Stimulation by insulin of the formation of ribonucleic acid and protein by mammary tissues in vitro

1. Insulin is one of the hormones that are essential for successful tissue culture of explants of the mammary glands of pregnant mice. We report here effects of insulin on RNA and protein formation by mammary tissue from pregnant mice and rats incubated in tissue-culture medium 199. 2. The incorporation of [(14)C]adenine over 3hr. into the RNA of explants of the mammary glands of pregnant mice was increased by an average of 68% when the medium contained 5mug. of insulin/ml. Under similar conditions the incorporation into the RNA of slices of the glands of pregnant rats was increased by an average of 61%. Incorporation into the RNA of slices from lactating rats was stimulated to a smaller extent. 3. Adipose tissue was separated from the glands of pregnant mice and the effect of insulin on the incorporation of adenine into its RNA was studied. In whole explants the incorporation of adenine, both with and without insulin, is almost entirely into the RNA of the mammary parenchyma and not of the adipose tissue. 4. Insulin also stimulated by 38% the incorporation of [(14)C]leucine over 3hr. into the proteins of slices of the glands of pregnant rats. It had no significant effect on slices from lactating rats. 5. Actinomycin D (10mug./ml.) decreased the incorporation of [(14)C]adenine into the RNA of slices of the glands of pregnant rats by an average of 97%. Though it also decreased the incorporation of [(14)C]leucine into the proteins by an average of 25%, the percentage stimulation by insulin of this incorporation remained unchanged.     

Effects of colchicine on nucleic acid metabolism during metamorphosis of Tenebrio molitor L. and in some mammalian tissues

1. Administration of 10mug. of colchicine/pupa of the beetle Tenebrio molitor L. arrests its differentiation, the pupa remaining alive for 2-3 weeks. 2. The same concentration of colchicine inhibits DNA synthesis and stimulates RNA synthesis (as shown by incorporation into the nucleic acids of labelled adenine, labelled uridine and labelled thymidine). The effects of colchicine on nucleic acid metabolism are first detected 3 days after its administration to first-day pupae. 3. No effects of colchicine are seen on [1-(14)C]glycine incorporation into protein in vivo. 4. Relatively high concentrations of colchicine (e.g. 10mm) suppress incorporation of [8-(14)C]adenine into RNA in dorsal abdominal wall in vitro. Such concentrations have no effect on its incorporation into acid-soluble nucleotides. 5. Colchicine (1mm) suppresses incorporation of [8-(14)C]adenine into DNA to a greater extent than into RNA in various mammalian tissues in vitro (e.g. rat spleen, regenerating rat liver, rat embryo, guinea-pig intestinal mucosa, Ehrlich ascites cells). Colchicine (1mm) has no effect on the rate of respiration of, or on incorporation of radioactivity into acid-soluble nucleotides in, the mammalian tissues tested. 6. Further evidence indicates complex-formation between colchicine and DNA, and it is suggested that the effect of colchicine in suppressing DNA synthesis is due to its combination with the DNA primer (template).     

Effect of chloramphenicol on ribonucleic acid synthesis in liver cells in suspension

1. Chloramphenicol has a stimulatory effect on the incorporation of radioactive phosphate into the RNA of perfused rat-liver slices, whole liver homogenates or the liver-cell suspensions, and no effect on the incorporation of [(14)C]adenine and [(14)C]uracil into the RNA of the tissue slices. 2. Chloramphenicol completely inhibits the incorporation of labelled adenine and uracil into the RNA of the cell suspensions, or into the RNA of homogenates derived from the whole liver tissues. 3. Chloramphenicol has at most a slight inhibitory effect on the transport of labelled adenine or uracil in the hepatic cells in suspension; in the slices, the transport of these bases is not inhibited at all. 4. The above observations indicate that: (a) unlike the tissue slices, hepatic cells in suspension are permeable to chloramphenicol; (b) in the presence of chloramphenicol, for reasons that are not clear, the conversion of the base into the appropriate nucleotide does not proceed.     

