Synthesis of ribonucleic acids during the germination of Rhizopus stolonifer sporangiospores

A number of ribonucleic acids initiated synthesis during the first 15 min of germination of Rhizopus stolonifer sporangiospores. They included ribosomal, 5S, and transfer RNA, and a heterogeneously-sedimenting fraction that composed about 5% of the total cellular RNA; this fraction was unmethylated, did not compete with ribosomal RNA for hybridization to DNA, and was bound to poly dT-cellulose in a manner characteristic of RNAs containing polyadenylate segments. The nearly simultaneous onset of synthesis of the various RNAs with germination contrasts with the sequential onset of RNA synthesis reported for other fungal spores.     

CONTROL OF 5S RNA SYNTHESIS DURING EARLY DEVELOPMENT OF ANUCLEOLATE AND PARTIAL NUCLEOLATE MUTANTS OF XENOPUS LAEVIS

Ribosomes of all eukaryotes contain a single molecule of 5S, 18S, and 28S RNA. In the frog Xenopus laevis the genes which code for 18S and 28S RNA are located in the nucleolar organizer, but these genes are not linked to the 5S RNA genes. Therefore the synthesis of the three ribosomal RNAs provides a model system for studying interchromosomal aspects of gene regulation. In order to determine if the synthesis of the three ribosomal RNAs are interdependent, the relative rate of 5S RNA synthesis was measured in anucleolate mutants (o/o), which do not synthesize any 18S or 28S RNA, and in partial nucleolate mutants (p^l-1/o), which synthesize 18S and 28S RNA at 25% of the normal rate. Since the o/o and p^l-1/o mutants have a complete and partial deletion of 18S and 28S RNA genes respectively, but the normal number of 5S RNA genes, they provide a unique system in which to study the dependence of 5S RNA synthesis on the synthesis of 18S and 28S RNA. Total RNA was extracted from embryos labeled during different stages of development and analyzed by polyacrylamide gel electrophoresis. Quite unexpectedly it was found that 5S RNA synthesis in o/o and p^l-1/o mutants proceeds at the same rate as it does in normal embryos. Furthermore, 5S RNA synthesis is initiated normally at gastrulation in o/o mutants in the complete absence of 18S and 28S RNA synthesis.     

The action of α-amanitin in vivo on the synthesis and maturation of mouse liver ribonucleic acids

α-Amanitin acts in vitro and in vivo as a selective inhibitor of nucleoplasmic RNA polymerases. Treatment of mice with low doses of α-amanitin causes the following changes in the synthesis, maturation and nucleocytoplasmic transfer of liver RNA species. 1. The synthesis of the nuclear precursor of mRNA is strongly inhibited and all electrophoretic components are randomly affected. The labelling of cytoplasmic mRNA is blocked. These effects may be correlated with the rapid and lasting inhibition of nucleoplasmic RNA polymerase. 2. The synthesis and maturation of the nuclear precursor of rRNA is inhibited within 30min. (a) The initial effect is a strong (about 80%) inhibition of the early steps of 45S precursor rRNA maturation. (b) The synthesis of 45S precursor rRNA is also inhibited and the effect increases from about 30% at 30min to more than 70% at 150min. (c) The labelling of nuclear and cytoplasmic 28S and 18S rRNA is almost completely blocked. The labelling of nuclear 5S rRNA is inhibited by about 50%, but that of cytoplasmic 5S rRNA is blocked. (d) The action of α-amanitin on the synthesis of precursor rRNA cannot be correlated with the slight gradual decrease of nucleolar RNA polymerase activity (only 10–20% inhibition at 150min). (e) The inhibition of precursor rRNA maturation and synthesis precedes the ultrastructural lesions of the nucleolus detected by standard electron microscopy. 3. The synthesis of nuclear 4.6S precursor of tRNA is not affected by α-amanitin. However, the labelling of nuclear and cytoplasmic tRNA is decreased by about 50%, which indicates an inhibition of precursor tRNA maturation. The results of this study suggest that the synthesis and maturation of the precursor of rRNA and the maturation of the precursor of tRNA are under the control of nucleoplasmic gene products. The regulator molecules may be either RNA or proteins with exceedingly fast turnover.     

