Sixteen discrete RNA components in the cytoplasmic ribosome of Euglena gracilis

We have isolated cytoplasmic ribosomes from Euglena gracilis and characterized the RNA components of these particles. We show here that instead of the four rRNAs (17-19 S, 25-28 S, 5.8 S and 5 S) found in typical eukaryotic ribosomes, Euglena cytoplasmic ribosomes contain 16 RNA components. Three of these Euglena rRNAs are the structural equivalents of the 17-19 S, 5.8 S and 5 S rRNAs of other eukaryotes. However, the equivalent of 25-28 S rRNA is found in Euglena as 13 separate RNA species. We demonstrate that together with 5 S and 5.8 S rRNA, these 13 RNAs are all components of the large ribosomal subunit, while a 19 S RNA is the sole RNA component of the small ribosomal subunit. Two of the 13 pieces of 25-28 S rRNA are not tightly bound to the large ribosomal subunit and are released at low (0 to 0.1 mM) magnesium ion concentrations. We present here the complete primary sequences of each of the 14 RNA components (including 5.8 S rRNA) of Euglena large subunit rRNA. Sequence comparisons and secondary structure modeling indicate that these 14 RNAs exist as a non-covalent network that together must perform the functions attributed to the covalently continuous, high molecular weight, large subunit rRNA from other systems.     

Study of the interaction of soluble and particle-bound nicotinamide adenine dinucleotide pyrophosphorylase with cytoplasmic ribosomes

The cytoplasm of cells infected with EMC virus contains new structures which possess activity of the nuclear enzyme NAD pyrophosphorylase [14]. An attempt was made to understand the mode of formation of these structures in the infected cell. It was found that soluble NAD pyrophosphorylase manifests a strong affinity for cytoplasmic ribosomes, sedimenting at 90S. When cytoplasmic ribosomes were dissociated to the 60S and 40S subunits, the enzyme was found to be adsorbed only to the 60S unit. In extracts of rat liver nuclei, NAD pyrophosphorylase is associated with 35S particles, composed mainly of protein and DNA. The bond between enzyme and particle is of a loose nature. When ribosomes are mixed with 35S nuclear particles, most of the enzyme activity is transferred from the nuclear particles to the ribosomes, thus forming particles with an average sedimentation coefficient of 90S. Similar structures are obtained when either soluble NAD pyrophosphorylase or 35S nuclear particles are mixed with preparations of cytoplasm isolated from non-infected cells. The results of these experiments suggest that the 90S cytoplasmic structures found in virus-infected cells could result from an association between either free or particle-bound NAD pyrophosphorylase with cytoplasmic ribosomes.     

Partial purification of a ribosomal ribonucleic acid methylase from rat liver nuclei and methylation of undermethylated nuclear ribonucleic acid from regenerating liver of ethionine-treated rat

S-Adenosylmethionine-dependent ribosomal RNA (rRNA) methylase has been purified approx. 90-fold from rat liver nuclei. The partially purified methylase catalyzes the methylation of base and ribose in hypomethylated nuclear rRNA prepared from the regenerating rat liver after treatment with ethionine and adenine. The enzyme has an apparent molecular weight of about 3 x 10(4) and a sedimentation coefficient of 3.0 S. The enzyme is optimally active at pH 9.5 and sensitive to p-chloromercuribenzoate. Thiol-protecting reagents, such as dithiothreitol, are necessary for its activity, and the enzyme requires no divalent cations for its full activity. This enzyme did not efficiently transfer the methyl group to nuclear rRNA from normal rat liver, compared with hypomethylated nuclear rRNA. Methyl groups were mainly incorporated into pre-rRNA larger than 28 S, and the extent of 2'-O-methylation of ribose by this enzyme was greater than that of base methylation in the hypomethylated rRNA. No other nucleic acids, including transfer RNA (tRNA) and microsomal RNA from normal as well as ethionine-treated rat livers, tRNA from Escherichia coli, yeast RNA, and DNA from rat liver and calf thymus, were significantly methylated by this methylase. These results suggest that partially purified rRNA methylase from rat liver nuclei incorporates methyl groups into hypomethylated pre-rRNA from S-adenosylmethionine.     