Methylation of newly synthesized ribonucleic acid by isolated rat liver nuclei. Characterization of the ribonucleic acid synthesized by nuclei from starved animals

1. Nuclei from rat liver incubated with S-adenosyl[methyl-(14)C]methionine incorporated radioactivity into RNA and into lipid and protein. 2. All of the labelled RNA was extracted from the nuclei with trichloroacetic acid at 90 degrees C. 3. The [(14)C]methyl-group incorporation into the hot-trichloroacetic acid extract was 30% inhibited by the addition of actinomycin D (100mug/mg of DNA) or by the omission of CTP, GTP and UTP. 4. Assuming that the main substrate for this triphosphate-dependent methylation was newly synthesized precursor rRNA containing one methyl group/30 uridylate residues, it was calculated that approx. 60% of the [(14)C]UMP incorporated under similar conditions represented precursor rRNA synthesis. 5. In agreement with this, low concentrations of actinomycin D (approx. 1mug/mg of DNA) sufficient to abolish the triphosphate-dependent incorporation of [(14)C]methyl group inhibited 68% of the [(14)C]UMP incorporation. 6. The incorporation of [(14)C]UMP by nuclei from starved animals decreased progressively with increasing periods of starvation, whereas the triphosphate-dependent [(14)C]methyl-group incorporation was not further decreased after 1 day of starvation. 7. This suggests that precursor rRNA synthesis decreased within 1 day whereas other species of RNA were affected only after longer periods of starvation.     

Effect of pyridoxine deficiency on nucleic acid metabolism in the rat

1. The nucleic acid metabolism in the pyridoxine-deficient rat has been investigated through studies on the incorporation of radioactivity from various isotopically labelled compounds into liver and spleen DNA and RNA. 2. In pyridoxine deficiency, the incorporation of radioactivity from sodium [¹⁴C]formate was apparently increased. The magnitude of this effect on incorporation into liver RNA and DNA and spleen RNA was approximately the same. The incorporation into spleen DNA was enhanced to a much greater degree. Administration of pyridoxine 24hr. before the rats were killed reversed the changes in incorporation of radioactivity from [¹⁴C]formate. 3. In pyridoxine deficiency, the incorporation of radioactivity from dl-[3-¹⁴C]serine, [8-¹⁴C]adenine, [Me-³H]thymidine and [2-¹⁴C]deoxyuridine was decreased. The incorporation of radioactivity from l-[Me-¹⁴C]methionine was not affected. No noteworthy differences in the effect of pyridoxine deficiency on the incorporation of radioactivity from dl-[3-¹⁴C]serine into DNA and RNA were observed, whereas the effect of the deficiency on the incorporation of radioactivity from [8-¹⁴C]adenine into spleen DNA was somewhat greater than that into spleen RNA. Administration of pyridoxine 24hr. before the rats were killed reversed the changes in incorporation of radioactivity from [3-¹⁴C]serine and [8-¹⁴C]adenine. 4. The adverse effects of pyridoxine deficiency on the biosynthesis of nucleic acids and cell multiplication are discussed in relation to the role of pyridoxal phosphate in the production of C₁ units via the serine-hydroxymethylase reaction.     

