follows similar kinetics suggesting that uptake is rate limiting for incorporation. Within three hours after shiftdown the rate of uptake is decreased by an order of magnitude. Also at three hours after shiftdown pairing occurs between cells of complementary mating types. It seems likely that the change in uptake is a reflection of a surface change associated with differentiation. The rate of uptake was also measured during the interdivision period using cells synchronized by a physical selection procedure. A change in rate occurs at the time the cells begin replication of DNA and is essentially stable thereafter. These results indicate that there exists in Tetrahymena a relationship between surface properties as assayed by uridine uptake and properties of growth and differentiation.     

Thymidine transport by cultured Novikoff hepatoma cells and uptake by simple diffusion and relationship to incorporation into deoxyribonucleic acid

The initial rate of thymidine-³H incorporation into the acid-soluble pool by cultured Novikoff rat hepatoma cells was investigated as a function of the thymidine concentration in the medium. Below, but not above 2 µM, thymidine incorporation followed normal Michaelis-Menten kinetics at 22°, 27°, 32°, and 37°C with an apparent K_m of 0.5 µM, and the V_max values increased with an average Q₁₀ of 1.8 with an increase in temperature. The intracellular acid-soluble ³H was associated solely with thymine nucleotides (mainly deoxythymidine triphosphate [dTTP]). Between 2 and 200 µM, on the other hand, the initial rate of thymidine incorporation increased linearly with an increase in thymidine concentration in the medium and was about the same at all four temperatures. Pretreatment of the cells with 40 or 100 µM p-chloromercuribenzoate for 15 min or heat-shock (49.5°C, 5 min) markedly reduced the saturable component of uptake without affecting the unsaturable component or the phosphorylation of thymidine. The effect of p-chloromercuribenzoate was readily reversed by incubating the cells in the presence of dithiothreitol. Persantin and uridine competitively inhibited thymidine incorporation into the acid-soluble pool without inhibiting thymidine phosphorylation. At concentrations below 2 µM, thymidine incorporation into DNA also followed normal Michaelis-Menten kinetics and was inhibited in an apparently competitive manner by Persantin and uridine. The apparent K_m and K_i values were about the same as those for thymidine incorporation into the nucleotide pool. The over-all results indicate that uptake is the rate-limiting step in the incorporation of thymidine into the nucleotide pool as well as into DNA. The cells possess an excess of thymidine kinase, and thymidine is phosphorylated as rapidly as it enters the cells and is thereby trapped. At low concentrations, thymidine is taken up mainly by a transport reaction, whereas at concentrations above 2 µM simple diffusion becomes the principal mode of uptake. Evidence is presented that indicates that uridine and thymidine are transported by different systems. Upon inhibition of DNA synthesis, net thymidine incorporation into the acid-soluble pool ceased rapidly. Results from pulse-chase experiments indicate that a rapid turnover of dTTP to thymidine may be involved in limiting the level of thymine nucleotides in the cell.     

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.     

Replication of mengovirus. II. General properties of the viral-induced ribonucleic acid polymerase

Plagemann, Peter G. W. (Western Reserve University, Cleveland, Ohio), and H. Earle Swim. Replication of mengovirus. II. General properties of the viral-induced ribonucleic acid polymerase. J. Bacteriol. 91:2327-2332. 1966.-Mengovirus induces the appearance of a ribonucleic acid (RNA) polymerase activity in Novikoff hepatoma cells which is readily distinguished from the deoxyribonucleic acid (DNA)-dependent RNA polymerase since it is not inhibited by actinomycin D or deoxyribonuclease, but is inhibited by ammonium sulfate, and is stable at -17 C. The incorporation of uridine into RNA by infected cells in the presence of actinomycin D does not reflect the viral polymerase activity as measured in cell-free preparations. The viral-induced RNA polymerase is produced in a biphasic fashion. Puromycin inhibits the production of viral polymerase, and in its presence the enzyme appears to be unstable between 4 and 6 hr. Puromycin also prevents the secondary rise in polymerase which begins at the end of replicative cycle. Under these conditions, however, the polymerase appears to be stable. The overall data indicated that some unspecified process is responsible for the apparent instability of viral-induced RNA polymerase between 4 and 6 hr and that it becomes inoperative toward the end of the replicative cycle.     

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.     

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.     

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.     

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.     

Purine and pyrimidine transport by cultured Novikoff cells. Specificities and mechanism of transport and relationship to phosphoribosylation.

