Structural features unique to the 5 S ribosomal RNAs of the thermophilic cyanobacterium Synechococcus lividus III and the green plant chloroplasts

The complete nucleotide sequence of the 5 S ribosomal RNA from the thermophilic cyanobacterium Synechococcus lividus III was determined. The sequence is: ^5′U-C- C-U-G-G-U-G-G-U-G-A-U-G-G-C-G-A-U-G-U-G-G-A-C-C-C-A-C-A-C-U-C-A-U-C- C-A-U-C-C-C-G-A-A-C-U-G-A-G-U-G-G-U-G-A-A-A-C-G-C-A-U-U-U-G-C-G-G-C- G-A-C-G-A-U-A-G-U-U-G-G-A-G-G-G-U-A-G-C-C-U-C-C-U-G-U-C-A-A-A-A-U-A- G-C-U-A-A-C-C-G-C-C-A-G-G-G-U_OH^3′This 5 S RNA has regional structural characteristics that are found in the green plant chloroplast 5 S RNAs and not in other known sequences of 5 S ribosomal RNAs. These homologies suggest a close phylogenetic relationship between S. lividus and the green plant chloroplasts.     

Primary hematopoietic cells from DBA patients with mutations in RPL11 and RPS19 genes exhibit distinct erythroid phenotype in vitro

Diamond-Blackfan anemia (DBA) is caused by aberrant ribosomal biogenesis due to ribosomal protein (RP) gene mutations. To develop mechanistic understanding of DBA pathogenesis, we studied CD34⁺ cells from peripheral blood of DBA patients carrying RPL11 and RPS19 ribosomal gene mutations and determined their ability to undergo erythroid differentiation in vitro. RPS19 mutations induced a decrease in proliferation of progenitor cells, but the terminal erythroid differentiation was normal with little or no apoptosis. This phenotype was related to a G₀/G₁ cell cycle arrest associated with activation of the p53 pathway. In marked contrast, RPL11 mutations led to a dramatic decrease in progenitor cell proliferation and a delayed erythroid differentiation with a marked increase in apoptosis and G₀/G₁ cell cycle arrest with activation of p53. Infection of cord blood CD34⁺ cells with specific short hairpin (sh) RNAs against RPS19 or RPL11 recapitulated the two distinct phenotypes in concordance with findings from primary cells. In both cases, the phenotype has been reverted by shRNA p53 knockdown. These results show that p53 pathway activation has an important role in pathogenesis of DBA and can be independent of the RPL11 pathway. These findings shed new insights into the pathogenesis of DBA.     

Human DIMT1 generates N26,6A-dimethylation–containing small RNAs

Dimethyladenosine transferase 1 (DIMT1) is an evolutionarily conserved RNA N^6,6-dimethyladenosine (m₂^6,6A) methyltransferase. DIMT1 plays an important role in ribosome biogenesis, and the catalytic activity of DIMT1 is indispensable for cell viability and protein synthesis. A few RNA-modifying enzymes can install the same modification in multiple RNA species. However, whether DIMT1 can work on RNA species other than 18S rRNA is unclear. Here, we describe that DIMT1 generates m₂^6,6A not only in 18S rRNA but also in small RNAs. In addition, m₂^6,6A in small RNAs were significantly decreased in cells expressing catalytically inactive DIMT1 variants (E85A or NLPY variants) compared with cells expressing wildtype DIMT1. Both E85A and NLPY DIMT1 variant cells present decreased protein synthesis and cell viability. Furthermore, we observed that DIMT1 is highly expressed in human cancers, including acute myeloid leukemia. Our data suggest that downregulation of DIMT1 in acute myeloid leukemia cells leads to a decreased m₂^6,6A level in small RNAs. Together, these data suggest that DIMT1 not only installs m₂^6,6A in 18S rRNA but also generates m₂^6,6A-containing small RNAs, both of which potentially contribute to the impact of DIMT1 on cell viability and gene expression.     

A common conformational feature in several prokaryotic and eukaryotic 5 S RNAs: a highly exposed, single-stranded loop around position 40

Psendomonas fluorescens, yeast and HeLa cells ³²P-labelled 5 S RNAs were submitted to partial hydrolysis with T₁, T₂ or pancreatic ribonucleases; the fragments were separated by two-dimensional acrylamide gel electrophoresis. First splits (obtained when only one cleavage takes place in the molecule) were found to occur essentially around position 40 in the sequence, as already demonstrated for Escherichia coli 5 S RNA. The existence in prokaryotic and eukaryotic 5 S RNAs of this very accessible region is thus proved. Eukaryotic 5 S RNAs also display a very accessible region around position 90 of the sequence.     