The inhibition of nucleic acid synthesis by mycophenolic acid

1. Mycophenolic acid, an antibiotic of some antiquity that more recently has been found to have marked activity against a range of tumours in mice and rats, strongly inhibits DNA synthesis in the L strain of fibroblasts in vitro. 2. The extent of the inhibition of DNA synthesis is markedly increased by preincubation of the cells with mycophenolic acid before the addition of [(14)C]thymidine. 3. The inhibition of DNA synthesis by mycophenolic acid in L cells in vitro is reversed by guanine in a non-competitive manner, but not by hypoxanthine, xanthine or adenine. 4. The reversal of inhibition by guanine can be suppressed by hypoxanthine, 6-mercaptopurine and adenine. 5. Mycophenolic acid does not inhibit the incorporation of [(14)C]thymidine into DNA in suspensions of Landschütz and Yoshida ascites cells in vitro. 6. Mycophenolic acid inhibits the conversion of [(14)C]hypoxanthine into cold-acid-soluble and -insoluble guanine nucleotides in Landschütz and Yoshida ascites cells and also in L cells in vitro. There is some increase in the radioactivity of the adenine fraction in the presence of the antibiotic. 7. Mycophenolic acid inhibits the conversion of [(14)C]hypoxanthine into xanthine and guanine fractions in a cell-free system from Landschütz cells capable of converting hypoxanthine into IMP, XMP and GMP. 8. Preparations of IMP dehydrogenase from Landschütz ascites cells, calf thymus and LS cells are strongly inhibited by mycophenolic acid. The inhibition showed mixed type kinetics with K(i) values of between 3.03x10(-8) and 4.5x10(-8)m. 9. Evidence was also obtained for a partial, possibly indirect, inhibition by mycophenolic acid of an early stage of biosynthesis of purine nucleotides as indicated by a decrease in the accumulation of formylglycine amide ribonucleotide induced by the antibiotic azaserine in suspensions of Landschütz and Yoshida ascites cells and L cells in vitro.     

Stimulation of incorporation of nucleic acid precursors into HeLa cells caused by provaline

1. The effect of proflavine and other acridines on the incorporation of precursors into the nucleic acids of HeLa cells was examined. 2. Relatively low concentrations (50mum) of proflavine completely inhibited incorporation of precursors into DNA, but allowed a small extent of incorporation into RNA. 3. Acridine-resistant incorporation into RNA was unaffected by actinomycin D at 2mug./ml. and persisted even at high concentrations (500mum) of many acridines. 4. A few combinations of acridine and precursor, notably 250mum-proflavine and [(14)C]adenine, caused a stimulation of incorporation. 5. The proflavine-stimulated incorporation was into alkali-stable di- and tri-nucleotides. 6. It was concluded that the effect was due to the preferential inhibition of degradation of a fraction of RNA that normally turned over, thus allowing small radioactive oligonucleotides to accumulate in the cells.     

Effect of a single dose of dimethylnitrosamine on biosynthesis of nucleic acid and protein in rat liver and kidney

1. Administration of a single dose of dimethylnitrosamine to rats temporarily fed on a protein-deficient diet causes a high incidence of kidney tumours. The effect of such a dose of dimethylnitrosamine (40mg/kg body wt.) on metabolism of nucleic acids and protein in rat liver and kidneys was examined during the week immediately after administration. 2. Incorporation of [(14)C]leucine and [(14)C]orotate into hepatic macromolecules was inhibited within 5h of injection of dimethylnitrosamine, and did not recover for at least 5 days. Interpretation of these results is complicated by the concomitant extensive hepatic necrosis. 3. Renal RNA synthesis was assayed by incorporation of [(14)C]orotate in vivo and measurement of DNA-dependent RNA polymerase activity in vitro. Both systems indicate biphasic inhibition; minimal activity was recorded 9h and 3 days after treatment. Changes in incorporation of [(14)C]leucine into renal protein were similar but less marked. 4. Sucrose-density-gradient analysis of renal cytoplasmic RNA indicated increased synthesis of rRNA 24h after injection of the nitrosamine. The rate of loss of radioactivity from kidney ribosomes pre-labelled with [(14)C]orotate was not modified by dimethylnitrosamine. 5. Dimethylnitrosamine increased incorporation of [(3)H]-thymidine into renal DNA. The three distinct periods of stimulated synthesis observed are discussed, with particular reference to recently published morphological studies of the sequential development of kidney tumours induced by dimethylnitrosamine in protein-depleted rats.     

