Nitrosamine-induced carcinogenesis. The alkylation of nucleic acids of the rat by N-methyl-N-nitrosourea, dimethylnitrosamine, dimethyl sulphate and methyl methanesulphonate

1. N[(14)C]-Methyl-N-nitrosourea, [(14)C]dimethylnitrosamine, [(14)C]dimethyl sulphate and [(14)C]methyl methanesulphonate were injected into rats, and nucleic acids were isolated from several organs after various time-intervals. Radioactivity was detected in DNA and RNA, partly in major base components and partly as the methylated base, 7-methylguanine. 2. No 7-methylguanine was detected in liver DNA from normal untreated rats. 3. The specific radioactivity of 7-methylguanine isolated from DNA prepared from rats treated with [(14)C]dimethylnitrosamine was virtually the same as that of the dimethylnitrosamine injected. 4. The degree of methylation of RNA and DNA produced in various organs by each compound was determined, and expressed as a percentage of guanine residues converted into 7-methylguanine. With dimethylnitrosamine both nucleic acids were considerably more highly methylated in the liver (RNA, about 1% of guanine residues methylated; DNA, about 0.6% of guanine residues methylated) than in the other organs. Kidney nucleic acids were methylated to about one-tenth of the extent of those in the liver, lung showed slightly lower values and the other organs only very low values. N-Methyl-N-nitrosourea methylated nucleic acids to about the same extent in all the organs studied, the amount being about the same as that in the kidney after treatment with dimethylnitrosamine. In each case the RNA was more highly methylated than the DNA. Methyl methanesulphonate methylated the nucleic acids in several organs to about the same extent as N-methyl-N-nitrosourea, but the DNA was more highly methylated than the RNA. Dimethyl sulphate, even in toxic doses, gave considerably less methylation than N-methyl-N-nitrosourea in all the organs studied, the greatest methylation being in the brain. 5. The rate of removal of 7-methylguanine from DNA of kidneys from rats treated with dimethylnitrosamine was compared with the rate after treatment of rats with methyl methanesulphonate. No striking difference was found. 6. The results are discussed in connexion with the organ distribution of tumours induced by the compounds under study and in relation to the possible importance of alkylation of cellular components for the induction of cancer.     

The mechanism of thyrotrophin action in relation to lipid metabolism in thyroid tissue

1. The effects of thyrotrophin in vitro on the incorporation of [(14)C]-glucose, -glycerol, -palmitate and -oleate into the lipids of thyroid tissue were examined. 2. Thyrotrophin increased the incorporation of these (14)C-labelled precursors into phosphatidylinositol specifically. 3. Thyrotrophin also increased the proportion of (14)C radioactivity from labelled glucose, glycerol, palmitate and oleate incorporated into the 1,2-diglycerides. 4. The addition of thyrotrophin to thyroid slices for 10min., after 2hr. of prelabelling with [(14)C]glycerol, also increased the proportion of (14)C radioactivity incorporated into the 1,2-diglyceride fraction. 5. After incubation of thyroid tissue with [1-(14)C]palmitate, thyrotrophin caused a two- to three-fold increase in the specific radioactivity of palmitate isolated from phosphatidylinositol and 1,2-diglycerides. In contrast, the specific radioactivity of palmitate isolated from the choline and ethanolamine phosphoglycerides, 1,3-diglycerides and triglycerides was not increased by thyrotrophin.     