Formaldehyde-containing slab gels for analysis of denatured, tritium-labeled RNA

Procedures were adapted for electrophoretic analysis and fluorography of ³H-labeled RNA (molecular length 300–4000 nucleotides) in formaldehyde-containing, agarose-acrylamide slab gels. This system gave sharp banding of denatured RNA and accurate molecular length determination using T7 early RNAs and Escherichia coli ribosomal RNAs as standards.     

Chloroplast ribosomal RNA genes in Euglena gracilis exist as three clustered tandem repeats

Chloroplast ribosomal DNA from Euglena gracilis was partially purified, digested with restriction endonucleases BamHI or EcoRI and cloned into bacterial plasmids. Plasmids containing the ribosomal DNA were identified by their ability to hybridize to chloroplast ribosomal RNA and were physically mapped using restriction endonucleases BamHI, EcoRI, HindIII and HpaI. The nucleotide sequences coding for the 16S and the 23S chloroplast ribosomal RNAs were located on these plasmids by hybridizing the individual RNAs to denatured restriction endonuclease DNA fragments immobilized on nitrocellulose filters. Restriction endonuclease fragments from chloroplast DNA were analyzed in a similar fashion. These data permitted the localization on a BamHI map of the chloroplast DNA three tandemly arranged chloroplast ribosomal RNA genes. Each ribosomal RNA gene consisted of a 4.6 kilobase pair region coding for the 16S and 23S ribosomal RNAs and a 0.8 kilobase pair spacer region. The chloroplast ribosomal DNA represented 12% of the chloroplast DNA and is G + C rich.     

Balanced Production of Ribosome Components Is Required for Proper G1/S Transition in Saccharomyces cerevisiae

Cell cycle regulation is a very accurate process that ensures cell viability and the genomic integrity of daughter cells. A fundamental part of this regulation consists in the arrest of the cycle at particular points to ensure the completion of a previous event, to repair cellular damage, or to avoid progression in potentially risky situations. In this work, we demonstrate that a reduction in nucleotide levels or the depletion of RNA polymerase I or III subunits generates a cell cycle delay at the G₁/S transition in Saccharomyces cerevisiae. This delay is concomitant with an imbalance between ribosomal RNAs and proteins which, among others, provokes an accumulation of free ribosomal protein L5. Consistently with a direct impact of free L5 on the G₁/S transition, rrs1 mutants, which weaken the assembly of L5 and L11 on pre-60S ribosomal particles, enhance both the G₁/S delay and the accumulation of free ribosomal protein L5. We propose the existence of a surveillance mechanism that couples the balanced production of yeast ribosomal components and cell cycle progression through the accumulation of free ribosomal proteins. This regulatory pathway resembles the p53-dependent nucleolar-stress checkpoint response described in human cells, which indicates that this is a general control strategy extended throughout eukaryotes.     

RNA metabolism during light-induced chloroplast development in euglena

Methods are described which provide good recoveries of non-degraded chloroplast and non-chloroplast RNAs from Euglena gracilis var. bacillaris. These have been characterized by comparing the RNA from W₃BUL (an aplastidic mutant of Euglena), with that of wild-type cells which have been resolved into chloroplast and non-chloroplast fractions. Using E. coli RNA as a standard, the RNAs from W₃BUL and from the non-chloroplast fraction of green cells exhibit optical density peaks, upon sucrose gradient centrifugation, at 4S, 10S, and 19S. The chloroplast fraction exhibits optical density peaks at 19S and 14S with the 19S component predominating. Application of various techniques for the separation of RNAs to the problem of separating the chloroplast and non-chloroplast RNAs, without prior separation of the organelle, have not proven successful.

³²P_i is readily incorporated into RNA by cells undergoing light-induced chloroplast development, and fractionation at the end of development reveals that although chloroplast RNAs have a higher specific activity, the other RNAs of the cells are significantly labeled as well. The succession of labeling patterns of total cellular RNA as light-induced chloroplast development proceeds are displayed and reveal that all RNA species mentioned above eventually become labeled. In contrast, cells kept in darkness during this period incorporate little ³²P_i into any RNA fraction. In addition, a heavy RNA component, designated as 28S, while representing a negligible fraction of the total RNA, becomes significantly labeled during the first 24 hours of illumination. While there is light stimulated uptake of ³²P_i into the cells, this uptake is never limiting in the light or dark, for RNA labeling.

On the basis of these findings, we suggest that extensive activation of non-chloroplast RNA labeling during chloroplast development is the result of the activation of the cellular synthetic machinery external to the chloroplast necessary to provide metabolic precursors for plastid development. Thus the plastid is viewed as an auxotrophic resident within the cell during development. Other possibilities for interaction at this and other levels are also discussed.