The differential regulation of the synthesis of ribosomal RNA, 5 S RNA, and 4 S RNA in the polytenic salivary gland cells of the blowfly, Calliphora erythrocephala

Third-instar larvae of the blowfly Calliphora erythrocephala were injected with [2-³H]adenosine, and its flow into the salivary gland ATP pool and each of several electrophoretically resolved salivary gland RNA species were quantitated. From these data, the individual in vivo rates of synthesis, accumulation, and processing of salivary gland ribosomal RNA (rRNA), 4 S RNA, and 5 S RNA have been measured at several different developmental stages. These results indicate that the synthesis of 5 S RNA and rRNA are coordinate, developmentally regulated, and independent of the synthesis of 4 S RNA. A nonribosomal, heterodisperse RNA component (hdRNA) was also identified. This species contributes to both the rapidly turning over pulse-labeled RNA and the accumulating pulse-labeled RNA populations. Indirect measurements suggest that the developmental pattern of regulation of this RNA species is also independent of 5 S RNA and rRNA synthesis. The rate of synthesis and accumulation of each of these RNA species either remained constant or declined during the first three-fourths of the instar, despite a six- to sevenfold increase in the content of cellular DNA.     

A Correlation between a Ribonucleic Acid Fraction Selectively Labeled in the Presence of Gibberellic Acid and Amylase Synthesis in Barley Aleurone Layers

The effects of gibberellic acid on the incorporation of radio-active uridine and adenosine into RNA of barley aleurone layers were investigated using a double labeling method combined with acrylamide gel electrophoresis. After 16 hours of incubation, gibberellic acid stimulated the incorporation of label into all species of RNA, but the effects were very small (0-10%) for ribosomal and transfer RNA and comparatively large (up to 300%) for RNA sedimenting between 5S and 14S. This result was obtained for both isolated aleurone layers and for layers still attached to the endosperm. A similar but less marked pattern occurred in layers incubated for 8 hours, but the effect was not observed after 4 hours. The gibberellic acid-enhanced RNA labeling was not due to micro-organisms. The following evidence was obtained for an association between the gibberellic acid-enhanced RNA synthesis and α-amylase synthesis: (a) synthesis of α-amylase took place in parallel with incorporation of label into gibberellic acid-RNA; (b) actinomycin D inhibited amylase synthesis and gibberellic acid-RNA by similar percentages; (c) 5-fluorouracil halved incorporation of label into ribosomal RNA but had no effect on amylase synthesis and gibberellic acid-RNA; and (d) abscisic acid had little effect on synthesis of RNA in the absence of gibberellic acid, but when it was included with gibberellic acid the synthesis of both enzyme and gibberellic acid-RNA was eliminated. We conclude that large changes in the synthesis of the major RNA species are not necessary for α-amylase synthesis to occur but that α-amylase synthesis does not occur without the production of gibberrellic acid-RNA. Gibberellic acid-RNA is probably less than 1% of the total tissue RNA, is polydisperse on acrylamide gels, and could be messenger species for α-amylase and other hydrolytic enzymes whose synthesis is under gibberellic acid control.     

The Synthesis of 5s RNA and Its Relationship to 18s and 28s Ribosomal RNA in the Bobbed Mutants of DROSOPHILA MELANOGASTER

Ribosomes contain one molecule each of 5S, 18S and 28S RNA. In Drosophila melanogaster although the genes for 18S+28S are physically separated from the 5S RNA genes, the multiplicity of various ribosomal RNA genes is roughly the same. Thus a coordinate synthesis of these three molecules might seem feasible. This problem has been approached by determining the molar ratios of various RNA's in ovaries and in adult flies. In ovaries there is a slight excess of 5S RNA molecules over other rRNA's, but in adult flies no such differences exist. Bobbed mutants also have the same molar ratios as wild-type flies. Results on 5S RNA synthesis in both in vitro and in vivo studies show that it is reduced in coordination with 18S+28S rRNA in the bobbed mutants of Drosophila melanogaster. Various possibilities are discussed in considering the implications of these results.     

Inhibitor of ribosomal RNA synthesis in Xenopus laevis embryos. V. Inability of inhibitor to repress 5S RNA synthesis.

A specific inhibitor of ribosomal RNA (rRNA) synthesis was partially purified from an acid-soluble fraction of Xenopus laevis blastulae. Effects of this inhibitor on 5S rRNA synthesis of isolated neurula cells of the same species were investigated. The results show that the synthesis of both 5S rRNA and 4S RNA proceeds normally when both 18 and 28S rRNA are almost completely inhibited. Failure of the inhibitor to suppress 5S rRNA synthesis suggests that it plays an important role in the regulation of 18 and 28S rRNA synthesis during development and that the synthesis of 5S rRNA is not coordinated to that of 18 and 28S rRNA.     

