Ribosomal RNA synthesis in mitochondria of Neurospora crassa

Ribosomal RNA synthesis in Neurospora crassa mitochondria has been investigated by continuous labeling with [5-³H]uracil and pulse-chase experiments. A short-lived 32 S mitochondrial RNA was detected, along with two other short-lived components; one slightly larger than large subunit ribosomal RNA, and the other slightly larger than small subunit ribosomal RNA. The experiments give support to the possibility that 32 S RNA is the precursor of large and small subunit ribosomal RNA's. Both mature ribosomal RNA's compete with 32 S RNA in hybridization to mitochondrial DNA. Quantitative results from such hybridization-competition experiments along with measurements of electrophoretic mobility have been used to construct a molecular size model for synthesis of mitochondrial ribosomal RNA's. The large molecular weight precursor (32 S) of both ribosomal RNA's appears to be 2.4 × 10⁶ daltons in size. Maturation to large subunit RNA (1.28 × 10⁶ daltons) is assumed to involve an intermediate ~1.6 × 10⁶ daltons in size, while cleavage to form small subunit RNA (0.72 × 10⁶ daltons) presumably involves a 0.9 × 10⁶ dalton intermediate. In the maturation process ~22% of the precursor molecule is lost. As is the case for ribosomal RNA's, the mitochondrial precursor RNA has a strikingly low G + C content.     

Vorstufen der ribosomalen RNA in frei suspendierten Calluszellen der Petersilie (Petroselinum sativum)

Summary Six high molecular weight, rapidly labelled RNA species were detected in freely suspended callus cells of Petroselinum sativum by means of isotope labelling and electrophoretic separation in agarose-polyacrylamide gels. On the basis of their migration in the latter the RNA species were calculated to have the following molecular weights: 2.9×10⁶, 2,4×10⁶, 1.9×10⁶, 1.4×10⁶, 1.0×10⁶ and 0.75×10⁶ daltons. Thus they can clearly be distinguished from the two ribosomal RNA species (1.3×10⁶ and 0.7×10⁶ daltons). During incubation of the cells with [³H]methyl-methionine as a methyl donator all six components incorporated radioactivity rapidly. With [³H]nucleosides or [³H]orotic acid as precursors the 2.9×10⁶ and the 2.4×10⁶ daltons RNA were labelled within 10 min, while the other high molecular weight species appeared after about 20 min of labelling.Prolongation to 45–120 min resulted in accumulation of radioactivity preferentially in the 1.4×10⁶ and 0.75×10⁶ daltons RNA and in the ribosomal RNA species. The results of cell fractionation experiments provide evidence that these rapidly labelled high molecular weight RNA species are synthesized in the cell nucleus. The kinetics of their synthesis together with the other data obtained strongly support the suggestion that these RNA species function as precursors in the processing of ribosomal RNA. The possible mechanism of this process is discussed.

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Verwendete Abkürzungen EDTA Äthylendiamintetraessigsäure - DNase Desoxyribonuclease - Imp./min epm - MAK methyliertes Albumin an Kieselgur - POPOP 1,4- bis (4-Methyl-5-Phenyloxazol)-Benzol - PPO 2,5-Diphenyloxazol - RNase Ribonuclease - S Sedimentationskoeffizient in Svedberg-Einheiten - SDS Natriumdodecylsulfat - TPE Tris-Phosphat-EDTA-Puffer - Tris Tris-(hydroxymethyl)-aminomethan - Upm rpm     

Ribonucleic acid synthesis and loss of viability in pea seed

Summary RNA synthesis and protein synthesis in embryonic axis tissue of viable pea (Pisum arvense L. var. N.Z. maple) seed commences during the first hour of germination. Protein synthesis in axis tissue of non-viable pea seed is barely detectable during the first 24 h after the start of imbibition. Nonviable axis tissue incorporates significant levels of [³H]uridine into RNA during this period but the level of incorporation does not increase significantly over the first 24 h of imbibition. In axis tissue of non-viable seed during the first hour of imbibition most of the [³H]uridine was incorporated into low molecular weight material migrating in advance of the 4S and 5S RNA species in polyacrylamide gels but some radioactivity was incorporated into a discrete species of RNA having a molecular weight of 2.7×10⁶. After 24 h, non-viable axis tissue incorporates [³H]uridine into ribosomal RNA, the low molecular weight material migrating in advance of the 4S and 5S RNA peak in polyacrylamide gels and a heterogeneous RNA species of molecular weight ranging from 2.2×10⁶ to 2.7×10⁶. No 4S or 5S RNA synthesis is detectable after 24 h of imbibition in non-viable axis tissue. Axis tissue of viable pea seed synthesises rRNA, 4S and 5S RNA, the low molecular weight material migrating in advance of the 4S and 5S RNA peak in polyacrylamide gels and the rRNA precursor species at both periods of germination studied. Loss of viability in pea seed appears to be accompanied by the appearance of lesions in the processing of rRNA precursor species and a significant loss of RNA synthesising activity.Abbreviations rRNA ribosomal RNA - TCA trichloroacetic acid - SLS sodium lauryl sulphate - PPO 2,5 Diphenyloxazole - POPOP 1,4-Bis-2-(4-methyl-5-penyloxazolyl)-benzene     

