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.     

CYTOPLASMIC SYNTHESIS OF NUCLEAR PROTEINS : Kinetics of Accumulation of Radioactive Proteins in Various Cell Fractions after Brief Pulses

The synthesis of cytoplasmic and nuclear proteins has been studied in HeLa cells by examining the amount of radioactive protein appearing in the various subcellular fractions after labeling for brief periods. Due to the rapid equilibration of the amino acid pool, the total radioactivity in cytoplasmic protein increases linearly. The radioactivity observed in the cytoplasm is the sum of two components, the nascent proteins on the ribosomes and the completed proteins. At very short labeling times the specific activity of newly formed proteins found in the soluble supernatant fraction (completed protein) increases as the square of time, whereas the specific activity of the ribosomal fraction (nascent protein) reaches a plateau after 100 sec. The kinetics of accumulation of radioactive protein in the nucleus and the nucleolus is very similar to that of completed cytoplasmic protein, which suggests that the proteins are of similar origin. The rate of release and migration of proteins from the ribosomes into the nucleus requires less time than the synthesis of a polypeptide, which is about 80 sec. The uptake of label into nucleolar proteins is as rapid as the uptake of label into proteins of the soluble fraction of the cytoplasm, while nuclear proteins, including histones, tend to be labeled more slowly. The same results are obtained if protein synthesis is slowed with low concentrations of cycloheximide. The kinetics of incorporation of amino acids into various fractions of the cell indicates that the nucleus and the nucleolus contain few if any growing polypeptide chains, and thus do not synthesize their own proteins.     

Intracellular transport of nuclear ribosomal RNA in Acetabularia mediterranea]

The ribosomal RNA transport from a nucleus to a perinuclear cytoplasm and its following distribution in the cytoplasm of Acetabularia mediterranea cells were studied using transplantation of RNA-labeled rhizoid into unlabeled stalk. In addition rifamycin treatment was used for inhibition of cytoplasmic RNA synthesis. Acetabularia nuclei contain the stable RNA fractions similar to those present in some other eukaryotes. Nuclear 25S and 17S ribosomal RNA rapidly enter the rhizoid cytoplasm whereas the following trasfer of them to other regions of the cell is a very slow process. Within two days only an insignificant part of 25S and 17S ribosomal RNA is transferred from the rhizoid to the stalk and is distributed there over the base-apical gradient. No preferential transfer of the nuclear ribosomal RNA to the apical region was observed.     

Transport of different RNA species from the nucleus to the cytoplasm in Xenopus laevis neurula cells

Isolated cells from Xenopus laevis neurulae were labeled, and the RNAs extracted from their nuclear and soluble cytoplasmic fractions were analyzed on polyacrylamide gels. In the soluble cytoplasm, 4S RNA emerged very rapidly, and this was immediately followed by the emergence of poly(A)-containing RNA and 18S ribosomal RNA. In contrast, the emergence of 28S ribosomal RNA was delayed by about 2 hr. The size distribution of cytoplasmic poly(A)-containing RNA was much smaller as compared to that of nuclear poly(A)-containing RNA. These results indicate that the newly synthesized RNAs in Xenopus neurula cells are transported from the nucleus to the cytoplasm in a characteristic sequence.     

RNA-protein interactions of stored 5S RNA with TFIIIA and ribosomal protein L5 during Xenopus oogenesis