Characterization of cytoplasmic and nuclear genomes in the colorless alga Polytoma. III. Ribosomal RNA cistrons of the nucleus and leucoplast

The colorless alga Polytoma obtusum has been found to possess leucoplasts, and two kinds of ribosomes with sedimentation values of 73S and 79S. The ribosomal RNA (rRNA) of the 73S but not the 79S ribosomes was shown to hybridize with the leucoplast DNA (rho - 1.682 g/ml). Nuclear DNA of Polytoma (rho = 1.711) showed specific hybridization with rRNA from the 79S ribosomes. Saturation hybridization indicated that only one copy of the rRNA cistrons was present per leucoplast genome, with an average buoyant density of rho = 1.700. On the other hand, about 750 copies of the cytoplasmic rRNA cistrons were present per nuclear genome with a density of rho = 1.709. Heterologous hybridization studies with Chlamydomonas reinhardtii rRNAs showed an estimated 80% homology between the two cytoplasmic rRNAs, but only a 50% homology between chloroplast and leucoplast rRNAs of the two species. We conclude that the leucoplasts of Polytoma derive from chloroplasts of a Chlamydomonas-like ancestor, but that the leucoplast rRNA cistrons have diverged in evolution more extensively than the cistrons for cytoplasmic rRNA.     

Ribonucleic Acid Synthesis in Cells Infected with Herpes Simplex Virus: I. Patterns of Ribonucleic Acid Synthesis in Productively Infected Cells

HEp-2 cells were pulse-labeled at different times after infection with herpes simplex virus, and nuclear ribonucleic acid (RNA) and cytoplasmic RNA were examined. The data showed the following: (i) Analysis by acrylamide gel electrophoresis of cytoplasmic RNA of cells infected at high multiplicities [80 to 200 plaque-forming units (PFU)/cell] revealed that ribosomal RNA (rRNA) synthesis falls to less than 10% of control (uninfected cell) values by 5 hr after infection. The synthesis of 4S RNA also declined but not as rapidly, and at its lowest level it was still 20% of control values. At lower multiplicities (20 PFU), the rate of inhibition was slower than at high multiplicities. However, at all multiplicities the rates of inhibition of 18S and 28S rRNA remained identical and higher than that of 4S RNA. (ii) Analysis of nuclear RNA of cells infected at high multiplicities by sucrose density gradient centrifugation showed that the synthesis and methylation of 45S rRNA precursor continued at a reduced but significant rate (ca. 30% of control values) at times after infection when no radioactive uridine was incorporated or could be chased into 28S and 18S rRNA. This indicates that the inhibition of rRNA synthesis after herpesvirus infection is a result of two processes: a decrease in the rate of synthesis of 45S RNA and a decrease in the rate of processing of that 45S RNA that is synthesized. (iii) Hybridization of nuclear and cytoplasmic RNA of infected cells with herpesvirus DNA revealed that a significant proportion of the total viral RNA in the nucleus has a sedimentation coefficient of 50S or greater. The sedimentation coefficient of virus-specific RNA associated with cytoplasmic polyribosomes is smaller with a maximum at 16S to 20S, but there is some rapidly sedimenting RNA (> 28S) here too. (iv) Finally, there was leakage of low-molecular weight (4S) RNA from infected cells, the leakage being approximately three-fold that of uninfected cells by approximately 5 hr after infection.     

Higher-plant mitochondrial ribosomes contain a 5S ribosomal ribonucleic acid component.

Ribosomes from higher-plant mitochondria contain 5S rRNA, in contrast with the mitochondrial ribosomes of animals and fungi, in which such a component has not been detected. In common with the ribosomes of prokaryotes and chloroplasts, higher-plant mitochondrial ribosomes do not appear to contain an RNA equivalent to the 5.8 S rRNA that is found in eukaryoytes hydrogen-bonded to the largest of the cytoplasmic rRNA species.     

Study of the type of RNA, degraded by polynucleotide phosphorylase in polyribosomal fraction of rat liver]

The type of RNA is studied, which is degraded by polynucleotide phosphorylase (PNPase) in the fraction of free ribosomes and ribosomes released from endoplasmic reticulum membranes with Triton X-100. Beta-32P labelled ADP, UDP, GDP and CDP are found among the degradation products of endogenous RNA of free and bound ribosomes in vitro in the presence of 32P-ortophosphate. An analysis of molar ratio of beta-32P-NDP isolated revealed that PNPase degrades RNA of GC type in both ribosome fractions. The amount of PNPase-degraded RNA in bound ribosimes is 4-fold as high as that in free ribosomes under the same conditions. Analysis of stable 32P-RNA and rapidly labelled 32-P-dRNA, isolated from bound ribosomes after the incubation with and without inorganic phosphate, revealed that PNPase attacks the 28S fragment of RNA, which consists of about 370 nucleotides, and dRNA having a sedimentation coefficient less than 12S. The rate of dRNA degradation is considerably higher than that of rRNA. 5'-RNAase, hydrolysing synthetic homopolyribonucleotides to oligonucleotides with free 3'-OH terminal group, apparently participates, together with PNPase, in dRNA and rRNA degradation.     