Isolation and some properties of a mammalian ribosomal DNA

The DNA coding for 28 S and 18 S ribosomal RNA, including the spacer regions, has been isolated from calf (Bos taurus) thymus gland. The method used included shearing of the total DNA to a highly homogeneous size population, selective heat denaturation and S 1 nuclease treatment to remove single stranded DNA. Repeated centrifugation on density gradients yields a 140-fold purified rDNA fraction with a GC content of 61.2%. Eco RI nuclease cleaves this DNA into two fragments of 16.4 and 4.9×10⁶ daltons. Hybridization of these fragments with 28 S and 18 S rRNA shows that the 28 S coding sequence is located mostly on the 4.9×10⁶ dalton fragment, while both the 16.4 and 4.9×10⁶ dalton fragments contain the 18 S sequence. The data indicate that the ribosomal RNA gene has a repeat unit of 21.3×10⁶ daltons which includes a nontranscribed spacer of about 12.5×10⁶ daltons.     

A denaturation map of sea urchin ribosomal DNA

The ribosomal RNA genes from the sea urchin Lytechinus variegatus have been studied with the electron microscope using the technique of denaturation mapping. A repeating pattern of denatured regions was found with an average repeat length of 3.87±0.24m. This corresponds to a DNA sequence of approximately 12,000 base pairs with a molecular weight of 8×10⁶ daltons.Abbreviations rRNA ribosomal RNA, including 26S and 18S RNA - Tris tris(hydroxymethyl)-aminomethane - EDTA ethylenediaminetetraacetate     

The properties and function of rapidly-labelled nuclear RNA

Summary Nuclei were isolated from cultured cells of Acer pseudoplatanus L. previously pulse-labelled with [5-³H]uridine or [³²P]phosphate and the properties of the rapidly-labelled RNA were studied. Polyacrylamide gel electrophoresis showed ribosomal RNA precursors and processing intermediates with molecular weights of 3.4, 2.5, 1.4 and 1×10⁶ daltons, together with polydisperse RNA. The relative proportions of ribosomal RNA precursors and polydisperse RNA varied according to the length of the labelling period, but after 30 min approximately 90% of the radioactive RNA was polydisperse. The relationship between this polydisperse RNA and messenger RNA was investigated. The percentage of total nuclear RNA retained by chromatography on oligodeoxythymidylic acid-cellulose columns varied from 6% to 16% depending on the length of the labelling period. This RNA fraction, which has an adenylic acid content of approximately 45%, is assumed to represent RNA with polyadenylic acid sequences attached. A larger proportion of the nuclear polydisperse RNA lacked polyadenylic acid. Both types of polydisperse RNA were similar in size and during polyacrylamide gel electrophoresis migrated as broad peaks with an average molecular weight of approximately 10⁶ daltons. The polydisperse nuclear RNA that lacks polyadenylic acid was found to be similar in nucleotide composition to ribosomal RNA and is assumed to represent growing chains of ribosomal precursor RNA. After short labelling times the majority of the radioactivity incorporated into nuclear RNA is present in molecules of this type. This suggests that the designation of pulse-labelled polydisperse RNA as messenger RNA or precursor to messenger RNA solely on the basis of rapid labelling and size heterogeneity is unsound. The average molecular weight of the polyadenylic acid-containing messenger RNA from the cytoplasm was less than that of the corresponding nuclear RNA (6 and 9×10⁵ daltons respectively). This suggest either that the majority of the nuclear polyadenylic acid-containing RNA does not enter the cytoplasm, or if it does, that it first undergoes a reduction in size.Abbreviations rRNA ribosomal RNA - mRNA messenger - RNA poly(A), polyadenylic acid, poly(A) and poly(A) - RNA RNA with and without poly(A) sequences attached - poly(U) polyuridylic acid - oligo (dT)-cellulose cellulose with oligo deoxythymidylic acid covalently attached - C cytidylic acid - A adenylic acid - G guanylic acid - U uridylic acid     