Mitochondrial DNA,RNA, and protein synthesis in different regions of developing rat brain

In vivo and in vitro (tissue slices) incorporation of labeled precursors into DNA, RNA, and proteins was measured in mitochondria obtained from cerebral hemispheres, cerebellum, and brain stem of rats at different days of postnatal development. To compare the synthesis of macromolecules in mitochondria with that in other subcellular fractions, the incorporation of labeled precursors into DNA, RNA, and proteins extracted from nuclei and into RNA and proteins extracted from microsomes and cytoplasmic soluble fractions was also measured.The results obtained showed that the incorporation of [³H]thymidine into DNA and of [¹⁴C]leucine into proteins of nuclei and mitochondria from the various brain regions examined decreased during postnatal development, however, at 30 days of age the specific radioactivity of mitochondrial DNA was higher than that of nuclear DNA. [³H]Uridine incorporation into RNA decreased from 10 to 30 days of age in nuclei while in mitochondria it was quite similar at both ages. This result may be due to a faster turnover of mitochondrial RNA compared to that of mitochondrial DNA and proteins. The results obtained suggest an active biosynthesis of macromolecules in brain mitochondria and might indicate an intense biogenesis of these organelles in rat brain during postnatal development.Preliminary reports of these results were presented at the XI FEBS Meeting, Copenhagen, August 14–19, 1977, Poster number A2-2-155-3, and at III Meeting of Italian Biochem. Soc., Siena, October 3–5, 1977, Abstract C6.     

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 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.     

Identification of [1-14C]pantothenic-acid-mediated modified mitochondrial proteins

The in vivo administration of [1-14C]pantothenic acid, which is the precursor of coenzyme A, resulted in the radioactive labelling of several mitochondrial proteins in rat liver. The incorporated radioactivity could be released by glutathione or 2-mercaptoethanol. Two mitochondrial matrix proteins acetyl-CoA acetyltransferase (liver and heart), an enzyme involved in the biosynthesis or degradation of ketone bodies, and 3-oxoacyl-CoA thiolase (liver), a protein participating in fatty acid oxidation were identified as modified proteins. The radioactivity was localized exclusively in forms A1 and A2 indicating that these forms represent the modified states of the acetyl-CoA acetyltransferase protein. Kinetics of incorporation of radioactivity revealed an accumulation of the modified forms. The ratio of specific radioactivities of A2 compared to A1 was 2.41 +/- 0.15 (n = 10). After in vivo labelling with [14C]leucine, the specific radioactivity of acetyl-CoA acetyltransferase depended on the state of the enzyme protein. The unmodified enzyme exhibited a lower specific radioactivity than its modified forms suggesting different turnover rates of these proteins.     

Phospholipid exchange reactions within the liver cell

1. Isolated rat liver mitochondria do not synthesize labelled phosphatidylcholine from CDP-[(14)C]choline or any phospholipid other than phosphatidic acid from [(32)P]phosphate. The minimal labelling of phosphatidylcholine and other phosphoglycerides can be attributed to microsomal contamination. However, when mitochondria and microsomes are incubated together with [(32)P]phosphate, the phosphatidylcholine, phosphatidylinositol and phosphatidylethanolamine of the reisolated mitochondria become labelled, suggesting a transfer of phospholipids between the two fractions. 2. When liver microsomes or mitochondria containing labelled phosphatidylcholine are independently incubated with the opposite un-labelled fraction, there is a substantial and rapid exchange of the phospholipid between the two membranes. Exchange of phosphatidylinositol also occurs rapidly, whereas phosphatidylethanolamine and phosphatidic acid exchange only slowly. There is no corresponding transfer of marker enzymes. The transfer of phosphatidylcholine does not occur at 0 degrees , and there is no requirement for added substrate, ATP or Mg(2+), but the omission of a heat-labile supernatant fraction markedly decreases the exchange. 3. After intravenous injection of [(32)P]phosphate, short-period labelling experiments of the individual phospholipids of rat liver microsomes and mitochondria in vivo give no evidence for a similar exchange process. However, the incubation of isolated microsomes and mitochondria with [(32)P]phosphate also fails on reisolation of the fractions to demonstrate a precursor-product relationship between the individual phospholipids of the two membranes. 4. The intraperitoneal injection of [(32)P]phosphate results in a far greater proportion of the dose entering the liver than does intravenous administration. After intraperitoneal administration of [(32)P]phosphate the specific radioactivities of the individual phospholipids are in the order microsomes > outer mitochondrial membrane > inner mitochondrial membrane. 5. The incorporation of (32)P into cardiolipin is very slow both in vivo and in vitro. After labelling in vivo the radioactivity in the cardiolipin persists compared with that of the other phospholipids, whose specific radioactivities in the microsomes and mitochondrial fragments decay at a similar rate to that of the acid-soluble phosphate pool. 6. The possibility of phospholipid exchange processes occurring in the liver cell in vivo is discussed, and it is suggested that only a small but highly labelled part of the endoplasmic-reticulum lipoprotein pool is involved in the transfer.     