The control of nucleic acid and nicotinamide nucleotide synthesis in regenerating rat liver

1. The effect of injecting nicotinamide on the incorporation of [(14)C]orotate into the hepatic nucleic acids of rats after partial hepatectomy was investigated. 2. At 3h after partial hepatectomy the rapid incorporation of [(14)C]orotate into RNA, and at 20h after partial hepatectomy the incorporation of [(14)C]orotate into both RNA and DNA, were inhibited in a dose-dependent fashion by the previous injection of nicotinamide. 3. The injection of nicotinamide at various times before the injection of [(14)C]orotate at 20h after partial hepatectomy revealed an inhibition of the incorporation of orotate into RNA and DNA which was non-linear with respect to the duration of nicotinamide pretreatment. 4. The induction of a hepatic ATP depletion by ethionine demonstrated that the synthesis of hepatic NAD and NADP in partially hepatectomized rats was more susceptible to an ATP deficiency than in control rats. 5. The total hepatic activity of ribose phosphate pyrophosphokinase (EC 2.7.6.1) was assayed at various times after partial hepatectomy and found to be only marginally greater than the maximum rate of hepatic NAD synthesis induced in vivo by nicotinamide injection between 12 and 24h after partial hepatectomy. 6. It is suggested that a competition exists between NAD synthesis and purine and pyrimidine nucleotide synthesis for available ATP and particularly 5-phosphoribosyl 1-pyrophosphate. In regenerating liver the competition is normally in favour of the synthesis of nucleic acid precursors, at the expense of NAD synthesis. This situation may be reversed by the injection of nicotinamide with a subsequent inhibition of nucleic acid synthesis.     

Purine ribonucleotide biosynthesis, interconversion and catabolism in mouse brain in vitro

The relative rates of the synthetic, interconversion and catabolic reactions of purine metabolism in chopped mouse cerebrum were studied. The rates of incorporation of [(14)C]adenine and [(14)C]hypoxanthine into purine ribonucleotides were much less than the potential activities of adenine phosphoribosyltransferase and hypoxanthine phosphoribosyltransferase, and the rates of incorporation were stimulated by the addition of guanosine to the incubation mixture. The availability of ribose phosphates may be a limiting factor for the formation of ribonucleotides from purine bases. The rate of incorporation of [(14)C]adenosine into purine ribonucleotides was at least seven- to eight-fold higher than that of adenine. The radioactivity in adenine ribonucleotides synthesized from adenine and hypoxanthine was about 100- and ten-fold respectively higher than that in the radioactive guanine ribonucleotides. The conversion of inosinate into guanine ribonucleotides was probably limited by the amount of inosinate available, and the conversion of adenine ribonucleotides into guanine ribonucleotides was probably limited by the activity of adenylate deaminase. The rate of catabolism of [(14)C]adenosine was low in comparison with its rate of utilization for ribonucleotide synthesis. A fraction of the [(14)C]hypoxanthine was catabolized to xanthine and urate. [(14)C]Guanine was completely converted into xanthine, mostly by the guanine deaminase that was released during incubation of chopped mouse cerebrum.     

Preferential alkylation of mitochondrial deoxyribonucleic acid by N-methyl-N-nitrosourea

The reaction of the carcinogen N-methyl-N-nitrosourea with mitochondrial DNA from various rat tissues was examined in vivo and in vitro. After incubation of isolated mitochondria or cell nuclei with N[(14)C]-methyl-N-nitrosourea in vitro and subsequent isolation and purification of the DNA the specific radioactivity of the mitochondrial DNA was 3-7 times that of the nuclear DNA. The incorporation of (14)C into embryonic mitochondrial DNA in vitro was about twice that into the liver mitochondrial DNA. Identical incorporation rates, however, were found for the reaction of isolated mitochondrial DNA or nuclear DNA respectively with N[(14)C]-methyl-N-nitrosourea. After intraperitoneal injection of 43.3-58.5mg of N[(14)C]-methyl-N-nitrosourea/kg body wt. to adult rats the labelling of the mitochondrial DNA was on average 5 times that of the nuclear DNA. A smaller specific labelling was observed for the ribosomal RNA, transfer RNA, and mitochondrial RNA as well as for the mitochondrial protein as compared with the mitochondrial DNA. After hydrolysis of the alkylated nucleic acids with hydrochloric acid, fractionation was carried out on Dowex 50 cation-exchange columns. In most experiments 70-80% of the input (14)C radioactivity was eluted in the 7-methylguanine fraction. The preferential alkylation of the mitochondrial DNA by N-methyl-N-nitrosourea in situ is discussed in connexion with the cytoplasmic-mutation hypothesis of carcinogenesis.     