We studied the pathway of 5S RNA during oogenesis in Xenopus laevis from its storage in the cytoplasm to accumulation in the nucleus, the sequence requirements for the 5S RNA to follow that pathway, and the 5S RNA-protein interactions that occur during the mobilization of stored 5S RNA for assembly into ribosomes. In situ hybridization to sections of oocytes indicates that 5S RNA first becomes associated with the amplified nucleoli during vitellogenesis when the nucleoli are activity synthesizing ribosomal RNA and assembling ribosomes. When labeled 5S RNA is microinjected into the cytoplasm of stage V oocytes, it migrates into the nucleus, whether microinjected naked or complexed with the protein TFIIIA as a 7S RNP storage particle. During vitellogenesis, a nonribosome bound pool of 5S RNA complexed with ribosomal protein L5 (5S RNPs) is formed, which is present throughout the remainder of oogenesis. Immunoprecipitation assays on homogenates of microinjected oocytes showed that labeled 5S RNA can become complexed either with L5 or with TFIIIA. Nucleotides 11 through 108 of the 5S RNA molecule provide the necessary sequence and conformational information required for the formation of immunologically detectable complexes with TFIIIA or L5 and for nuclear accumulation. Furthermore, labeled 5S RNA from microinjected 7S RNPs can subsequently become associated with L5. Such labeled 5S RNA is found in both 5S RNPs and 7S RNPs in the cytoplasm, but only in 5S RNPs in the nucleus of microinjected oocytes. These data suggest that during oogenesis a major pathway for incorporation of 5S RNA into nascent ribosomes involves the migration of 5S RNA from the nucleus to the cytoplasm for storage in an RNP complex with TFIIIA, exchange of that protein association for binding with ribosomal protein L5, and a return to the nucleus for incorporation into ribosomes as they are being assembled in the amplified nucleoli.     

EVIDENCE FOR CYTOPLASMIC DNA IN ROOT CELLS OF NICOTIANA

Sterile root cultures from Nicotiana tabacum were grown with H³-thymidine added to the medium for various intervals. Incorporation of the labeled nucleoside into nuclear DNA occurred in a fraction of the nuclei which increased with time. In addition, the cytoplasm of all cells incorporated enough tritium to be readily detected by autoradiography. The tritium was not removed by hydrolysis in 1 N HCl at 60°C for 10 minutes, but was removed by digestion in a DNase solution which also removed nuclear DNA. The amount of tritium in the cytoplasm increased during the first 2 hours, but did not appear to increase significantly during the following 5 hours. If the roots were transferred to unlabeled medium after 2 hours, the label was diluted faster than expected by growth without turnover of the labeled component. If FUdR was added to the unlabeled medium, the depletion occurred faster during the first 6 hours, but later appeared to level off so that at 10 hours these cultures did not differ from those incubated without FUdR. However, the addition of an excess of unlabeled carrier had no effect on the rate of depletion of the cytoplasmic label. Actinomycin D, which inhibited the incorporation of H³-cytidine into RNA in the root tips, had no effect on the incorporation of H³-thymidine into the cytoplasmic component. However, Mitomycin C or a high concentration of deoxyadenosine inhibited the incorporation of H³-thymidine into the cytoplasmic component as well as into the nuclear DNA. It is concluded that H³-thymidine is incorporated into a cytoplasmic fraction which has the characteristics of DNA, with a measurable rate of turnover. This fraction is synthesized regardless of whether or not the nucleus is synthesizing DNA. Although the function of cytoplasmic fraction is not yet known, it does not appear to be that of supplying precursors for the synthesis of the nuclear DNA.     

RNA metabolsim during vegetative growth and morphogenesis of the cellular slime mold Dictyostelium discoideum

During vegetative growth of the cellular slime mold Dictyostelium discoideum, RNA is rapidly labeled by radioactive precursor and both the 25 S and the 17 S ribosomal RNA species appear in the cytoplasm 6–7 min after the onset of labeling. Thirty minutes after further incorporation of radioactive RNA precursors has been blocked, less than 10% of the label in RNA is associated with the nuclear fraction. After aggregation of the slime mold amoebae, RNA appears in the cytoplasm at a reduced rate, the small ribosomal subunit appearing in the cytoplasmic fraction more slowly than the larger ribosomal subunit. Some labeled RNA remains in the nuclei of developing cells long after the incorporation of ³H-uridine is blocked.     

