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.     

Synthesis of ribonucleic acid in the venom gland of Crotalus durissus terrificus (Ophidia, Reptilia) after manual extraction of the venom

1. The incorporation of [5-(3)H]uridine into RNA of the venom gland of Crotalus durissus terrificus was studied after manual extraction (;milking') of the venom. The labelled precursor was injected immediately after milking. 2. The RNA was extracted 1, 2, 4, 6 and 8h after injection of the label and analysed by sucrose-density-gradient centrifugation. 3. The sedimentation analysis showed that 18S rRNA synthesis is higher than 28S rRNA at all time-intervals. The specific radioactivities of both ribosomal components did not reach a plateau even at 8h after injection. 4. An RNA fraction was detected sedimenting between 18S rRNA and 4S tRNA and was called the 10-14S fraction. The specific radioactivity was always higher than that of both classes of rRNA and reached the maximum value at 6h of labelling. 5. The incorporation of the precursor was also studied by radioautography, which helped to elucidate the intracellular origin of the RNA analysed by sucrose-density-gradient centrifugation.     

Synthesis and processing of high molecular weight RNA by nuclei isolated from embryos of Rana pipiens

When synthesized under conditions optimal for maximal methylation, two of the major classes of high molecular-weight RNA produced by isolated nuclei were indistinguishable from RNA purified from cytoplasmic ribosomes. The degree of methylation was found to influence the sedimentation velocity of only the heavier major RNA fraction. Upon becoming maximally methylated, this RNA sedimented at 27 s rather than 25 s. When comparing maximally-methylated nuclear RNA to cytoplasmic rRNA, it was found that on the basis of sedimentation coefficient, base composition and electrophoretic mobility, the 0.7 million dalton nuclear RNA was equivalent to 18 s cytoplasmic rRNA, the 1.5 million dalton nuclear RNA was equivalent to the 27 s moiety of 28 s cytoplasmic rRNA, and the 0.058 million dalton nuclear RNA was the same as the 7 s moiety of 28 s cytoplasmic rRNA. In isolated nuclei, the 27 s and 7 s RNA did not associate to form the 28 s duplex found in mature cytoplasmic ribosomes.     

STUDY OF RNA IN SUBCELLULAR FRACTIONS FROM RAT BRAIN: SIMULTANEOUS INCORPORATION OF [14C]URIDINE AND [3H]METHYL-l-METHIONINE

Abstract— By using a combination of subcutaneous and intraventricular injections of [¹⁴C]uridine and [³H]methyl- l -methionine we have obtained maximum incorporation in about 40 min of both radioactive precursors into nuclear RNA from rat brain. In this nuclear fraction we found at least two different types of RNA that were rapidly labelled. One of them incorporated both [¹⁴C]uridine and [³H]methyl groups and seemed to correspond to species of rRNA and their precursors. The other RNA fraction was less methylated or non-methylated and exhibited sedimentation coefficients distributed along a continuous 8–30 % sucrose density gradient. At least part of the latter type of RNA very probably was mRNA, but much of it must conespond to a different RNA similar to that recently described in HeLa cells by P enman , V esco and P enman (1968).
We also found that labelled 185 and 285 rRNA components began leaving the nucleus for the cytoplasm within 24 to 33 min after the radioactive precursors had been injected, and, in the cytoplasmic fraction, the patterns of incorporation for [¹⁴C]uridine and [³H]-methyl groups were similar for the 18S and 28S rRNA components. We estimate that in this fraction of rat brain the 18S rRNA component was 1·4 times more methylated than the 28S component. We also detected a lower sedimentation coefficient for the non- or slightly methylated, species of soluble RNA found in the cytoplasmic fraction.     