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 incorporation of radioactive fatty acids into the phospholipids of nerve-cell-body membranes in vivo. Evidence for highly labelled neuronal nuclei

1. Nerve cell bodies were isolated in bulk from cerebral cortices of 15 day-old rabbits after intrathecal injections of [³H]plamitate, [³H]oleate or [³H]arachidonate and [¹⁴C]glycerol. 2. Nuclear, microsomal and two mitochondrial fractions were isolated from homogenates of the radioactively labelled nerve cell bodies by using differential and discontinuous-gradient centrifugation. 3. After 7.5min in vivo, a high percentage (>80%) of the total ³H-labelled fatty acid radioactivity was found in the membrane fractions of the nerve cell bodies, whereas after 60min in vivo 50% of the total [¹⁴C]glycerol radioactivity was found in the high-speed supernatant. 4. The specific radioactivities of phosphatidylcholine, phosphatidylethanolamine and phosphatidylinositol, and the radioactivity in neutral lipid and non-esterified fatty acid fractions were determined in the four subfractions, as were the distributions of several marker enzymes and nucleates. 5. With respect of ³H-labelled fatty acid, the phospholipids of the nuclear fraction had the highest specific radioactivities of the four subfractions. However, for [¹⁴C]glycerol labelling, generally the ¹⁴C specific radioactivities for individual phospholipids were comparable in the four subfractions. This latter observation suggests transport of phospholipids synthesized de novo between membranes of the nerve cell body. 6. Double-labelling experiments demonstrated that individual phospholipids and the combined neutral lipids of the nuclear fraction had higher labelling ratios of ³H-labelled fatty acid/[¹⁴C]glycerol than did the corresponding lipids of the microsomal or mitochondrial fractions. 7. On the basis of the labelling results and the marker studies, it is proposed that it is indeed the nuclei of the nuclear fraction that have these lipids highly labelled with ³H-labelled fatty acid, and the existence of nuclear acyl transferases that are responsible for this fatty acid incorporation is suggested.     

ADP-ribosylation of histones and NAD-pyrophosphorylase activity of chicken liver nuclei during induction of DNA damage

The rate of [14C]NAD incorporation into chicken liver nuclear histones was studied under conditions of DNA damage by N-methyl-N-nitrosourea and pancreatic DNAase I. With an increase in N-methyl-N-nitrosourea concentration from 8.5 X 10(-2) to 34.0 X 10(-2) mM, the ADP ribosylation of histones increases by 20% as compared to the control. In DNAase I-treated nuclei, the binding by histones of [14C]NAD sharply increases, reaching its maximum (18.3 X 10(-8) mM) at 30% cleavage of DNA. When 50% of DNA was cleaved, the rate of [14C]NAD incorporation into the histones was 8.0 X 10(-8) mM as compared to 6.1 X 10(-8) mM/mg protein in control samples. The poly(ADPR)polymerase activity was increased in both cases. It was shown that the NAD-pyrophosphorylase activity in chicken liver nuclei treated with N-methyl-N-nitrosourea does not differ from the control one, while in DNAase I-treated nuclei the maximum of the NAD-pyrophosphorylase activity was achieved, as well as the maximum of [14]NAD incorporation into the histones within the range of DNA damage of 25-35%, being equal to 37 X 10(-8) mM NAD/min/mg protein as compared to 26.0 X 10(-8) mM/min/mg protein in the control. At different degrees of DNA damage, the average length of the poly-ADP-ribose chain did not practically alter, thus suggesting the increase in the number of polymer binding sites in the histones.     