Chicken erythrocyte membranes: comparison of nuclear and plasma membranes from adults and embryos

These experiments were designed to determine whether the migration of RNA molecules from an implanted nucleus to the host cytoplasm and from there into the host cell nucleus against a concentration gradient might reflect an artefact induced by the process of nuclear transplantation. That is, are RNA molecules, as previously shown for certain nuclear proteins, caused to artefactually leave a manipulated nucleus and then move into the host cell nucleus (as well as return to the grafted nucleus) during the recovery period?A variety of experiments involving different kinds of manipulative sequences and different numbers of nuclear transplantations suggest—but do not prove—that no artefact is involved in the migration of RNA from one nucleus to another but two experiments strongly support the view that the shuttling activity is a normal physiological process. One of the latter involved a determination of the rate of egress of ³H-RNA from an implanted nucleus and reveals that that rate, in contrast with the equivalent rate of egress for labeled proteins which is clearly abnormal after micromanipulation, is totally consonant with the rate of movement of RNA from nucleus to cytoplasm established from experiments that do not involve micromanipulation. The other experiment involves comparison of (1) the amount of radioactivity acquired by an unlabeled nucleus present in the cell at the time a labeled nucleus is implanted with (2) the amount of radioactivity acquired by an unlabeled nucleus implanted after a labeled nucleus had been implanted and had time to recover from any possible operation-induced trauma. With ³H-protein nuclei the host nuclei of (1) acquired much more label than the host nuclei of (2) because in (1) the host nuclei were able to acquire much of the artefactually-released ³H-protein. For the ³H-RNA experiments, however, little difference was found between (1) and (2) in the amount of label acquired by the host cell nuclei. It can be concluded that little, if any, of the non-random shuttling activity of RNA molecules can be a reflection of an artefact.     

THE CYTONUCLEOPROTEINS OF AMEBAE : I. Some Chemical Properties and Intracellular Distribution

Autoradiographs of whole Amoeba proteus host cells fixed after the implantation of single nuclei from A. proteus donors labeled with any one of 8 different radioactive amino acids showed that the label had become highly concentrated in the host cell nucleus as well as in the donor nucleus and that the cytoplasmic activity was relatively low. When these amebae were sectioned, the radioactivity was found to be homogeneously distributed throughout the nuclei. The effect of unlabeled amino acid "chaser," the solubility of the labeled material, and the long-term behavior of the labeled material gave evidence that the radioactivity was in protein. At equilibrium, the host cell nucleus contained approximately 30 per cent of the radioactivity distributed between the two nuclei. This unequal nuclear distribution is attributed to the presence of two classes of nuclear proteins: a non-migratory one that does not leave the nucleus during interphase, and a migratory one, called cytonucleoprotein, that shuttles between nucleus and cytoplasm in a non-random manner. It is estimated that between 12 per cent and 44 per cent of the cytonucleoproteins are present in the cytoplasm of a binucleate cell at any one moment. Nuclei of Chaos chaos host cells also concentrated label acquired from implanted radioactive A. proteus nuclei.     

Essential factors in the kinetic analysis of RNA synthesis in HeLa cells

Further evidence of mRNA in HeLa cells with a half-life two hours or less is given. A kinetic model of RNA synthesis in HeLa cells is described in which equilibration of label occurs first into the acid soluble pool (evidence is given that this pool feeds RNA synthesis) and thence in nuclear and cytoplasmic molecules. The measured accumulation of label in nuclear and cytoplasmic poly(A) is examined with the model and parameters were found which are consistent with the quantitative transfer of nuclear poly(A) to the cytoplasm. The strengths and limitations of the model are discussed.     