Selective Degradation of Newly Synthesized Nonmessenger Simian Virus 40 Transcripts

By pretreating simian virus 40-infected BSC-1 cells with glucosamine, [(3)H]uridine labeling of both cellular and viral RNA can be halted instantaneously by addition of cold uridine. We have studied the fate of pulse-labeled viral RNA from cells at 45 h postinfection under these conditions. During a 5-min period of labeling, both the messenger and nonmessenger regions of the late strand were transcribed. After various chase periods, nuclear viral species which sediment at 19, 17.5, and 16S were observed. Nuclear viral RNA decays in a multiphasic manner. Of the material present at the beginning of the chase period, 50% was degraded rapidly with a half-life of 8 min (initial processing). This rapidly degraded material was that fraction of the late strand which did not give rise to stable late mRNA species. Forty percent was transported to the cytoplasm, and 10% remained in the nucleus as material which sedimented in the 2 to 4S region. These 2 to 4S viral RNAs had a half-life of 3 h, and hybridization studies suggest that they are in part coded for by the late-strand nonmessenger region and are derived from the initial nuclear processing step. Another part is coded for by the late-strand messenger region and may be generated by some subsequent nuclear cleavages of 19S RNA into 17.5 and 16S RNAs. Transport of nuclear viral RNA into the cytoplasm was detected after a 5-min pulse and a 7-min chase. The maximum amount of labeled viral RNA was accumulated in the cytoplasm after a 30-min to 1-h chase. At least two viral cytoplasmic species were observed. Kinetic data suggest that 19S RNA is transported directly from the nucleus. Whether cytoplasmic 16S is formed by cleavage of 19S RNA in the cytoplasm is not clear. The half-lives of cytoplasmic 19 and 16S RNAs can be approximated as 2 and 5 h, respectively.     

The loss of rapidly labelled ribonucleic acid from isolated HeLa cell nuclei

1. The loss of nucleic acids and protein from isolated HeLa-cell nuclei was studied. During 4hr. incubation at 37 degrees DNA was conserved, but appreciable amounts of RNA and protein were lost. 2. Two classes of nuclear RNA were distinguished: at least 75% of the RNA was lost from the nuclei relatively slowly through degradation to acid-soluble fragments; the rest of the RNA was lost much more rapidly, not only through degradation to acid-soluble fragments but also through diffusion of RNA out of the nuclei into the incubation medium. 3. The RNA that was preferentially lost was the fraction of nuclear RNA that was rapidly labelled when intact HeLa cells were grown in a medium containing radioactive precursors of RNA. 4. The RNA appearing in the incubation medium was apparently partially degraded and had a sedimentation coefficient of about that of transfer RNA. 5. Both the degradation of RNA and the loss of RNA from the nuclei were sensitive to bivalent cations. Low concentrations of Mg(2+) and Mn(2+) greatly increased the rate of degradation of the rapidly labelled RNA to acid-soluble fragments, and produced a corresponding decrease in the amount of RNA diffusing into the medium. At higher concentrations they suppressed both degradation and diffusion of RNA. The cations Ca(2+), Cu(2+), Zn(2+) and Ni(2+) all progressively inhibited both forms of loss of RNA. 6. Salts of univalent cations produced appreciable effects only at ionic strengths of about 0.2, when degradation to acid-soluble fragments was preferentially inhibited. 7. Both ADP and ATP inhibited loss of RNA at about 30mm. 8. It was concluded that the diffusion of rapidly labelled RNA out of the isolated nuclei was not related to the movement of RNA from nucleus to cytoplasm in vivo, but reflected the ease with which the rapidly labelled RNA detached from the chromatin and the permeability of the membranes of isolated nuclei.     

Ribosomal-type ribonucleic acid from rodent mitochondria

1. Highly purified mitochondria containing 3.0mug of RNA/mg of mitochondrial protein were prepared from rat liver by differential centrifugation. 2. RNA, labelled with [(32)P]P(i) or [(3)H]orotate, was isolated from these mitochondria by a phenol extraction method. The RNA sedimented at 15S and 13S on sucrose density gradients. Its nucleotide composition was 23% uridylate, 30% adenylate, 22% guanylate and 25% cytidylate. 3. RNA from mouse L cells was labelled with [(3)H]-uridine in the presence of 0.1mug of actinomycin D/ml to suppress the synthesis of cytoplasmic rRNA. The RNA isolated from crude L-cell mitochondria by a cold-phenol-sodium dodecyl sulphate method had components sedimenting at 15S and 12.5S. These components had an electrophoretic mobility on agarose-acrylamide gels of 21 and 12S(E) compared with 28 and 18S(E) for cytoplasmic rRNA. The nucleotide composition was 26% uridylate, 34% adenylate, 18% guanylate and 22% cytidylate. 4. RNA extracted from crude L-cell mitochondria by a hotphenol-sodium dodecyl sulphate method had an additional component sedimenting at 21S and having an electrophoretic mobility of 18S(E). It was probably DNA because of its sensitivity to deoxyribonuclease and its insensitivity to ribonuclease and alkali. It was present in nuclear fragments contaminating the crude mitochondrial fraction and could be removed by deoxyribonuclease or isopycnic-gradient centrifugation.     