Adenine, guanine, and hypoxanthine were rapidly incorporated into the acid-soluble nucleotide pool and nucleic acids by wild type Novikoff cells. Incorporation followed normal Michaelis-Menten kinetics, but the following evidence indicates that specific transport processes precede the phosphoribosyltransferase reactions and are the rate-limiting step in purine incorporation by whole cells. Cells of an azaguanine-resistant subline of Novikoff cells which lacked hypoxanthine-guanine phosphoribosyltransferase activity and failed to incorporate guanine or hypoxanthine into the nucleotide pool, exhibited uptake of guanine and hypoxanthine by a saturable process. Similarly, wild type cells which had been preincubated in a glucose-free basal medium containing KCN and iodoacetate transported guanine and hypoxanthine normally, although a conversion of these purines to nucleotides did not occur in these cells. The mutant and KCN-iodoacetate treated wild type cells also exhibited countertransport of guanine and hypoxanthine when preloaded with various purines, uracil, and pyrimidine nucleosides. The cells also possess a saturable transport system for uracil although they lack phosphoribosyltransferase activity for uracil. In the absence of phosphoribosylation, none of the substrates was accumulated against a concentration gradient. Thus transport is by facilitated diffusion (nonconcentrative transport). Furthermore, the apparent Km values for purine uptake by untreated wild type and azaguanine-resistant cells were higher and the apparent Vmax values were lower than those for the corresponding phosphoribosyltransferases...     

Selective Irreversible Inactivation of Replicating Mengovirus by Nucleoside Analogues: a New Form of Viral Interference

We describe the selective irreversible inhibition of mengovirus growth in cultured cells by a combination of two pyrrolopyrimidine nucleoside analogues, 5-bromotubercidin (BrTu) and tubercidin (Tu). At a concentration of 5 microgram/ml, BrTu reversibly blocked the synthesis of cellular mRNA and rRNA but did not inhibit either mengovirus RNA synthesis or multiplication. BrTu is a potent inhibitor of adenosine kinase, and low concentrations of BrTu (e.g., 0.5 microgram/ml), which did not by themselves inhibit cell growth, blocked phosphorylation of Tu and thus protected uninfected cells against irreversible cytotoxicity resulting from Tu incorporation into nucleic acids. In contrast, in mengovirus-infected cells, BrTu did not completely inhibit Tu incorporation into mengovirus RNA, allowing the formation of Tu-containing functionally defective polynucleotides that aborted the virus development cycle. This increased incorporation of Tu coupled to mengovirus infection could be attributed either to a reduction in the inhibitory action of BrTu and/or its nucleotide derivatives at the level of nucleoside and nucleotide kinases and/or, perhaps, to an effect upon the nucleoside transport system. The virus life cycle in nucleoside-treated cells progressed to the point of synthesis of negative strands and probably to the production of a few defective new positive strands. Irreversible virus growth arrest was achieved if the nucleoside mixture of BrTu (0.5 to 10 microgram/ml) and Tu (1 to 20 microgram/ml) was added no later than 30 min after virus infection and maintained for periods of 2 to 8 h. The cultures thus "cured" of mengovirus infection could be maintained and transferred for several weeks, during which they neither produced detectable virus nor showed a visible cytopathic effect; however, the infected and cured cells themselves, while metabolically viable, were permanently impaired in RNA synthesis and unable to divide. Although completely resistant to superinfecting picornaviruses, they retained the ability to support the growth of several other viruses (vaccinia virus, reovirus, and vesicular stomatitis virus), showing that cured cells had, in general, retained the metabolic and structural machinery needed for virus production. The resistance of cured cells to superinfection with picornaviruses seemed attributable neither to interferon action nor to destruction or blockade of virus receptors but more likely to the consumption of some host factor(s) involved in the expression of early viral functions during the original infection.     

Free pyrimidine nucleotide pool of Ehrlich ascites-tumour cells. Compartmentation with respect to the synthesis of heterogeneous nuclear RNA and precursors to ribosomal RNA.

The incorporation of [14C]orotate and [14C]uridine into UMP residues of hnRNA (heterogeneous nuclear RNA) and pre-rRNA (precursors to rRNA) of Eharlich ascites-tumour cells was compared: orotate was incorporated at a markedly higher rate into hnRNA. On the other hand, the rate of incorporation of uridine into pre-rRTNA was even somewhat higher than into hnRNA. The ratio of specific radioactivities of CMP to UMP residues in pre-rRNA and hnRNA was studied. At all times of labelling this ratio was similar for both RNA species independently of the precursor used. On addition of excess unlabelled uridine, the CMP/UMP labelling ratio in both pre-rRNA and hnRNA rose. However, this increase was much more pronounced with hnRNA. It is concluded that nuclear pyrimidine nucleotide pool for RNA synthesis is compartmentalized. The synthesis of hnRNa is supplied preferentially by the large and the small compartment, respectively. A detailed model for the cellular compartmentation of uridine nucleotide precursors to RNA is proposed.U     