NUCLEOLAR-DERIVED RIBONUCLEIC ACID IN CHROMOSOMES, NUCLEAR SAP, AND CYTOPLASM OF CHIRONOMUS TENTANS SALIVARY GLAND CELLS

The distribution of monodisperse high molecular weight RNA (38, 30, 28, 23, and 18S RNA) was studied in the salivary gland cells of Chironomus tentans. RNA labeled in vitro and in vivo with tritiated cytidine and uridine was isolated from microdissected nucleoli, chromosomes, nuclear sap, and cytoplasm and analyzed by electrophoresis on agarose-acrylamide composite gels. As shown earlier, the nucleoli contain labeled 38, 30, and 23S RNA. In the chromosomes, labeled 18S RNA was found in addition to the 30 and 23S RNA previously reported. The nuclear sap contains labeled 30 and 18S RNA, and the cytoplasm labeled 28 and 18S RNA. On the basis of the present and earlier analyses, it was concluded that the chromosomal monodisperse high molecular weight RNA fractions (a) show a genuine chromosomal localization and are not due to unspecific contamination, (b) are not artefacts caused by in vitro conditions, but are present also in vivo, and (c) are very likely related to nucleolar and cytoplasmic (pre)ribosomal RNA. The 30 and 23S RNA components are likely to be precursors to 28 and 18S ribosomal RNA. The order of appearance of the monodisperse high molecular weight RNA fractions in the nucleus is in turn and order: (a) nucleolus, (b) chromosomes, and (c) nuclear sap. Since both 23 and 18S RNA are present in the chromosomes, the conversion to 18S RNA may take place there. On the other hand, 30S RNA is only found in the nucleus while 28S RNA can only be detected in the cytoplasm, suggesting that this conversion takes place in connection with the exit of the molecule from the nucleus.     

PROTEINS IN NUCLEOCYTOPLASMIC INTERACTIONS : II. Turnover and Changes in Nuclear Protein Distribution with Time and Growth

In previous studies, we showed that essentially all the proteins of the Amoeba proteus nucleus could be classified either as Rapidly Migrating Proteins (RMP), which shuttle between nucleus and cytoplasm continuously at a relatively rapid rate during interphase, or as Slow Turnover Proteins (STP), which seem to move hardly at all during interphase. In this paper, we report on the kinetics and direction of the movement of both classes of protein, as well as on aspects of their localization, with and without growth. The effects of growth were observed with and without cell division. These nuclear proteins have been studied in several ways: by transplantation of labeled nuclei into unlabeled cells and noting the rate of distribution to cytoplasm and host cell nuclei; by repeated amputation of cytoplasm from labeled cells—with and without initially labeled cytoplasm—each amputation being followed by refeeding on unlabeled food; by noting the redistribution of the various protein classes following growth and cell division. The data show (a) labeled RMP equilibrate between a grafted labeled nucleus and an unlabeled host nucleus in ca. 3 hr, but are detectable in the latter less than 30 min after the operation; (b) STP label does, indeed, leave the nucleus and does so at a rate of ca. 25% of the nuclear total per cell generation (ca. 36–40 hr at 23°C); (c) the cytoplasm appears to have a reserve of material that is converted to RMP; (d) when labeled cells are amputated just before they would have divided and are refed unlabeled food after each amputation, there is a loss of 20–25% of the nuclear protein label with each amputation; (e) under the latter circumstances, an essentially complete turnover of all nuclear protein can be demonstrated.     

Characterization of RNA molecules restricted to the nucleus in mouse L-cells

RNA molecules which are restricted to the nucleus in mouse L-cells were characterized by the technique of RNA/DNA hybridization. Competition of cytoplasmic RNA with labeled nuclear RNA of various sizes revealed that the RNA restricted to the cell nucleus is heterogeneous in size. Competition for sites on fractions of mouse DNA of various base compositions indicated that this unstable RNA is also heterogeneous in base composition. Fractionation of nuclei into three subfractions failed to separate the uniquely nuclear RNA from the precursors of cytoplasmic RNA. The significance of the selective transport of RNA from the nucleus to the cytoplasm and its importance in the control of gene activity in eucaryotic cells is discussed.     