The effect of high ionic strength on the sedimentation properties of the biologically active component of bacterial ribonucleic acid

1. The sedimentation properties of the fraction of bacterial RNA which stimulates the incorporation of amino acids into acid-insoluble material in vitro depend on the ionic strength of the sedimentation medium. 2. The different distributions of stimulatory activity found in centrifuged linear sucrose gradients loaded with bacterial RNA and containing 0.1m- or 0.6m-sodium chloride resemble closely the different sedimentation profiles of rapidly labelled RNA observed under the same conditions. 3. These findings agree with those of previous work of a similar nature (Willson & Gros, 1964) and demonstrate that the component of bacterial RNA preparations which stimulates the incorporation of amino acids into acid-insoluble peptides in vitro is contained in their rapidly labelled fraction.     

The behaviour of heterogeneous nuclear ribonucleic acid in partially and completely denaturing conditions

It is shown that the heterogeneous nuclear RNA (HnRNA) synthesized in the presence of actinomycin and at low and high temperatures sediments in low-ionic-strength sucrose gradients between the rRNA components, similar to the unmethylated RNA synthesized under ;step-down' conditions. If the ionic strength is increased then the HnRNA sediments more rapidly than 28S rRNA, with a large proportion about the 45S precursor rRNA position. Initially this was thought to be due to aggregation of the HnRNA; however, centrifugation and electrophoresis in completely denaturing conditions suggest that the molecular weight of this species of RNA is very large The experiments reveal that HnRNA is conformationally unstable relative to the nucleolar RNA and that the slower sedimentation rate of HnRNA in 5mm-EDTA-Tris base-sucrose gradients reflects the greater expansion of the HnRNA relative to the nucleolar RNA. The implications of this finding are discussed.     

A study of nucleated erythrocytes by density-gradient centrifugation in a zonal rotor

1. Several substances of high molecular weight were examined for their suitability as suspension media in the formation of density gradients for the zonal centrifugation of avian erythrocytes. None proved satisfactory. 2. The behaviour of pigeon erythrocytes in rate-sedimentation experiments in a type A zonal rotor with density gradients of sucrose was examined. The mature cells sediment more rapidly than the younger cells and have a lower RNA/DNA ratio. Maturation is accompanied by a greater loss of RNA from the nucleus than from the cytoplasm. 3. The base composition of the nuclear RNA and of the two species of cytoplasmic ribosomal RNA is reported. 4. The RNA of erythrocytes may be labelled in vivo by injection of inorganic [(32)P]phosphate. The cells most active in the synthesis of RNA sediment less rapidly than the bulk of the cells. 5. Reticulocyte nuclei sediment more slowly than those from erythrocytes. Reticulocyte nuclei have a mean volume of 35mu(3) and are isopycnic with sucrose of density 1.2871 (measured at 20 degrees ). Maturation of the nuclei causes them to shrink to a volume of 25mu(3) and the density to increase to 1.2944.     