Mitochondrial ribosomes of the phytoflagellata Astasia longa

The physico-chemical properties of ribosomes and rRNA isolated from the mitochondria of the phytoflagellata Astasia longa were studied. It was shown that the mitochondrial ribosomes of A. longa have the sedimentation coefficient of 81S (those of the cytoplasm-82S); upon a decrease of Mg2+ concentration in the medium they dissociate into subparticles with sedimentation coefficients of 60 and 45S. The relative protein content in the mitochondrial ribosomes of A. longa is equal to 42% (rho = 1,60 g/cm3), that of cytoplasmic ribosomes-49%. The molecular weights of mitochondrial rRNA are equal to 1,05 . 10(6) and 0,71 . 10(6) and differ from those for cytoplasmic rRNA (1,32 . 10(6) and 0,94 . 10(6)). It was shown that the GC-content in mitochondrial rRNA is equal to 32,0 mol. %, that in cytoplasmic rRNA-55,9 mol. %. Thus, the mitochondrial ribosomes of A. longa differ in some of their properties from both procaryotic and eucaryotic ribosomes and are probably related to a special type of mitochondrial 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.     

Sea urchin embryo chromatin and nuclear ribonucleoproteins fractionated by anion exchange chromatography.

Chromatin and ribonucleoproteins released from sea urchin embryo nuclei were characterized on the basis of sedimentation properties, buoyant densities and fractionation by anion exchange chromatography. DEAE- and ECTEOLA-cellulose chromatography was used to assay nuclear purity, insofar as ribosomes and polyribosomes could be readily distinguished from ribonucleoproteins released from nuclei. This chromatography was used to separate chromatin fragments on the basis of DNA size, to prepare chromatin fragments substantially enriched in nonhistone proteins, and to analyze nuclear ribonucleoproteins. Solubilized chromatin is fractionated into major and minor components by ECTEOLA-cellulose chromatography. The DNA of these chromatin fractions was analyzed with respect to buoyant density and hybridization with nuclear RNA.     

Messenger ribonucleic acid of cerebral nuclei

1. RNA was isolated from crude nuclear preparations and from ribosomes derived from rat brain and liver. Nuclear RNA was obtained by lysis of the nuclei with sodium dodecyl sulphate, followed by denaturation and removal of DNA and protein with hot phenol. 2. Base composition analyses indicated that the cerebral nuclear RNA preparation contained a higher proportion of non-ribosomal RNA than the analogous hepatic preparation. 3. Sucrose-density-gradient analyses revealed a heterogeneous profile for each nuclear RNA preparation, with two major peaks possessing the sedimentation properties of ribosomal RNA (18s and 28s). 4. Template activities of both preparations were widely distributed through the sucrose density gradients. 5. The cerebral nuclear RNA preparation was more active than the hepatic nuclear RNA preparation in promoting amino acid incorporation in cell-free systems from Escherichia coli and rat brain. 6. Cerebral nuclear RNA stimulated amino acid incorporation in a cerebral ribosomal system even in the presence of an excess of purified E. coli transfer RNA. 7. It is concluded that a significant proportion of cerebral nuclear RNA has the characteristics of messenger RNA.     

Release of rRNA from liver nuclei during the early stages of the acute-phase reaction

Liver nuclei isolated from rats 5 h after turpentine injection show an increased release of rRNA, of the transport-related nucleoside-triphosphatase activity and of the amount of nuclear RNA; RNA methylation is also likely to undergo some activation. These changes occur when RNA synthesis is still normal.     

Quantitative analysis of rat liver nucleolar and nucleoplasmic ribosomal ribonucleic acids.

rRNA from detergent-purified nuclei was fractionated quantitatively, by two independent methods, into nucleolar and nucleoplasmic RNA fractions. The two RNA fractions were analysed by urea/agar-gel electrophoresis and the amount of pre-rRNA (precursor of rRNA) and rRNA components was determined. The rRNA constitutes 35% of total nuclear RNA, of which two-thirds are in nucleolar RNA and one-third in nucleoplasmic RNA. The identified pre-rRNA components (45 S, 41 S, 39 S, 36 S, 32 S and 21 S) are confined to the nucleolus and constitute about 70% of its rRNA. The remaining 30% are represented by 28 S and 18 S rRNA, in a molar ratio of 1.4. The bulk of rRNA in nucleoplasmic RNA is represented by 28 S and 18 S rRNA in a molar ratio close to 1.0. Part of the mature rRNA species in nucleoplasmic RNA originate from ribosomes attached to the outer nuclear membrane, which resist detergent treatment. The absolute amount of nuclear pre-rRNA and rRNA components was evaluated. The amount of 32 S and 21 S pre-rRNA (2.9 x 10(4) and 2.5 x 10(4) molecules per nucleus respectively) is 2-3-fold higher than that of 45 S, 41 S and 36 S pre-rRNA.     