The morphological site of synthesis of cytochrome c in mammalian cells (Krebs cells)

In Krebs ascites-tumour cells, cytochrome c is segregated in the mitochondria and the level in microsomes could not be measured. At 22° in glucose–buffer Krebs cells synthesized a spectrum of proteins including cytochrome c. Mild osmotic shock in the presence of ribonuclease had little effect on incorporation of [¹⁴C]-leucine or [¹⁴C]valine into mixed mitochondrial protein but strongly inhibited synthesis of non-mitochondrial cytoplasmic proteins. Under these conditions, labelling of cytochrome c was also strongly inhibited. After pulse labelling of Krebs cells at 22° for 10min. the cytcchrome radioactivity found in mitochondria was higher than in microsomes. After addition of unlabelled amino acid as `chase' there was 137% increase in radioactivity of cytochrome c but only a 3% increase in radioactivity of whole-cell protein. It is concluded that the peptide chain of cytochome c is synthesized on cytoplasmic ribosomes. Mitochondria therefore do not have the character of self-replicating entities, but are formed by the cooperative function of messenger RNA of cytoplasmic ribosomes and, possibly, of intramitochondrial messenger derived from the mitochondrial DNA.     

The labelling of nucleic acids by radioactive precursors in the blue-green algae Anacystis nidulans and Synechocystis aquatilis Sanv.

Summary The labelling of nucleic acids of growing cells of the blue-green algae Anacystis nidulans and Synechocystis aquatilis by radioactive precursors has been studies. A. nidulans cells most actively incorporate radioactivity from [2-¹⁴C]uracil into both RNA and DNA, while S. aquatilis cells incorporate most effectively [2-¹⁴C]uracil and [2-¹⁴C]thymine.Deoxyadenosine does not affect incorporation of label from [2-¹⁴C]thymidine into DNA, but weakly inhibits [2-¹⁴C]thymine incorporation into both nucleic acids and significantly suppresses the incorporation of [2-¹⁴C]uracil.The radioactivity from [2-¹⁴C]uracil and [2-¹⁴C]thymine is found in RNA uracil and cytosine and DNA thymine and cytosine. The radioactivity of [2-¹⁴C]thymidine is incorporated into DNA thymine and cytosine. These results and data of comparative studies of nucleic acid labelling by [2-¹⁴C]thymine and [5-methyl-¹⁴C]thymine suggest that the incorporation of thymine and thymidine into nucleic acids of A. nidulans and S. aquatilis is accompanied by demethylation of these precursors. In this respect blue-green algae resemble fungi and certain green algae.     

Biosynthesis of thiamine. Incorporation experiments with 14C-labelled substrates and with [15N]glycine in Saccharomyces cerevisiae

1. Yeast was grown in a minimal synthetic medium together with a range of (14)C-labelled substrates under standardized conditions. After isolation, the purified thiamine was cleaved by sulphite and the pyrimidine and thiazole moieties were purified and assayed for radioactivity. 2. In order of decreasing incorporation, [(14)C]formate, [3-(14)C]serine, [2-(14)C]glycine and [2-(14)C]acetate supplied label for the pyrimidine, and [2-(14)C]glycine, [3-(14)C]serine, [1-(14)C]glycine, [(14)C]formate and [2-(14)C]acetate for the thiazole. Incorporation of label into the fragments from several other (14)C-labelled substrates, including [Me-(14)C]- and [3,4-(14)C(2)]-methionine, was insignificant. 3. [3-(14)C]Serine was shown not to contribute label to C-2 of the thiazole ring. 4. Significant incorporation of nitrogen from [(15)N]glycine into the thiazole moiety, but not into the pyrimidine moiety, was established. 5. It appears that C-2 and N-3 of the thiazole ring are formed from C-2 and the nitrogen atom of glycine, but the entire methionine molecule does not appear to be implicated.     