Biochemical research on oogenesis. Comparison between the proteins of the ribosomes and the proteins of the 42 S particles from small oocytes of Xenopus laevis

Previtellogenic oocytes of Xenopus laevis synthesize large amounts of 5 S RNA and transfer RNA, but very little, if any, 28 S and 18 S RNA. About half of the RNA of these oocytes is stored in nucleoprotein particles sedimenting at 42 S. These particles contain 5 S RNA, transfer RNA, and several proteins, the function of which remains so far unknown.The proteins of the 42 S particles were analyzed by two-dimensional electrophoresis on polyacrylamide gel. The resulting fingerprints displayed one major and two minor basic spots. None of these coincided with any of the 37 spots produced by the 60 S subunit of the ribosomes and with the 30 spots produced by the 40 S subunit. We conclude that no ribosomal component other than 5 S RNA is present in the 42 S particles.The fingerprints of 40 S and 60 S ribosomal proteins from X. laevis coincided almost completely with the corresponding fingerprints from the rat and the rabbit.     

Biochemical studies of mammalian oogenesis: synthesis and stability of various classes of RNA during growth of the mouse oocyte in vitro

The synthesis of various classes of RNA in mouse oocytes at different stages of growth has been examined after incubating follicles in medium containing radiolabeled uridine. After fractionation on poly(U)-Sepharose of radiolabeled oocyte RNA, of which about 83% is associated with the nucleus after a 5-hr labeling period, revealed that about 40–50% of the radiolabeled RNA behaved as poly(A)-containing RNA. This value remained fairly constant during the period of oocyte growth in which oocyte diameter increased from about 35 to about 55 μm. After a 5-hr labeling, the percentage of radiolabeled poly(A)-containing RNA in either the fully grown dictyate oocyte, metaphase II oocyte, or one-cell embryo was about 20%. After a 5-hr labeling, agarose gel electrophoretic analysis of the radiolabeled species of oocyte RNA obtained after fractionation on poly(U)-Sepharose revealed the presence of a putative ribosomal RNA precursor, ribosomal (28 and 18 S) RNA, transfer plus 5 S RNA and heterodisperse poly(A)-containing RNA. A significant fraction of the radiolabeled RNA species was quite large (>40 S). The ratios of the relative proportions of the radiolabeled ribosomal RNAs and transfer plus 5 S RNA remained essentially constant during oocyte growth. The stability of various classes of RNA was examined by incubating follicles with radiolabeled uridine, washing the follicles free of radioactivity and culturing the follicles under conditions which support oocyte growth in vitro (Eppig, 1977). Under these conditions, total oocyte radiolabeled RNA was quite stable as determined by retention of acid-insoluble radioactive material ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{= 28}\text{days}$). However, under conditions in which oocytes are viable but do not grow, the half-life of total RNA was about 4.5 days. Poly(A)-containing RNA was also very stable; after 8 days in culture, about 50% of the radiolabeled poly(A)-containing RNA present after 5 hr of labeling was still present. Agarose gel electrophoretic analysis of radiolabeled RNA in oocytes after 4 days of culture and after fractionation on poly(U)-Sepharose revealed the presence of ribosomal (28 and 18 S) RNA, transfer plus 5 S RNA, and heterodisperse poly(A)-containing RNA. At this time, these RNAs are located in the oocyte cytoplasm. In addition, the molecular weight distribution of poly(A)-containing RNA was significantly lower than that after 5 hr of labeling. The ratios of the relative proportions of radiolabeled ribosomal RNAs and transfer plus 5 S RNA were quite similar to those after 5 hr of labeling.     

