A Novel In Vivo Assay Reveals Inhibition of Ribosomal Nuclear Export in Ran-Cycle and Nucleoporin Mutants

To identify components involved in the nuclear export of ribosomes in yeast, we developed an in vivo assay exploiting a green fluorescent protein (GFP)-tagged version of ribosomal protein L25. After its import into the nucleolus, L25-GFP assembles with 60S ribosomal subunits that are subsequently exported into the cytoplasm. In wild-type cells, GFP-labeled ribosomes are only detected by fluorescence in the cytoplasm. However, thermosensitive rna1-1 (Ran-GAP), prp20-1 (Ran-GEF), and nucleoporin nup49 and nsp1 mutants are impaired in ribosomal export as revealed by nuclear accumulation of L25-GFP. Furthermore, overexpression of dominant-negative RanGTP (Gsp1-G21V) and the tRNA exportin Los1p inhibits ribosomal export. The pattern of subnuclear accumulation of L25-GFP observed in different mutants is not identical, suggesting that transport can be blocked at different steps. Thus, nuclear export of ribosomes requires the nuclear/cytoplasmic Ran-cycle and distinct nucleoporins. This assay can be used to identify soluble transport factors required for nuclear exit of ribosomes.     

Simian virus 40-specific ribosome-binding proteins induced by a nondefective adenovirus 2-simian virus 40 hybrid.

We have studied the intracellular distribution of the two simian virus 40-specific proteins, with apparent molecular weights of 56,000 and 42,000, detectable in human KB cells infected by a nondefective adenovirus 2-simian virus 40 hybrid, Ad2+ND2. After a 20-min pulse of [35S]methionine, about two-thirds of the newly synthesized 56K protein and one-third of the 42K protein were found localized on the plasma membrane. The remainder of each protein was found in the cytoplasm, whereas the nuclear fraction was virtually free of either component. A significant portion of both proteins present in the cytoplasmic fraction was complexed to the 40S ribosomal subunits and was not removed by treatment with 0.5 M KCl. Moreover, the portion that was found free in the cytoplasm could bind preferentially and quantitatively to purified 40S ribosomes in vitro, leading us to propose that these simian virus 40 proteins may act as translational control elements in cells.     

Association of maternal and newly synthesized ribosomes with membranous noncytoskeletal structures in Xenopus laevis embryonic cells

In Xenopus laevis embryos a high concentration of both KCl and 0.5% DOC (sodium deoxycholate) is needed for maximal extraction of ribosomes and polysomes. We studied the nature of the structures that keep ribosomes and polysomes immobilized within the cytoplasm of embryonic cells at cleavage through tailbud stages, using various combinations of a low-salt buffer (20 mM KCl), a high-salt buffer (500 mM KCl), 0.5% DOC, and 0.5% Triton X-100. With a low-salt buffer and 0.5% DOC, but not Triton X-100, 80S ribosomal monomers and polysomes were liberated from the cytoplasmic rapidly sedimenting structures (RSS) to the soluble fraction. With a high-salt buffer (500 mM KCl), ribosomes were solubilized as 60S and 40S subunits together with about one-half of the total polysomes. When cells were homogenized in a low-salt buffer with added inhibitors of the cytoskeleton (cytochalasin B or colchicine), the majority of polysomes but not ribosomes were solubilized. These results provide evidence for the following conclusions. 1) Polysomes are bound to cytoskeletal structures in Xenopus embryos, but ribosomes, both maternal and newly synthesized, are associated with membranous noncytoskeletal structures. 2) The membranous structures consist of two compartments, one high-salt sensitive and the other high-salt resistant. 3) Ribosomes of the high-salt resistant group increase in amount with developmental stage and appear to be the precursor to the ribosomes of the high-salt sensitive group.     