ISOLATION OF TWO DISTINCT CLASSES OF POLYSOMES FROM A NUCLEAR FRACTION OF RAT LIVER

Isolated rat liver nuclei were washed with Triton-X-100 in the presence of liver cell sap. This treatment liberated a fraction of polysomes which were isolated by differential centrifugation and were designated "outer membrane polysomes." The outer membrane polysomes synthesized protein in vivo. Shortly after injection of orotic acid-¹⁴C, the RNA of outer membrane polysomes had a higher specific activity than that of cytoplasmic polysomes. It was postulated that outer membrane polysomes may be an intermediate in the transfer of newly synthesized RNA from the nucleus to the cytoplasm. In other experiments, Triton-washed rat liver nuclei were lysed in the presence of deoxycholate and deoxyribonuclease. A ribonucleoprotein fraction was isolated from the lysate by differential centrifugation. This fraction contained "intranuclear ribosomes," which sedimented like partially degraded polysomes in sucrose gradients. This degradation could be partially prevented if intranuclear ribosomes were purified by sedimentation through heavy sucrose. The resulting pellets were termed "intranuclear polysomes" because they contained some undergraded polysomes. Intranuclear polysomes were highly radioactive after a brief pulse with orotic acid-¹⁴C, but did not appear to synthesize protein rapidly in vivo. Intranuclear polysomes may represent the initial stage of assembly of polyribosomes in the nucleus.     

Distribution of elongation factors EF-1 and EF-2 among components of rabbit reticulocyte lysate

The distribution of activity of the elongation factors EF-1 and EF-2 among the components of rabbit reticulocyte lysate separated by sucrose density gradient centrifugation was studied. At low ionic strength (0.01 M KCl) about 30% of the EF-1 activity was found in polyribosomes. At moderate ionic strength (0.1 M KCl) the EF-1 activity was absent in the polyribosomes. An addition of RNA excess to the lysate prior to centrifugation at low ionic strength resulted in elimination of the EF-1 activity from the polyribosomes. This indicates that EF-1 is reversibly bound to the polyribosomes and that EF-1 may be retained on them due to interaction with RNA of polysomes mediated by its RNA-binding site. After dissociation of polyribosomes containing EF-1 in the presence of EDTA and subsequent fractionation of the dissociation products at low ionic strength (0.01 M KCl) the EF-1 activity was revealed in the ribosomal subparticles (predominantly in 60S). At 0.1 M KCl EF-1 mainly sedimented in the zone of distribution of polyribosomal informosomes. The elongation factor EF-2 was not revealed in polyribosomes during lysate centrifugation even at low ionic strength which corresponds to its lower affinity for RNA.     

Isolierung und Charakterisierung schnell markierter,hochmolekularer RNS aus frei suspendierten Calluszellen der Petersilie (Petroselinum sativum)

Summary By culturing of callus tissue originating from root explants of Petroselinum sativum in a synthetic liquid medium under aeration, freely suspended single cells and small clusters consisting of mostly five cells were obtained. The rapidly dividing cells did not exhibit any morphogenesis. Their nucleic acid metabolism was investigated by pulse experiments with ³²P-orthophosphate. Rapidly labelled RNA was prominently found associated with high molecular RNA. During the fractionation of the total nucleic acids on MAK columns it was eluted after the ribosomal RNA components. Its base ratio, however, differed from the latter in that the AMP content was higher than the GMP content. Sucrose gradient centrifugation and polyacrylamide gel electrophoresis resulted in the separation of the ribosomal RNA from the rapidly labelled RNA, thus proving the higher molecular weight of the latter. Based upon the migration in the gel a sedimentation coefficient of approximately 32S was calculated. The possible function of the heavy rapidly labelled RNA component as precursor of ribosomal RNA is discussed.     

Size of murine RNA tumor virus-specific nuclear RNA molecules.

About 1% of the total RNA of cell lines producing murine leukemia virus is virus-specific RNA. About one-third of the virus-specific RNA is located within the nucleus. The size distribution of virus-specific RNA was determined before and after denaturation. Before denaturation, virus-specific RNA sequences sedimented as a heterogeneous population of RNA molecules, some of which sedimented very rapidly. After denaturation, most of the virus-specific RNA had a sedimentation coefficient of 35S or lower, but a small fraction of the nuclear virus-specific RNA sedimented more rapidly than 35S RNA even after denaturation.     

A study of the heterogeneous 37s ribonucleic acid induced by foot-and-mouth-disease virus

1. The 37s RNA induced in baby-hamster kidney cells by infection with foot-and-mouth-disease virus was examined on sucrose gradients and by filtration through Sepharose 4B. 2. The RNA sedimented faster (37s) and as a broader band than the 35s RNA from purified virus. 3. Treatment with deoxyribonuclease, Pronase or amylase did not alter the sedimentation profile of the 37s RNA. 4. Treatment of individual fractions of the RNA with phenol, dimethyl sulphoxide or methylCellosolve did not decrease the sedimentation rate of the faster-sedimenting molecules. 5. Sedimentation in sucrose gradients of different ionic strengths or containing EDTA had no effect on the heterogeneous nature of the profile. 6. On filtration through Sepharose 4B columns, the 37s virus-induced RNA was eluted before viral RNA. 7. Only 20% of the rapidly sedimenting RNA was incorporated into complete virus particles.     