Ribosomal RNA Turnover in Contact Inhibited Cells

CONTACT inhibition of animal cell growth is accompanied by a decreased rate of incorporation of nucleosides into RNA^1–3. Contact inhibited cells, however, transport exogenously-supplied nucleosides more slowly than do rapidly growing cells^4,5, suggesting that the rate of incorporation of isotopically labelled precursors into total cellular RNA may be a poor measure of the absolute rate of RNA synthesis by these cells. Recently, Emerson⁶ determined the actual rates of synthesis of ribosomal RNA (rRNA) and of the rapidly labelled heterogeneous species (HnRNA) by labelling with ³H-adenosine and measuring both the specific activity of the ATP pool and the rate of incorporation of isotope into the various RNA species. He concluded that contact inhibited cells synthesize ribosomal precursor RNA two to four times more slowly than do rapidly growing cells, but that there is little if any reduction in the instantaneous rate of synthesis of HnRNA by the non-growing cells. We have independently reached the same conclusion from simultaneous measurements on the specific radioactivity of the UTP pool and the rate of ³H-uridine incorporation into RNAs (unpublished work of Edlin and myself). However, although synthesis of the 45S precursor to ribosomal RNA is reduced two to four times in contact inhibited cells, the rate of cell multiplication and the rate of rRNA accumulation are reduced ten times. This suggests either “wastage”⁷ of newly synthesized 45S rRNA precursor, or turnover of ribosomes in contact inhibited cells Two lines of evidence suggest that “wastage” of 45S RNA does not play a significant role in this system. (1) The rate of synthesis of 45S RNA in both growing and contact inhibited cells agrees well with that expected from the observed rates of synthesis of 28S and 18S RNAs (unpublished work of Edlin and myself). Emerson has made similar calculations⁶. (2) 45S RNA labelled with a 20 min pulse of ³H-uridine is converted in the presence of actinomycin D to 28S and 18S RNAs with the same efficiency (approximately 50%) in both growing and contact inhibited cells. These results indicate that, in order to maintain a balanced complement of ribosomal RNAs, contact inhibited cells must turn over their ribosomes. We present evidence here that rRNA is stable in rapidly growing chick cells, but begins to turn over with a half-life of approximately 35–45 h as cells approach confluence and become contact inhibited.     

Cell cycle analysis in asynchronous cultures using the BUdR-Hoechst technique.

During synchronized germination of spores of Dictyostelium discoideum, protein synthesis begins almost concomitantly with syntheses of messenger-like RNA (mlRNA) and 4–5S RNA (presumably tRNA) in the swollen spore stage and the initiation of ribosomal RNA (rRNA) synthesis is somewhat delayed. DNA synthesis occurs in the early stages of the amoeba emergence phase. Cycloheximide (200 μg/ml) blocked spore germination as well as total protein synthesis, whereas actinomycin D (60 μg/ml) did not affect either. This concentration of actinomycin D selectively inhibited formation of rRNA but did not influence the synthesis of mlRNA. Examinations of RNA labeled with [¹⁴C]uracil during germination indicated that polysomes initially detectable in the course of the germination process contain ¹⁴C-labeled mlRNA. It was concluded that at least some of mRNA synthesized during germination of D. discoideum spores is involved in protein synthesis required for the germination.     

Effects of Actinomycin D and Ultraviolet and Ionizing Radiation on Pichinde Virus

Actinomycin D (0.05 μg/ml) suppresses the synthesis of ribosomal RNA of baby hamster kidney (BHK21) cells. The production of infectious Pichinde virus was enhanced in the presence of actinomycin D, although the production of virus particles was not substantially different from cultures inoculated in the absence of the drug. By prelabeling BHK21 cells with ³H-uridine and then allowing the virus to replicate in the presence of actinomycin D, it was possible to show that ribosomal RNA synthesized prior to infection was incorporated into the virion. A single-hit kinetics of inactivation of Pichinde virus was observed with ultraviolet light, suggesting that the virus contains only a single copy of genome per virion. Comparison of the inactivation kinetics by gamma irradiation of Pichinde virus with Sindbis and rubella virus indicated that the radiosensitive genome of Pichinde virus was about 6 × 10⁶ to 8 × 10⁶ daltons. This value is greater than the 3.2 × 10⁶ daltons which was estimated by biochemical analysis. One possible explanation considered is that the ribosomal RNA of host cell origin is functional and accounts for the differences in genome size estimated by the two methods.     