Effect of cycloheximide on protein and ribonucleic acid synthesis in cultured human lymphocytes

1. Phytohaemagglutinin stimulates the transformation into blast cells of human lymphocytes incubated in vitro. This transformation is accompanied by an increase in the incorporation of [(14)C]leucine into protein and [(3)H]uridine into RNA. 2. The incorporation of [(14)C]leucine by cultures grown in the presence or absence of phytohaemagglutinin is inhibited to the same extent by cycloheximide, a known inhibitor of protein synthesis. 3. Lymphocytes grown without phytohaemagglutin synthesize mainly non-ribosomal RNA. [(3)H]Uridine incorporation by these cells was increased by cycloheximide. 4. Lymphocytes incubated with phytohaemagglutinin begin to synthesize substantial quantities of ribosomal RNA. Under these conditions [(3)H]uridine incorporation was partially inhibited by cycloheximide. This inhibition is shown to be largely a result of inhibition of the synthesis of ribosomal RNA.     

Production of dissolved DNA, RNA, and protein by microbial populations in a Florida reservoir.

Production of dissolved macromolecules by ambient autotrophic and heterotrophic microbial populations was measured in a eutrophic Florida reservoir by in situ labeling with various radioactive substrates. When [3H]thymidine was used as the precursor, production of labeled dissolved DNA, RNA, and protein was observed. The rate of production of labeled dissolved macromolecules was 3.1% the rate of cellular incorporation of [3H]thymidine, and the production of dissolved DNA represented 2.3% the rate of cellular DNA incorporation. Microautotrophic populations labeled with NaH[14C]CO3 produced dissolved RNA and protein at rates of 0.24 and 0.11 micrograms of C/liter per h, respectively, or 1.8% the total rate of carbon fixation, with no measurable dissolved DNA production. In an attempt to specifically label phytoplankton DNA, samples were incubated with [3H]adenine or 32Pi in the presence and absence of the photosynthetic inhibitor 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU). Although DCMU inhibited 14C fixation by approximately 99%, this antimetabolite had only a slight effect on [3H]adenine incorporation and no effect on 32P incorporation into cellular macromolecules. Significant amounts of dissolved DNA were produced in both [3H]adenine and 32Pi incubations, but again DCMU had no effect on the production rates. These results indicate that actively growing populations of both phytoplankton and bacterioplankton produced dissolved RNA and protein, while only active bacterioplankton produced measurable quantities of dissolved DNA. Dead or senescent phytoplankton may have produced dissolved DNA, but would not be measured in the relatively short incubations used. These findings also indicate that [3H]adenine and 32Pi primarily labeled heterotrophic bacterioplankton and not phytoplankton in this environment.     

Production of dissolved DNA, RNA, and protein by microbial populations in a Florida reservoir.