Studies in rapidly labelled ribonucleic acid in cell fractions and in tumour tissues

1. Twenty minutes after injection of [(3)H]orotic acid into rats the rapidly labelled RNA from the liver is mainly associated with the nuclear fraction and little with the ribosomal cytoplasmic fraction. 2. The thermal denaturation of RNA from the fractions was not as reversible as that of the RNA extracted from whole liver. 3. Rapidly labelled RNA is synthesized by cells from a transplantable hepatoma when incubated in the presence of [(3)H]uridine and, after extraction and centrifugation, the label is present in three main fractions: one which sediments to the bottom of a gradient and is associated with DNA, a second which sediments to the heavy side of the 28s RNA, and a third which has a peak of activity between 28s RNA and 18s RNA and is associated with DNA. 4. After labelling and extraction of the RNA from Ehrlich ascites cells the distribution of radioactive components is similar to that of the material from the hepatoma cells. 5. The difference between the tumour cells and liver is due to some extent to the method of homogenizing the tissues and the nature of the components is discussed.     

Chromatographic Separation, and Characteristics of Nucleic Acids from HeLa Cells

The application of the phenol-duponol method to extraction of nucleic acids from HeLa cells is described. Chromatography of the phenol extract on an esterified bovine serum albumin column with a salt gradient of sodium chloride gives separation of soluble RNA, DNA, and two different high molecular RNA fractions. Ultracentrifugation of the DNA eluted from the column gives a sedimentation coefficient (s₂₀^o,w) of 38, which agrees with ultracentrifugation data on the phenol extract. The eluted RNA appears polydisperse at low ionic strength, but at high ionic strength and after alcohol precipitation two fractions with the sedimentation coefficients of 16 and 25 to 29, respectively, were obtained.     

Cytoplasmic Incorporation of a Ribonucleic Acid Precursor in Amoeba proteus

The question of RNA synthesis in enucleate cytoplasm of Amoeba has been approached experimentally by incubating enucleate amoebae in a labelled RNA precursor and determining the incorporation into RNA autoradiographically. The results indicate that there is a cytoplasmic incorporation mechanism which can operate in the absence of the nucleus. A comparison is made between Acetabularia and Amoeba with respect to the origins of cytoplasmic RNA. It is concluded that the existing data are consistent with the assumption that some cytoplasmic RNA is of nuclear origin in both organisms.     

Deoxyribonucleic acid poymerase of BHK-21/C13 cells. Heterogeneity, molecular asymmetry and subcellular distribution of the enzymes.

Nuclear and cytoplasmic fractions were prepared from exponentially-growing BHK-21/C13 cells; DNA polymerase was extracted from them and analysed by gel filtration and sucrose-density-gradient centrifugation. DNA polymerase I is heterogeneous comprising species covering a considerable range of molecular weights. These have been tentatively identified as four subspecies of apparent molecular weights 900000-1000000 (IA), 460000-560000 (IB), 270000-320000 (IC) and 140000-200000 (ID), as assessed by gel filtration through Sepharose 6B. DNA polymerase II has a mol.wt. of 46000 +/- 4000 as assessed by gel filtration on Sepharose 6B, and 48000 +/- 2000 as assessed by gel filtration on Sephadex G-100. Sedimentation analyses on sucrose density gradients showed that the DNA polymerase I species had sedimentation coefficients predominantly in the range 6-8 S. DNA polymerase II had predominantly a sedimentation coefficient of 3.2 S although a component with lower sedimentation coefficient was found. The lack of correlation between the molecular weights derived from gel filtration and the sedimentation coefficients is attributed to molecular asymmetry. DNA polymerase I was found to be associated predominantly with the cytoplasm although certain types of nuclear preparation contained large amounts of it. DNA polymerase II was found to be mostly if not exclusively in nuclear preparations.