STUDIES ON THE ORIGIN OF RIBOSOMES IN AMOEBA PROTEUS

The origin of cytoplasmic RNA and ribosomes was studied in Amoeba proteus by transplantation of a radioactive nucleus into an unlabeled cell followed by examination of the cytoplasm of the recipient for the presence of label. When a RNA-labeled nucleus was used, label appeared in the ribosomes, ribosomal RNA, and soluble RNA. Since the kinetics of appearance of labeled RNA indicates that the nucleus was not injured during the transfer, and since the transferred nuclear pool of labeled acid-soluble RNA precursors is inadequate to account for the amount of cytoplasmic RNA label, it is concluded that cytoplasmic ribosomal RNA is derived from acid-insoluble nuclear RNA and is probably transported as an intact molecule. Likewise, cytoplasmic soluble RNA probably originated in the nucleus, although labeling by terminal exchange in the cytoplasm is also possible. The results were completely different when a protein-labeled nucleus was grafted into an unlabeled host. In this case, label was found only in soluble proteins in the host cell cytoplasm, and there were no (or very few) radioactive ribosomes. This suggests that the nuclear pool of ribosomal protein and ribosomal protein precursors is relatively small and perhaps nonexistent (and, furthermore, shows that there was no cytoplasmic ribosomal contamination of the transferred nucleus).     

TRANSPORT OF VIRAL RNA IN KB CELLS INFECTED WITH ADENOVIRUS TYPE 2

Messenger RNA transport was studied in KB cells infected with the nuclear DNA virus adenovirus type 2. Addition of 0.04 µg/ml of actinomycin completes the inhibition of ribosome synthesis normally observed late after infection and apparently does not alter the pattern of viral RNA synthesis: Hybridization-inhibition experiments indicate that similar viral RNA sequences are transcribed in cells treated or untreated with actinomycin. The polysomal RNA synthesized during a 2 hr labeling period in the presence of actinomycin is at least 60% viral specific. Viral messenger RNA transport can occur in the absence of ribosome synthesis. When uridine-³H is added to a late-infected culture pretreated with actinomycin, viral RNA appears in the cytoplasm at 10 min, but the polysomes do not receive viral RNA-³H until 30 min have elapsed. Only 25% of the cytoplasmic viral RNA is in polyribosomes even when infected cells have been labeled for 150 min. The nonpolysomal viral RNA in cytoplasmic extracts sediments as a broad distribution from 10S to 80S and does not include a peak cosedimenting with 45S ribosome subunits. The newly formed messenger RNA that is ribosome associated is not equally distributed among the ribosomes; by comparison to polyribosomes, 74S ribosomes are deficient at least fivefold in receipt of new messenger RNA molecules.     

DNA synthesis in circulating erythroblasts of anemic duck. Isolation and properties of nuclear and cytoplasmic-nonmitochondrial DNA.

In the circulating blood of anemic ducks, 5% of all erythroid cells synthesize DNA. Immature erythroblasts, at all stages of differentiation, synthesize DNA although to a varying degree, while reticulocytes and erythrocytes do not. In the erythroid cell population labeled in vitro 2 h with 32Pi, half of the labeled DNA sediments as small-molecular-weight molecules, suggesting that these molecules fail to integrate into the high-molecular-weight components. Labeled DNA is found in the cytoplasmic postmitochondrial fractions and it is in a form of deoxyribonucleoproteins which cosediment with ribosomes as well as subribosomal particles in sucrose gradients. However, fixation with HCHO and centrifugation to equilibrium in CsCl gradient of these particles shows that the deoxyribonucleoprotein bands at the density different than the ribosomes and, thus, not physically linked to them. In EDTA-dissociated ribosomes, the deoxyribonucleoprotein particles cosediment with ribosomes as well as subribosomal particles in sucorse gradients. However, fixation with HCHO and centrifugation to equilibrium in CsCl gradient of these particles shows that the deoxyribonucleoprotein bands at the density different than the ribosomes and, thus, not physically linked to them. In EDTA-dissociated ribosomes, the deoxyribonucleoprotein particles cosdeiment with ribosomal subunits in such a way that the larger the particle, the larger the molecular weight of the DNA cosedimenting with it. The specific radioactivity of the cytoplasmic ribosome-derived and postribosomal-particle-derived DNAs and the small molecular-weight nuclear DNA is similar and 10-20-fold higher than that of the bulk nuclear DNA. The former three DNA species sediment between 4-14 S. It is concluded that the cytoplasmic nonmitochondrial DNA species are of the nuclear origin. Less than 0.5% of the total cellular nonmitochondrial DNA can be purified from the nucleus and the cytoplasm as fast-labeled small-molecular-weight components. All of the cellular nonmitochondrial DNA species band at the same mean buoyand density in Cs2SO4/urea gradients. All behave as native structures in hydroxyapatite and contain less than 5% of their length as single-stranded regions.     