Production of dissolved macromolecules by ambient autotrophic and heterotrophic microbial populations was measured in a eutrophic Florida reservoir by in situ labeling with various radioactive substrates. When [3H]thymidine was used as the precursor, production of labeled dissolved DNA, RNA, and protein was observed. The rate of production of labeled dissolved macromolecules was 3.1% the rate of cellular incorporation of [3H]thymidine, and the production of dissolved DNA represented 2.3% the rate of cellular DNA incorporation. Microautotrophic populations labeled with NaH[14C]CO3 produced dissolved RNA and protein at rates of 0.24 and 0.11 micrograms of C/liter per h, respectively, or 1.8% the total rate of carbon fixation, with no measurable dissolved DNA production. In an attempt to specifically label phytoplankton DNA, samples were incubated with [3H]adenine or 32Pi in the presence and absence of the photosynthetic inhibitor 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU). Although DCMU inhibited 14C fixation by approximately 99%, this antimetabolite had only a slight effect on [3H]adenine incorporation and no effect on 32P incorporation into cellular macromolecules. Significant amounts of dissolved DNA were produced in both [3H]adenine and 32Pi incubations, but again DCMU had no effect on the production rates. These results indicate that actively growing populations of both phytoplankton and bacterioplankton produced dissolved RNA and protein, while only active bacterioplankton produced measurable quantities of dissolved DNA. Dead or senescent phytoplankton may have produced dissolved DNA, but would not be measured in the relatively short incubations used. These findings also indicate that [3H]adenine and 32Pi primarily labeled heterotrophic bacterioplankton and not phytoplankton in this environment.     

Metabolism of tissue cells in suspension. Synthesis of ribonucleic acid by liver cells in suspension

1. Liver cells in suspension are shown to incorporate several RNA precursors into their RNA. 2. The incorporation of [³²P]phosphate and [¹⁴C]adenine into the RNA of the cell suspension is usually of the same order as that in the perfused (or unperfused) liver slices. However, the initial lag in the incorporation of adenine into the RNA of the cell suspensions is much longer than that obtained for the tissue slices, and the optimum incorporation of adenine in the former, unlike that in the latter, needs exogenous glucose and probably a high concentration of phosphate. 3. The cell suspensions also differ from the tissue slices in being unable to incorporate [¹⁴C]orotic acid into their RNA, and resemble tumour tissues in incorporating uracil into their RNA at a rate significantly higher than that obtained with the tissue slices. 4. The above differences in the metabolic behaviour of liver-cell suspensions and tissue slices are considered to be due to the different levels of organization of the liver cells in the two tissue preparations.     

Deoxyribonucleic acid metabolism and nuclear division during spore germination in Fusarium oxysporum.

Ungerminated microconidia of Fusarium oxysporum have a mean cell DNA content of 0-134 times 10--12 g/cell with a guanine-plus-cytosine composition (%GC) of 50-75%. During germination, the first dry weight increase of the spore population was defected after 3 h incubation and the first germ tube appeared after 4 h. The total DNA of the culture sharply increased after 5 h, followed by a pause at 6 h. At this time the DNA content per nucleus was maximal and the first nuclear divisions were detected. auses in the rise of total DNA of the culture and in the [14C]adenine incorporation pattern suggest that there is partial synchrony in DNA synthesis at the beginning of incubation. This is also supported by the fact that until 8 h, only hyphae with 1, 2 and 4 nucleic were observed. [14C]adenine incorporation into DNA averaged 2-68% of the total taken up in 10 h incubation.     

The relationship between cellular nucleic acids in the developing rat cerebral cortex

1. In the rat cerebral cortex net DNA synthesis ceases when the animal has reached about 25g. body weight (18 days of age). There is then little further change in the DNA content per cortex. 2. Nuclear and transfer RNA follow a similar pattern to DNA. 3. Microsomal and ribosomal RNA content increases up to 25g. body weight but then declines. The decrease in ribosomal and microsomal RNA content is associated with a change in RNA base composition. 4. Incorporation of [(14)C]orotic acid into nuclear RNA proceeds at a similar rate in 4-day-old and adult animals. However, there is a lag period of about 60min. in the young animals during which incorporation into the ribosome fractions proceeds slowly. In the adult animals the lag period is not seen.     