Processing and migration of ribosomal ribonculeic acids in the nucleolus and nucleoplasm of rat liver nuclei.

Kinetic studies on the labelling in vivo with [14C]orotate of rat liver nucleolar and nucleoplasmic pre-rRNA (precursor of rRNA) and rRNA, isolated from detergent-purified nuclei, were carried out. The mathematical methods used for the computer analysis of specific-radioactivity curves are described. Evaluation of the experimental data permitted the selection of the most probable models for the processing of pre-rRNA and the nucleo-cytoplasmic transfer of rRNA. It was shown that considerable flexibility exists in the sequence of endonuclease attacks at critical sites of 45 and 41 S pre-rRNA chains, resulting in the simultaneous occurrence of several processing pathways. However, the phosphodiester bonds involved in the formation of mature 28 and 18 S rRNA appear to be protected until the generation of their immediate pre-rRNA. The turnover rates and half-lives of all pre-rRNA and rRNA pools were determined. The turnover rate of 45 S pre-rRNA corresponds to the formation of 1100 ribosomes/min per nucleus. The model for the nucleolus-nucleoplasm-cytoplasm migration of rRNA includes a 'nucleoplasm' compartment in which the small ribosomal subparticle is in rapid equilibrium with the respective cytoplasmic pool. At equimolar amounts of nuclear 28 and 18 S rRNA this model explains the faster appearance of labelled small ribosomal subparticles in the cytoplasm simultaneous with a lower labelling of nuclear 18 S rRNA as compared with 28 S rRNA.     

The effect of pancreatic ribonuclease on rabbit reticulocyte ribosomes and its interpretation in terms of ribosome structure

1. Parts of the 16s and 30s RNA species of reticulocytes are readily hydrolysed by pancreatic ribonuclease. The biological activity of the ribosomes is diminished after treatment with low concentrations of the enzyme (e.g. 1ng. of ribonuclease/2.5mg. of polyribosome fraction/ml.). A high proportion of the chain scissions are ;hidden' owing to the secondary structure of the RNA moiety. 2. As the concentration of ribonuclease is increased RNA is lost from the ribosome. About 20-30% of the RNA may be removed from the ribosome without altering appreciably its sedimentation coefficient or its appearance in the electron microscope. 3. The amount of RNA removed from the ribosome is not increased by raising the concentration of enzyme from about 1mug. to 2.5mg. of ribonuclease/2.5mg. of polyribosome fraction/ml., or by increasing the temperature from 0 degrees to 30 degrees , or by first converting the RNA moiety into a single-stranded form before exposure to ribonuclease. 4. Untreated polyribosomes aggregate at about 75 degrees , whereas ribosomes treated with ribonuclease aggregate at about 45 degrees . The aggregates that are found on heating ribosomes after enzymic hydrolysis contain about 40-50% of the complement of RNA of intact ribosomes. 5. From the size of the fragments of RNA isolated from RNA-depleted ribosomes it is inferred that there is one site/60-100 nucleotides that is sensitive to ribonuclease. 6. The RNA moiety of RNA-depleted ribosomes has some double-helical character as shown by the optical properties and X-ray-diffraction pattern of ribonuclease-treated ribosomes and by the ;melting' properties of the isolated RNA. 7. Subparticles prepared by titration with an excess of EDTA are readily hydrolysed by ribonuclease to fragments of S(20,w) less than 4s, in contrast with the intact particle.     

The RNA N-glycosidase activity of ricin A-chain

The RNA N-glycosidase activity of ricin A-chain has been characterized. When rat liver ribosomes were used as substrates, the A-chain cleaved the N-glycosidic bond at A-4324 in 28S rRNA. An apparent Michaelis constant (Km) for the reaction was determined to be 2.6 microM and the turnover number (Kcat) was 1777 min-1. When naked rRNA was the substrate, the A-chain cleaved the same bond in 28S rRNA but at a greatly reduced rate. The Km value was 5.8 microM. The results suggest that the A-chain has a similar affinity for 28S rRNA in both ribosomes and the naked states. When the deproteinized Escherichia coli rRNA was the substrates, ricin A-chain cleaved a N-glycosidic bond at A-2600 in 23S rRNA which corresponds to the ricin-site in 28S rRNA of rat liver ribosomes, while the A-chain has little activity on 23S rRNA in the ribosomes. The results suggest that ricin A-chain acts directly on RNA by recognizing a certain structure in the molecules. Using the secondary structure models for each species of rRNA, we have deduced a loop and stem structure having GAGA in the loop to be a minimum requirement for the substrate of ricin A-chain.     