Membrane-bound ribosomes of myeloma cells. III. The role of the messenger RNA and the nascent polypeptide chain in the binding of ribosomes to membranes

Mild ribonuclease treatment of the membrane fraction of P3K cells released three types of membrane-bound ribosomal particles: (a) all the newly made native 40S subunits detected after 2 h of [3H]uridine pulse. Since after a 3-min pulse with [35S]methionine these membrane native subunits appear to contain at least sevenfold more Met-tRNA per particle than the free native subunits, they may all be initiation complexes with mRNA molecules which have just become associated with the membranes; (b) about 50% of the ribosomes present in polyribosomes. Evidence is presented that the released ribosomes carry nascent chains about two and a half to three times shorter than those present on the ribosomes remaining bound to the membranes. It is proposed that in the membrane-bound polyribosomes of P3K cells, only the ribosomes closer to the 3' end of the mRNA molecules are directly bound, while the latest ribosomes to enter the polyribosomal structures are indirectly bound through the mRNA molecules; (c) a small number of 40S subunits of polyribosomal origin, presumably initiation complexes attached at the 5' end of mRNA molecules of polyribosomes. When the P3K cells were incubated with inhibitors acting at different steps of protein synthesis, it was found that puromycin and pactamycin decreased by about 40% the proportion of ribosomes in the membrane fraction, while cycloheximide and anisomycin had no such effect. The ribosomes remaining on the membrane fraction of puromycin-treated cells consisted of a few polyribosomes, and of an accumulation of 80S and 60S particles, which were almost entirely released by high salt treatment of the membranes. The membrane-bound ribosomes found after pactamycin treatment consisted of a few polyribosomes, with a striking accumulation of native 60S subunits and an increased number of native 40S subunits. On the basis of the observations made in this and the preceding papers, a model for the binding of ribosomes to membranes and for the ribosomal cycle on the membranes is proposed. It is suggested that ribosomal subunits exchange between free and membrane-bound polyribosomes through the cytoplasmic pool of free native subunits, and that their entry into membrane-bound ribosomes is mediated by mRNA molecules associated with membranes.     

Characterization of intracellular viral RNA in interferon-treated cells chronically infected with murine leukemia virus.

We have recently found that Moloney murine leukemia virus assembles within cytoplasmic vacuoles of chronically infected NIH/3T3 cells rather than at their surface (submitted for publication). In the present study we found that if these cells were treated with interferon (IF) for 24 to 48 h the intracellular virus particles accumulated at a two- to threefold-higher level than that observed in untreated cells. Nevertheless, despite this accumulation, no difference between IF-treated and untreated cells was observed in the amount of the total cytoplasmic viral RNA or in its 35S or 21S species. When cellular virions were sedimented from the cytoplasmic fraction, a markedly higher amount of viral RNA was detected in the viral pellet of IF-treated cells than was detected in untreated cells, whereas the amount of viral RNA left in the virus-free cytoplasm of IF-treated cells was much lower than that in the untreated cells. Furthermore, the amount of the cytoplasmic polyriboadenylic acid-containing viral RNA was also remarkably higher in the IF-treated cells. Viral polyribosomes appeared to be fully functional in IF-treated cells, since no effect of IF on viral protein synthesis could be detected. Analysis of the nuclear viral RNA showed no difference between IF-treated and untreated cells after 24 h of IF treatment. Both contained a comparable amount of 35S viral RNA. However, at 48 h a significant accumulation of viral RNA was observed in the nucleus of the IF-treated cells as compared with the untreated cells, although in both cases only 35S species were evident. This accumulation appeared to activate a degradation process which destroyed nuclear viral RNA, since a dramatic shift toward smaller-sized molecules of viral RNA and a remarkable reduction in its amount were observed after 72 h of IF treatment.     