The polyadenylated RNA of zoospores and growth phase cells of the aquatic fungus,Blastocladiella

The stored poly(A) + RNA from zoospores of the aquatic fungus Blastocladiella emersonii represents 2.5% of the total RNA and has a model MW of 425,000 daltons and an average poly(A) isostich of 32 bases. The poly(A) + RNA also represents 2.5% of the total RNA from early growth phase cells and has a modal MW of 360,000 daltons and an average poly(A) isostich of 38 bases. The poly(A) + RNA from spores and 2-hr plants contains a structure resistant to RNases T₁, T₂, and A, which can be labeled with ³²PO₄ and which will bind to DBAE-cellulose. These characteristics strongly suggest that both the zoospore poly(A) + RNA and the 2-hr cell poly(A) + RNA are capped at the 5′ end; and, hence, it is unlikely that capping is involved in the control of protein synthesis during germination.Approximately 80% of the poly(A) + RNA of the spore is located in the membrane-enclosed ribosomal nuclear cap, and more than 90% of the poly(A) + RNA within the cap is found in the 80S monoribosome and heavier fractions.Synthesis of new poly(A) + RNA occurs very early during zoospore germination, and the labeled poly(A) + RNA rapidly enters the newly organized polysomes. The labeling data for early germination also suggest that cytoplasmic polyadenylation occurs.     

Kern-Plasma-Transport neusynthetisierter rRNS in Zellen einer Suspensionskultur von Petroselinum sativum

Summary A rapidly labelled rRNA precursor can be detected in callus cells of Petroselinum sativum grown on a liquid synthetic medium. Its molecular weight has been calculated to be 2.3×10⁶. This value agrees with that of the rRNA precursor from other plant material. In order to follow the synthesis and processing of rRNA in time and to correlate single steps in this process with cell organelles it was necessary to obtain pure fractions of nuclei and ribosomes. The isolation method for nuclei is given in detail. The nucleic acids are separated on polyacrylamide gels of low acrylamide concentration. Pulse-chase experiments show that the rRNA precursor is split into two fragments within the nucleus: an 18S and a 25S component. The 18S RNA leaves the nucleus rapidly. It is already found quantitatively in the ribosomal fraction after 30–60 min chase. At that time the 25S RNA is still within the nucleus; it appears much later in the ribosomes. Since the increase in ribosomal label occurs simultaneously with the decrease in nuclear label, it is concluded that there is no degradation of 18S RNA within the nucleus. Apparently there are two distinct transport mechanisms with different kinetics for the two RNA components.     

Characterization of the ribosomal RNA precursor in Ilyanassa

Ilyanassa embryos synthesized a high molecular weight, rapidly-labeled RNA species that, as time progressed, diminished in proportion to increasing amounts of nascent ribosomal RNA. We tentatively identify this rapidly-labeled RNA species as the ribosomal RNA precursor. Its molecular weight, determined by acrylamide gel electrophoresis, was 2.4–2.5 × 10⁶; a molecule of intermediate size (1.8 × 10⁶ Daltons) was also detected.     

Isolation of ribosomal RNA precursors from Physarum polycephalum

Ribosomal RNA synthesis in Physarum polycephalum was studied by labeling intact microplasmodia with [³H]uridine. Labeled, high-molecular-weight RNA species were found in a 30,000 S structure released by phenol extraction at room temperature. RNA was released from the structure by further phenol extraction at 65–70 °C. If the labeling period was 15 min or longer, the labeled RNA was seen by polyacrylamide gel electrophoresis to be of two major types, a heterodisperse collection of 45-35 S molecules and a 26 S species. If the labeling was carried out for 30 min in the presence of cycloheximide, the major labeled species had an electrophoretic mobility corresponding to 40 S. Studies of the labeling kinetics, methylation, and base composition of these RNA molecules indicate that they are precursors to ribosomal RNA. The molecular weights of the homogeneous 40 and 26 S precursors are 3.0 × 10⁶ and 1.45 × 10⁶ daltons, respectively, in comparison with molecular weights of 1.29 × 10⁶ and 0.68 × 10⁶ daltons for the completed ribosomal RNA's.     

Ribosomal Ribonucleic Acid Maturation During Bacterial Spore Germination

All the ribosomal ribonucleic acid made during the early stages of germination of spores of Bacillus subtilis is of the "precursor" type, i.e., that type appearing in the incomplete forms of the ribosome. Shortly before the onset of deoxyribonucleic acid synthesis in germination, this precursor ribonucleic acid changed to the mature ribosomal ribonucleic acid characteristic of the 30S and 50S ribosomal subunits.