Effect of denervation on the synthesis of ribonucleic acid and deoxyribonucleic acid in rat diaphragm muscle

1. The effect of unilateral denervation of rat diaphragm muscle on its content of nucleic acids and their incorporation of precursors was investigated. 2. After denervation the paralysed hemidiaphragm hypertrophies and within 3 days its content of RNA increases considerably. The concentration of DNA/unit mass remains fairly constant. 3. During this period there is some increase in the rate of incorporation of [(14)C]adenine into RNA, whereas there is some diminution in the rate of incorporation of [(14)C]orotic acid. 4. Incorporation of [(14)C]adenine and [(3)H]thymidine into DNA is much increased in the paralysed tissue, reaching its maximum by about the third day, but returning to normal by the tenth. 5. The significance of these results in relation to the hypertrophy after denervation is discussed.     

Metabolism of uridine and determination of liver ribonucleic acid synthesis in developing and adult mice

The metabolism of [5-3H]uridine and the incorporation of the precursor into liver RNA was studied in developing (13-day-old) and adult (45-day-old) mice. Different time-courses of labelling and increased amounts of labelled catabolic products of uridine were found in liver and blood of developing mice compared with adult animals. This is suggested to be a consequence of enlarged metabolite pools resulting from a lower total amount of uracil-degrading enzymes in the developing mice. The labelling of the uracil nucleotides was decreased in the developing liver. However, in spite of a lower specific radioactivity of UTP, the RNA-specific radioactivity of developing liver was increased compared with adult liver. Also the labelling of liver RNA with [6-14C]orotic acid was found to be increased in developing mice, thus indicating a higher rate of RNA synthesis in these animals. A more pronounced difference in liver RNA labelling between the developing and the adult mice obtained with the use of [14C]orotic acid than with [3H]uridine may suggest that the de novo pathway, relative to the salvage pathways, is more important in developing than in adult liver.     

The rate of breakdown of methyl methanesulphonate, dimethyl sulphate and N-methyl-N-nitrosourea in the rat

1. The rates of decomposition of methyl methanesulphonate, dimethyl sulphate and N-methyl-N-nitrosourea in the rat were measured. 2. Dimethyl sulphate is no longer detectable in the blood of the rat 3min. after an intravenous dose (75mg./kg. body wt.). Methyl methanesulphonate is only just detectable in the blood 1(1/2)hr. after an intravenous dose (100mg./kg. body wt.). N-Methyl-N-nitrosourea is no longer detectable in the blood 15min. after an intravenous dose (100mg./kg. body wt.). 3. The exhalation of (14)CO(2) after an intragastric dose of N[(14)C]-methyl-N-nitrosourea (100mg./kg. body wt.) is appreciably slower than after an intravenous dose, from which it is estimated that the lifetime in the rat is 2-3hr.     

Problems associated with the labelling of RNA with radioactive precursors in vivo (author's transl)]

The radioactivity of RNA, DNA and proteins in the liver, muscles and cerebrum of 30-day-old rats after labelling with [3H]uridine, [14C]uridine, [3H]cytidine or [3H]orotic acid was measured. It was found that after administration of [3H]uridine, the proteins were 5 - 10 times more radioactive than the RNA. After administration of [14C]uridine, the proteins were 1 - 2 times more heavily labelled than the RNA. Hydrolysis of the proteins followed by chromatography of the amino acids revealed that the protein labelling was mostly due to [3H]glutamate. In the liver, [3H]orotic acid produced very specific labelling of the RNA. The radioactivity of the proteins is very slight. However, the specific labelling of the RNA in the muscles and cerebrum is not so pronounced with this precursor. [3H]Cytidine is an ideal precursor for RNA. The labelling of protein in all three organs examined is very slight, and furthermore, the specific activity of the RNA is 10 - 20 times higher than after labelling with uridine. We were also able to show that after labelling with radioactive uridine, the method of isolation of RNA by alkaline hydrolysis gives incorrect results, because [3H]amino acids interfere with the measurement of the specific activity of the RNA. The heavy labelling of proteins by [3H]-uridine must also be taken into account in histoautoradiography, because our experiments showed that in liver, the proteins in the cell nucleus are 3 times as radioactive as the nucleic acids. The particulate components of the cytoplasm are even 20 times more radioactive than the nucleic acids.     