Bevorzugter Einbau markierten Uridins in die Vorläufer von Chloroplasten-Ribosomen in Algenzellen

Summary After short time pulses with 5-[3H]uridine have been given to Chlorella cells, most of the radioactivity of the ribosome fractions is neither in the polysomes nor in the cytoplasmic ribosomes. Peaks with sedimentation of about 50 S and 30 S are found which are comparable in sedimentation to ribosomal subunits of Escherichia coli. During chase treatment with the one-hundred-fold amount of unlabelled uridine, the radioactivity shifts into the 70 S region. The RNA of the rapidly labelled 50 S and 30 S particles is shown to have 23 S, 14 S and 5 S, respectively.In contrast to this, radioactive inorganic phosphate and amino acids are mainly incorporated into the cytoplasmic ribosomes with 80 S and into, their polysomes.The chloroplast-damaged mutant of Chlorella, Nr.125 of Schwarze, shows no uridine incorporation into particles of 50 S and of 30 S, but some very weak labelling of the 80 S cytoplasmic monosomes.Nitrogen deficient Chlorella cells also incorporate uridine mainly into the 50 S and 30 S particles. When chase treatment with unlabelled uridine is performed under recovering conditions, the label shifts into the 70 S particles as well as into the 80 S cytoplasmic ribosomes.The results indicate that in Chlorella, uridine is incorporated into chloroplast ribosome precursors rather than into particles of nuclear origin.     

60S pre-ribosome formation viewed from assembly in the nucleolus until export to the cytoplasm

60S ribosomes undergo initial assembly in the nucleolus before export to the cytoplasm and recent analyses have identified several nucleolar pre-60S particles. To unravel the steps in the pathway of ribosome formation, we have purified the pre-60S ribosomes associated with proteins predicted to act at different stages as the pre-ribosomes transit from the nucleolus through the nucleoplasm and are then exported to the cytoplasm for final maturation. About 50 non-ribosomal proteins are associated with the early nucleolar pre-60S ribosomes. During subsequent maturation and transport to the nucleoplasm, many of these factors are removed, while others remain attached and additional factors transiently associate. When the 60S precursor particles are close to exit from the nucleus they associate with at least two export factors, Nmd3 and Mtr2. As the 60S pre-ribosome reaches the cytoplasm, almost all of the factors are dissociated. These data provide an initial biochemical map of 60S ribosomal subunit formation on its path from the nucleolus to the cytoplasm.     

RNA metabolism of murine leukemia virus: detection of virus-specific RNA sequences in infected and uninfected cells and identification of virus-specific messenger RNA

Virus-specific RNA sequences were detected in mouse cells infected with murine leukemia virus by hybridization with radioactively labeled DNA complementary to Moloney murine leukemia virus RNA. The DNA was synthesized in vitro using the endogenous virion RNA-dependent DNA polymerase and the DNA product was characterized by size and its ability to protect radioactive viral RNA. Virus-specific RNA sequences were found in two lines of leukemia virus-infected cells (JLS-V11 and SCRF 60A) and also in an uninfected line (JLS-V9). Approximately 0.3% of the cytoplasmic RNA in JLS-VII cells was virus-specific and 0.9% of SCRF 60A cell RNA was virus-specific. JLS-V9 cells contained approximately tenfold less virus-specific RNA than infected JLS-VII cells. Moloney leukemia virus DNA completely annealed to JLS-VII or SCRF 60A RNA but only partial annealing was observed with JLS-V9 RNA. This difference is ascribed to non-homologies between the RNA sequences of Moloney virus and the endogenous virus of JLS-V9 cells.Virus-specific RNA was found to exist in infected cells in three major size classes: 60–70 S RNA, 35 S RNA and 20–30 S RNA. The 60–70 S RNA was apparently primarily at the cell surface, since agents which remove material from the cell surface were effective in removing a majority of the 60–70 S RNA. The 35 S and 20–30 S RNA is relatively unaffected by these procedures. Sub-fractionation of the cytoplasm indicated that approximately 35% of the cytoplasmic virus-specific RNA in infected cells is contained in the membrane-bound material. The membrane-bound virus-specific RNA consists of some residual 60–70 S RNA and 35 S RNA, but very little 20–30 S RNA. Virus-specific messenger RNA was identified in polyribosome gradients of infected cell cytoplasm. Messenger RNA was differentiated from other virus-specific RNAs by the criterion that virus-specific messenger RNA must change in sedimentation rate following polyribosome disaggregation. Two procedures for polyribosome disaggregation were used: treatment with EDTA and in vitro incubation of polyribosomes with puromycin in conditions of high ionic strength. As identified by this criterion, the virus-specific messenger RNA appeared to be mostly 35 S RNA. No function for the 20–30 S was determined.     