     

Nature of the ribosomal RNA transcribed from the X and Y chromosomes of Drosophila melanogaster

In Drosophila melanogaster there is one nucleolar organizer (NO) on each X and Y chromosome. Experiments were carried out to compare the ribosomal RNAs derived from the two nucleolar organizers. ³²PO₄-labelled ribosomal RNA was isolated from two strains of D. melanogaster, one containing only the X chromosome NO, the other containing only the Y chromosome NO. 28 S and 18 S RNA from the two strains were subjected to a variety of “fingerprinting” and sequencing procedures. Fingerprints of 28 S RNA were very different from those of 18 S RNA. Fingerprints of “X” and “Y” 28 S RNA were indistinguishable from each other, as also were fingerprints of “X” and “Y” 18 S RNA. In combined “T₁ plus pancreatic” RNAase fingerprints several distinctive products were characterized and quantitated. Identical products were obtained from X and Y RNA, and the molar yields of the products were indistinguishable. Together these findings imply that the rRNA sequences encoded by the X and Y NOs are closely similar and probably identical to each other.Two further findings were of interest in “T₁ plus pancreatic” RNAase fingerprints: (1) in 28 S (as well as in 18 S) fingerprints several distinctive products were recovered in approximately unimolar yields. This indicates that 28 S RNA does not consist of two identical half molecules, though it does consist of two non-identical half molecules together with a “5.8 S” fragment. (2) Several methylated components in Drosophila rRNA also occur in rRNA from HeLa cells and yeast. This suggests that certain features of rRNA structure involving methylated nucleotides may be highly conserved in eukaryotic evolution.     

Detection of specific sequences among DNA fragments separated by gel electrophoresis.

Ribosomal RNA and precursor ribosomal RNA from at least one representative of each vertebrate class have been analyzed by electron microscopic secondary structure mapping. Reproducible patterns of hairpin loops were found in both 28 S ribosomal and precursor ribosomal RNA, whereas almost all the 18 S ribosomal RNA molecules lack secondary structure under the spreading conditions used. The precursor ribosomal RNA of all species analyzed have a common design. The 28 S ribosomal RNA is located at or near the presumed 5′-end and is separated from the 18 S ribosomal RNA region by the internal spacer region. In addition there is an external spacer region at the 3′-end of all precursor ribosomal RNA molecules. Changes in the length of these spacer regions are mainly responsible for the increase in size of the precursor ribosomal RNA during vertebrate evolution. In cold blooded vertebrates the precursor contains two short spacer regions; in birds the precursor bears a long internal and a short external spacer region, and in mammals it has two long spacer regions. The molecular weights, as determined from the electron micrographs, are 2·6 to 2·8 × 10⁶ for the precursor ribosomal RNA of cold blooded vertebrates, 3·7 to 3·9 × 10⁶ for the precursor of birds, and 4·2 to 4·7 × 10⁶ for the mammalian precursor. Ribosomal RNA and precursor ribosomal RNA of mammals have a higher proportion of secondary structure loops when compared to lower vertebrates. This observation was confirmed by digesting ribosomal RNAs and precursor ribosomal RNAs with single-strandspecific S₁ nuclease in aqueous solution. Analysis of the double-stranded, S₁-resistant fragments indicates that there is a direct relationship between the hairpin loops seen in the electron microscope and secondary structure in aqueous solution.     

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.     

Protein synthesis in rabbit reticulocytes. XIII. Lack of mRNA (poly r (A)) binding activity in highly purified EIF-1.

Met-tRNA_f^Met binding factor (EIF-1) has been purified more than 100 fold over crude high salt (0.5 M KCl) ribosomal wash. The purified factor binds 2 nmoles Met-tRNA_f^Met per mg protein and shows very little poly r(A) binding activity. Crude ribosomal high salt wash possesses significant amounts of poly r(A) binding activity and also binds to other RNAs. The bulk of this unspecific RNA binding protein is separated from EIF-1 by DEAE-cellulose chromatography.     

Effect of light on ribonucleic Acid metabolism in greening maize leaves

The effect of illumination on the incorporation of labeled precursors into RNA of dark-grown maize (Zea mays) leaves was studied using either ³²P-phosphate or double labeling with ¹⁴C- and ³H-uridine. In the dark, label was preferentially incorporated into etioplast ribosomal RNAs. Incorporation into this fraction and into lower molecular weight fractions was strongly and preferentially stimulated by light during the first 2 hours of illumination. The effect persisted after illumination was terminated. The possibility that light-induced alterations in plastid ribosomal RNA metabolism may not be required for chlorophyll accumulation in maize is discussed.