Frequency of N-benzyladenine incorporation into major RNA fractions of tobacco cell suspensions grown at stimulatory or cytostatic cytokinin concentration

The frequency of incorporation of the cytokinin N⁶-[p-³H]benzyladenine into major RNA species of tobacco (Nicotiana tabacum cv W 38) cells steadily increased as a function of its concentration in the culture medium, up to a 10 micromolar cytostatic overdose. During a 55-hour incubation of cells with 0.4 micromolar benzyladenine (BA), which is the optimal concentration for cell division, the incorporation frequency increased to one BA per 1.5 to 2.0 × 10⁴ conventional bases in total RNA. Frequencies of BA incorporation into 18S and 25S rRNA and into RNA precursors were very similar, 2- to 3-fold higher than the frequency of BA incorporation into the 4S + 5S RNA fraction. In cells incubated with 10 micromolar BA, the rate of RNA synthesis between 24 and 55 hours was lower than at optimal growth conditions; 18S and 25S rRNA synthesis was depressed more than the synthesis of 4S + 5S RNA. At 55 hours, BA was incorporated into total RNA at the steady state frequency of one per 1,300 conventional bases. All major RNA species were BA-labeled to approximately the same level, except that the labeling of the RNA precursors was 2-fold higher than the labeling of mature RNA species. These results may reflect an alteration in the processing of the RNA precursors at supra-optimal cytokinin concentration.     

Inhibition of nucleic acid synthesis in Ehrlich tumor cells by periodate-oxidized adenosine and adenylic acid

Periodate-oxidized adenosine and AMP were inhibitory to both RNA and DNA synthesis in Ehrlich tumor cells in culture. With periodate-oxidized adenosine, the inhibition of RNA synthesis paralleled the inhibition of DNA synthesis. Periodate-oxidized AMP, however, was more inhibitory to DNA synthesis than to RNA synthesis. With both compounds, there was a decrease in the conversion of [¹⁴C]cytidine nucleotides to [¹⁴C]deoxycytidine nucleotides in the acid-soluble pool. The borohy-dride-reduced trialcohol derivative of the periodate-oxidized adenosine compound was not inhibitory to DNA or RNA synthesis in the tumor cells. The incorporation of [³H]uridine into 28S and 18S ribosomal RNA was inhibited by both periodate-oxidized adenosine and AMP, but the incorporation of [³H]uridine in 45S, 5S, and 4S RNA was essentially unaffected by these compounds. Periodate-oxidized adenosine inhibited Ehrlich tumor cell growth in vivo.     

Evidence for ribosomal RNA synthesis in pollen tubes in culture

The evidence is presented that pollen tubes ofNicotiana tabacum L. cultivated in shaken suspension do synthesize 5S, 18S and 28S RNA. Following incubation of pollen tubes in the presence of radioactive uracil or uridine, RNA was isolated from total pollen tube material after the removal of 4S RNA, from polysomes and from 80S ribosomal particles, and fractionated by density gradient centrifugation and MAK column chromatography. The results obtained further suggest a higher rate of 5S RNA synthesis with respect to 18S+28S RNA.     

Alteration of 23 S ribosomal RNA and erythromycin-induced resistance to lincomycin and spiramycin in Staphylococcus aureus

Functionally active “hybrid” 50 S ribosomal subunits can be reconstituted using 23 S RNA from Staphylococcus aureus (strain 1206) and 5 S RNA, as well as 50 S ribosomal proteins from Bacillus stearothermophilus. Using this system, resistance of S. aureus 50 S subunits to lincomycin and spiramycin was analyzed. When 23 S RNA from either phenotypically resistant (“induced resistance”) S. aureuscells or derived genetically resistant (“constitutive resistance”) S. aureus cells, were used, the reconstituted 50 S subunits showed the resistant phenotype similar to that seen in native 50 S subunits obtained from resistant cells; only very weak inhibition by the antibiotics was observed in poly (U) - directed polyphenylalanine synthesis involving these 50 S subunits. In contrast, the 50 S particles reconstituted using 23 S RNA from uninduced (sensitive) S. aureus were subject to greater inhibition by the antibiotics in cell-free poly-peptide synthesis. It is concluded that modification of 23 S RNA, presumably the previously observed methylation to form dimethyladenine, is responsible for the resistance to the antibiotics in this strain of S. aureus.     