Isolation, subunit composition, and site of synthesis of human cytochrome c oxidase

Cytochrome c oxidase (ferrocytochrome c:oxygen oxidoreductase, EC 1.9.3.1), the terminal oxidase of the respiratory chain in eucaryotic cells, has been purified from human placenta mitochondria. Seven polypeptides have been identified reproducibly by high-resolution electrophoresis of the enzyme complex through sodium dodecyl sulfate (Na-DodSO4)--urea polyacrylamide gels; these correspond closely in size to the subunits of beef heart cytochrome c oxidase. When HeLa cells, grown in suspension culture, were pulse-labeled with [35S]methionine in the presence of cycloheximide to inhibit cytoplasmic protein synthesis and chased with an excess of unlabeled methionine in the absence of the drug, the mitochondrially synthesized polypeptides were resolved into at least 17 components by NaDodSO4--urea polyacrylamide gel electrophoresis. After labeled HeLa mitochondria were mixed with human placenta mitochondria and the cytochrome c oxidase was isolated, three of the labeled components were found to copurify with the three largest subunits of the complex. We conclude that human cytochrome c oxidase contains seven subunits, the three largest of which are synthesized on mitochondrial ribosomes, while the other four are synthesized in the cytoplasm.     

Detection of a membrane-associated protein on detached membrane ribosomes in Staphylococcus aureus

Membrane ribosomes from Staphylococcus aureus which were detached from the membrane by extraction with the nonionic detergent Triton X-100 retained a protein (MBRP) with a molecular weight of 60 000, which was absent from cytoplasmic ribosomes. MBRP was detected and quantified by immunological methods. When membrane ribosomes were dissociated into 50S and 30S subunits, MBRP remained associated with the 50S particle. MBRP was found both on membrane ribosomes and in the cytoplasm in roughly equal amounts. When added to Triton X-100-solubilized protoplasts, antibodies to MBRP produced immunoprecipitates which contained a complex of MBRP and three other proteins with molecular weights of 71 000, 46 000 and 41 000. Four proteins with the same molecular weights as those of the MBRP complex were found associated with membrane ribosomes. The proteins of molecular weight 71 000, 60 000, 46 000 and 41 000 seemed to be present in stoichiometrically equivalent amounts in the complex.     

Cytopathology and release of an RNA virus from a strain of Trichomonas vaginalis

A strain of Trichomonas vaginalis infected with a double-stranded RNA virus showed pronounced cytopathology in the form of giant syncytia generated by the recruitment of single cells. The giant cells ultimately lysed, releasing virus into the culture medium. In the infected cells, clusters of electron-dense particles resembling viral structures were found in the cytoplasm. In addition, distinctive inclusions composed of similar particles were present in the nuclei of some cells. Double-stranded viral RNA of 5.5 kbp was demonstrated in both cytoplasmic and nuclear fractions from these cells. Viral particles collected from the cell-free culture supernatant were of the same shape and size as the RNA virus isolated from a strain of T. vaginalis described previously (Wang & Wang, Journal of Biological Chemistry, 260: 3697–3702, 1985; Wang & Wang, Proceedings of the National Academy of Sciences of the U.S.A. 83: 7956–7986) which does not show this cytopathology.     

Isolation of ribosome particles from meningopneumonitis organisms

In ribonucleic acid (RNA) extracted by phenol and sodium dodecyl sulfate from purified reticulate bodies of meningopneumonitis (MP) organisms, 21S, 16S, and 4S RNA were found by sucrose density gradient sedimentation analysis. When purified reticulate bodies were homogenized by sonic treatment or by treatment with sodium deoxycholate and were fractionated by differential centrifugation, more than 50% of the RNA was recovered in the fraction which was sedimented by centrifugation at 105,000 x g for 2 hr, but not at 13,000 x g for 20 min. From homogenates prepared in this manner, 50S and 30S particles containing RNA were isolated by sucrose density gradient centrifugation. These 50S and 30S particles were also found in lysates of cytoplasmic fractions of infected cells which were labeled by (32)P during 17 to 17.5 hr or 15 to 18 hr after infection. The synthesis of 50S and 30S particles was not inhibited by actinomycin D. When infected cells were homogenized in the presence of 0.01 or 0.02 m MgCl(2), 70S particles were isolated instead of 50S and 30S particles. When dialyzed against low concentrations of MgCl(2), the 70S particles dissociated to 50S and 30S particles. The base ratio of the 70S particles is very similar to that of 16S plus 21S RNA. The characteristics of the 70S, 50S, and 30S particles suggest that these are ribosome particles, similar to bacterial ribosomes.     