A Comparison of the Killing of Cultured Mammalian Cells Induced by Decay of Incorporated Tritiated Molecules at -196°C

The killing efficiency of tritium disintegrations in frozen mammalian cells labeled with tritiated uridine, histidine, and lysine was compared with the killing efficiency of incorporated tritiated thymidine. In each case, the distribution of tritium in the cells was determined by chemical fractionation as well as by radio-autography. Of all tritium disintegrations, by far the most effective were those occurring in DNA molecules within frozen cells; such incorporated tritium has a killing efficiency of 0.006. When cells were incubated with tritiated uridine for 10 min to label nuclear RNA, the killing efficiency was 0.0015. When the cells were pulse labeled with tritiated uridine and permitted to grow in nonradioactive media for 10 hr before freezing in order to incorporate tritium into cytoplasmic RNA, the killing efficiency was reduced to 0.0010. The results suggest that decay of tritium in nuclear RNA is more effective than that in cytoplasmic RNA. When the cells were labeled with tritiated histidine or lysine for 30 min, tritium atoms were found mainly in the acid soluble rather than in the protein fraction and the killing efficiency in each case was approximately 0.0007. The results of these suicide experiments indicate that the killing efficiency of tritium disintegrations depends on where tritium is located within the cells. Tritium disintegrations in the nucleus are more effective in killing the cell than that in cytoplasm; and tritium disintegrations on DNA in the nucleus is more effective in killing the cell than that of nuclear RNA.     

LOCALIZATION OF MACROMOLECULES IN ESCHERICHIA COLI : II. RNA and its Site of Synthesis

The distribution of RNA in cells of E. coli 15 T^-U^- labeled with uridine-H³ was studied by methods involving the analysis of radioautographic grain counts over random thin cross-sections and serial sections of the cells. The results were correlated with electron microscope morphological data. Fractionation and enzyme digestion studies showed that a large proportion of the label was found in RNA uracil and cytosine, the rest being incorporated as DNA cytosine. In fully labeled cells the distribution of label was found to be uniform throughout the cell. The situation remained unchanged when labeled cells were subsequently treated with chloramphenicol. When short pulses of label were employed a localization of a large proportion of the radioactivity became apparent. The nuclear region was identified as the site of concentration. Similar results were obtained when cells were exposed to much longer pulses of uridine-H³ in the presence of chloramphenicol. If cells were subjected to a short pulse of cytidine-H³, then allowed to grow for a while in unlabeled medium, the label, originally concentrated to some extent in the nuclear region, was found dispersed throughout the cell. The simplest hypothesis which accounts for these results is that a large fraction of the cell RNA is synthesized in a region in or near the nucleus and subsequently transferred to the cytoplasm.     

Kinetics of Incorporation of DNA Precursors from Ingested Bacteria into Macronuclear DNA of Paramecium aurelia12

SYNOPSIS. The kinetics of transfer of tritium-labeled material from the DNA of ingested bacteria into macronuclear DNA of Paramecium was examined by autoradiography. Bacteria labeled with tritiated thymidine were almost immediately incorporated into food vacuoles, thus becoming available for digestion and a potential source of labeled DNA precursors. Soluble label derived from food vacuoles appeared in low concentrations in the cytoplasm soon after cells were transferred to medium with labeled bacteria; incorporation of labeled precursors into macronuclear DNA began within 5 min. Labeled food vacuoles remained as potential sources of tritiated DNA precursors for a long and variable period after removal of labeled cells to non-labeled medium. The activity of the soluble cytoplasmic DNA precursors decreased parallel to the loss of labeled food vacuoles and no soluble DNA precursors were carried over from one macronuclear DNA synthetic period to the next. Labeling experiments were designed, using this information, which allowed determination of the pattern of macronuclear DNA synthesis and nuclear mass increase during the cell cycle. Macronuclear DNA synthesis began 25–30% of the way thru the cell cycle, continued at a constant rate during the middle half, and decreased in rate during the last quarter. Macronuclear mass increased in an approximately linear fashion, beginning with the onset of DNA synthesis and doubling by the time of karyokinesis.     

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.