Topography of 5.8 S rRNA in rat liver ribosomes. Identification of diethyl pyrocarbonate-reactive sites

The topography of 5.8 rRNA in rat liver ribosomes has been examined by comparing diethyl pyrocarbonate-reactive sites in free 5.8 S RNA, the 5.8 S-28 rRNA complex, 60 S subunits, and whole ribosomes. The ribosomal components were treated with diethyl pyrocarbonate under salt and temperature conditions which allow cell-free protein synthesis; the 5.8 S rRNA was extracted, labeled in vitro, chemically cleaved with aniline, and the fragments were analyzed by rapid gel-sequencing techniques. Differences in the cleavage patterns of free and 28 S or ribosome-associated 5.8 S rRNA suggest that conformational changes occur when this molecule is assembled into ribosomes. In whole ribosomes, the reactive sites were largely restricted to the "AU-rich" stem and an increased reactivity at some of the nucleotides suggested that a major change occurs in this region when the RNA interacts with ribosomal proteins. The reactivity was generally much less restricted in 60 S subunits but increased reactivity in some residues was also observed. The results further indicate that in rat ribosomes, the two -G-A-A-C- sequences, putative binding sites for tRNA, are accessible in 60 S subunits but not in whole ribosomes and suggest that part of the molecule may be located in the ribosomal interface. When compared to 5 S rRNA, the free 5.8 S RNA molecule appears to be generally more reactive with diethyl pyrocarbonate and the cleavage patterns suggest that the 5 S RNA molecule is completely restricted or buried in whole ribosomes.     

Differences in sequence content of nuclear and cytoplasmic polyribosomal RNA from adenovirus-infected cells.

RNA molecules from nuclear and cytoplasmic polyribosomes of adenovirus-infected HeLa cells were compared by hybridization to analyse the sequence content. Nuclear polyribosomes were released by exposure of intact detergent-washed nuclei to poly(U) and purified. Cytoplasmic polyribosomes were also purified from the same cells. To show that nuclear polyribosomes contain ribosomes linked by mRNA, polyribosomes were labelled with methionine and uridine in the presence of actinomycin D in adenovirus-infected cells. Purified nuclear polyribosomes were treated with EDTA under conditions which dissociate polyribosomes into ribosomes and subunits with a simultaneous release of mRNA, and sedimented. The treatment dissociated these polyribosomes, releasing the mRNA from them. Radiolabelled total RNA from each polyribosome population was fractionated in sucrose gradients into several pools or hybridized to intact adenovirus DNA to select virus-specific RNA. Sucrose-gradient-fractionated pool-3 RNA (about 28S) and virus-specific RNA were then hybridized to fragments of adenovirus DNA cleaved by restriction endonucleases SmaI, HindIII and EcoRI by the Southern-blot technique and by filter hybridization. The results showed that nuclear RNA contained sequences, from about 0 to 18 map units, which were essentially absent from cytoplasmic RNA. Furthermore, the amount of virus-specific RNA for a particular sequence was also different in the two populations.     

RNA SYNTHESIS IN CULTURED CHICK EMBRYO CELLS IN GROWING AND CONFLUENT PHASES

RNA synthesis at the growing phase in monolayer cultures of chick embryo fibroblasts was compared with that at confluent phases by zonal sedimentation, base composition and hybridization experiments. The nuclei were isolated by treatment with Nonidet p-40. The ratio of RNA/DNA in isolated nuclei was higher at the growing phase than that of confluent. The rate of RNA synthesis was reduced in the cells at confluent phase to 15.1% of that at the growing phase. The sucrose density gradient sedimentation pattern of nuclear RNA was on the whole the same in both phases. According to the distribution of ¹⁴C-uridine incorporated into nuclear RNA, 45S ribosomal precursor RNA was more distinct for the growing cell, while the radioactivities were found to be polydispersed, including the RNA which sedimented faster than 28S RNA in the cells at confluent phase. The base compositions and hybridization analyses indicated that ribosomal RNA was synthesized more actively in the growing cells. About 50% of newly synthesized RNA was ribosomal in the growing cells but 35% in the confluent.
It was found that newly synthesized 18S and 28S ribosomal RNAs appeared in cytoplasm after 21 and 33 min lag periods respectively. These times were exactly same in both growing and confluent phases.