RIBOSOME SYNTHESIS IN TETRAHYMENA PYRIFORMIS

The cellular site of synthesis of ribosomal RNA in Tetrahymena pyriformis was studied by analyzing the purified nuclear and cytoplasmic RNA from cells pulse labeled with uridine-³H. The results of studies using zonal centrifugation in sucrose density gradients show that the ribosomal RNA is synthesized in the nucleus as a large precursor molecule sedimenting at 35S. The 35S molecule undergoes rapid transformation through two main nuclear intermediates, sedimenting at about 30S and 26S. The smaller ribosomal RNA (17S) appears first in the cytoplasm and it seems to be absent from the nucleus. The apparent delay in the appearance of the larger ribosomal RNA (26S) in the cytoplasm is due to the presence of a larger pool of its precursors in the nucleus as indicated by pulse-chase experiments. The newly synthesized ribosomal RNA's appear in the cytoplasm as discrete 60S and 45S ribonucleoprotein particles, before their incorporation into the polysomes.     

Ultrastructural investigation on a strain of a cytoplasmic-polyhedrosis virus with nuclear inclusions

A strain of a cytoplasmic-polyhedrosis virus causes the formation of crystalline inclusions almost entirely in the nucleus, and only rarely in the cytoplasm, of the midgut epithelial cells of the silkworm Bombyx mori. It also differs from the typical strain in causing the hypertrophy of the nucleoli and the formation of dense reticulum and spherical bodies in the nucleus. The virus particles and the virogenic stromata of the new strain resemble those of the typical strain. The cytoplasmic inclusions contain virus particles, while the nuclear inclusions do not. When the infected larvae are kept at 30°C for 15 hr or at 35°C for 3–15 hr, the nuclear inclusions break up into particles of 70–250 nm in diameter. The particles are dispersed in the cells but not present in the spaces previously occupied by the decomposed inclusions.     

Wheat Streak Mosaic Virus-induced Cytoplasmic Expansion and Membrane Proliferation

The cytoplasmic volume of wheat streak mosaic virus-infected cells was significantly greater than that of cells in healthy control tissue. Ultrastructural examination revealed that mainly cellular membranes and ribosomes filled the expanded cytoplasm. Imperfectly spherical inclusions, containing continuous endoplasmic reticulum membranes at the periphery and a mixture of membranes and ribosomes in the centre, were observed near nuclei at early infection stages. The inclusions became larger as infection progressed. Membranes and ribosomes proliferated also throughout the cell, forming a matrix in which organelles and various cytopathic structures were enclosed. Numerous vesicles were observed in the cytoplasm of other WSMV-infected cells. Multi-layered membrane bodies were found at later infection stages. Virus particles were present in the central space of these myelin-like structures. The presence of apparently intermediate stages in myelin-like structure development in chloroplasts suggest that at least some of the myelin-like structures originated from the chloroplasts.     

The AAA ATPase Rix7 powers progression of ribosome biogenesis by stripping Nsa1 from pre-60S particles

Ribosome biogenesis takes place successively in the nucleolar, nucleoplasmic, and cytoplasmic compartments. Numerous nonribosomal factors transiently associate with the nascent ribosomes, but the mechanisms driving ribosome formation are mostly unknown. Here, we show that an energy-consuming enzyme, the AAA-type (ATPases associated with various cellular activities) ATPase Rix7, restructures a novel pre-60S particle at the transition from the nucleolus to nucleoplasm. Rix7 interacts genetically with Nsa1 and is targeted to the Nsa1-defined preribosomal particle. In vivo, Nsa1 cannot dissociate from pre-60S particles in rix7 mutants, causing nucleolar Nsa1 to escape to the cytoplasm, where it remains associated with aberrant 60S subunits. Altogether, our data suggest that Rix7 is required for the release of Nsa1 from a discrete preribosomal particle, thereby triggering the progression of 60S ribosome biogenesis.