Quantitative Measurement of Rates of 5S RNA and Transfer RNA Synthesis in Sea Urchin Embryos

Embryonic differentiation is believed to be due to a programmed expression of genes, which includes their time of activation, sequence of appearance, and amount transcribed into the immediate gene product, RNA. Differential synthesis of the major RNA classes, such as the ribosomal RNAs (28S, 18S, 5S) and transfer RNA (tRNA), characterizes many animal developing systems, including the sea urchin embryological system. Previous work has shown that the genes for 5S RNA and tRNA are active during early cleavage in sea urchin embryos. The present study focused on quantitatively measuring and comparing the rate of 5S RNA and tRNA synthesis in cleavage, early blastula, and early pluteus embryos of Arbacia punctulata. At each stage, embryos were labeled for 3 h with [8-³H]-guanosine. Total cellular RNA was extracted using the cold (4°C)-phenol-sodium dodecyl sulfate method and purified (LiCl-soluble) RNA preparations were fractionated by electrophoresis on 10% polyacrylamide gels. The amount of 5S RNA and tRNA synthesized at each stage was calculated from the radioactivity coincident with the 5S RNA and with the tRNA absorbance peaks (A_{260 nm}) on each gel, from the known guanosine monophosphate (GMP) compositions of sea urchin 5S RNA and tRNA and from the average specific radioactivity of the GTP precursor pool during each 3 h labeling period. The results showed that on a per embryo basis the rates of 5S RNA and tRNA synthesis increased slightly (about 1.4-fold) from cleavage through pluteus stages, while on a per cell basis the rates declined severalfold (about 3-fold) during embryogenesis. The rates of 5S RNA and tRNA synthesis determined here parallel previously-reported levels of RNA polymerase III in sea urchin embryos, suggesting that cellular levels of RNA polymerase III may exert some positive control over 5S RNA and tRNA synthesis during sea urchin embryogenesis.     

Biochemical research on oogenesis. RNA accumulation during oogenesis of the dogfish Scyliorhinus caniculus

Four biochemical mechanisms have been shown to operate in the oocytes of amphibians and teleosts: (1) amplification of the 28 S and 18 S genes, (2) noncoordinate accumulation of 5 S RNA and 28 S + 18 S RNA, (3) storage of 5 S and transfer RNA made in excess by small oocytes within nucleoprotein particles, (4) expression of different 5 S genes in oocytes and somatic cells. We have tried to extend these observations to another group of vertebrates, i.e., selacians (Chondrichthya). Our data suggest that ribosomal gene amplification is low or absent in the oocytes of the dogfish Scyliorhinus caniculus. However, previtellogenic oocytes of this species accumulate more 5 S RNA than needed for ribosome assembly. Transfer and 5 S RNA present in small oocytes are probably not free in the cell sap. A substantial fraction of these RNAs sediments at 10 S when homogenates of immature ovaries are centrifuged in sucrose density gradients. In contrast to what we observed in amphibians and teleosts, 5 S RNA from ovaries of S. caniculus is identical in sequence to 5 S RNA from liver. Among the four mechanisms mentioned above, the second and probably the third one are used by the oocytes of S. caniculus. Mechanism (4) is absent in this species. No definitive conclusion can be drawn concerning mechanism (1), i.e., ribosomal gene amplification.     

Changes in rate of RNA synthesis and ribosomal gene number during oogenesis of Drosophila melanogaster.

A new method for separating Drosophila egg chambers into different developmental classes (Jacobs-Lorena and Crippa, 1977) made it possible to study changes in the rate of ribosomal RNA (rRNA), 5S RNA, and tRNA synthesis and the changes in ribosomal gene number during oogenesis. Synthesis of RNA was measured by [³H]uridine incorporation in vivo and subsequent analysis on sucrose gradients or gel electrophoresis. Specific radioactivity of nucleotide pools has also been determined. Ribosomal gene number has been measured by hybridization of egg chamber DNA to rRNA of high specific radioactivity. Our findings led us to conclude that in Drosophila melanogaster: (i) rRNA, 5S RNA, and tRNA are synthesized in all stages of oogenesis. (ii) In every stage, rRNA is the main RNA species synthesized. (iii) The rate of rRNA, 5S RNA, and tRNA synthesis increases greatly during oogenesis and is paralleled by a similar increase in ribosomal gene number resulting from the polyploidization of the nurse cell nuclei.     

Human cytomegalovirus stimulates host cell RNA synthesis.

Human cytomegalovirus infection of human fibroblast cells (WI-38) induced cellular RNA synthesis. The RNA synthesis in infected cultures preceded the synthesis of viral DNA and progeny virus by approximately 24 h. RNA species synthesized in infected cells included ribosomal 28S and 18S; and 4S transfer RNA; all were markedly increased in comparison to uninfected cells. This induction of host cell RNA synthesis was dependent upon a protein(s) that was synthesized during the early stages of infection.