ADP-ribosylation of histones of the chicken liver nucleus at different rates of glycohydrolase hydrolysis of NAD

The rate of incorporation of nicotinamide-[adenosine-U-14C]adenine dinucleotide [( Ado-U-14C]NAD) into histones and the poly(ADPR) polymerase activity of chromatin suggest that the NAD-dependent ADP-ribosylation of histones depends on the rate of NAD hydrolysis by glycohydrolase in chicken liver nuclei. With a rise in the NAD-glycohydrolase activity after treatment of nuclei with Triton X-100 the synthesis of poly(ADP-ribose) via the poly(ADPR)polymerase reaction is augmented, as a result of which the rate of [Ado-U-14C]NAD incorporation into total histones is increased. On the contrary, the decrease of NAD-glycohydrolase hydrolysis after treatment of nuclei with SDS lowers the poly(ADPR)polymerase activity and [Ado-U-14C]NAD incorporation into histones. Under these conditions, i. e. different rates of glycohydrolase hydrolysis of NAD in the nuclei, some redistribution of [Ado U-14C]NAD incorporation into individual histones occurs.     

Inhibition by soluble ribonucleic acid of stimulatory effect of liver template ribonucleic acid

1. Liver soluble RNA (s-RNA) and, to a smaller extent, Escherichia coli s-RNA inhibited the stimulation of [(14)C]leucine incorporation into protein in an E. coli S-30 system brought about by liver microsomal RNA or polyuridylic acid as template. 2. The inhibitory activity was associated with the fraction of the s-RNA possessing transfer-RNA activity. 3. The inhibition was exercised at a stage after charging of the s-RNA with amino acid. 4. Neither the method of preparation of the s-RNA nor its state of amino acid acylation affected its inhibitory action. 5. Stimulation of [(14)C]phenylalanine incorporation by polyuridylic acid or by liver microsomal RNA was not inhibited by addition of s-RNA. 6. It appears that excess of s-RNA inhibits the ambiguous incorporation of leucine with polyuridylic acid and also that something similar occurs with a natural template. 7. Estimation of messenger activity of samples of RNA should be carried out only after removal of s-RNA.     

Effects of pancreozymin, urecholine and actinomycin D on the metabolism of ribonucleic acid by canine pancreas

1. Canine pancreas slices were incubated with [6-(14)C]orotic acid and the rate of its incorporation into RNA was measured. RNA was fractionated by shaking homogenates with phenol at 2 degrees , 50 degrees , 65 degrees and 80 degrees . Cytoplasmic RNA was extracted at the lowest temperature and nuclear RNA at the higher temperatures. The samples were centrifuged through sucrose gradients and the E(260) and (14)C-sedimentation patterns determined. Incorporation of orotic acid was very rapid into cytoplasmic 4s RNA. This probably represents end-group turnover. No incorporation into cytoplasmic ribosomal RNA was observed. 2. The nuclear 50 degrees -RNA exhibited two E(260) peaks, at 18s and 28s. This portion of the sample contained but moderate amounts of [(14)C]RNA. The highly labelled material had sedimentation coefficients in the range 35-50s. The nuclear 65 degrees -RNA showed an E(260) peak at 16s. The [(14)C]RNA peak occurred at 25-35s and this portion demonstrated the highest specific activity of any RNA fraction. 3. The 50 degrees -RNA, 65 degrees -RNA and 80 degrees -RNA were hydrolysed and their base compositions were determined. All three samples possess a ribosomal type of composition (G+C)/(A+U)=(1.4-1.7). For this reason they are considered to contain ribosomal precursor RNA as their major constituent. 4. Actinomycin D (0.5mug./ml.) in the incubation medium inhibited incorporation of orotic acid into both nuclear fractions but not into 4s RNA. 5. The cholinergic drug Urecholine inhibited incorporation into the heavy, high-specific-activity portions of the nuclear fractions but did not inhibit incorporation into the ribosomal precursor type of nuclear RNA. A similar result was also obtained with the hormone pancreozymin. Moderate inhibition of incorporation of orotic acid into 4s RNA likewise resulted from the presence of the drug and the hormone.