Interaction of bovine mitochondrial ribosomes with messenger RNA

The gene for subunit II of cytochrome oxidase (CoII) from bovine mitochondria has been cloned behind a T7 promoter and the corresponding mRNA synthesized in vitro. The RNA transcribed from this vector has a single nucleotide 5' to the start AUG and, thus, corresponds closely to the native mRNA. It binds to the small 28 S ribosomal subunit of bovine mitochondria but not to the large (39 S) subunit or to 55 S ribosomes. The binding occurs readily in the absence of auxiliary initiation factors or initiator tRNA. The complex formed appears to contain 1 mRNA/28 S subunit. The observed binding is specific for mRNA since neither tRNA nor ribosomal RNA can act as competitive inhibitors. The interaction of the mRNA with the 28 S subunit does not require an AUG codon near the 5' end and constructs containing 5' leaders of more than 100 nucleotides still bind efficiently. About 5% of the bound mRNA is protected from digestion by T1 RNase. The protected fragments do not arise from a specific region of the mRNA since they hybridize to several restriction fragments of the cloned CoII gene.     

RNA synthesis in isolated bovine thyroid nuclei and nucleoli. alpha-Amanitin effect, a hint to the existence of a specific regulatory system

DNA dependent RNA polymerase activities in isolated bovine thyroid nuclei and nucleoli have been studied. They retain their RNA synthetic activity for an extended period of time. This RNA synthetic activity is sensitive to actinomycin D and requires the presence of all four ribonucleoside triphosphates. The optimal conditions have been determined. Polyacrylamide gel electrophoresis reveals that the RNA synthesized has a size distribution ranging from 34S to 4S. The production of 18S-8S RNA is very sensitive to low concentrations of alpha-amanitin. However, in isolated bovine thyroid nuclei (not in nucleoli) this drug displays an effect on all RNA classes produced. The alpha-amanitin induced drastic decrease of [3H]-UMP incorporation in RNA of all sizes synthesized by isolated bovine thyroid nuclei is discussed.     

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.     

The Effects of Chemical Animalizing and Vegetalizing Agents and of Cell Dissociation on the Synthesis of 5S RNA and Transfer RNA in Cleaving Sea Urchin Embryos

The effect of altering normal cell associations and interactions on the synthesis of 5S RNA and transfer RNA (tRNA) was studied in cleaving embryos of the sea urchin, Arbacia punctulata. Cell interactions were altered: (1) by culturing cleaving embryos in the animalizing agent, Evans Blue, and in the vegetalizing agent, Li⁺ as LiCl and (2) by culturing dissociated cells. Control and experimental embryos each were labeled from 3 h to 6 h post fertilization with [8-³H]-guanosine. Sixteen-cell embryos, whose GTP precursor pools had been preloaded, were dissociated, labeled and cultured under conditions which prevent reaggregation. Quantitative measurements of rates of accumulation of newly synthesized 5S RNA and tRNA showed that these rates are similar in cleaving sea urchin embryos and in corresponding embryos cultured in the presence of Evans Blue and of Li⁺. In addition, cells dissociated from cleavage embryos and maintained under conditions which prevent reaggregation retained the ability to synthesize 5S RNA and tRNA. These results suggest that normal cell associations and interactions are not necessary for the synthesis of 5S RNA and tRNA to occur in cleaving sea urchin embryos.     

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.     

Differential effects of cordycepin triphosphate and 9 beta-D-arabinofuranosyladenine triphosphate on tRNA and 5 S RNA synthesis in isolated nuclei.

Although cordycepin 5'-triphosphate (3'-dATP), at low concentrations, preferentially inhibits chromatin-associated poly(A) synthesis in isolated nuclei, higher levels of the inhibitor prevent both rRNA (RNA polymerase I activity) and hnRNA (RNA polymerase II activity) synthesis in vitro (Rose, K.M., Bell, L.E. and Jacob, S.T. (1977) Nature 267, 178-180). The present studies demonstrate that this nucleotide can also inhibit tRNA and 5 S RNA synthesis (RNA polymerase III activity). At 50-200 microgram/ml, 3'-dATP inhibits incorporation of [3H]UTP into tRNA and 5 S RNA by approximately 65%, whereas the syntheses of these RNAs were completely blocked when [3H]GTP was used as the substrate. These data suggest the formation of poly(U) in the tRNA and 5 S RNA regions, which is resistant to 3'-dATP. In contrast, another ATP analog, Ara-ATP, which selectively inhibits poly(A) synthesis, does not block tRNA and 5 S RNA synthesis in isolated nuclei. The production of these RNA species in isolated nuclei is also insensitive to Ara-CTP and 2'-dATP. These data suggest that 3'-dATP exerts general inhibitory effects on RNA synthesis and further substantiate the conclusion that Ara-ATP is a selective inhibitor of the polyadenylation reaction in vitro.     

The major RNA in prosomes of HeLa cells and duck erythroblasts is tRNA(Lys,3).