Synthesis of ribonucleic acid in normal bone in vitro

1. The incorporation of [2-(14)C]uridine into nucleic acids of bone cells was studied in rat and pig trabecular-bone fragments surviving in vitro. 2. The rapid uptake of uridine into trichloroacetic acid-soluble material, and its subsequent incorporation into a crude nucleic acid fraction of bone or purified RNA extracted from isolated bone cells, was proportional to uridine concentration in the incubation medium over a range 0.5-20.0mum. 3. During continued exposure to radioactive uridine, bulk RNA became labelled in a curvilinear fashion. Radioactivity rapidly entered nuclear RNA, which approached its maximum specific activity by 2hr. of incubation; cytoplasmic RNA, and particularly microsomal RNA, was more slowly labelled. The kinetics of labelling and rapid decline of the nuclear/microsomal specific activity ratio were consistent with a precursor-product relationship. 4. Bulk RNA preparations were resolved by zonal centrifugation in sucrose density gradients into components with approximate sedimentation coefficients 28s, 18s and 4s. 5. Rapidly labelled RNA, predominantly nuclear in location, demonstrated a polydisperse sedimentation pattern that did not conform to the major types of stable cellular RNA. Material of highest specific activity, sedimenting in the 4-18s region and insoluble in 10% (w/v) sodium chloride, rapidly achieved its maximum activity during continued exposure to radioactive precursor and decayed equally rapidly during ;chase' incubation, exhibiting an average half-life of 4.3hr. 6. Ribosomal 28s and 18s RNA were of lower specific activity, which increased linearly for at least 6hr. in the continued presence of radioactive uridine. There was persistent but variable incorporation into ribosomal RNA during ;chase' incubation despite rapid decline in total radioactivity of the acid-soluble pool containing RNA precursors.     

The biosynthesis of cytochrome c. Sequence of incorporation in vivo of [14C]lysine into cytochrome c and total proteins of rat-liver subcellular fractions

1. In order to determine the initial intracellular site of synthesis of cytochrome c in the liver cell, groups of rats were injected with [(14)C]lysine and killed 7.5, 15, 30 and 60min. later. The livers were homogenized in 0.3m-sucrose and subcellular fractions obtained. The mitochondrial fraction was further subfractionated. Pure cytochrome c was isolated from extracts of each fraction, obtained first with water at pH4.0 and then with 0.15m-sodium chloride. 2. A comparison of the kinetics of incorporation of [(14)C]lysine into total protein for each particulate fraction showed the usual two different kinds of kinetics. Incorporation into all the mitochondrial subfractions and the nuclear fraction rose gradually to a plateau value at about 20min., in contrast with that into the two microsomal fractions which rose rapidly to a peak value about seven times that for the mitochondrial fractions. The kinetics for the incorporation into mitochondrial cytochrome c showed a plateau value at 30min. about three times that for the total mitochondrial protein. There was no difference in the specific radioactivity of the mitochondrial cytochrome c extracted with water or 0.15m-sodium chloride or between the different mitochondrial subfractions. In contrast, the cytochrome c isolated from water extracts of the microsomal fractions had a lower specific radioactivity than that obtained from the 0.15m-sodium chloride extract. The specific radioactivity of the latter showed a rapid rise to a peak value about four times that for the mitochondrial cytochrome c, and the shape of the curve was similar to that for the total protein of the microsomal fraction. The results suggest that cytochrome c is synthesized in toto by the morphological components of the microsomal fraction. It seems first to be bound tightly to a microsomal particle, passing then to a looser microsomal binding and being finally transferred to the mitochondria. The newly synthesized cytochrome c in the mitochondrion could not be differentiated from the old by its degree of extractability at pH 4.0.