The Uptake of Pyrimidine Nucleosides in Tetrahymena. I. Uridine*

SYNOPSIS. Uridine uptake was examined in Tetrahymena pyriformis GL-7 in defined medium under conditions where food vacuole formation is not a significant factor in solute acquisition by the cell. The results indicate the presence of a saturable mechanism which follows Michaelis-Menten kinetics. When corrected for diffusion the apparent K_m for the carrier is 2.3 ± 0.6 μM and the V_max is 7.3 ± 0.2 × 10^?7 nmoles/cell/min. It is evident from nucleotide pool analysis that most of the radioactivity of externally supplied [³H]uridine appears in UMP with the remainder in UTP. Uridine is apparently phosphorylated immediately upon entry into the cell and neither uridine-cytidine kinase activity nor RNA synthesis are rate-limiting in the uptake process. Uridine transport is competitively inhibited by a variety of ribo- and deoxyribonucleosides as well as several nucleoside analogs. Neither uracil nor ribose or deoxyribose are effective inhibitors of uridine transport indicating the carrier is specific for the nucleoside. There is little difference between the K_i values for ribo- as opposed to deoxyribonucleosides except in the case of deoxyguanosine which is much less effective as an inhibitor under the conditions of this study, than all the other nucleosides, including guanosine.     

The cyclo-oxygenase inhibitors indomethacin and ibuprofen inhibit the insulin-induced stimulation of ribosomal RNA synthesis in L6 myoblasts.

Insulin stimulated total RNA accretion and the incorporation of [3H]uridine into RNA in L6 skeletal-muscle myoblasts. Incorporation of uridine into the rRNA was measured after either separation of 18 S and 28 S rRNA species by agarose-gel electrophoresis or separation of dissociated 40 S and 60 S ribosomal subunits on sucrose density gradients. Both methods showed a stimulation by insulin of uridine incorporation into the RNA of the two subunits. Two non-steroidal anti-inflammatory drugs, indomethacin and ibuprofen, which inhibit the metabolism of arachidonic acid by the cyclo-oxygenase pathway, inhibited the insulin-induced accretion of total cellular RNA and the incorporation of uridine into the RNA of both ribosomal subunits. The effect of insulin was observed both by using a tracer dose of [3H]uridine (5 microM) and in the presence of a high concentration (1 mM) of uridine to minimize possible changes in intracellular precursor pools. Neither insulin nor indomethacin was found to affect the incorporation of uridine into the total intracellular nucleotide pool, or the conversion of uridine into UTP. The ability of inhibitors of arachidonic acid metabolism to prevent insulin-induced increases in RNA metabolism suggests that a prostaglandin or other eicosanoid is involved in the signal mechanism whereby insulin stimulates RNA synthesis.     

Effect of streptovaricin on the incorporation of uridine into cellular and viral RNA.

Poxvirus replication is inhibited by streptovaricin. The most readily observed effect is the inhibition of incorporation of [3H]uridine into viral mRNA, suggesting an inhibition of RNA synthesis. Streptovaricin also inhibits the incorporation of [3H]uridine into cellular RNA but not as severely as viral RNA. On the other hand, [3H]uridine incorporation into the RNA of Semliki Forest virus (SFV), which contains a positive strand RNA genome, does not seem to be inhibited by streptovaricin. The inhibitory effect of streptovaricin is completely reversible after removal of the inhibitor. In addition to inhibiting RNA synthesis, streptovaricin also may inhibit the methylation of cellular RNA. Viral RNA is stable in the presence of streptovaricin.     

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.     

Cytochalasin B. VI. Competitive inhibition of nucleoside transport by cultured Novikoff rat hepatoma cells

Cytochalasin B competitively inhibits the transport of uridine and thymidine by Novikoff rat hepatoma cells growing in suspension culture with apparent K_i''s of 2 and 6 µM, respectively, but has no effect on the intracellular phosphorylation of the nucleosides. Choline transport is not affected by cytochalasin B. Results from pulse-chase experiments indicate that cytochalasin B has no direct effect on the synthesis of RNA, DNA, or uridine diphosphate-sugars. The inhibition of uridine and thymidine incorporation into nucleic acids by cytochalasin B is solely the consequence of the inhibition of nucleoside transport.     

Neonatal hypothyroidism: enhanced incorporation of precursors into cerebral RNA in vivo and normalizing effect of a semi-acute injection of thyroxine.

The incorporation of radioactivity from intracisternally injected (6−¹⁴C) orotic acid into cerebral RNA and precursor pool was markedly elevated in 25 day-old hypothyroid rats compared to controls. Similar results were achieved with (2−¹⁴C) uridine as the isotopic precursor. The increase in specific radioactivity of cerebral ribosomal RNA and the purified nucleotide precursor pool was essentially restored to normal by a single injection of L-thyroxine at 22 days of age (72 hours prior to sacrifice). The results are compatible with an increased intracellular uptake (transport) of RNA precursors and reflect the participation of thyroid hormones in the regulation of events at the membrane during brain development.