Two-dimensional gel electrophoresis of HeLa cell prosomal RNAs, 3'-end labeled by RNA ligase, revealed one prominent spot. Determination of a partial sequence at the 3'-end indicated full homology to the 18 nucleotides at the 3'-end of tRNA(Lys,3) from rabbit, the bovine and the human species. An oligonucleotide complementary to the 3'-end of tRNA(Lys,3) hybridized on Northern blots with prosomal RNA from both HeLa cells and duck erythroblasts. In two-dimensional PAGE, the major pRNA of HeLa cells co-migrated with bovine tRNA(Lys,3). Reconstitution of the CCA 3'-end of RNA from both human and duck prosomes, by tRNA-nucleotidyl-transferase, confirmed the tRNA character of this type of RNA. Furthermore, it revealed at least one additional tRNA band about 85 nt long among the prosomal RNA from both species. Finally, confirming an original property of prosomal RNA, we show that in vitro synthesized tRNA(Lys,3) hybridizes stably to duck globin mRNA, and to poly(A)(+)- and poly(A)(-)-RNA from HeLa cells.     

Interaction of RNA with transformed glucocorticoid receptor. II. Identification of the RNA as transfer RNA

An endogenous RNA (designated as PIVB RNA), which is capable of associating with the 4 S glucocorticoid receptor (GR) to generate the 6 S form, has been purified from AtT-20 cells (Ali, M., and Vedeckis, W. V. (1987) J. Biol. Chem., 262, 6771-6777). We describe here the physiochemical properties, GR-RNA interaction characteristics, and the chemical identification of PIVB RNA. 32P-Labeled PIVB RNA was similar to transfer RNA (tRNA) in its sedimentation coefficient (4 S) on sucrose gradients, electrophoretic mobility on formaldehyde-agarose gels, and receptor binding characteristics. The amino acid acceptor activity of PIVB RNA displayed a typical tRNA-dependent saturation curve and was 2-3-fold higher than that of homologous rabbit liver tRNA when tested using rabbit liver aminoacyl-tRNA synthetase. The purified [3H] aminoacyl-PIVB complex was also capable of binding to the 4 S GR to generate the 6 S form. The analysis of PIVB RNA on an acrylamide-urea sequencing gel revealed that it contained a major tRNA of 76 nucleotides and other minor tRNA species of 74 and 78 nucleotides. The identity of the tRNA present in the PIVB RNA was indirectly deduced by analyzing the 3H-amino acids, liberated from the [3H]aminoacyl-PIVB RNA (tRNA) complex, and subsequent analysis on an amino acid analyzer. PIVB RNA mainly contained tRNAArg (51.8%), tRNALys (17.1%), and tRNAHis (9.2%) which together accounted for 78% of the total PIVB tRNA. The remaining 22% of tRNA was contributed by threonine, valine, aspartic acid, alanine, and phenylalanine tRNAs. The GR displayed no species specificity, and tRNA samples from mouse, cow, rabbit, yeast, and Escherichia coli can bind to the mouse 4 S GR to generate the 6 S form. However, PIVB RNA did not affect the sedimentation profiles of albumin, chymotrypsinogen, and histone, indicating that PIVB RNA does not bind to all proteins. Thus, there may exist some specificity both at the level of protein (GR) and the selection of RNA (tRNA). The GR binding to PIVB RNA occurred at low (nM) receptor concentration, and PIVB RNA showed limited capacity to shift 4 S GR to the 6 S form. 22.4 X 10(-11) mol of PIVB RNA can completely shift 4.8 X 10(-13) mol of 4 S GR to 6 S. That is, PIVB RNA has to be in a 500-600-fold excess over the amounts of GR to observe a stable 6 S GR X RNA complex on sucrose gradients. These results conclusively demonstrate that the transformed GR specifically binds to endogenous tRNA.     

Preparative scale fractionation of Escherichai coli robosomal RNA and transfer RNA on Sjepharose 6B

Total Escherichia coli RNA has been fractionated on Sepharose 6B in 0.1 M ammonium acetate, pH 5.0. The elution order was 23S rRNA, 16S rRNA,, 5S rRNA, and tRNA, which is in contrast with the reported elution order of eukaryotic RNA, chromatographed under similar conditions. tRNA was obtained in two regions, well separated from the high molecular weight rRNA but with a slight contamination of 5S rRNA. The capacity is at least 40 A260 units of RNA per ml of gel.     

Effect of heat shock on the synthesis of low molecular weight RNAs in drosophila: Accumulation of a novel form of 5S RNA

The synthesis and stability of low molecular weight RNAs following heat shock in Drosophila melanogaster cell cultures have been examined. When cultures are raised from 25°C to 37°C, the synthesis of tRNA and at least two other low molecular weight RNAs continues at the 25°C rate. 5.8S ribosomal RNA and most of the low molecular weight nuclear RNAs are not synthesized. The synthesis of 5S ribosomal RNA is greatly reduced. A large amount of an RNA of about 135 nucleotides in length accumulates at 37°C. Nucleotide sequence analysis reveals that this RNA is a novel form of 5S RNA with approximately 15 additional nucleotides at its 3′ end.     

Biosynthesis of transfer RNA: isolation and characterization of precursors to transfer RNA in the posterior silkgland of Bombyx mori.

Distinct low molecular weight RNA species that have properties expected for the precursor to tRNA have been isolated from the posterior silkglands of the silkworm Bombyx mori. These RNAs migrate between 4 S and 5 S markers on acrylamide gels and are labeled preferentially in vivo in relation to tRNA. The precursor RNAs can be converted specifically into molecules indistinguishable in size from tRNA upon incubation with “cleavage” enzymes isolated from the silkgland ribosomes. Two of the three low molecular weight RNAs contain the modified residues, pseudouridine, dihydrouridine and ribothymidine, and are methylated in vivo, suggesting that these base modifications occur while the tRNA is still in its precursor stage.